/** ****************************************************************************** * @file SDIO/sdcard.c * @author MCD Application Team * @version V3.1.2 * @date 09/28/2009 * @brief This file provides all the SD Card driver firmware functions. ****************************************************************************** * @copy * * THE PRESENT FIRMWARE WHICH IS FOR GUIDANCE ONLY AIMS AT PROVIDING CUSTOMERS * WITH CODING INFORMATION REGARDING THEIR PRODUCTS IN ORDER FOR THEM TO SAVE * TIME. AS A RESULT, STMICROELECTRONICS SHALL NOT BE HELD LIABLE FOR ANY * DIRECT, INDIRECT OR CONSEQUENTIAL DAMAGES WITH RESPECT TO ANY CLAIMS ARISING * FROM THE CONTENT OF SUCH FIRMWARE AND/OR THE USE MADE BY CUSTOMERS OF THE * CODING INFORMATION CONTAINED HEREIN IN CONNECTION WITH THEIR PRODUCTS. * *

© COPYRIGHT 2009 STMicroelectronics

*/ /* Includes ------------------------------------------------------------------*/ #include "sdcard.h" #include "stm32f10x_dma.h" #include "stm32f10x_sdio.h" #include "stdbool.h" #include /** @addtogroup STM32F10x_StdPeriph_Examples * @{ */ /** @addtogroup SDIO_Example * @{ */ /* Private typedef -----------------------------------------------------------*/ /* Private define ------------------------------------------------------------*/ #define NULL 0 #define SDIO_STATIC_FLAGS ((uint32_t)0x000005FF) #define SDIO_CMD0TIMEOUT ((uint32_t)0x00002710) #define SDIO_FIFO_Address ((uint32_t)0x40018080) /* Mask for errors Card Status R1 (OCR Register) */ #define SD_OCR_ADDR_OUT_OF_RANGE ((uint32_t)0x80000000) #define SD_OCR_ADDR_MISALIGNED ((uint32_t)0x40000000) #define SD_OCR_BLOCK_LEN_ERR ((uint32_t)0x20000000) #define SD_OCR_ERASE_SEQ_ERR ((uint32_t)0x10000000) #define SD_OCR_BAD_ERASE_PARAM ((uint32_t)0x08000000) #define SD_OCR_WRITE_PROT_VIOLATION ((uint32_t)0x04000000) #define SD_OCR_LOCK_UNLOCK_FAILED ((uint32_t)0x01000000) #define SD_OCR_COM_CRC_FAILED ((uint32_t)0x00800000) #define SD_OCR_ILLEGAL_CMD ((uint32_t)0x00400000) #define SD_OCR_CARD_ECC_FAILED ((uint32_t)0x00200000) #define SD_OCR_CC_ERROR ((uint32_t)0x00100000) #define SD_OCR_GENERAL_UNKNOWN_ERROR ((uint32_t)0x00080000) #define SD_OCR_STREAM_READ_UNDERRUN ((uint32_t)0x00040000) #define SD_OCR_STREAM_WRITE_OVERRUN ((uint32_t)0x00020000) #define SD_OCR_CID_CSD_OVERWRIETE ((uint32_t)0x00010000) #define SD_OCR_WP_ERASE_SKIP ((uint32_t)0x00008000) #define SD_OCR_CARD_ECC_DISABLED ((uint32_t)0x00004000) #define SD_OCR_ERASE_RESET ((uint32_t)0x00002000) #define SD_OCR_AKE_SEQ_ERROR ((uint32_t)0x00000008) #define SD_OCR_ERRORBITS ((uint32_t)0xFDFFE008) /* Masks for R6 Response */ #define SD_R6_GENERAL_UNKNOWN_ERROR ((uint32_t)0x00002000) #define SD_R6_ILLEGAL_CMD ((uint32_t)0x00004000) #define SD_R6_COM_CRC_FAILED ((uint32_t)0x00008000) #define SD_VOLTAGE_WINDOW_SD ((uint32_t)0x80100000) #define SD_HIGH_CAPACITY ((uint32_t)0x40000000) #define SD_STD_CAPACITY ((uint32_t)0x00000000) #define SD_CHECK_PATTERN ((uint32_t)0x000001AA) #define SD_VOLTAGE_WINDOW_MMC ((uint32_t)0x80FF8000) #define SD_MAX_VOLT_TRIAL ((uint32_t)0x0000FFFF) #define SD_ALLZERO ((uint32_t)0x00000000) #define SD_WIDE_BUS_SUPPORT ((uint32_t)0x00040000) #define SD_SINGLE_BUS_SUPPORT ((uint32_t)0x00010000) #define SD_CARD_LOCKED ((uint32_t)0x02000000) #define SD_CARD_PROGRAMMING ((uint32_t)0x00000007) #define SD_CARD_RECEIVING ((uint32_t)0x00000006) #define SD_DATATIMEOUT ((uint32_t)0xFFFFFFFF) #define SD_0TO7BITS ((uint32_t)0x000000FF) #define SD_8TO15BITS ((uint32_t)0x0000FF00) #define SD_16TO23BITS ((uint32_t)0x00FF0000) #define SD_24TO31BITS ((uint32_t)0xFF000000) #define SD_MAX_DATA_LENGTH ((uint32_t)0x01FFFFFF) #define SD_HALFFIFO ((uint32_t)0x00000008) #define SD_HALFFIFOBYTES ((uint32_t)0x00000020) /* Command Class Supported */ #define SD_CCCC_LOCK_UNLOCK ((uint32_t)0x00000080) #define SD_CCCC_WRITE_PROT ((uint32_t)0x00000040) #define SD_CCCC_ERASE ((uint32_t)0x00000020) /* Following commands are SD Card Specific commands. SDIO_APP_CMD should be sent before sending these commands. */ #define SDIO_SEND_IF_COND ((uint32_t)0x00000008) #define SDIO_INIT_CLK_DIV ((uint8_t)0xB2) #define SDIO_TRANSFER_CLK_DIV ((uint8_t)0x1) /* Private macro -------------------------------------------------------------*/ /* Private variables ---------------------------------------------------------*/ static uint32_t CardType = SDIO_STD_CAPACITY_SD_CARD_V1_1; static uint32_t CSD_Tab[4], CID_Tab[4], RCA = 0; static uint32_t DeviceMode = SD_POLLING_MODE; static uint32_t TotalNumberOfBytes = 0, StopCondition = 0; uint32_t *SrcBuffer, *DestBuffer; volatile SD_Error TransferError = SD_OK; __IO uint32_t TransferEnd = 0; __IO uint32_t NumberOfBytes = 0; SDIO_InitTypeDef SDIO_InitStructure; SDIO_CmdInitTypeDef SDIO_CmdInitStructure; SDIO_DataInitTypeDef SDIO_DataInitStructure; /* Private function prototypes -----------------------------------------------*/ static SD_Error CmdError(void); static SD_Error CmdResp1Error(uint8_t cmd); static SD_Error CmdResp7Error(void); static SD_Error CmdResp3Error(void); static SD_Error CmdResp2Error(void); static SD_Error CmdResp6Error(uint8_t cmd, uint16_t *prca); static SD_Error SDEnWideBus(FunctionalState NewState); static SD_Error IsCardProgramming(uint8_t *pstatus); static SD_Error FindSCR(uint16_t rca, uint32_t *pscr); static uint8_t convert_from_bytes_to_power_of_two(uint16_t NumberOfBytes); static void GPIO_Configuration(void); static void DMA_TxConfiguration(uint32_t *BufferSRC, uint32_t BufferSize); static void DMA_RxConfiguration(uint32_t *BufferDST, uint32_t BufferSize); /* Private functions ---------------------------------------------------------*/ /** * @brief Initializes the SD Card and put it into StandBy State (Ready * for data transfer). * @param None * @retval SD_Error: SD Card Error code. */ SD_Error SD_Init(void) { SD_Error errorstatus = SD_OK; /* Configure SDIO interface GPIO */ GPIO_Configuration(); /* Enable the SDIO AHB Clock */ RCC_AHBPeriphClockCmd(RCC_AHBPeriph_SDIO, ENABLE); /* Enable the DMA2 Clock */ RCC_AHBPeriphClockCmd(RCC_AHBPeriph_DMA2, ENABLE); SDIO_DeInit(); errorstatus = SD_PowerON(); if (errorstatus != SD_OK) { /* CMD Response TimeOut (wait for CMDSENT flag) */ return(errorstatus); } errorstatus = SD_InitializeCards(); if (errorstatus != SD_OK) { /* CMD Response TimeOut (wait for CMDSENT flag) */ return(errorstatus); } /* Configure the SDIO peripheral */ /* HCLK = 72 MHz, SDIOCLK = 72 MHz, SDIO_CK = HCLK/(2 + 1) = 24 MHz */ SDIO_InitStructure.SDIO_ClockDiv = SDIO_TRANSFER_CLK_DIV; SDIO_InitStructure.SDIO_ClockEdge = SDIO_ClockEdge_Rising; SDIO_InitStructure.SDIO_ClockBypass = SDIO_ClockBypass_Disable; SDIO_InitStructure.SDIO_ClockPowerSave = SDIO_ClockPowerSave_Disable; SDIO_InitStructure.SDIO_BusWide = SDIO_BusWide_1b; SDIO_InitStructure.SDIO_HardwareFlowControl = SDIO_HardwareFlowControl_Enable; SDIO_Init(&SDIO_InitStructure); return(errorstatus); } /** * @brief Enquires cards about their operating voltage and configures * clock controls. * @param None * @retval SD_Error: SD Card Error code. */ SD_Error SD_PowerON(void) { SD_Error errorstatus = SD_OK; uint32_t response = 0, count = 0, i = 0; bool validvoltage = false; uint32_t SDType = SD_STD_CAPACITY; /* Power ON Sequence -------------------------------------------------------*/ /* Configure the SDIO peripheral */ SDIO_InitStructure.SDIO_ClockDiv = SDIO_INIT_CLK_DIV; /* HCLK = 72MHz, SDIOCLK = 72MHz, SDIO_CK = HCLK/(178 + 2) = 400 KHz */ SDIO_InitStructure.SDIO_ClockEdge = SDIO_ClockEdge_Rising; SDIO_InitStructure.SDIO_ClockBypass = SDIO_ClockBypass_Disable; SDIO_InitStructure.SDIO_ClockPowerSave = SDIO_ClockPowerSave_Disable; SDIO_InitStructure.SDIO_BusWide = SDIO_BusWide_1b; SDIO_InitStructure.SDIO_HardwareFlowControl = SDIO_HardwareFlowControl_Disable; SDIO_Init(&SDIO_InitStructure); /* Set Power State to ON */ SDIO_SetPowerState(SDIO_PowerState_ON); /* Enable SDIO Clock */ SDIO_ClockCmd(ENABLE); /* CMD0: GO_IDLE_STATE -------------------------------------------------------*/ /* No CMD response required */ SDIO_CmdInitStructure.SDIO_Argument = 0x0; SDIO_CmdInitStructure.SDIO_CmdIndex = SDIO_GO_IDLE_STATE; SDIO_CmdInitStructure.SDIO_Response = SDIO_Response_No; SDIO_CmdInitStructure.SDIO_Wait = SDIO_Wait_No; SDIO_CmdInitStructure.SDIO_CPSM = SDIO_CPSM_Enable; for(i = 0; i < 74; i++) { SDIO_SendCommand(&SDIO_CmdInitStructure); errorstatus = CmdError(); } if (errorstatus != SD_OK) { /* CMD Response TimeOut (wait for CMDSENT flag) */ return(errorstatus); } /* CMD8: SEND_IF_COND --------------------------------------------------------*/ /* Send CMD8 to verify SD card interface operating condition */ /* Argument: - [31:12]: Reserved (shall be set to '0') - [11:8]: Supply Voltage (VHS) 0x1 (Range: 2.7-3.6 V) - [7:0]: Check Pattern (recommended 0xAA) */ /* CMD Response: R7 */ SDIO_CmdInitStructure.SDIO_Argument = SD_CHECK_PATTERN; SDIO_CmdInitStructure.SDIO_CmdIndex = SDIO_SEND_IF_COND; SDIO_CmdInitStructure.SDIO_Response = SDIO_Response_Short; SDIO_CmdInitStructure.SDIO_Wait = SDIO_Wait_No; SDIO_CmdInitStructure.SDIO_CPSM = SDIO_CPSM_Enable; SDIO_SendCommand(&SDIO_CmdInitStructure); errorstatus = CmdResp7Error(); if (errorstatus == SD_OK) { CardType = SDIO_STD_CAPACITY_SD_CARD_V2_0; /* SD Card 2.0 */ SDType = SD_HIGH_CAPACITY; } else { /* CMD55 */ SDIO_CmdInitStructure.SDIO_Argument = 0x00; SDIO_CmdInitStructure.SDIO_CmdIndex = SDIO_APP_CMD; SDIO_CmdInitStructure.SDIO_Response = SDIO_Response_Short; SDIO_CmdInitStructure.SDIO_Wait = SDIO_Wait_No; SDIO_CmdInitStructure.SDIO_CPSM = SDIO_CPSM_Enable; SDIO_SendCommand(&SDIO_CmdInitStructure); errorstatus = CmdResp1Error(SDIO_APP_CMD); } /* CMD55 */ SDIO_CmdInitStructure.SDIO_Argument = 0x00; SDIO_CmdInitStructure.SDIO_CmdIndex = SDIO_APP_CMD; SDIO_CmdInitStructure.SDIO_Response = SDIO_Response_Short; SDIO_CmdInitStructure.SDIO_Wait = SDIO_Wait_No; SDIO_CmdInitStructure.SDIO_CPSM = SDIO_CPSM_Enable; SDIO_SendCommand(&SDIO_CmdInitStructure); errorstatus = CmdResp1Error(SDIO_APP_CMD); /* If errorstatus is Command TimeOut, it is a MMC card */ /* If errorstatus is SD_OK it is a SD card: SD card 2.0 (voltage range mismatch) or SD card 1.x */ if (errorstatus == SD_OK) { /* SD CARD */ /* Send ACMD41 SD_APP_OP_COND with Argument 0x80100000 */ while ((!validvoltage) && (count < SD_MAX_VOLT_TRIAL)) { /* SEND CMD55 APP_CMD with RCA as 0 */ SDIO_CmdInitStructure.SDIO_Argument = 0x00; SDIO_CmdInitStructure.SDIO_CmdIndex = SDIO_APP_CMD; SDIO_CmdInitStructure.SDIO_Response = SDIO_Response_Short; SDIO_CmdInitStructure.SDIO_Wait = SDIO_Wait_No; SDIO_CmdInitStructure.SDIO_CPSM = SDIO_CPSM_Enable; SDIO_SendCommand(&SDIO_CmdInitStructure); errorstatus = CmdResp1Error(SDIO_APP_CMD); if (errorstatus != SD_OK) { return(errorstatus); } SDIO_CmdInitStructure.SDIO_Argument = SD_VOLTAGE_WINDOW_SD | SDType; SDIO_CmdInitStructure.SDIO_CmdIndex = SDIO_SD_APP_OP_COND; SDIO_CmdInitStructure.SDIO_Response = SDIO_Response_Short; SDIO_CmdInitStructure.SDIO_Wait = SDIO_Wait_No; SDIO_CmdInitStructure.SDIO_CPSM = SDIO_CPSM_Enable; SDIO_SendCommand(&SDIO_CmdInitStructure); errorstatus = CmdResp3Error(); if (errorstatus != SD_OK) { return(errorstatus); } response = SDIO_GetResponse(SDIO_RESP1); validvoltage = (bool) (((response >> 31) == 1) ? 1 : 0); count++; } if (count >= SD_MAX_VOLT_TRIAL) { errorstatus = SD_INVALID_VOLTRANGE; return(errorstatus); } if (response &= SD_HIGH_CAPACITY) { CardType = SDIO_HIGH_CAPACITY_SD_CARD; } }/* else MMC Card */ else { CardType = SDIO_MULTIMEDIA_CARD; /* Send CMD1 SEND_OP_COND with Argument 0x80FF8000 */ while ((!validvoltage) && (count < SD_MAX_VOLT_TRIAL)) { /* SEND CMD55 APP_CMD with RCA as 0 */ SDIO_CmdInitStructure.SDIO_Argument = SD_VOLTAGE_WINDOW_MMC; SDIO_CmdInitStructure.SDIO_CmdIndex = SDIO_SEND_OP_COND; SDIO_CmdInitStructure.SDIO_Response = SDIO_Response_Short; SDIO_CmdInitStructure.SDIO_Wait = SDIO_Wait_No; SDIO_CmdInitStructure.SDIO_CPSM = SDIO_CPSM_Enable; SDIO_SendCommand(&SDIO_CmdInitStructure); errorstatus = CmdResp3Error(); if (errorstatus != SD_OK) { return(errorstatus); } response = SDIO_GetResponse(SDIO_RESP1); validvoltage = (bool) (((response >> 31) == 1) ? 1 : 0); count++; } if (count >= SD_MAX_VOLT_TRIAL) { errorstatus = SD_INVALID_VOLTRANGE; return(errorstatus); } } return(SD_OK); } /** * @brief Turns the SDIO output signals off. * @param None * @retval SD_Error: SD Card Error code. */ SD_Error SD_PowerOFF(void) { SD_Error errorstatus = SD_OK; /* Set Power State to OFF */ SDIO_SetPowerState(SDIO_PowerState_OFF); return(errorstatus); } /** * @brief Intialises all cards or single card as the case may be. * Card(s) come into standby state. * @param None * @retval SD_Error: SD Card Error code. */ SD_Error SD_InitializeCards(void) { SD_Error errorstatus = SD_OK; uint16_t rca = 0x01; if (SDIO_GetPowerState() == SDIO_PowerState_OFF) { errorstatus = SD_REQUEST_NOT_APPLICABLE; return(errorstatus); } if (SDIO_SECURE_DIGITAL_IO_CARD != CardType) { /* Send CMD2 ALL_SEND_CID */ SDIO_CmdInitStructure.SDIO_Argument = 0x0; SDIO_CmdInitStructure.SDIO_CmdIndex = SDIO_ALL_SEND_CID; SDIO_CmdInitStructure.SDIO_Response = SDIO_Response_Long; SDIO_CmdInitStructure.SDIO_Wait = SDIO_Wait_No; SDIO_CmdInitStructure.SDIO_CPSM = SDIO_CPSM_Enable; SDIO_SendCommand(&SDIO_CmdInitStructure); errorstatus = CmdResp2Error(); if (SD_OK != errorstatus) { return(errorstatus); } CID_Tab[0] = SDIO_GetResponse(SDIO_RESP1); CID_Tab[1] = SDIO_GetResponse(SDIO_RESP2); CID_Tab[2] = SDIO_GetResponse(SDIO_RESP3); CID_Tab[3] = SDIO_GetResponse(SDIO_RESP4); } if ((SDIO_STD_CAPACITY_SD_CARD_V1_1 == CardType) || (SDIO_STD_CAPACITY_SD_CARD_V2_0 == CardType) || (SDIO_SECURE_DIGITAL_IO_COMBO_CARD == CardType) || (SDIO_HIGH_CAPACITY_SD_CARD == CardType)) { /* Send CMD3 SET_REL_ADDR with argument 0 */ /* SD Card publishes its RCA. */ SDIO_CmdInitStructure.SDIO_Argument = 0x00; SDIO_CmdInitStructure.SDIO_CmdIndex = SDIO_SET_REL_ADDR; SDIO_CmdInitStructure.SDIO_Response = SDIO_Response_Short; SDIO_CmdInitStructure.SDIO_Wait = SDIO_Wait_No; SDIO_CmdInitStructure.SDIO_CPSM = SDIO_CPSM_Enable; SDIO_SendCommand(&SDIO_CmdInitStructure); errorstatus = CmdResp6Error(SDIO_SET_REL_ADDR, &rca); if (SD_OK != errorstatus) { return(errorstatus); } } if (SDIO_MULTIMEDIA_CARD == CardType) { /* Send CMD3 SET_REL_ADDR with argument 0 */ /* SD Card publishes its RCA. */ SDIO_CmdInitStructure.SDIO_Argument = (uint32_t)(rca << 16); SDIO_CmdInitStructure.SDIO_CmdIndex = SDIO_SET_REL_ADDR; SDIO_CmdInitStructure.SDIO_Response = SDIO_Response_Short; SDIO_CmdInitStructure.SDIO_Wait = SDIO_Wait_No; SDIO_CmdInitStructure.SDIO_CPSM = SDIO_CPSM_Enable; SDIO_SendCommand(&SDIO_CmdInitStructure); errorstatus = CmdResp2Error(); if (SD_OK != errorstatus) { return(errorstatus); } } if (SDIO_SECURE_DIGITAL_IO_CARD != CardType) { RCA = rca; /* Send CMD9 SEND_CSD with argument as card's RCA */ SDIO_CmdInitStructure.SDIO_Argument = (uint32_t)(rca << 16); SDIO_CmdInitStructure.SDIO_CmdIndex = SDIO_SEND_CSD; SDIO_CmdInitStructure.SDIO_Response = SDIO_Response_Long; SDIO_CmdInitStructure.SDIO_Wait = SDIO_Wait_No; SDIO_CmdInitStructure.SDIO_CPSM = SDIO_CPSM_Enable; SDIO_SendCommand(&SDIO_CmdInitStructure); errorstatus = CmdResp2Error(); if (SD_OK != errorstatus) { return(errorstatus); } CSD_Tab[0] = SDIO_GetResponse(SDIO_RESP1); CSD_Tab[1] = SDIO_GetResponse(SDIO_RESP2); CSD_Tab[2] = SDIO_GetResponse(SDIO_RESP3); CSD_Tab[3] = SDIO_GetResponse(SDIO_RESP4); } errorstatus = SD_OK; /* All cards get intialized */ return(errorstatus); } /** * @brief Returns information about specific card. * @param cardinfo : pointer to a SD_CardInfo structure * that contains all SD card information. * @retval SD_Error: SD Card Error code. */ SD_Error SD_GetCardInfo(SD_CardInfo *cardinfo) { SD_Error errorstatus = SD_OK; uint8_t tmp = 0; cardinfo->CardType = (uint8_t)CardType; cardinfo->RCA = (uint16_t)RCA; /* Byte 0 */ tmp = (uint8_t)((CSD_Tab[0] & 0xFF000000) >> 24); cardinfo->SD_csd.CSDStruct = (tmp & 0xC0) >> 6; cardinfo->SD_csd.SysSpecVersion = (tmp & 0x3C) >> 2; cardinfo->SD_csd.Reserved1 = tmp & 0x03; /* Byte 1 */ tmp = (uint8_t)((CSD_Tab[0] & 0x00FF0000) >> 16); cardinfo->SD_csd.TAAC = tmp; /* Byte 2 */ tmp = (uint8_t)((CSD_Tab[0] & 0x0000FF00) >> 8); cardinfo->SD_csd.NSAC = tmp; /* Byte 3 */ tmp = (uint8_t)(CSD_Tab[0] & 0x000000FF); cardinfo->SD_csd.MaxBusClkFrec = tmp; /* Byte 4 */ tmp = (uint8_t)((CSD_Tab[1] & 0xFF000000) >> 24); cardinfo->SD_csd.CardComdClasses = tmp << 4; /* Byte 5 */ tmp = (uint8_t)((CSD_Tab[1] & 0x00FF0000) >> 16); cardinfo->SD_csd.CardComdClasses |= (tmp & 0xF0) >> 4; cardinfo->SD_csd.RdBlockLen = tmp & 0x0F; /* Byte 6 */ tmp = (uint8_t)((CSD_Tab[1] & 0x0000FF00) >> 8); cardinfo->SD_csd.PartBlockRead = (tmp & 0x80) >> 7; cardinfo->SD_csd.WrBlockMisalign = (tmp & 0x40) >> 6; cardinfo->SD_csd.RdBlockMisalign = (tmp & 0x20) >> 5; cardinfo->SD_csd.DSRImpl = (tmp & 0x10) >> 4; cardinfo->SD_csd.Reserved2 = 0; /* Reserved */ if ((CardType == SDIO_STD_CAPACITY_SD_CARD_V1_1) || (CardType == SDIO_STD_CAPACITY_SD_CARD_V2_0)) { cardinfo->SD_csd.DeviceSize = (tmp & 0x03) << 10; /* Byte 7 */ tmp = (uint8_t)(CSD_Tab[1] & 0x000000FF); cardinfo->SD_csd.DeviceSize |= (tmp) << 2; /* Byte 8 */ tmp = (uint8_t)((CSD_Tab[2] & 0xFF000000) >> 24); cardinfo->SD_csd.DeviceSize |= (tmp & 0xC0) >> 6; cardinfo->SD_csd.MaxRdCurrentVDDMin = (tmp & 0x38) >> 3; cardinfo->SD_csd.MaxRdCurrentVDDMax = (tmp & 0x07); /* Byte 9 */ tmp = (uint8_t)((CSD_Tab[2] & 0x00FF0000) >> 16); cardinfo->SD_csd.MaxWrCurrentVDDMin = (tmp & 0xE0) >> 5; cardinfo->SD_csd.MaxWrCurrentVDDMax = (tmp & 0x1C) >> 2; cardinfo->SD_csd.DeviceSizeMul = (tmp & 0x03) << 1; /* Byte 10 */ tmp = (uint8_t)((CSD_Tab[2] & 0x0000FF00) >> 8); cardinfo->SD_csd.DeviceSizeMul |= (tmp & 0x80) >> 7; cardinfo->CardCapacity = (cardinfo->SD_csd.DeviceSize + 1) ; cardinfo->CardCapacity *= (1 << (cardinfo->SD_csd.DeviceSizeMul + 2)); cardinfo->CardBlockSize = 1 << (cardinfo->SD_csd.RdBlockLen); cardinfo->CardCapacity *= cardinfo->CardBlockSize; } else if (CardType == SDIO_HIGH_CAPACITY_SD_CARD) { /* Byte 7 */ tmp = (uint8_t)(CSD_Tab[1] & 0x000000FF); cardinfo->SD_csd.DeviceSize = (tmp & 0x3F) << 16; /* Byte 8 */ tmp = (uint8_t)((CSD_Tab[2] & 0xFF000000) >> 24); cardinfo->SD_csd.DeviceSize |= (tmp << 8); /* Byte 9 */ tmp = (uint8_t)((CSD_Tab[2] & 0x00FF0000) >> 16); cardinfo->SD_csd.DeviceSize |= (tmp); /* Byte 10 */ tmp = (uint8_t)((CSD_Tab[2] & 0x0000FF00) >> 8); cardinfo->CardCapacity = (cardinfo->SD_csd.DeviceSize + 1) * 512 * 1024; cardinfo->CardBlockSize = 512; } cardinfo->SD_csd.EraseGrSize = (tmp & 0x40) >> 6; cardinfo->SD_csd.EraseGrMul = (tmp & 0x3F) << 1; /* Byte 11 */ tmp = (uint8_t)(CSD_Tab[2] & 0x000000FF); cardinfo->SD_csd.EraseGrMul |= (tmp & 0x80) >> 7; cardinfo->SD_csd.WrProtectGrSize = (tmp & 0x7F); /* Byte 12 */ tmp = (uint8_t)((CSD_Tab[3] & 0xFF000000) >> 24); cardinfo->SD_csd.WrProtectGrEnable = (tmp & 0x80) >> 7; cardinfo->SD_csd.ManDeflECC = (tmp & 0x60) >> 5; cardinfo->SD_csd.WrSpeedFact = (tmp & 0x1C) >> 2; cardinfo->SD_csd.MaxWrBlockLen = (tmp & 0x03) << 2; /* Byte 13 */ tmp = (uint8_t)((CSD_Tab[3] & 0x00FF0000) >> 16); cardinfo->SD_csd.MaxWrBlockLen |= (tmp & 0xC0) >> 6; cardinfo->SD_csd.WriteBlockPaPartial = (tmp & 0x20) >> 5; cardinfo->SD_csd.Reserved3 = 0; cardinfo->SD_csd.ContentProtectAppli = (tmp & 0x01); /* Byte 14 */ tmp = (uint8_t)((CSD_Tab[3] & 0x0000FF00) >> 8); cardinfo->SD_csd.FileFormatGrouop = (tmp & 0x80) >> 7; cardinfo->SD_csd.CopyFlag = (tmp & 0x40) >> 6; cardinfo->SD_csd.PermWrProtect = (tmp & 0x20) >> 5; cardinfo->SD_csd.TempWrProtect = (tmp & 0x10) >> 4; cardinfo->SD_csd.FileFormat = (tmp & 0x0C) >> 2; cardinfo->SD_csd.ECC = (tmp & 0x03); /* Byte 15 */ tmp = (uint8_t)(CSD_Tab[3] & 0x000000FF); cardinfo->SD_csd.CSD_CRC = (tmp & 0xFE) >> 1; cardinfo->SD_csd.Reserved4 = 1; /* Byte 0 */ tmp = (uint8_t)((CID_Tab[0] & 0xFF000000) >> 24); cardinfo->SD_cid.ManufacturerID = tmp; /* Byte 1 */ tmp = (uint8_t)((CID_Tab[0] & 0x00FF0000) >> 16); cardinfo->SD_cid.OEM_AppliID = tmp << 8; /* Byte 2 */ tmp = (uint8_t)((CID_Tab[0] & 0x000000FF00) >> 8); cardinfo->SD_cid.OEM_AppliID |= tmp; /* Byte 3 */ tmp = (uint8_t)(CID_Tab[0] & 0x000000FF); cardinfo->SD_cid.ProdName1 = tmp << 24; /* Byte 4 */ tmp = (uint8_t)((CID_Tab[1] & 0xFF000000) >> 24); cardinfo->SD_cid.ProdName1 |= tmp << 16; /* Byte 5 */ tmp = (uint8_t)((CID_Tab[1] & 0x00FF0000) >> 16); cardinfo->SD_cid.ProdName1 |= tmp << 8; /* Byte 6 */ tmp = (uint8_t)((CID_Tab[1] & 0x0000FF00) >> 8); cardinfo->SD_cid.ProdName1 |= tmp; /* Byte 7 */ tmp = (uint8_t)(CID_Tab[1] & 0x000000FF); cardinfo->SD_cid.ProdName2 = tmp; /* Byte 8 */ tmp = (uint8_t)((CID_Tab[2] & 0xFF000000) >> 24); cardinfo->SD_cid.ProdRev = tmp; /* Byte 9 */ tmp = (uint8_t)((CID_Tab[2] & 0x00FF0000) >> 16); cardinfo->SD_cid.ProdSN = tmp << 24; /* Byte 10 */ tmp = (uint8_t)((CID_Tab[2] & 0x0000FF00) >> 8); cardinfo->SD_cid.ProdSN |= tmp << 16; /* Byte 11 */ tmp = (uint8_t)(CID_Tab[2] & 0x000000FF); cardinfo->SD_cid.ProdSN |= tmp << 8; /* Byte 12 */ tmp = (uint8_t)((CID_Tab[3] & 0xFF000000) >> 24); cardinfo->SD_cid.ProdSN |= tmp; /* Byte 13 */ tmp = (uint8_t)((CID_Tab[3] & 0x00FF0000) >> 16); cardinfo->SD_cid.Reserved1 |= (tmp & 0xF0) >> 4; cardinfo->SD_cid.ManufactDate = (tmp & 0x0F) << 8; /* Byte 14 */ tmp = (uint8_t)((CID_Tab[3] & 0x0000FF00) >> 8); cardinfo->SD_cid.ManufactDate |= tmp; /* Byte 15 */ tmp = (uint8_t)(CID_Tab[3] & 0x000000FF); cardinfo->SD_cid.CID_CRC = (tmp & 0xFE) >> 1; cardinfo->SD_cid.Reserved2 = 1; return(errorstatus); } /** * @brief Enables wide bus opeartion for the requeseted card if * supported by card. * @param WideMode: Specifies the SD card wide bus mode. * This parameter can be one of the following values: * @arg SDIO_BusWide_8b: 8-bit data transfer (Only for MMC) * @arg SDIO_BusWide_4b: 4-bit data transfer * @arg SDIO_BusWide_1b: 1-bit data transfer * @retval SD_Error: SD Card Error code. */ SD_Error SD_EnableWideBusOperation(uint32_t WideMode) { SD_Error errorstatus = SD_OK; /* MMC Card doesn't support this feature */ if (SDIO_MULTIMEDIA_CARD == CardType) { errorstatus = SD_UNSUPPORTED_FEATURE; return(errorstatus); } else if ((SDIO_STD_CAPACITY_SD_CARD_V1_1 == CardType) || (SDIO_STD_CAPACITY_SD_CARD_V2_0 == CardType) || (SDIO_HIGH_CAPACITY_SD_CARD == CardType)) { if (SDIO_BusWide_8b == WideMode) { errorstatus = SD_UNSUPPORTED_FEATURE; return(errorstatus); } else if (SDIO_BusWide_4b == WideMode) { errorstatus = SDEnWideBus(ENABLE); if (SD_OK == errorstatus) { /* Configure the SDIO peripheral */ SDIO_InitStructure.SDIO_ClockDiv = SDIO_TRANSFER_CLK_DIV; SDIO_InitStructure.SDIO_ClockEdge = SDIO_ClockEdge_Rising; SDIO_InitStructure.SDIO_ClockBypass = SDIO_ClockBypass_Disable; SDIO_InitStructure.SDIO_ClockPowerSave = SDIO_ClockPowerSave_Disable; SDIO_InitStructure.SDIO_BusWide = SDIO_BusWide_4b; SDIO_InitStructure.SDIO_HardwareFlowControl = SDIO_HardwareFlowControl_Disable; SDIO_Init(&SDIO_InitStructure); } } else { errorstatus = SDEnWideBus(DISABLE); if (SD_OK == errorstatus) { /* Configure the SDIO peripheral */ SDIO_InitStructure.SDIO_ClockDiv = SDIO_TRANSFER_CLK_DIV; SDIO_InitStructure.SDIO_ClockEdge = SDIO_ClockEdge_Rising; SDIO_InitStructure.SDIO_ClockBypass = SDIO_ClockBypass_Disable; SDIO_InitStructure.SDIO_ClockPowerSave = SDIO_ClockPowerSave_Disable; SDIO_InitStructure.SDIO_BusWide = SDIO_BusWide_1b; SDIO_InitStructure.SDIO_HardwareFlowControl = SDIO_HardwareFlowControl_Disable; SDIO_Init(&SDIO_InitStructure); } } } return(errorstatus); } /** * @brief Sets device mode whether to operate in Polling, Interrupt or * DMA mode. * @param Mode: Specifies the Data Transfer mode. * This parameter can be one of the following values: * @arg SD_DMA_MODE: Data transfer using DMA. * @arg SD_INTERRUPT_MODE: Data transfer using interrupts. * @arg SD_POLLING_MODE: Data transfer using flags. * @retval SD_Error: SD Card Error code. */ SD_Error SD_SetDeviceMode(uint32_t Mode) { SD_Error errorstatus = SD_OK; if ((Mode == SD_DMA_MODE) || (Mode == SD_INTERRUPT_MODE) || (Mode == SD_POLLING_MODE)) { DeviceMode = Mode; } else { errorstatus = SD_INVALID_PARAMETER; } return(errorstatus); } /** * @brief Selects od Deselects the corresponding card. * @param addr: Address of the Card to be selected. * @retval SD_Error: SD Card Error code. */ SD_Error SD_SelectDeselect(uint32_t addr) { SD_Error errorstatus = SD_OK; /* Send CMD7 SDIO_SEL_DESEL_CARD */ SDIO_CmdInitStructure.SDIO_Argument = addr; SDIO_CmdInitStructure.SDIO_CmdIndex = SDIO_SEL_DESEL_CARD; SDIO_CmdInitStructure.SDIO_Response = SDIO_Response_Short; SDIO_CmdInitStructure.SDIO_Wait = SDIO_Wait_No; SDIO_CmdInitStructure.SDIO_CPSM = SDIO_CPSM_Enable; SDIO_SendCommand(&SDIO_CmdInitStructure); errorstatus = CmdResp1Error(SDIO_SEL_DESEL_CARD); return(errorstatus); } /** * @brief Allows to read one block from a specified address in a card. * @param addr: Address from where data are to be read. * @param readbuff: pointer to the buffer that will contain the * received data * @param BlockSize: the SD card Data block size. * @retval SD_Error: SD Card Error code. */ SD_Error SD_ReadBlock(uint32_t addr, uint32_t *readbuff, uint16_t BlockSize) { SD_Error errorstatus = SD_OK; uint32_t count = 0, *tempbuff = readbuff; uint8_t power = 0; if (NULL == readbuff) { errorstatus = SD_INVALID_PARAMETER; return(errorstatus); } TransferError = SD_OK; TransferEnd = 0; TotalNumberOfBytes = 0; /* Clear all DPSM configuration */ SDIO_DataInitStructure.SDIO_DataTimeOut = SD_DATATIMEOUT; SDIO_DataInitStructure.SDIO_DataLength = 0; SDIO_DataInitStructure.SDIO_DataBlockSize = SDIO_DataBlockSize_1b; SDIO_DataInitStructure.SDIO_TransferDir = SDIO_TransferDir_ToCard; SDIO_DataInitStructure.SDIO_TransferMode = SDIO_TransferMode_Block; SDIO_DataInitStructure.SDIO_DPSM = SDIO_DPSM_Disable; SDIO_DataConfig(&SDIO_DataInitStructure); SDIO_DMACmd(DISABLE); if (SDIO_GetResponse(SDIO_RESP1) & SD_CARD_LOCKED) { errorstatus = SD_LOCK_UNLOCK_FAILED; return(errorstatus); } if (CardType == SDIO_HIGH_CAPACITY_SD_CARD) { BlockSize = 512; // addr /= 512; } if ((BlockSize > 0) && (BlockSize <= 2048) && ((BlockSize & (BlockSize - 1)) == 0)) { power = convert_from_bytes_to_power_of_two(BlockSize); /* Set Block Size for Card */ SDIO_CmdInitStructure.SDIO_Argument = (uint32_t) BlockSize; SDIO_CmdInitStructure.SDIO_CmdIndex = SDIO_SET_BLOCKLEN; SDIO_CmdInitStructure.SDIO_Response = SDIO_Response_Short; SDIO_CmdInitStructure.SDIO_Wait = SDIO_Wait_No; SDIO_CmdInitStructure.SDIO_CPSM = SDIO_CPSM_Enable; SDIO_SendCommand(&SDIO_CmdInitStructure); errorstatus = CmdResp1Error(SDIO_SET_BLOCKLEN); if (SD_OK != errorstatus) { return(errorstatus); } } else { errorstatus = SD_INVALID_PARAMETER; return(errorstatus); } SDIO_DataInitStructure.SDIO_DataTimeOut = SD_DATATIMEOUT; SDIO_DataInitStructure.SDIO_DataLength = BlockSize; SDIO_DataInitStructure.SDIO_DataBlockSize = (uint32_t) power << 4; SDIO_DataInitStructure.SDIO_TransferDir = SDIO_TransferDir_ToSDIO; SDIO_DataInitStructure.SDIO_TransferMode = SDIO_TransferMode_Block; SDIO_DataInitStructure.SDIO_DPSM = SDIO_DPSM_Enable; SDIO_DataConfig(&SDIO_DataInitStructure); TotalNumberOfBytes = BlockSize; StopCondition = 0; DestBuffer = readbuff; /* Send CMD17 READ_SINGLE_BLOCK */ SDIO_CmdInitStructure.SDIO_Argument = (uint32_t)addr; SDIO_CmdInitStructure.SDIO_CmdIndex = SDIO_READ_SINGLE_BLOCK; SDIO_CmdInitStructure.SDIO_Response = SDIO_Response_Short; SDIO_CmdInitStructure.SDIO_Wait = SDIO_Wait_No; SDIO_CmdInitStructure.SDIO_CPSM = SDIO_CPSM_Enable; SDIO_SendCommand(&SDIO_CmdInitStructure); errorstatus = CmdResp1Error(SDIO_READ_SINGLE_BLOCK); if (errorstatus != SD_OK) { return(errorstatus); } /* In case of single block transfer, no need of stop transfer at all.*/ if (DeviceMode == SD_POLLING_MODE) { /* Polling mode */ while (!(SDIO->STA &(SDIO_FLAG_RXOVERR | SDIO_FLAG_DCRCFAIL | SDIO_FLAG_DTIMEOUT | SDIO_FLAG_DBCKEND | SDIO_FLAG_STBITERR))) { if (SDIO_GetFlagStatus(SDIO_FLAG_RXFIFOHF) != RESET) { for (count = 0; count < 8; count++) { *(tempbuff + count) = SDIO_ReadData(); } tempbuff += 8; } } if (SDIO_GetFlagStatus(SDIO_FLAG_DTIMEOUT) != RESET) { SDIO_ClearFlag(SDIO_FLAG_DTIMEOUT); errorstatus = SD_DATA_TIMEOUT; return(errorstatus); } else if (SDIO_GetFlagStatus(SDIO_FLAG_DCRCFAIL) != RESET) { SDIO_ClearFlag(SDIO_FLAG_DCRCFAIL); errorstatus = SD_DATA_CRC_FAIL; return(errorstatus); } else if (SDIO_GetFlagStatus(SDIO_FLAG_RXOVERR) != RESET) { SDIO_ClearFlag(SDIO_FLAG_RXOVERR); errorstatus = SD_RX_OVERRUN; return(errorstatus); } else if (SDIO_GetFlagStatus(SDIO_FLAG_STBITERR) != RESET) { SDIO_ClearFlag(SDIO_FLAG_STBITERR); errorstatus = SD_START_BIT_ERR; return(errorstatus); } while (SDIO_GetFlagStatus(SDIO_FLAG_RXDAVL) != RESET) { *tempbuff = SDIO_ReadData(); tempbuff++; } /* Clear all the static flags */ SDIO_ClearFlag(SDIO_STATIC_FLAGS); } else if (DeviceMode == SD_INTERRUPT_MODE) { SDIO_ITConfig(SDIO_IT_DCRCFAIL | SDIO_IT_DTIMEOUT | SDIO_IT_DATAEND | SDIO_IT_RXOVERR | SDIO_IT_RXFIFOHF | SDIO_IT_STBITERR, ENABLE); while ((TransferEnd == 0) && (TransferError == SD_OK)) {} if (TransferError != SD_OK) { return(TransferError); } } else if (DeviceMode == SD_DMA_MODE) { rt_tick_t tick; SDIO_ITConfig(SDIO_IT_DCRCFAIL | SDIO_IT_DTIMEOUT | SDIO_IT_DATAEND | SDIO_IT_RXOVERR | SDIO_IT_STBITERR, ENABLE); SDIO_DMACmd(ENABLE); tick = rt_tick_get(); DMA_RxConfiguration(readbuff, BlockSize); while (DMA_GetFlagStatus(DMA2_FLAG_TC4) == RESET) { if ((TransferError != SD_OK) || (rt_tick_get() - tick > 10)) { errorstatus = SD_ERROR; // rt_kprintf("sd error\n"); break; } } } return(errorstatus); } /** * @brief Allows to read blocks from a specified address in a card. * @param addr: Address from where data are to be read. * @param readbuff: pointer to the buffer that will contain the * received data. * @param BlockSize: the SD card Data block size. * @param NumberOfBlocks: number of blocks to be read. * @retval SD_Error: SD Card Error code. */ SD_Error SD_ReadMultiBlocks(uint32_t addr, uint32_t *readbuff, uint16_t BlockSize, uint32_t NumberOfBlocks) { SD_Error errorstatus = SD_OK; uint32_t count = 0, *tempbuff = readbuff; uint8_t power = 0; if (NULL == readbuff) { errorstatus = SD_INVALID_PARAMETER; return(errorstatus); } TransferError = SD_OK; TransferEnd = 0; TotalNumberOfBytes = 0; /* Clear all DPSM configuration */ SDIO_DataInitStructure.SDIO_DataTimeOut = SD_DATATIMEOUT; SDIO_DataInitStructure.SDIO_DataLength = 0; SDIO_DataInitStructure.SDIO_DataBlockSize = SDIO_DataBlockSize_1b; SDIO_DataInitStructure.SDIO_TransferDir = SDIO_TransferDir_ToCard; SDIO_DataInitStructure.SDIO_TransferMode = SDIO_TransferMode_Block; SDIO_DataInitStructure.SDIO_DPSM = SDIO_DPSM_Disable; SDIO_DataConfig(&SDIO_DataInitStructure); SDIO_DMACmd(DISABLE); if (SDIO_GetResponse(SDIO_RESP1) & SD_CARD_LOCKED) { errorstatus = SD_LOCK_UNLOCK_FAILED; return(errorstatus); } if (CardType == SDIO_HIGH_CAPACITY_SD_CARD) { BlockSize = 512; // addr /= 512; } if ((BlockSize > 0) && (BlockSize <= 2048) && (0 == (BlockSize & (BlockSize - 1)))) { power = convert_from_bytes_to_power_of_two(BlockSize); /* Set Block Size for Card */ SDIO_CmdInitStructure.SDIO_Argument = (uint32_t) BlockSize; SDIO_CmdInitStructure.SDIO_CmdIndex = SDIO_SET_BLOCKLEN; SDIO_CmdInitStructure.SDIO_Response = SDIO_Response_Short; SDIO_CmdInitStructure.SDIO_Wait = SDIO_Wait_No; SDIO_CmdInitStructure.SDIO_CPSM = SDIO_CPSM_Enable; SDIO_SendCommand(&SDIO_CmdInitStructure); errorstatus = CmdResp1Error(SDIO_SET_BLOCKLEN); if (SD_OK != errorstatus) { return(errorstatus); } } else { errorstatus = SD_INVALID_PARAMETER; return(errorstatus); } if (NumberOfBlocks > 1) { /* Common to all modes */ if (NumberOfBlocks * BlockSize > SD_MAX_DATA_LENGTH) { errorstatus = SD_INVALID_PARAMETER; return(errorstatus); } TotalNumberOfBytes = NumberOfBlocks * BlockSize; StopCondition = 1; DestBuffer = readbuff; SDIO_DataInitStructure.SDIO_DataTimeOut = SD_DATATIMEOUT; SDIO_DataInitStructure.SDIO_DataLength = NumberOfBlocks * BlockSize; SDIO_DataInitStructure.SDIO_DataBlockSize = (uint32_t) power << 4; SDIO_DataInitStructure.SDIO_TransferDir = SDIO_TransferDir_ToSDIO; SDIO_DataInitStructure.SDIO_TransferMode = SDIO_TransferMode_Block; SDIO_DataInitStructure.SDIO_DPSM = SDIO_DPSM_Enable; SDIO_DataConfig(&SDIO_DataInitStructure); /* Send CMD18 READ_MULT_BLOCK with argument data address */ SDIO_CmdInitStructure.SDIO_Argument = (uint32_t)addr; SDIO_CmdInitStructure.SDIO_CmdIndex = SDIO_READ_MULT_BLOCK; SDIO_CmdInitStructure.SDIO_Response = SDIO_Response_Short; SDIO_CmdInitStructure.SDIO_Wait = SDIO_Wait_No; SDIO_CmdInitStructure.SDIO_CPSM = SDIO_CPSM_Enable; SDIO_SendCommand(&SDIO_CmdInitStructure); errorstatus = CmdResp1Error(SDIO_READ_MULT_BLOCK); if (errorstatus != SD_OK) { return(errorstatus); } if (DeviceMode == SD_POLLING_MODE) { /* Polling mode */ while (!(SDIO->STA &(SDIO_FLAG_RXOVERR | SDIO_FLAG_DCRCFAIL | SDIO_FLAG_DATAEND | SDIO_FLAG_DTIMEOUT | SDIO_FLAG_STBITERR))) { if (SDIO_GetFlagStatus(SDIO_FLAG_RXFIFOHF) != RESET) { for (count = 0; count < SD_HALFFIFO; count++) { *(tempbuff + count) = SDIO_ReadData(); } tempbuff += SD_HALFFIFO; } } if (SDIO_GetFlagStatus(SDIO_FLAG_DTIMEOUT) != RESET) { SDIO_ClearFlag(SDIO_FLAG_DTIMEOUT); errorstatus = SD_DATA_TIMEOUT; return(errorstatus); } else if (SDIO_GetFlagStatus(SDIO_FLAG_DCRCFAIL) != RESET) { SDIO_ClearFlag(SDIO_FLAG_DCRCFAIL); errorstatus = SD_DATA_CRC_FAIL; return(errorstatus); } else if (SDIO_GetFlagStatus(SDIO_FLAG_RXOVERR) != RESET) { SDIO_ClearFlag(SDIO_FLAG_RXOVERR); errorstatus = SD_RX_OVERRUN; return(errorstatus); } else if (SDIO_GetFlagStatus(SDIO_FLAG_STBITERR) != RESET) { SDIO_ClearFlag(SDIO_FLAG_STBITERR); errorstatus = SD_START_BIT_ERR; return(errorstatus); } while (SDIO_GetFlagStatus(SDIO_FLAG_RXDAVL) != RESET) { *tempbuff = SDIO_ReadData(); tempbuff++; } if (SDIO_GetFlagStatus(SDIO_FLAG_DATAEND) != RESET) { /* In Case Of SD-CARD Send Command STOP_TRANSMISSION */ if ((SDIO_STD_CAPACITY_SD_CARD_V1_1 == CardType) || (SDIO_HIGH_CAPACITY_SD_CARD == CardType) || (SDIO_STD_CAPACITY_SD_CARD_V2_0 == CardType)) { /* Send CMD12 STOP_TRANSMISSION */ SDIO_CmdInitStructure.SDIO_Argument = 0x0; SDIO_CmdInitStructure.SDIO_CmdIndex = SDIO_STOP_TRANSMISSION; SDIO_CmdInitStructure.SDIO_Response = SDIO_Response_Short; SDIO_CmdInitStructure.SDIO_Wait = SDIO_Wait_No; SDIO_CmdInitStructure.SDIO_CPSM = SDIO_CPSM_Enable; SDIO_SendCommand(&SDIO_CmdInitStructure); errorstatus = CmdResp1Error(SDIO_STOP_TRANSMISSION); if (errorstatus != SD_OK) { return(errorstatus); } } } /* Clear all the static flags */ SDIO_ClearFlag(SDIO_STATIC_FLAGS); } else if (DeviceMode == SD_INTERRUPT_MODE) { SDIO_ITConfig(SDIO_IT_DCRCFAIL | SDIO_IT_DTIMEOUT | SDIO_IT_DATAEND | SDIO_IT_RXOVERR | SDIO_IT_RXFIFOHF | SDIO_IT_STBITERR, ENABLE); while ((TransferEnd == 0) && (TransferError == SD_OK)) {} if (TransferError != SD_OK) { return(TransferError); } } else if (DeviceMode == SD_DMA_MODE) { rt_tick_t tick; SDIO_ITConfig(SDIO_IT_DCRCFAIL | SDIO_IT_DTIMEOUT | SDIO_IT_DATAEND | SDIO_IT_RXOVERR | SDIO_IT_STBITERR, ENABLE); SDIO_DMACmd(ENABLE); tick = rt_tick_get(); DMA_RxConfiguration(readbuff, (NumberOfBlocks * BlockSize)); while (DMA_GetFlagStatus(DMA2_FLAG_TC4) == RESET) { if ((TransferError != SD_OK) || (rt_tick_get() - tick > 10)) { errorstatus = SD_ERROR; // rt_kprintf("sd error\n"); return errorstatus; } } while ((TransferEnd == 0) && (TransferError == SD_OK)) {} if (TransferError != SD_OK) { return(TransferError); } } } return(errorstatus); } /** * @brief Allows to write one block starting from a specified address * in a card. * @param addr: Address from where data are to be read. * @param writebuff: pointer to the buffer that contain the data to be * transferred. * @param BlockSize: the SD card Data block size. * @retval SD_Error: SD Card Error code. */ SD_Error SD_WriteBlock(uint32_t addr, uint32_t *writebuff, uint16_t BlockSize) { SD_Error errorstatus = SD_OK; uint8_t power = 0, cardstate = 0; uint32_t timeout = 0, bytestransferred = 0; uint32_t cardstatus = 0, count = 0, restwords = 0; uint32_t *tempbuff = writebuff; if (writebuff == NULL) { errorstatus = SD_INVALID_PARAMETER; return(errorstatus); } TransferError = SD_OK; TransferEnd = 0; TotalNumberOfBytes = 0; SDIO_DataInitStructure.SDIO_DataTimeOut = SD_DATATIMEOUT; SDIO_DataInitStructure.SDIO_DataLength = 0; SDIO_DataInitStructure.SDIO_DataBlockSize = SDIO_DataBlockSize_1b; SDIO_DataInitStructure.SDIO_TransferDir = SDIO_TransferDir_ToCard; SDIO_DataInitStructure.SDIO_TransferMode = SDIO_TransferMode_Block; SDIO_DataInitStructure.SDIO_DPSM = SDIO_DPSM_Disable; SDIO_DataConfig(&SDIO_DataInitStructure); SDIO_DMACmd(DISABLE); if (SDIO_GetResponse(SDIO_RESP1) & SD_CARD_LOCKED) { errorstatus = SD_LOCK_UNLOCK_FAILED; return(errorstatus); } if (CardType == SDIO_HIGH_CAPACITY_SD_CARD) { BlockSize = 512; // addr /= 512; } /* Set the block size, both on controller and card */ if ((BlockSize > 0) && (BlockSize <= 2048) && ((BlockSize & (BlockSize - 1)) == 0)) { power = convert_from_bytes_to_power_of_two(BlockSize); SDIO_CmdInitStructure.SDIO_Argument = (uint32_t) BlockSize; SDIO_CmdInitStructure.SDIO_CmdIndex = SDIO_SET_BLOCKLEN; SDIO_CmdInitStructure.SDIO_Response = SDIO_Response_Short; SDIO_CmdInitStructure.SDIO_Wait = SDIO_Wait_No; SDIO_CmdInitStructure.SDIO_CPSM = SDIO_CPSM_Enable; SDIO_SendCommand(&SDIO_CmdInitStructure); errorstatus = CmdResp1Error(SDIO_SET_BLOCKLEN); if (errorstatus != SD_OK) { return(errorstatus); } } else { errorstatus = SD_INVALID_PARAMETER; return(errorstatus); } /* Wait till card is ready for data Added */ SDIO_CmdInitStructure.SDIO_Argument = (uint32_t) (RCA << 16); SDIO_CmdInitStructure.SDIO_CmdIndex = SDIO_SEND_STATUS; SDIO_CmdInitStructure.SDIO_Response = SDIO_Response_Short; SDIO_CmdInitStructure.SDIO_Wait = SDIO_Wait_No; SDIO_CmdInitStructure.SDIO_CPSM = SDIO_CPSM_Enable; SDIO_SendCommand(&SDIO_CmdInitStructure); errorstatus = CmdResp1Error(SDIO_SEND_STATUS); if (errorstatus != SD_OK) { return(errorstatus); } cardstatus = SDIO_GetResponse(SDIO_RESP1); timeout = SD_DATATIMEOUT; while (((cardstatus & 0x00000100) == 0) && (timeout > 0)) { timeout--; SDIO_CmdInitStructure.SDIO_Argument = (uint32_t) (RCA << 16); SDIO_CmdInitStructure.SDIO_CmdIndex = SDIO_SEND_STATUS; SDIO_CmdInitStructure.SDIO_Response = SDIO_Response_Short; SDIO_CmdInitStructure.SDIO_Wait = SDIO_Wait_No; SDIO_CmdInitStructure.SDIO_CPSM = SDIO_CPSM_Enable; SDIO_SendCommand(&SDIO_CmdInitStructure); errorstatus = CmdResp1Error(SDIO_SEND_STATUS); if (errorstatus != SD_OK) { return(errorstatus); } cardstatus = SDIO_GetResponse(SDIO_RESP1); } if (timeout == 0) { return(SD_ERROR); } /* Send CMD24 WRITE_SINGLE_BLOCK */ SDIO_CmdInitStructure.SDIO_Argument = addr; SDIO_CmdInitStructure.SDIO_CmdIndex = SDIO_WRITE_SINGLE_BLOCK; SDIO_CmdInitStructure.SDIO_Response = SDIO_Response_Short; SDIO_CmdInitStructure.SDIO_Wait = SDIO_Wait_No; SDIO_CmdInitStructure.SDIO_CPSM = SDIO_CPSM_Enable; SDIO_SendCommand(&SDIO_CmdInitStructure); errorstatus = CmdResp1Error(SDIO_WRITE_SINGLE_BLOCK); if (errorstatus != SD_OK) { return(errorstatus); } TotalNumberOfBytes = BlockSize; StopCondition = 0; SrcBuffer = writebuff; SDIO_DataInitStructure.SDIO_DataTimeOut = SD_DATATIMEOUT; SDIO_DataInitStructure.SDIO_DataLength = BlockSize; SDIO_DataInitStructure.SDIO_DataBlockSize = (uint32_t) power << 4; SDIO_DataInitStructure.SDIO_TransferDir = SDIO_TransferDir_ToCard; SDIO_DataInitStructure.SDIO_TransferMode = SDIO_TransferMode_Block; SDIO_DataInitStructure.SDIO_DPSM = SDIO_DPSM_Enable; SDIO_DataConfig(&SDIO_DataInitStructure); /* In case of single data block transfer no need of stop command at all */ if (DeviceMode == SD_POLLING_MODE) { while (!(SDIO->STA & (SDIO_FLAG_DBCKEND | SDIO_FLAG_TXUNDERR | SDIO_FLAG_DCRCFAIL | SDIO_FLAG_DTIMEOUT | SDIO_FLAG_STBITERR))) { if (SDIO_GetFlagStatus(SDIO_FLAG_TXFIFOHE) != RESET) { if ((TotalNumberOfBytes - bytestransferred) < 32) { restwords = ((TotalNumberOfBytes - bytestransferred) % 4 == 0) ? ((TotalNumberOfBytes - bytestransferred) / 4) : (( TotalNumberOfBytes - bytestransferred) / 4 + 1); for (count = 0; count < restwords; count++, tempbuff++, bytestransferred += 4) { SDIO_WriteData(*tempbuff); } } else { for (count = 0; count < 8; count++) { SDIO_WriteData(*(tempbuff + count)); } tempbuff += 8; bytestransferred += 32; } } } if (SDIO_GetFlagStatus(SDIO_FLAG_DTIMEOUT) != RESET) { SDIO_ClearFlag(SDIO_FLAG_DTIMEOUT); errorstatus = SD_DATA_TIMEOUT; return(errorstatus); } else if (SDIO_GetFlagStatus(SDIO_FLAG_DCRCFAIL) != RESET) { SDIO_ClearFlag(SDIO_FLAG_DCRCFAIL); errorstatus = SD_DATA_CRC_FAIL; return(errorstatus); } else if (SDIO_GetFlagStatus(SDIO_FLAG_TXUNDERR) != RESET) { SDIO_ClearFlag(SDIO_FLAG_TXUNDERR); errorstatus = SD_TX_UNDERRUN; return(errorstatus); } else if (SDIO_GetFlagStatus(SDIO_FLAG_STBITERR) != RESET) { SDIO_ClearFlag(SDIO_FLAG_STBITERR); errorstatus = SD_START_BIT_ERR; return(errorstatus); } } else if (DeviceMode == SD_INTERRUPT_MODE) { SDIO_ITConfig(SDIO_IT_DCRCFAIL | SDIO_IT_DTIMEOUT | SDIO_IT_DATAEND | SDIO_FLAG_TXFIFOHE | SDIO_IT_TXUNDERR | SDIO_IT_STBITERR, ENABLE); while ((TransferEnd == 0) && (TransferError == SD_OK)) {} if (TransferError != SD_OK) { return(TransferError); } } else if (DeviceMode == SD_DMA_MODE) { SDIO_ITConfig(SDIO_IT_DCRCFAIL | SDIO_IT_DTIMEOUT | SDIO_IT_DATAEND | SDIO_IT_TXUNDERR | SDIO_IT_STBITERR, ENABLE); DMA_TxConfiguration(writebuff, BlockSize); SDIO_DMACmd(ENABLE); while (DMA_GetFlagStatus(DMA2_FLAG_TC4) == RESET) {} while ((TransferEnd == 0) && (TransferError == SD_OK)) {} if (TransferError != SD_OK) { return(TransferError); } } /* Clear all the static flags */ SDIO_ClearFlag(SDIO_STATIC_FLAGS); /* Wait till the card is in programming state */ errorstatus = IsCardProgramming(&cardstate); while ((errorstatus == SD_OK) && ((cardstate == SD_CARD_PROGRAMMING) || (cardstate == SD_CARD_RECEIVING))) { errorstatus = IsCardProgramming(&cardstate); } return(errorstatus); } /** * @brief Allows to write blocks starting from a specified address in * a card. * @param addr: Address from where data are to be read. * @param writebuff: pointer to the buffer that contain the data to be * transferred. * @param BlockSize: the SD card Data block size. * @param NumberOfBlocks: number of blocks to be written. * @retval SD_Error: SD Card Error code. */ SD_Error SD_WriteMultiBlocks(uint32_t addr, uint32_t *writebuff, uint16_t BlockSize, uint32_t NumberOfBlocks) { SD_Error errorstatus = SD_OK; uint8_t power = 0, cardstate = 0; uint32_t bytestransferred = 0; uint32_t count = 0, restwords = 0; uint32_t *tempbuff = writebuff; if (writebuff == NULL) { errorstatus = SD_INVALID_PARAMETER; return(errorstatus); } TransferError = SD_OK; TransferEnd = 0; TotalNumberOfBytes = 0; SDIO_DataInitStructure.SDIO_DataTimeOut = SD_DATATIMEOUT; SDIO_DataInitStructure.SDIO_DataLength = 0; SDIO_DataInitStructure.SDIO_DataBlockSize = SDIO_DataBlockSize_1b; SDIO_DataInitStructure.SDIO_TransferDir = SDIO_TransferDir_ToCard; SDIO_DataInitStructure.SDIO_TransferMode = SDIO_TransferMode_Block; SDIO_DataInitStructure.SDIO_DPSM = SDIO_DPSM_Disable; SDIO_DataConfig(&SDIO_DataInitStructure); SDIO_DMACmd(DISABLE); if (SDIO_GetResponse(SDIO_RESP1) & SD_CARD_LOCKED) { errorstatus = SD_LOCK_UNLOCK_FAILED; return(errorstatus); } if (CardType == SDIO_HIGH_CAPACITY_SD_CARD) { BlockSize = 512; // addr /= 512; } /* Set the block size, both on controller and card */ if ((BlockSize > 0) && (BlockSize <= 2048) && ((BlockSize & (BlockSize - 1)) == 0)) { power = convert_from_bytes_to_power_of_two(BlockSize); SDIO_CmdInitStructure.SDIO_Argument = (uint32_t) BlockSize; SDIO_CmdInitStructure.SDIO_CmdIndex = SDIO_SET_BLOCKLEN; SDIO_CmdInitStructure.SDIO_Response = SDIO_Response_Short; SDIO_CmdInitStructure.SDIO_Wait = SDIO_Wait_No; SDIO_CmdInitStructure.SDIO_CPSM = SDIO_CPSM_Enable; SDIO_SendCommand(&SDIO_CmdInitStructure); errorstatus = CmdResp1Error(SDIO_SET_BLOCKLEN); if (errorstatus != SD_OK) { return(errorstatus); } } else { errorstatus = SD_INVALID_PARAMETER; return(errorstatus); } /* Wait till card is ready for data Added */ SDIO_CmdInitStructure.SDIO_Argument = (uint32_t) (RCA << 16); SDIO_CmdInitStructure.SDIO_CmdIndex = SDIO_SEND_STATUS; SDIO_CmdInitStructure.SDIO_Response = SDIO_Response_Short; SDIO_CmdInitStructure.SDIO_Wait = SDIO_Wait_No; SDIO_CmdInitStructure.SDIO_CPSM = SDIO_CPSM_Enable; SDIO_SendCommand(&SDIO_CmdInitStructure); errorstatus = CmdResp1Error(SDIO_SEND_STATUS); if (errorstatus != SD_OK) { return(errorstatus); } if (NumberOfBlocks > 1) { /* Common to all modes */ if (NumberOfBlocks * BlockSize > SD_MAX_DATA_LENGTH) { errorstatus = SD_INVALID_PARAMETER; return(errorstatus); } if ((SDIO_STD_CAPACITY_SD_CARD_V1_1 == CardType) || (SDIO_STD_CAPACITY_SD_CARD_V2_0 == CardType) || (SDIO_HIGH_CAPACITY_SD_CARD == CardType)) { /* To improve performance */ SDIO_CmdInitStructure.SDIO_Argument = (uint32_t) (RCA << 16); SDIO_CmdInitStructure.SDIO_CmdIndex = SDIO_APP_CMD; SDIO_CmdInitStructure.SDIO_Response = SDIO_Response_Short; SDIO_CmdInitStructure.SDIO_Wait = SDIO_Wait_No; SDIO_CmdInitStructure.SDIO_CPSM = SDIO_CPSM_Enable; SDIO_SendCommand(&SDIO_CmdInitStructure); errorstatus = CmdResp1Error(SDIO_APP_CMD); if (errorstatus != SD_OK) { return(errorstatus); } /* To improve performance */ SDIO_CmdInitStructure.SDIO_Argument = (uint32_t)NumberOfBlocks; SDIO_CmdInitStructure.SDIO_CmdIndex = SDIO_SET_BLOCK_COUNT; SDIO_CmdInitStructure.SDIO_Response = SDIO_Response_Short; SDIO_CmdInitStructure.SDIO_Wait = SDIO_Wait_No; SDIO_CmdInitStructure.SDIO_CPSM = SDIO_CPSM_Enable; SDIO_SendCommand(&SDIO_CmdInitStructure); errorstatus = CmdResp1Error(SDIO_SET_BLOCK_COUNT); if (errorstatus != SD_OK) { return(errorstatus); } } /* Send CMD25 WRITE_MULT_BLOCK with argument data address */ SDIO_CmdInitStructure.SDIO_Argument = (uint32_t)addr; SDIO_CmdInitStructure.SDIO_CmdIndex = SDIO_WRITE_MULT_BLOCK; SDIO_CmdInitStructure.SDIO_Response = SDIO_Response_Short; SDIO_CmdInitStructure.SDIO_Wait = SDIO_Wait_No; SDIO_CmdInitStructure.SDIO_CPSM = SDIO_CPSM_Enable; SDIO_SendCommand(&SDIO_CmdInitStructure); errorstatus = CmdResp1Error(SDIO_WRITE_MULT_BLOCK); if (SD_OK != errorstatus) { return(errorstatus); } TotalNumberOfBytes = NumberOfBlocks * BlockSize; StopCondition = 1; SrcBuffer = writebuff; SDIO_DataInitStructure.SDIO_DataTimeOut = SD_DATATIMEOUT; SDIO_DataInitStructure.SDIO_DataLength = NumberOfBlocks * BlockSize; SDIO_DataInitStructure.SDIO_DataBlockSize = (uint32_t) power << 4; SDIO_DataInitStructure.SDIO_TransferDir = SDIO_TransferDir_ToCard; SDIO_DataInitStructure.SDIO_TransferMode = SDIO_TransferMode_Block; SDIO_DataInitStructure.SDIO_DPSM = SDIO_DPSM_Enable; SDIO_DataConfig(&SDIO_DataInitStructure); if (DeviceMode == SD_POLLING_MODE) { while (!(SDIO->STA & (SDIO_FLAG_TXUNDERR | SDIO_FLAG_DCRCFAIL | SDIO_FLAG_DATAEND | SDIO_FLAG_DTIMEOUT | SDIO_FLAG_STBITERR))) { if (SDIO_GetFlagStatus(SDIO_FLAG_TXFIFOHE) != RESET) { if (!((TotalNumberOfBytes - bytestransferred) < SD_HALFFIFOBYTES)) { for (count = 0; count < SD_HALFFIFO; count++) { SDIO_WriteData(*(tempbuff + count)); } tempbuff += SD_HALFFIFO; bytestransferred += SD_HALFFIFOBYTES; } else { restwords = ((TotalNumberOfBytes - bytestransferred) % 4 == 0) ? ((TotalNumberOfBytes - bytestransferred) / 4) : ((TotalNumberOfBytes - bytestransferred) / 4 + 1); for (count = 0; count < restwords; count++, tempbuff++, bytestransferred += 4) { SDIO_WriteData(*tempbuff); } } } } if (SDIO_GetFlagStatus(SDIO_FLAG_DTIMEOUT) != RESET) { SDIO_ClearFlag(SDIO_FLAG_DTIMEOUT); errorstatus = SD_DATA_TIMEOUT; return(errorstatus); } else if (SDIO_GetFlagStatus(SDIO_FLAG_DCRCFAIL) != RESET) { SDIO_ClearFlag(SDIO_FLAG_DCRCFAIL); errorstatus = SD_DATA_CRC_FAIL; return(errorstatus); } else if (SDIO_GetFlagStatus(SDIO_FLAG_TXUNDERR) != RESET) { SDIO_ClearFlag(SDIO_FLAG_TXUNDERR); errorstatus = SD_TX_UNDERRUN; return(errorstatus); } else if (SDIO_GetFlagStatus(SDIO_FLAG_STBITERR) != RESET) { SDIO_ClearFlag(SDIO_FLAG_STBITERR); errorstatus = SD_START_BIT_ERR; return(errorstatus); } if (SDIO_GetFlagStatus(SDIO_FLAG_DATAEND) != RESET) { if ((SDIO_STD_CAPACITY_SD_CARD_V1_1 == CardType) || (SDIO_STD_CAPACITY_SD_CARD_V2_0 == CardType) || (SDIO_HIGH_CAPACITY_SD_CARD == CardType)) { /* Send CMD12 STOP_TRANSMISSION */ SDIO_CmdInitStructure.SDIO_Argument = 0x0; SDIO_CmdInitStructure.SDIO_CmdIndex = SDIO_STOP_TRANSMISSION; SDIO_CmdInitStructure.SDIO_Response = SDIO_Response_Short; SDIO_CmdInitStructure.SDIO_Wait = SDIO_Wait_No; SDIO_CmdInitStructure.SDIO_CPSM = SDIO_CPSM_Enable; SDIO_SendCommand(&SDIO_CmdInitStructure); errorstatus = CmdResp1Error(SDIO_STOP_TRANSMISSION); if (errorstatus != SD_OK) { return(errorstatus); } } } } else if (DeviceMode == SD_INTERRUPT_MODE) { SDIO_ITConfig(SDIO_IT_DCRCFAIL | SDIO_IT_DTIMEOUT | SDIO_IT_DATAEND | SDIO_IT_TXFIFOHE | SDIO_IT_TXUNDERR | SDIO_IT_STBITERR, ENABLE); while ((TransferEnd == 0) && (TransferError == SD_OK)) {} if (TransferError != SD_OK) { return(TransferError); } } else if (DeviceMode == SD_DMA_MODE) { SDIO_ITConfig(SDIO_IT_DCRCFAIL | SDIO_IT_DTIMEOUT | SDIO_IT_DATAEND | SDIO_IT_TXUNDERR | SDIO_IT_STBITERR, ENABLE); SDIO_DMACmd(ENABLE); DMA_TxConfiguration(writebuff, (NumberOfBlocks * BlockSize)); while (DMA_GetFlagStatus(DMA2_FLAG_TC4) == RESET) {} while ((TransferEnd == 0) && (TransferError == SD_OK)) {} if (TransferError != SD_OK) { return(TransferError); } } } /* Clear all the static flags */ SDIO_ClearFlag(SDIO_STATIC_FLAGS); /* Wait till the card is in programming state */ errorstatus = IsCardProgramming(&cardstate); while ((errorstatus == SD_OK) && ((cardstate == SD_CARD_PROGRAMMING) || (cardstate == SD_CARD_RECEIVING))) { errorstatus = IsCardProgramming(&cardstate); } return(errorstatus); } /** * @brief Gets the cuurent data transfer state. * @param None * @retval SDTransferState: Data Transfer state. * This value can be: * - SD_NO_TRANSFER: No data transfer is acting * - SD_TRANSFER_IN_PROGRESS: Data transfer is acting */ SDTransferState SD_GetTransferState(void) { if (SDIO->STA & (SDIO_FLAG_TXACT | SDIO_FLAG_RXACT)) { return(SD_TRANSFER_IN_PROGRESS); } else { return(SD_NO_TRANSFER); } } /** * @brief Aborts an ongoing data transfer. * @param None * @retval SD_Error: SD Card Error code. */ SD_Error SD_StopTransfer(void) { SD_Error errorstatus = SD_OK; /* Send CMD12 STOP_TRANSMISSION */ SDIO_CmdInitStructure.SDIO_Argument = 0x0; SDIO_CmdInitStructure.SDIO_CmdIndex = SDIO_STOP_TRANSMISSION; SDIO_CmdInitStructure.SDIO_Response = SDIO_Response_Short; SDIO_CmdInitStructure.SDIO_Wait = SDIO_Wait_No; SDIO_CmdInitStructure.SDIO_CPSM = SDIO_CPSM_Enable; SDIO_SendCommand(&SDIO_CmdInitStructure); errorstatus = CmdResp1Error(SDIO_STOP_TRANSMISSION); return(errorstatus); } /** * @brief Allows to erase memory area specified for the given card. * @param startaddr: the start address. * @param endaddr: the end address. * @retval SD_Error: SD Card Error code. */ SD_Error SD_Erase(uint32_t startaddr, uint32_t endaddr) { SD_Error errorstatus = SD_OK; uint32_t delay = 0; __IO uint32_t maxdelay = 0; uint8_t cardstate = 0; /* Check if the card coomnd class supports erase command */ if (((CSD_Tab[1] >> 20) & SD_CCCC_ERASE) == 0) { errorstatus = SD_REQUEST_NOT_APPLICABLE; return(errorstatus); } maxdelay = 72000 / ((SDIO->CLKCR & 0xFF) + 2); if (SDIO_GetResponse(SDIO_RESP1) & SD_CARD_LOCKED) { errorstatus = SD_LOCK_UNLOCK_FAILED; return(errorstatus); } if (CardType == SDIO_HIGH_CAPACITY_SD_CARD) { startaddr /= 512; endaddr /= 512; } /* According to sd-card spec 1.0 ERASE_GROUP_START (CMD32) and erase_group_end(CMD33) */ if ((SDIO_STD_CAPACITY_SD_CARD_V1_1 == CardType) || (SDIO_STD_CAPACITY_SD_CARD_V2_0 == CardType) || (SDIO_HIGH_CAPACITY_SD_CARD == CardType)) { /* Send CMD32 SD_ERASE_GRP_START with argument as addr */ SDIO_CmdInitStructure.SDIO_Argument = startaddr; SDIO_CmdInitStructure.SDIO_CmdIndex = SDIO_SD_ERASE_GRP_START; SDIO_CmdInitStructure.SDIO_Response = SDIO_Response_Short; SDIO_CmdInitStructure.SDIO_Wait = SDIO_Wait_No; SDIO_CmdInitStructure.SDIO_CPSM = SDIO_CPSM_Enable; SDIO_SendCommand(&SDIO_CmdInitStructure); errorstatus = CmdResp1Error(SDIO_SD_ERASE_GRP_START); if (errorstatus != SD_OK) { return(errorstatus); } /* Send CMD33 SD_ERASE_GRP_END with argument as addr */ SDIO_CmdInitStructure.SDIO_Argument = endaddr; SDIO_CmdInitStructure.SDIO_CmdIndex = SDIO_SD_ERASE_GRP_END; SDIO_CmdInitStructure.SDIO_Response = SDIO_Response_Short; SDIO_CmdInitStructure.SDIO_Wait = SDIO_Wait_No; SDIO_CmdInitStructure.SDIO_CPSM = SDIO_CPSM_Enable; SDIO_SendCommand(&SDIO_CmdInitStructure); errorstatus = CmdResp1Error(SDIO_SD_ERASE_GRP_END); if (errorstatus != SD_OK) { return(errorstatus); } } /* Send CMD38 ERASE */ SDIO_CmdInitStructure.SDIO_Argument = 0; SDIO_CmdInitStructure.SDIO_CmdIndex = SDIO_ERASE; SDIO_CmdInitStructure.SDIO_Response = SDIO_Response_Short; SDIO_CmdInitStructure.SDIO_Wait = SDIO_Wait_No; SDIO_CmdInitStructure.SDIO_CPSM = SDIO_CPSM_Enable; SDIO_SendCommand(&SDIO_CmdInitStructure); errorstatus = CmdResp1Error(SDIO_ERASE); if (errorstatus != SD_OK) { return(errorstatus); } for (delay = 0; delay < maxdelay; delay++) {} /* Wait till the card is in programming state */ errorstatus = IsCardProgramming(&cardstate); while ((errorstatus == SD_OK) && ((SD_CARD_PROGRAMMING == cardstate) || (SD_CARD_RECEIVING == cardstate))) { errorstatus = IsCardProgramming(&cardstate); } return(errorstatus); } /** * @brief Returns the current card's status. * @param pcardstatus: pointer to the buffer that will contain the SD * card status (Card Status register). * @retval SD_Error: SD Card Error code. */ SD_Error SD_SendStatus(uint32_t *pcardstatus) { SD_Error errorstatus = SD_OK; if (pcardstatus == NULL) { errorstatus = SD_INVALID_PARAMETER; return(errorstatus); } SDIO_CmdInitStructure.SDIO_Argument = (uint32_t) RCA << 16; SDIO_CmdInitStructure.SDIO_CmdIndex = SDIO_SEND_STATUS; SDIO_CmdInitStructure.SDIO_Response = SDIO_Response_Short; SDIO_CmdInitStructure.SDIO_Wait = SDIO_Wait_No; SDIO_CmdInitStructure.SDIO_CPSM = SDIO_CPSM_Enable; SDIO_SendCommand(&SDIO_CmdInitStructure); errorstatus = CmdResp1Error(SDIO_SEND_STATUS); if (errorstatus != SD_OK) { return(errorstatus); } *pcardstatus = SDIO_GetResponse(SDIO_RESP1); return(errorstatus); } /** * @brief Returns the current SD card's status. * @param psdstatus: pointer to the buffer that will contain the SD * card status (SD Status register). * @retval SD_Error: SD Card Error code. */ SD_Error SD_SendSDStatus(uint32_t *psdstatus) { SD_Error errorstatus = SD_OK; uint32_t count = 0; if (SDIO_GetResponse(SDIO_RESP1) & SD_CARD_LOCKED) { errorstatus = SD_LOCK_UNLOCK_FAILED; return(errorstatus); } /* Set block size for card if it is not equal to current block size for card. */ SDIO_CmdInitStructure.SDIO_Argument = 64; SDIO_CmdInitStructure.SDIO_CmdIndex = SDIO_SET_BLOCKLEN; SDIO_CmdInitStructure.SDIO_Response = SDIO_Response_Short; SDIO_CmdInitStructure.SDIO_Wait = SDIO_Wait_No; SDIO_CmdInitStructure.SDIO_CPSM = SDIO_CPSM_Enable; SDIO_SendCommand(&SDIO_CmdInitStructure); errorstatus = CmdResp1Error(SDIO_SET_BLOCKLEN); if (errorstatus != SD_OK) { return(errorstatus); } /* CMD55 */ SDIO_CmdInitStructure.SDIO_Argument = (uint32_t) RCA << 16; SDIO_CmdInitStructure.SDIO_CmdIndex = SDIO_APP_CMD; SDIO_CmdInitStructure.SDIO_Response = SDIO_Response_Short; SDIO_CmdInitStructure.SDIO_Wait = SDIO_Wait_No; SDIO_CmdInitStructure.SDIO_CPSM = SDIO_CPSM_Enable; SDIO_SendCommand(&SDIO_CmdInitStructure); errorstatus = CmdResp1Error(SDIO_APP_CMD); if (errorstatus != SD_OK) { return(errorstatus); } SDIO_DataInitStructure.SDIO_DataTimeOut = SD_DATATIMEOUT; SDIO_DataInitStructure.SDIO_DataLength = 64; SDIO_DataInitStructure.SDIO_DataBlockSize = SDIO_DataBlockSize_64b; SDIO_DataInitStructure.SDIO_TransferDir = SDIO_TransferDir_ToSDIO; SDIO_DataInitStructure.SDIO_TransferMode = SDIO_TransferMode_Block; SDIO_DataInitStructure.SDIO_DPSM = SDIO_DPSM_Enable; SDIO_DataConfig(&SDIO_DataInitStructure); /* Send ACMD13 SD_APP_STAUS with argument as card's RCA.*/ SDIO_CmdInitStructure.SDIO_Argument = 0; SDIO_CmdInitStructure.SDIO_CmdIndex = SDIO_SD_APP_STAUS; SDIO_CmdInitStructure.SDIO_Response = SDIO_Response_Short; SDIO_CmdInitStructure.SDIO_Wait = SDIO_Wait_No; SDIO_CmdInitStructure.SDIO_CPSM = SDIO_CPSM_Enable; SDIO_SendCommand(&SDIO_CmdInitStructure); errorstatus = CmdResp1Error(SDIO_SD_APP_STAUS); if (errorstatus != SD_OK) { return(errorstatus); } while (!(SDIO->STA &(SDIO_FLAG_RXOVERR | SDIO_FLAG_DCRCFAIL | SDIO_FLAG_DTIMEOUT | SDIO_FLAG_DBCKEND | SDIO_FLAG_STBITERR))) { if (SDIO_GetFlagStatus(SDIO_FLAG_RXFIFOHF) != RESET) { for (count = 0; count < 8; count++) { *(psdstatus + count) = SDIO_ReadData(); } psdstatus += 8; } } if (SDIO_GetFlagStatus(SDIO_FLAG_DTIMEOUT) != RESET) { SDIO_ClearFlag(SDIO_FLAG_DTIMEOUT); errorstatus = SD_DATA_TIMEOUT; return(errorstatus); } else if (SDIO_GetFlagStatus(SDIO_FLAG_DCRCFAIL) != RESET) { SDIO_ClearFlag(SDIO_FLAG_DCRCFAIL); errorstatus = SD_DATA_CRC_FAIL; return(errorstatus); } else if (SDIO_GetFlagStatus(SDIO_FLAG_RXOVERR) != RESET) { SDIO_ClearFlag(SDIO_FLAG_RXOVERR); errorstatus = SD_RX_OVERRUN; return(errorstatus); } else if (SDIO_GetFlagStatus(SDIO_FLAG_STBITERR) != RESET) { SDIO_ClearFlag(SDIO_FLAG_STBITERR); errorstatus = SD_START_BIT_ERR; return(errorstatus); } while (SDIO_GetFlagStatus(SDIO_FLAG_RXDAVL) != RESET) { *psdstatus = SDIO_ReadData(); psdstatus++; } /* Clear all the static status flags*/ SDIO_ClearFlag(SDIO_STATIC_FLAGS); psdstatus -= 16; for (count = 0; count < 16; count++) { psdstatus[count] = ((psdstatus[count] & SD_0TO7BITS) << 24) |((psdstatus[count] & SD_8TO15BITS) << 8) | ((psdstatus[count] & SD_16TO23BITS) >> 8) |((psdstatus[count] & SD_24TO31BITS) >> 24); } return(errorstatus); } /** * @brief Allows to process all the interrupts that are high. * @param None * @retval SD_Error: SD Card Error code. */ SD_Error SD_ProcessIRQSrc(void) { uint32_t count = 0, restwords = 0; if (DeviceMode == SD_INTERRUPT_MODE) { if (SDIO_GetITStatus(SDIO_IT_RXFIFOHF) != RESET) { for (count = 0; count < SD_HALFFIFO; count++) { *(DestBuffer + count) = SDIO_ReadData(); } DestBuffer += SD_HALFFIFO; NumberOfBytes += SD_HALFFIFOBYTES; } else if (SDIO_GetITStatus(SDIO_IT_TXFIFOHE) != RESET) { if ((TotalNumberOfBytes - NumberOfBytes) < SD_HALFFIFOBYTES) { restwords = ((TotalNumberOfBytes - NumberOfBytes) % 4 == 0) ? ((TotalNumberOfBytes - NumberOfBytes) / 4) : ((TotalNumberOfBytes - NumberOfBytes) / 4 + 1); for (count = 0; count < restwords; count++, SrcBuffer++, NumberOfBytes += 4) { SDIO_WriteData(*SrcBuffer); } } else { for (count = 0; count < SD_HALFFIFO; count++) { SDIO_WriteData(*(SrcBuffer + count)); } SrcBuffer += SD_HALFFIFO; NumberOfBytes += SD_HALFFIFOBYTES; } } } if (SDIO_GetITStatus(SDIO_IT_DATAEND) != RESET) { if (DeviceMode != SD_DMA_MODE) { while ((SDIO_GetFlagStatus(SDIO_FLAG_RXDAVL) != RESET) && (NumberOfBytes < TotalNumberOfBytes)) { *DestBuffer = SDIO_ReadData(); DestBuffer++; NumberOfBytes += 4; } } if (StopCondition == 1) { TransferError = SD_StopTransfer(); } else { TransferError = SD_OK; } SDIO_ClearITPendingBit(SDIO_IT_DATAEND); SDIO_ITConfig(SDIO_IT_DCRCFAIL | SDIO_IT_DTIMEOUT | SDIO_IT_DATAEND | SDIO_IT_TXFIFOHE | SDIO_IT_RXFIFOHF | SDIO_IT_TXUNDERR | SDIO_IT_RXOVERR | SDIO_IT_STBITERR, DISABLE); TransferEnd = 1; NumberOfBytes = 0; return(TransferError); } if (SDIO_GetITStatus(SDIO_IT_DCRCFAIL) != RESET) { SDIO_ClearITPendingBit(SDIO_IT_DCRCFAIL); SDIO_ITConfig(SDIO_IT_DCRCFAIL | SDIO_IT_DTIMEOUT | SDIO_IT_DATAEND | SDIO_IT_TXFIFOHE | SDIO_IT_RXFIFOHF | SDIO_IT_TXUNDERR | SDIO_IT_RXOVERR | SDIO_IT_STBITERR, DISABLE); NumberOfBytes = 0; TransferError = SD_DATA_CRC_FAIL; return(SD_DATA_CRC_FAIL); } if (SDIO_GetITStatus(SDIO_IT_DTIMEOUT) != RESET) { SDIO_ClearITPendingBit(SDIO_IT_DTIMEOUT); SDIO_ITConfig(SDIO_IT_DCRCFAIL | SDIO_IT_DTIMEOUT | SDIO_IT_DATAEND | SDIO_IT_TXFIFOHE | SDIO_IT_RXFIFOHF | SDIO_IT_TXUNDERR | SDIO_IT_RXOVERR | SDIO_IT_STBITERR, DISABLE); NumberOfBytes = 0; TransferError = SD_DATA_TIMEOUT; return(SD_DATA_TIMEOUT); } if (SDIO_GetITStatus(SDIO_IT_RXOVERR) != RESET) { SDIO_ClearITPendingBit(SDIO_IT_RXOVERR); SDIO_ITConfig(SDIO_IT_DCRCFAIL | SDIO_IT_DTIMEOUT | SDIO_IT_DATAEND | SDIO_IT_TXFIFOHE | SDIO_IT_RXFIFOHF | SDIO_IT_TXUNDERR | SDIO_IT_RXOVERR | SDIO_IT_STBITERR, DISABLE); NumberOfBytes = 0; TransferError = SD_RX_OVERRUN; return(SD_RX_OVERRUN); } if (SDIO_GetITStatus(SDIO_IT_TXUNDERR) != RESET) { SDIO_ClearITPendingBit(SDIO_IT_TXUNDERR); SDIO_ITConfig(SDIO_IT_DCRCFAIL | SDIO_IT_DTIMEOUT | SDIO_IT_DATAEND | SDIO_IT_TXFIFOHE | SDIO_IT_RXFIFOHF | SDIO_IT_TXUNDERR | SDIO_IT_RXOVERR | SDIO_IT_STBITERR, DISABLE); NumberOfBytes = 0; TransferError = SD_TX_UNDERRUN; return(SD_TX_UNDERRUN); } if (SDIO_GetITStatus(SDIO_IT_STBITERR) != RESET) { SDIO_ClearITPendingBit(SDIO_IT_STBITERR); SDIO_ITConfig(SDIO_IT_DCRCFAIL | SDIO_IT_DTIMEOUT | SDIO_IT_DATAEND | SDIO_IT_TXFIFOHE | SDIO_IT_RXFIFOHF | SDIO_IT_TXUNDERR | SDIO_IT_RXOVERR | SDIO_IT_STBITERR, DISABLE); NumberOfBytes = 0; TransferError = SD_START_BIT_ERR; return(SD_START_BIT_ERR); } return(SD_OK); } /** * @brief Checks for error conditions for CMD0. * @param None * @retval SD_Error: SD Card Error code. */ static SD_Error CmdError(void) { SD_Error errorstatus = SD_OK; uint32_t timeout; timeout = SDIO_CMD0TIMEOUT; /* 10000 */ while ((timeout > 0) && (SDIO_GetFlagStatus(SDIO_FLAG_CMDSENT) == RESET)) { timeout--; } if (timeout == 0) { errorstatus = SD_CMD_RSP_TIMEOUT; return(errorstatus); } /* Clear all the static flags */ SDIO_ClearFlag(SDIO_STATIC_FLAGS); return(errorstatus); } /** * @brief Checks for error conditions for R7. * response. * @param None * @retval SD_Error: SD Card Error code. */ static SD_Error CmdResp7Error(void) { SD_Error errorstatus = SD_OK; uint32_t status; uint32_t timeout = SDIO_CMD0TIMEOUT; status = SDIO->STA; while (!(status & (SDIO_FLAG_CCRCFAIL | SDIO_FLAG_CMDREND | SDIO_FLAG_CTIMEOUT)) && (timeout > 0)) { timeout--; status = SDIO->STA; } if ((timeout == 0) || (status & SDIO_FLAG_CTIMEOUT)) { /* Card is not V2.0 complient or card does not support the set voltage range */ errorstatus = SD_CMD_RSP_TIMEOUT; SDIO_ClearFlag(SDIO_FLAG_CTIMEOUT); return(errorstatus); } if (status & SDIO_FLAG_CMDREND) { /* Card is SD V2.0 compliant */ errorstatus = SD_OK; SDIO_ClearFlag(SDIO_FLAG_CMDREND); return(errorstatus); } return(errorstatus); } /** * @brief Checks for error conditions for R1. * response * @param cmd: The sent command index. * @retval SD_Error: SD Card Error code. */ static SD_Error CmdResp1Error(uint8_t cmd) { SD_Error errorstatus = SD_OK; uint32_t status; uint32_t response_r1; status = SDIO->STA; while (!(status & (SDIO_FLAG_CCRCFAIL | SDIO_FLAG_CMDREND | SDIO_FLAG_CTIMEOUT))) { status = SDIO->STA; } if (status & SDIO_FLAG_CTIMEOUT) { errorstatus = SD_CMD_RSP_TIMEOUT; SDIO_ClearFlag(SDIO_FLAG_CTIMEOUT); return(errorstatus); } else if (status & SDIO_FLAG_CCRCFAIL) { errorstatus = SD_CMD_CRC_FAIL; SDIO_ClearFlag(SDIO_FLAG_CCRCFAIL); return(errorstatus); } /* Check response received is of desired command */ if (SDIO_GetCommandResponse() != cmd) { errorstatus = SD_ILLEGAL_CMD; return(errorstatus); } /* Clear all the static flags */ SDIO_ClearFlag(SDIO_STATIC_FLAGS); /* We have received response, retrieve it for analysis */ response_r1 = SDIO_GetResponse(SDIO_RESP1); if ((response_r1 & SD_OCR_ERRORBITS) == SD_ALLZERO) { return(errorstatus); } if (response_r1 & SD_OCR_ADDR_OUT_OF_RANGE) { return(SD_ADDR_OUT_OF_RANGE); } if (response_r1 & SD_OCR_ADDR_MISALIGNED) { return(SD_ADDR_MISALIGNED); } if (response_r1 & SD_OCR_BLOCK_LEN_ERR) { return(SD_BLOCK_LEN_ERR); } if (response_r1 & SD_OCR_ERASE_SEQ_ERR) { return(SD_ERASE_SEQ_ERR); } if (response_r1 & SD_OCR_BAD_ERASE_PARAM) { return(SD_BAD_ERASE_PARAM); } if (response_r1 & SD_OCR_WRITE_PROT_VIOLATION) { return(SD_WRITE_PROT_VIOLATION); } if (response_r1 & SD_OCR_LOCK_UNLOCK_FAILED) { return(SD_LOCK_UNLOCK_FAILED); } if (response_r1 & SD_OCR_COM_CRC_FAILED) { return(SD_COM_CRC_FAILED); } if (response_r1 & SD_OCR_ILLEGAL_CMD) { return(SD_ILLEGAL_CMD); } if (response_r1 & SD_OCR_CARD_ECC_FAILED) { return(SD_CARD_ECC_FAILED); } if (response_r1 & SD_OCR_CC_ERROR) { return(SD_CC_ERROR); } if (response_r1 & SD_OCR_GENERAL_UNKNOWN_ERROR) { return(SD_GENERAL_UNKNOWN_ERROR); } if (response_r1 & SD_OCR_STREAM_READ_UNDERRUN) { return(SD_STREAM_READ_UNDERRUN); } if (response_r1 & SD_OCR_STREAM_WRITE_OVERRUN) { return(SD_STREAM_WRITE_OVERRUN); } if (response_r1 & SD_OCR_CID_CSD_OVERWRIETE) { return(SD_CID_CSD_OVERWRITE); } if (response_r1 & SD_OCR_WP_ERASE_SKIP) { return(SD_WP_ERASE_SKIP); } if (response_r1 & SD_OCR_CARD_ECC_DISABLED) { return(SD_CARD_ECC_DISABLED); } if (response_r1 & SD_OCR_ERASE_RESET) { return(SD_ERASE_RESET); } if (response_r1 & SD_OCR_AKE_SEQ_ERROR) { return(SD_AKE_SEQ_ERROR); } return(errorstatus); } /** * @brief Checks for error conditions for R3 (OCR). * response. * @param None * @retval SD_Error: SD Card Error code. */ static SD_Error CmdResp3Error(void) { SD_Error errorstatus = SD_OK; uint32_t status; status = SDIO->STA; while (!(status & (SDIO_FLAG_CCRCFAIL | SDIO_FLAG_CMDREND | SDIO_FLAG_CTIMEOUT))) { status = SDIO->STA; } if (status & SDIO_FLAG_CTIMEOUT) { errorstatus = SD_CMD_RSP_TIMEOUT; SDIO_ClearFlag(SDIO_FLAG_CTIMEOUT); return(errorstatus); } /* Clear all the static flags */ SDIO_ClearFlag(SDIO_STATIC_FLAGS); return(errorstatus); } /** * @brief Checks for error conditions for R2 (CID or CSD). * response. * @param None * @retval SD_Error: SD Card Error code. */ static SD_Error CmdResp2Error(void) { SD_Error errorstatus = SD_OK; uint32_t status; status = SDIO->STA; while (!(status & (SDIO_FLAG_CCRCFAIL | SDIO_FLAG_CTIMEOUT | SDIO_FLAG_CMDREND))) { status = SDIO->STA; } if (status & SDIO_FLAG_CTIMEOUT) { errorstatus = SD_CMD_RSP_TIMEOUT; SDIO_ClearFlag(SDIO_FLAG_CTIMEOUT); return(errorstatus); } else if (status & SDIO_FLAG_CCRCFAIL) { errorstatus = SD_CMD_CRC_FAIL; SDIO_ClearFlag(SDIO_FLAG_CCRCFAIL); return(errorstatus); } /* Clear all the static flags */ SDIO_ClearFlag(SDIO_STATIC_FLAGS); return(errorstatus); } /** * @brief Checks for error conditions for R6 (RCA). * response. * @param cmd: The sent command index. * @param prca: pointer to the variable that will contain the SD * card relative address RCA. * @retval SD_Error: SD Card Error code. */ static SD_Error CmdResp6Error(uint8_t cmd, uint16_t *prca) { SD_Error errorstatus = SD_OK; uint32_t status; uint32_t response_r1; status = SDIO->STA; while (!(status & (SDIO_FLAG_CCRCFAIL | SDIO_FLAG_CTIMEOUT | SDIO_FLAG_CMDREND))) { status = SDIO->STA; } if (status & SDIO_FLAG_CTIMEOUT) { errorstatus = SD_CMD_RSP_TIMEOUT; SDIO_ClearFlag(SDIO_FLAG_CTIMEOUT); return(errorstatus); } else if (status & SDIO_FLAG_CCRCFAIL) { errorstatus = SD_CMD_CRC_FAIL; SDIO_ClearFlag(SDIO_FLAG_CCRCFAIL); return(errorstatus); } /* Check response received is of desired command */ if (SDIO_GetCommandResponse() != cmd) { errorstatus = SD_ILLEGAL_CMD; return(errorstatus); } /* Clear all the static flags */ SDIO_ClearFlag(SDIO_STATIC_FLAGS); /* We have received response, retrieve it. */ response_r1 = SDIO_GetResponse(SDIO_RESP1); if (SD_ALLZERO == (response_r1 & (SD_R6_GENERAL_UNKNOWN_ERROR | SD_R6_ILLEGAL_CMD | SD_R6_COM_CRC_FAILED))) { *prca = (uint16_t) (response_r1 >> 16); return(errorstatus); } if (response_r1 & SD_R6_GENERAL_UNKNOWN_ERROR) { return(SD_GENERAL_UNKNOWN_ERROR); } if (response_r1 & SD_R6_ILLEGAL_CMD) { return(SD_ILLEGAL_CMD); } if (response_r1 & SD_R6_COM_CRC_FAILED) { return(SD_COM_CRC_FAILED); } return(errorstatus); } /** * @brief Enables or disables the SDIO wide bus mode. * @param NewState: new state of the SDIO wide bus mode. * This parameter can be: ENABLE or DISABLE. * @retval SD_Error: SD Card Error code. */ static SD_Error SDEnWideBus(FunctionalState NewState) { SD_Error errorstatus = SD_OK; uint32_t scr[2] = {0, 0}; if (SDIO_GetResponse(SDIO_RESP1) & SD_CARD_LOCKED) { errorstatus = SD_LOCK_UNLOCK_FAILED; return(errorstatus); } /* Get SCR Register */ errorstatus = FindSCR(RCA, scr); if (errorstatus != SD_OK) { return(errorstatus); } /* If wide bus operation to be enabled */ if (NewState == ENABLE) { /* If requested card supports wide bus operation */ if ((scr[1] & SD_WIDE_BUS_SUPPORT) != SD_ALLZERO) { /* Send CMD55 APP_CMD with argument as card's RCA.*/ SDIO_CmdInitStructure.SDIO_Argument = (uint32_t) RCA << 16; SDIO_CmdInitStructure.SDIO_CmdIndex = SDIO_APP_CMD; SDIO_CmdInitStructure.SDIO_Response = SDIO_Response_Short; SDIO_CmdInitStructure.SDIO_Wait = SDIO_Wait_No; SDIO_CmdInitStructure.SDIO_CPSM = SDIO_CPSM_Enable; SDIO_SendCommand(&SDIO_CmdInitStructure); errorstatus = CmdResp1Error(SDIO_APP_CMD); if (errorstatus != SD_OK) { return(errorstatus); } /* Send ACMD6 APP_CMD with argument as 2 for wide bus mode */ SDIO_CmdInitStructure.SDIO_Argument = 0x2; SDIO_CmdInitStructure.SDIO_CmdIndex = SDIO_APP_SD_SET_BUSWIDTH; SDIO_CmdInitStructure.SDIO_Response = SDIO_Response_Short; SDIO_CmdInitStructure.SDIO_Wait = SDIO_Wait_No; SDIO_CmdInitStructure.SDIO_CPSM = SDIO_CPSM_Enable; SDIO_SendCommand(&SDIO_CmdInitStructure); errorstatus = CmdResp1Error(SDIO_APP_SD_SET_BUSWIDTH); if (errorstatus != SD_OK) { return(errorstatus); } return(errorstatus); } else { errorstatus = SD_REQUEST_NOT_APPLICABLE; return(errorstatus); } } /* If wide bus operation to be disabled */ else { /* If requested card supports 1 bit mode operation */ if ((scr[1] & SD_SINGLE_BUS_SUPPORT) != SD_ALLZERO) { /* Send CMD55 APP_CMD with argument as card's RCA.*/ SDIO_CmdInitStructure.SDIO_Argument = (uint32_t) RCA << 16; SDIO_CmdInitStructure.SDIO_CmdIndex = SDIO_APP_CMD; SDIO_CmdInitStructure.SDIO_Response = SDIO_Response_Short; SDIO_CmdInitStructure.SDIO_Wait = SDIO_Wait_No; SDIO_CmdInitStructure.SDIO_CPSM = SDIO_CPSM_Enable; SDIO_SendCommand(&SDIO_CmdInitStructure); errorstatus = CmdResp1Error(SDIO_APP_CMD); if (errorstatus != SD_OK) { return(errorstatus); } /* Send ACMD6 APP_CMD with argument as 2 for wide bus mode */ SDIO_CmdInitStructure.SDIO_Argument = 0x00; SDIO_CmdInitStructure.SDIO_CmdIndex = SDIO_APP_SD_SET_BUSWIDTH; SDIO_CmdInitStructure.SDIO_Response = SDIO_Response_Short; SDIO_CmdInitStructure.SDIO_Wait = SDIO_Wait_No; SDIO_CmdInitStructure.SDIO_CPSM = SDIO_CPSM_Enable; SDIO_SendCommand(&SDIO_CmdInitStructure); errorstatus = CmdResp1Error(SDIO_APP_SD_SET_BUSWIDTH); if (errorstatus != SD_OK) { return(errorstatus); } return(errorstatus); } else { errorstatus = SD_REQUEST_NOT_APPLICABLE; return(errorstatus); } } } /** * @brief Checks if the SD card is in programming state. * @param pstatus: pointer to the variable that will contain the SD * card state. * @retval SD_Error: SD Card Error code. */ static SD_Error IsCardProgramming(uint8_t *pstatus) { SD_Error errorstatus = SD_OK; __IO uint32_t respR1 = 0, status = 0; SDIO_CmdInitStructure.SDIO_Argument = (uint32_t) RCA << 16; SDIO_CmdInitStructure.SDIO_CmdIndex = SDIO_SEND_STATUS; SDIO_CmdInitStructure.SDIO_Response = SDIO_Response_Short; SDIO_CmdInitStructure.SDIO_Wait = SDIO_Wait_No; SDIO_CmdInitStructure.SDIO_CPSM = SDIO_CPSM_Enable; SDIO_SendCommand(&SDIO_CmdInitStructure); status = SDIO->STA; while (!(status & (SDIO_FLAG_CCRCFAIL | SDIO_FLAG_CMDREND | SDIO_FLAG_CTIMEOUT))) { status = SDIO->STA; } if (status & SDIO_FLAG_CTIMEOUT) { errorstatus = SD_CMD_RSP_TIMEOUT; SDIO_ClearFlag(SDIO_FLAG_CTIMEOUT); return(errorstatus); } else if (status & SDIO_FLAG_CCRCFAIL) { errorstatus = SD_CMD_CRC_FAIL; SDIO_ClearFlag(SDIO_FLAG_CCRCFAIL); return(errorstatus); } status = (uint32_t)SDIO_GetCommandResponse(); /* Check response received is of desired command */ if (status != SDIO_SEND_STATUS) { errorstatus = SD_ILLEGAL_CMD; return(errorstatus); } /* Clear all the static flags */ SDIO_ClearFlag(SDIO_STATIC_FLAGS); /* We have received response, retrieve it for analysis */ respR1 = SDIO_GetResponse(SDIO_RESP1); /* Find out card status */ *pstatus = (uint8_t) ((respR1 >> 9) & 0x0000000F); if ((respR1 & SD_OCR_ERRORBITS) == SD_ALLZERO) { return(errorstatus); } if (respR1 & SD_OCR_ADDR_OUT_OF_RANGE) { return(SD_ADDR_OUT_OF_RANGE); } if (respR1 & SD_OCR_ADDR_MISALIGNED) { return(SD_ADDR_MISALIGNED); } if (respR1 & SD_OCR_BLOCK_LEN_ERR) { return(SD_BLOCK_LEN_ERR); } if (respR1 & SD_OCR_ERASE_SEQ_ERR) { return(SD_ERASE_SEQ_ERR); } if (respR1 & SD_OCR_BAD_ERASE_PARAM) { return(SD_BAD_ERASE_PARAM); } if (respR1 & SD_OCR_WRITE_PROT_VIOLATION) { return(SD_WRITE_PROT_VIOLATION); } if (respR1 & SD_OCR_LOCK_UNLOCK_FAILED) { return(SD_LOCK_UNLOCK_FAILED); } if (respR1 & SD_OCR_COM_CRC_FAILED) { return(SD_COM_CRC_FAILED); } if (respR1 & SD_OCR_ILLEGAL_CMD) { return(SD_ILLEGAL_CMD); } if (respR1 & SD_OCR_CARD_ECC_FAILED) { return(SD_CARD_ECC_FAILED); } if (respR1 & SD_OCR_CC_ERROR) { return(SD_CC_ERROR); } if (respR1 & SD_OCR_GENERAL_UNKNOWN_ERROR) { return(SD_GENERAL_UNKNOWN_ERROR); } if (respR1 & SD_OCR_STREAM_READ_UNDERRUN) { return(SD_STREAM_READ_UNDERRUN); } if (respR1 & SD_OCR_STREAM_WRITE_OVERRUN) { return(SD_STREAM_WRITE_OVERRUN); } if (respR1 & SD_OCR_CID_CSD_OVERWRIETE) { return(SD_CID_CSD_OVERWRITE); } if (respR1 & SD_OCR_WP_ERASE_SKIP) { return(SD_WP_ERASE_SKIP); } if (respR1 & SD_OCR_CARD_ECC_DISABLED) { return(SD_CARD_ECC_DISABLED); } if (respR1 & SD_OCR_ERASE_RESET) { return(SD_ERASE_RESET); } if (respR1 & SD_OCR_AKE_SEQ_ERROR) { return(SD_AKE_SEQ_ERROR); } return(errorstatus); } /** * @brief Find the SD card SCR register value. * @param rca: selected card address. * @param pscr: pointer to the buffer that will contain the SCR value. * @retval SD_Error: SD Card Error code. */ static SD_Error FindSCR(uint16_t rca, uint32_t *pscr) { uint32_t index = 0; SD_Error errorstatus = SD_OK; uint32_t tempscr[2] = {0, 0}; /* Set Block Size To 8 Bytes */ /* Send CMD55 APP_CMD with argument as card's RCA */ SDIO_CmdInitStructure.SDIO_Argument = (uint32_t)8; SDIO_CmdInitStructure.SDIO_CmdIndex = SDIO_SET_BLOCKLEN; SDIO_CmdInitStructure.SDIO_Response = SDIO_Response_Short; SDIO_CmdInitStructure.SDIO_Wait = SDIO_Wait_No; SDIO_CmdInitStructure.SDIO_CPSM = SDIO_CPSM_Enable; SDIO_SendCommand(&SDIO_CmdInitStructure); errorstatus = CmdResp1Error(SDIO_SET_BLOCKLEN); if (errorstatus != SD_OK) { return(errorstatus); } /* Send CMD55 APP_CMD with argument as card's RCA */ SDIO_CmdInitStructure.SDIO_Argument = (uint32_t) RCA << 16; SDIO_CmdInitStructure.SDIO_CmdIndex = SDIO_APP_CMD; SDIO_CmdInitStructure.SDIO_Response = SDIO_Response_Short; SDIO_CmdInitStructure.SDIO_Wait = SDIO_Wait_No; SDIO_CmdInitStructure.SDIO_CPSM = SDIO_CPSM_Enable; SDIO_SendCommand(&SDIO_CmdInitStructure); errorstatus = CmdResp1Error(SDIO_APP_CMD); if (errorstatus != SD_OK) { return(errorstatus); } SDIO_DataInitStructure.SDIO_DataTimeOut = SD_DATATIMEOUT; SDIO_DataInitStructure.SDIO_DataLength = 8; SDIO_DataInitStructure.SDIO_DataBlockSize = SDIO_DataBlockSize_8b; SDIO_DataInitStructure.SDIO_TransferDir = SDIO_TransferDir_ToSDIO; SDIO_DataInitStructure.SDIO_TransferMode = SDIO_TransferMode_Block; SDIO_DataInitStructure.SDIO_DPSM = SDIO_DPSM_Enable; SDIO_DataConfig(&SDIO_DataInitStructure); /* make a delay */ { volatile uint32_t delay; for(delay = 0; delay < 20; delay++); } /* Send ACMD51 SD_APP_SEND_SCR with argument as 0 */ SDIO_CmdInitStructure.SDIO_Argument = 0x0; SDIO_CmdInitStructure.SDIO_CmdIndex = SDIO_SD_APP_SEND_SCR; SDIO_CmdInitStructure.SDIO_Response = SDIO_Response_Short; SDIO_CmdInitStructure.SDIO_Wait = SDIO_Wait_No; SDIO_CmdInitStructure.SDIO_CPSM = SDIO_CPSM_Enable; SDIO_SendCommand(&SDIO_CmdInitStructure); errorstatus = CmdResp1Error(SDIO_SD_APP_SEND_SCR); if (errorstatus != SD_OK) { return(errorstatus); } while (!(SDIO->STA & (SDIO_FLAG_RXOVERR | SDIO_FLAG_DCRCFAIL | SDIO_FLAG_DTIMEOUT | SDIO_FLAG_DBCKEND | SDIO_FLAG_STBITERR))) { if (SDIO_GetFlagStatus(SDIO_FLAG_RXDAVL) != RESET) { *(tempscr + index) = SDIO_ReadData(); index++; } } if (SDIO_GetFlagStatus(SDIO_FLAG_DTIMEOUT) != RESET) { SDIO_ClearFlag(SDIO_FLAG_DTIMEOUT); errorstatus = SD_DATA_TIMEOUT; return(errorstatus); } else if (SDIO_GetFlagStatus(SDIO_FLAG_DCRCFAIL) != RESET) { SDIO_ClearFlag(SDIO_FLAG_DCRCFAIL); errorstatus = SD_DATA_CRC_FAIL; return(errorstatus); } else if (SDIO_GetFlagStatus(SDIO_FLAG_RXOVERR) != RESET) { SDIO_ClearFlag(SDIO_FLAG_RXOVERR); errorstatus = SD_RX_OVERRUN; return(errorstatus); } else if (SDIO_GetFlagStatus(SDIO_FLAG_STBITERR) != RESET) { SDIO_ClearFlag(SDIO_FLAG_STBITERR); errorstatus = SD_START_BIT_ERR; return(errorstatus); } /* Clear all the static flags */ SDIO_ClearFlag(SDIO_STATIC_FLAGS); *(pscr + 1) = ((tempscr[0] & SD_0TO7BITS) << 24) | ((tempscr[0] & SD_8TO15BITS) << 8) | ((tempscr[0] & SD_16TO23BITS) >> 8) | ((tempscr[0] & SD_24TO31BITS) >> 24); *(pscr) = ((tempscr[1] & SD_0TO7BITS) << 24) | ((tempscr[1] & SD_8TO15BITS) << 8) | ((tempscr[1] & SD_16TO23BITS) >> 8) | ((tempscr[1] & SD_24TO31BITS) >> 24); return(errorstatus); } /** * @brief Converts the number of bytes in power of two and returns the * power. * @param NumberOfBytes: number of bytes. * @retval None */ static uint8_t convert_from_bytes_to_power_of_two(uint16_t NumberOfBytes) { uint8_t count = 0; while (NumberOfBytes != 1) { NumberOfBytes >>= 1; count++; } return(count); } /** * @brief Configures the SDIO Corresponding GPIO Ports * @param None * @retval None */ static void GPIO_Configuration(void) { GPIO_InitTypeDef GPIO_InitStructure; /* GPIOC and GPIOD Periph clock enable */ RCC_APB2PeriphClockCmd(RCC_APB2Periph_GPIOC | RCC_APB2Periph_GPIOD, ENABLE); /* Configure PC.08, PC.09, PC.10, PC.11, PC.12 pin: D0, D1, D2, D3, CLK pin */ GPIO_InitStructure.GPIO_Pin = GPIO_Pin_8 | GPIO_Pin_9 | GPIO_Pin_10 | GPIO_Pin_11 | GPIO_Pin_12; GPIO_InitStructure.GPIO_Speed = GPIO_Speed_50MHz; GPIO_InitStructure.GPIO_Mode = GPIO_Mode_AF_PP; GPIO_Init(GPIOC, &GPIO_InitStructure); /* Configure PD.02 CMD line */ GPIO_InitStructure.GPIO_Pin = GPIO_Pin_2; GPIO_Init(GPIOD, &GPIO_InitStructure); } /** * @brief Configures the DMA2 Channel4 for SDIO Tx request. * @param BufferSRC: pointer to the source buffer * @param BufferSize: buffer size * @retval None */ static void DMA_TxConfiguration(uint32_t *BufferSRC, uint32_t BufferSize) { DMA_InitTypeDef DMA_InitStructure; DMA_ClearFlag(DMA2_FLAG_TC4 | DMA2_FLAG_TE4 | DMA2_FLAG_HT4 | DMA2_FLAG_GL4); /* DMA2 Channel4 disable */ DMA_Cmd(DMA2_Channel4, DISABLE); /* DMA2 Channel4 Config */ DMA_InitStructure.DMA_PeripheralBaseAddr = (uint32_t)SDIO_FIFO_Address; DMA_InitStructure.DMA_MemoryBaseAddr = (uint32_t)BufferSRC; DMA_InitStructure.DMA_DIR = DMA_DIR_PeripheralDST; DMA_InitStructure.DMA_BufferSize = BufferSize / 4; DMA_InitStructure.DMA_PeripheralInc = DMA_PeripheralInc_Disable; DMA_InitStructure.DMA_MemoryInc = DMA_MemoryInc_Enable; DMA_InitStructure.DMA_PeripheralDataSize = DMA_PeripheralDataSize_Word; DMA_InitStructure.DMA_MemoryDataSize = DMA_MemoryDataSize_Word; DMA_InitStructure.DMA_Mode = DMA_Mode_Normal; DMA_InitStructure.DMA_Priority = DMA_Priority_High; DMA_InitStructure.DMA_M2M = DMA_M2M_Disable; DMA_Init(DMA2_Channel4, &DMA_InitStructure); /* DMA2 Channel4 enable */ DMA_Cmd(DMA2_Channel4, ENABLE); } /** * @brief Configures the DMA2 Channel4 for SDIO Rx request. * @param BufferDST: pointer to the destination buffer * @param BufferSize: buffer size * @retval None */ static void DMA_RxConfiguration(uint32_t *BufferDST, uint32_t BufferSize) { DMA_InitTypeDef DMA_InitStructure; DMA_ClearFlag(DMA2_FLAG_TC4 | DMA2_FLAG_TE4 | DMA2_FLAG_HT4 | DMA2_FLAG_GL4); /* DMA2 Channel4 disable */ DMA_Cmd(DMA2_Channel4, DISABLE); /* DMA2 Channel4 Config */ DMA_InitStructure.DMA_PeripheralBaseAddr = (uint32_t)SDIO_FIFO_Address; DMA_InitStructure.DMA_MemoryBaseAddr = (uint32_t)BufferDST; DMA_InitStructure.DMA_DIR = DMA_DIR_PeripheralSRC; DMA_InitStructure.DMA_BufferSize = BufferSize / 4; DMA_InitStructure.DMA_PeripheralInc = DMA_PeripheralInc_Disable; DMA_InitStructure.DMA_MemoryInc = DMA_MemoryInc_Enable; DMA_InitStructure.DMA_PeripheralDataSize = DMA_PeripheralDataSize_Word; DMA_InitStructure.DMA_MemoryDataSize = DMA_MemoryDataSize_Word; DMA_InitStructure.DMA_Mode = DMA_Mode_Normal; DMA_InitStructure.DMA_Priority = DMA_Priority_High; DMA_InitStructure.DMA_M2M = DMA_M2M_Disable; DMA_Init(DMA2_Channel4, &DMA_InitStructure); /* DMA2 Channel4 enable */ DMA_Cmd(DMA2_Channel4, ENABLE); } /** * @} */ /** * @} */ /******************* (C) COPYRIGHT 2009 STMicroelectronics *****END OF FILE****/ /* * RT-Thread SD Card Driver * 20100715 Bernard support SDHC card great than 4G. */ #include #include /* set sector size to 512 */ #define SECTOR_SIZE 512 static struct rt_device sdcard_device; static SD_CardInfo SDCardInfo; static struct dfs_partition part; static struct rt_semaphore sd_lock; static rt_uint8_t _sdcard_buffer[SECTOR_SIZE]; /* RT-Thread Device Driver Interface */ static rt_err_t rt_sdcard_init(rt_device_t dev) { NVIC_InitTypeDef NVIC_InitStructure; NVIC_InitStructure.NVIC_IRQChannel = SDIO_IRQn; NVIC_InitStructure.NVIC_IRQChannelPreemptionPriority = 0; NVIC_InitStructure.NVIC_IRQChannelSubPriority = 0; NVIC_InitStructure.NVIC_IRQChannelCmd = ENABLE; NVIC_Init(&NVIC_InitStructure); if (rt_sem_init(&sd_lock, "sdlock", 1, RT_IPC_FLAG_FIFO) != RT_EOK) { rt_kprintf("init sd lock semaphore failed\n"); } return RT_EOK; } static rt_err_t rt_sdcard_open(rt_device_t dev, rt_uint16_t oflag) { return RT_EOK; } static rt_err_t rt_sdcard_close(rt_device_t dev) { return RT_EOK; } static rt_size_t rt_sdcard_read(rt_device_t dev, rt_off_t pos, void* buffer, rt_size_t size) { SD_Error status; rt_uint32_t retry; rt_uint32_t factor; if (CardType == SDIO_HIGH_CAPACITY_SD_CARD) factor = 1; else factor = SECTOR_SIZE; rt_sem_take(&sd_lock, RT_WAITING_FOREVER); retry = 3; while(retry) { /* read all sectors */ if (((rt_uint32_t)buffer % 4 != 0) || ((rt_uint32_t)buffer > 0x20080000)) { rt_uint32_t index; /* which is not alignment with 4 or chip SRAM */ for (index = 0; index < size; index ++) { status = SD_ReadBlock((part.offset + index + pos) * factor, (uint32_t*)_sdcard_buffer, SECTOR_SIZE); if (status != SD_OK) break; /* copy to the buffer */ rt_memcpy(((rt_uint8_t*)buffer + index * SECTOR_SIZE), _sdcard_buffer, SECTOR_SIZE); } } else { if (size == 1) { status = SD_ReadBlock((part.offset + pos) * factor, (uint32_t*)buffer, SECTOR_SIZE); } else { status = SD_ReadMultiBlocks((part.offset + pos) * factor, (uint32_t*)buffer, SECTOR_SIZE, size); } } if (status == SD_OK) break; retry --; } rt_sem_release(&sd_lock); if (status == SD_OK) return size; rt_kprintf("read failed: %d, buffer 0x%08x\n", status, buffer); return 0; } static rt_size_t rt_sdcard_write (rt_device_t dev, rt_off_t pos, const void* buffer, rt_size_t size) { SD_Error status; rt_uint32_t factor; if (CardType == SDIO_HIGH_CAPACITY_SD_CARD) factor = 1; else factor = SECTOR_SIZE; rt_sem_take(&sd_lock, RT_WAITING_FOREVER); /* read all sectors */ if (((rt_uint32_t)buffer % 4 != 0) || ((rt_uint32_t)buffer > 0x20080000)) { rt_uint32_t index; /* which is not alignment with 4 or not chip SRAM */ for (index = 0; index < size; index ++) { /* copy to the buffer */ rt_memcpy(_sdcard_buffer, ((rt_uint8_t*)buffer + index * SECTOR_SIZE), SECTOR_SIZE); status = SD_WriteBlock((part.offset + index + pos) * factor, (uint32_t*)_sdcard_buffer, SECTOR_SIZE); if (status != SD_OK) break; } } else { if (size == 1) { status = SD_WriteBlock((part.offset + pos) * factor, (uint32_t*)buffer, SECTOR_SIZE); } else { status = SD_WriteMultiBlocks((part.offset + pos) * factor, (uint32_t*)buffer, SECTOR_SIZE, size); } } rt_sem_release(&sd_lock); if (status == SD_OK) return size; rt_kprintf("write failed: %d, buffer 0x%08x\n", status, buffer); return 0; } static rt_err_t rt_sdcard_control(rt_device_t dev, int cmd, void *args) { RT_ASSERT(dev != RT_NULL); if (cmd == RT_DEVICE_CTRL_BLK_GETGEOME) { struct rt_device_blk_geometry *geometry; geometry = (struct rt_device_blk_geometry *)args; if (geometry == RT_NULL) return -RT_ERROR; geometry->bytes_per_sector = 512; geometry->block_size = SDCardInfo.CardBlockSize; if (CardType == SDIO_HIGH_CAPACITY_SD_CARD) geometry->sector_count = (SDCardInfo.SD_csd.DeviceSize + 1) * 1024; else geometry->sector_count = SDCardInfo.CardCapacity/SDCardInfo.CardBlockSize; } return RT_EOK; } int rt_hw_sdcard_init(void) { /* SDIO POWER */ GPIO_InitTypeDef GPIO_InitStructure; RCC_APB2PeriphClockCmd(RCC_APB2Periph_GPIOC,ENABLE); GPIO_InitStructure.GPIO_Pin = GPIO_Pin_6; GPIO_InitStructure.GPIO_Mode = GPIO_Mode_Out_PP; GPIO_InitStructure.GPIO_Speed = GPIO_Speed_2MHz; GPIO_Init(GPIOC,&GPIO_InitStructure); GPIO_ResetBits(GPIOC,GPIO_Pin_6); /* SD card power up */ // delay same time for SD card power up if (SD_Init() == SD_OK) { SD_Error status; rt_uint8_t *sector; status = SD_GetCardInfo(&SDCardInfo); if (status != SD_OK) goto __return; status = SD_SelectDeselect((u32) (SDCardInfo.RCA << 16)); if (status != SD_OK) goto __return; SD_EnableWideBusOperation(SDIO_BusWide_4b); SD_SetDeviceMode(SD_DMA_MODE); /* get the first sector to read partition table */ sector = (rt_uint8_t*) rt_malloc (512); if (sector == RT_NULL) { rt_kprintf("allocate partition sector buffer failed\n"); return 0; } status = SD_ReadBlock(0, (uint32_t*)sector, 512); if (status == SD_OK) { /* get the first partition */ if (dfs_filesystem_get_partition(&part, sector, 0) != 0) { /* there is no partition */ part.offset = 0; part.size = 0; } } else { /* there is no partition table */ part.offset = 0; part.size = 0; } /* release sector buffer */ rt_free(sector); /* register sdcard device */ sdcard_device.type = RT_Device_Class_Block; sdcard_device.init = rt_sdcard_init; sdcard_device.open = rt_sdcard_open; sdcard_device.close = rt_sdcard_close; sdcard_device.read = rt_sdcard_read; sdcard_device.write = rt_sdcard_write; sdcard_device.control = rt_sdcard_control; /* no private */ sdcard_device.user_data = &SDCardInfo; rt_device_register(&sdcard_device, "sd0", RT_DEVICE_FLAG_RDWR | RT_DEVICE_FLAG_REMOVABLE | RT_DEVICE_FLAG_STANDALONE); return 0; } __return: rt_kprintf("sdcard init failed\n"); GPIO_SetBits(GPIOC,GPIO_Pin_6); /* SD card power down */ return 0; } INIT_DEVICE_EXPORT(rt_hw_sdcard_init); void SDIO_IRQHandler(void) { /* enter interrupt */ rt_interrupt_enter(); /* Process All SDIO Interrupt Sources */ SD_ProcessIRQSrc(); /* leave interrupt */ rt_interrupt_leave(); }