/* * Hardware SPI driver for MMC/SD/SDHC cards * * Part of esp-open-rtos * Copyright (C) 2016 Ruslan V. Uss * BSD Licensed as described in the file LICENSE */ #include #include #include #include "sdio.h" #define BUS 1 #define BV(x) (1 << (x)) #define MS 1000 #define INIT_TIMEOUT_US (2000 * MS) #define IO_TIMEOUT_US (500 * MS) #define MAX_ERR_COUNT 0xff #define R1_IDLE_STATE 0 #define R1_ERASE_RESET 1 #define R1_ILLEGAL_CMD 2 #define R1_CRC_ERR 3 #define R1_ERASE_SEQ_ERR 4 #define R1_ADDR_ERR 5 #define R1_PARAM_ERR 6 #define R1_BUSY 7 #define R2_LOCKED 8 #define R2_WPE_SKIP_LF 9 #define R2_ERROR 10 #define R2_CC_ERROR 11 #define R2_ECC_FAILED 12 #define R2_WP_VIOLATION 13 #define R2_ERASE_PARAM 14 #define R2_OUT_OF_RANGE 15 #define OCR_CCS 30 #define OCR_BUSY 31 #define OCR_SDHC (BV(OCR_CCS) | BV(OCR_BUSY)) #define TOKEN_SINGLE_TRAN 0xfe #define TOKEN_MULTI_TRAN 0xfc #define TOKEN_STOP_TRAN 0xfd #define WRITE_RES_MASK 0x1f #define WRITE_RES_OK 0x05 #define CMD0 0x00 // GO_IDLE_STATE - Resets the SD Memory Card #define CMD1 0x01 // SEND_OP_COND - Sends host capacity support information // and activates the card's initialization process. #define CMD6 0x06 // SWITCH_FUNC - Checks switchable function (mode 0) and // switches card function (mode 1). #define CMD8 0x08 // SEND_IF_COND - Sends SD Memory Card interface condition // that includes host supply voltage information and asks // the accessed card whether card can operate in supplied // voltage range. #define CMD9 0x09 // SEND_CSD - Asks the selected card to send its // card-specific data (CSD register) #define CMD10 0x0a // SEND_CID - Asks the selected card to send its card // identification (CID register) #define CMD12 0x0c // STOP_TRANSMISSION - Forces the card to stop transmission // in Multiple Block Read Operation #define CMD13 0x0d // SEND_STATUS - Asks the selected card to send its // status register. #define CMD16 0x10 // SET_BLOCKLEN - Sets a block length (in bytes) for all // following block commands (read and write) of a Standard // Capacity Card. Block length of the read and write // commands are fixed to 512 bytes in a High Capacity Card. // The length of LOCK_UNLOCK command is set by this command // in both capacity cards. #define CMD17 0x11 // READ_SINGLE_BLOCK - Reads a block of the size selected // by the SET_BLOCKLEN command. #define CMD18 0x12 // READ_MULTIPLE_BLOCK - Continuously transfers data blocks // from card to host until interrupted by a // STOP_TRANSMISSION command. #define CMD24 0x18 // WRITE_BLOCK - Writes a block of the size selected by the // SET_BLOCKLEN command. #define CMD25 0x19 // WRITE_MULTIPLE_BLOCK - Continuously writes blocks of // data until ’Stop Tran’ token is sent (instead ’Start // Block’). #define CMD27 0x1b // PROGRAM_CSD - Programming of the programmable bits of // the CSD. #define CMD28 0x1c // SET_WRITE_PROT #define CMD29 0x1d // CLR_WRITE_PROT #define CMD32 0x20 // ERASE_WR_BLK_START - Sets the address of the first block // to be erased. #define CMD33 0x21 // ERASE_WR_BLK_END - Sets the address of the last block of // the continuous range to be erased. #define CMD38 0x26 // ERASE - Erases all previously selected blocks. #define CMD55 0x37 // APP_CMD - Defines to the card that the next command is // an application specific command rather than a standard // command. #define CMD58 0x3a // READ_OCR - Reads the OCR register of a card. #define CMD59 0x3b // CRC_ON_OFF - Turns the CRC option on or off. #define ACMD23 0x17 // SET_WR_BLK_ERASE_COUNT - Sets the number of write blocks // to be pre-erased before writing #define ACMD41 0x29 // SD_SEND_OP_COMD - Sends host capacity support information // and activates the card's initialization process static uint8_t crc7(const uint8_t* data, uint8_t n) { uint8_t crc = 0; for (uint8_t i = 0; i < n; i++) { uint8_t d = data[i]; for (uint8_t j = 0; j < 8; j++) { crc <<= 1; if ((d & 0x80) ^ (crc & 0x80)) crc ^= 0x09; d <<= 1; } } return (crc << 1) | 1; } static uint16_t crc_ccitt(const uint8_t *data, size_t n) { uint16_t crc = 0; for (size_t i = 0; i < n; i++) { crc = (uint8_t)(crc >> 8) | (crc << 8); crc ^= data[i]; crc ^= (uint8_t)(crc & 0xff) >> 4; crc ^= crc << 12; crc ^= (crc & 0xff) << 5; } return crc; } #define spi_cs_low(card) do { gpio_write(card->cs_pin, false); } while(0) #define spi_cs_high(card) do { gpio_write(card->cs_pin, true); } while(0) #define spi_read_byte() (spi_transfer_8(BUS, 0xff)) #define spi_read_word() (((uint16_t)spi_read_byte() << 8) | spi_read_byte()) #define spi_read_dword() (((uint32_t)spi_read_byte() << 24) | ((uint32_t)spi_read_byte() << 16) | ((uint32_t)spi_read_byte() << 8) | spi_read_byte()) #define spi_skip_word() do { spi_read_byte(); spi_read_byte(); } while(0) #define spi_skip_dword() do { spi_read_byte(); spi_read_byte(); spi_read_byte(); spi_read_byte(); } while(0) #define timeout_expired(start, len) ((uint32_t)(sdk_system_get_time() - (start)) >= (len)) inline static uint16_t spi_write_word(uint16_t word) { return (spi_transfer_8(BUS, word >> 8) << 8) | spi_transfer_8(BUS, word); } inline static void spi_read_bytes(uint8_t *dst, size_t size) { for (uint8_t *offs = dst; offs < dst + size; offs ++) *offs = spi_read_byte(); } static bool wait() { uint32_t start = sdk_system_get_time(); while (spi_read_byte() != 0xff) if (timeout_expired(start, IO_TIMEOUT_US)) return false; return true; } static uint8_t command(sdio_card_t *card, uint8_t cmd, uint32_t arg) { uint8_t buf[6] = { cmd | 0x40, arg >> 24, arg >> 16, arg >> 8, arg }; if (card->crc_enabled) buf[5] = crc7(buf, 5); else buf[5] = cmd == CMD0 ? 0x95 : 0x87; spi_cs_low(card); wait(); spi_transfer(BUS, buf, NULL, 6, SPI_8BIT); // R1b response if (cmd == CMD12 || cmd == CMD28 || cmd == CMD29) spi_read_byte(); uint8_t res; for (uint8_t i = 0; i < MAX_ERR_COUNT; i ++) { res = spi_read_byte(); if (!(res & BV(R1_BUSY))) break; } return res; } inline static uint8_t app_command(sdio_card_t *card, uint8_t cmd, uint32_t arg) { command(card, CMD55, 0); return command(card, cmd, arg); } inline static sdio_error_t set_error(sdio_card_t *card, sdio_error_t err) { card->error = err; spi_cs_high(card); return err; } static sdio_error_t read_data(sdio_card_t *card, uint8_t *dst, size_t size) { uint32_t start = sdk_system_get_time(); while (true) { if (timeout_expired(start, IO_TIMEOUT_US)) return set_error(card, SDIO_ERR_TIMEOUT); uint8_t b = spi_read_byte(); if (b == TOKEN_SINGLE_TRAN) break; if (b != 0xff) return set_error(card, SDIO_ERR_IO); } spi_read_bytes(dst, size); uint16_t crc = spi_read_word(); if (card->crc_enabled && crc_ccitt(dst, size) != crc) return set_error(card, SDIO_ERR_CRC); return SDIO_ERR_NONE; } static sdio_error_t read_register(sdio_card_t *card, uint8_t cmd, void *dst) { if (command(card, cmd, 0)) return set_error(card, SDIO_ERR_IO); return read_data(card, dst, 16); } static sdio_error_t write_data_block(sdio_card_t *card, uint8_t token, uint8_t *src) { if (!wait()) return set_error(card, SDIO_ERR_TIMEOUT); spi_transfer_8(BUS, token); spi_transfer(BUS, src, NULL, SDIO_BLOCK_SIZE, SPI_8BIT); spi_write_word(card->crc_enabled ? crc_ccitt(src, SDIO_BLOCK_SIZE) : 0xffff); if ((spi_read_byte() & WRITE_RES_MASK) != WRITE_RES_OK) return set_error(card, SDIO_ERR_IO); return SDIO_ERR_NONE; } sdio_error_t sdio_init(sdio_card_t *card, uint8_t cs_pin, uint32_t high_freq_divider) { card->cs_pin = cs_pin; card->type = SDIO_TYPE_UNKNOWN; // setup SPI at 125kHz spi_settings_t s = { .mode = SPI_MODE0, .freq_divider = SPI_FREQ_DIV_125K, .msb = true, .endianness = SPI_LITTLE_ENDIAN, .minimal_pins = true }; spi_set_settings(BUS, &s); gpio_enable(card->cs_pin, GPIO_OUTPUT); uint32_t start = sdk_system_get_time(); spi_cs_low(card); spi_cs_high(card); for (uint8_t i = 0; i < 10; i++) spi_read_byte(); // Set card to the SPI idle mode while (command(card, CMD0, 0) != BV(R1_IDLE_STATE)) { if (timeout_expired(start, INIT_TIMEOUT_US)) return set_error(card, SDIO_ERR_TIMEOUT); } // Enable CRC card->crc_enabled = command(card, CMD59, 1) == BV(R1_IDLE_STATE); // Get card type while (true) { if (command(card, CMD8, 0x1aa) & BV(R1_ILLEGAL_CMD)) { card->type = SDIO_TYPE_SD1; break; } if ((spi_read_dword() & 0xff) == 0xaa) { card->type = SDIO_TYPE_SD2; break; } if (timeout_expired(start, INIT_TIMEOUT_US)) return set_error(card, SDIO_ERR_TIMEOUT); } if (card->type == SDIO_TYPE_SD1) { // SD1 or MMC3 if (app_command(card, ACMD41, 0) > 1) { card->type = SDIO_TYPE_MMC; while (command(card, CMD1, 0)) if (timeout_expired(start, INIT_TIMEOUT_US)) return set_error(card, SDIO_ERR_TIMEOUT); } else { while (app_command(card, ACMD41, 0)) if (timeout_expired(start, INIT_TIMEOUT_US)) return set_error(card, SDIO_ERR_TIMEOUT); } if (command(card, CMD16, SDIO_BLOCK_SIZE)) return set_error(card, SDIO_ERR_UNSUPPORTED); } else { // SD2 or SDHC while (app_command(card, ACMD41, BV(30)) != 0) if (timeout_expired(start, INIT_TIMEOUT_US)) return set_error(card, SDIO_ERR_TIMEOUT); } // read OCR if (command(card, CMD58, 0)) return set_error(card, SDIO_ERR_IO); card->ocr.data = spi_read_dword(); if (card->type == SDIO_TYPE_SD2 && (card->ocr.data & OCR_SDHC) == OCR_SDHC) card->type = SDIO_TYPE_SDHC; spi_set_frequency_div(BUS, high_freq_divider); if (read_register(card, CMD10, &card->cid.data) != SDIO_ERR_NONE) return card->error; if (read_register(card, CMD9, &card->csd.data) != SDIO_ERR_NONE) return card->error; // Card size if (card->csd.v1.csd_ver == 0) card->sectors = (uint32_t)(((card->csd.v1.c_size_high << 10) | (card->csd.v1.c_size_mid << 2) | card->csd.v1.c_size_low) + 1) << (((card->csd.v1.c_size_mult_high << 1) | card->csd.v1.c_size_mult_low) + card->csd.v1.read_bl_len - 7); else if (card->csd.v2.csd_ver == 1) card->sectors = (((uint32_t)card->csd.v2.c_size_high << 16) + ((uint32_t)card->csd.v2.c_size_mid << 8) + card->csd.v2.c_size_low + 1) << 10; else return set_error(card, SDIO_ERR_UNSUPPORTED); return set_error(card, SDIO_ERR_NONE); } sdio_error_t sdio_read_sectors(sdio_card_t *card, uint32_t sector, uint8_t *dst, uint32_t count) { if (!count) return set_error(card, SDIO_ERR_IO); if (card->type != SDIO_TYPE_SDHC) sector <<= 9; bool multi = count > 1; if (command(card, multi ? CMD18 : CMD17, sector)) return set_error(card, SDIO_ERR_IO); while (count--) { if (read_data(card, dst, SDIO_BLOCK_SIZE) != SDIO_ERR_NONE) return card->error; dst += SDIO_BLOCK_SIZE; } if (multi && command(card, CMD12, 0)) return set_error(card, SDIO_ERR_IO); return set_error(card, SDIO_ERR_NONE); } sdio_error_t sdio_write_sectors(sdio_card_t *card, uint32_t sector, uint8_t *src, uint32_t count) { if (!count) return set_error(card, SDIO_ERR_IO); if (card->type != SDIO_TYPE_SDHC) sector <<= 9; bool multi = count != 1; // send pre-erase count if (multi && (card->type == SDIO_TYPE_SD1 || card->type == SDIO_TYPE_SD2 || card->type == SDIO_TYPE_SDHC) && app_command(card, ACMD23, count)) { return set_error(card, SDIO_ERR_IO); } if (command(card, multi ? CMD25 : CMD24, sector)) return set_error(card, SDIO_ERR_IO); while (count--) { if (write_data_block(card, multi ? TOKEN_MULTI_TRAN : TOKEN_SINGLE_TRAN, src) != SDIO_ERR_NONE){ return card->error; } src += SDIO_BLOCK_SIZE; } if (multi && command(card, CMD12, 0)) return set_error(card, SDIO_ERR_IO); return set_error(card, SDIO_ERR_NONE); } sdio_error_t sdio_erase_sectors(sdio_card_t *card, uint32_t first, uint32_t last) { if (!card->csd.v1.erase_blk_en) { uint8_t mask = (card->csd.v1.sector_size_high << 1) | card->csd.v1.sector_size_low; if ((first & mask) || ((last + 1) & mask)) return set_error(card, SDIO_ERR_UNSUPPORTED); } if (card->type != SDIO_TYPE_SDHC) { first <<= 9; last <<= 9; } if (command(card, CMD32, first) || command(card, CMD33, last) || command(card, CMD38, 0)) { return set_error(card, SDIO_ERR_IO); } return set_error(card, wait() ? SDIO_ERR_NONE : SDIO_ERR_TIMEOUT); }