#include "sdcard.h" #include "pico.h" #include "pico/stdlib.h" #include "hardware/clocks.h" #include "hardware/spi.h" #include "hardware/gpio.h" //#include "hardware/gpio_ex.h" #include "ff.h" #include "diskio.h" /*-------------------------------------------------------------------------- Module Private Functions ---------------------------------------------------------------------------*/ /* MMC/SD command */ #define CMD0 (0) /* GO_IDLE_STATE */ #define CMD1 (1) /* SEND_OP_COND (MMC) */ #define ACMD41 (0x80+41) /* SEND_OP_COND (SDC) */ #define CMD8 (8) /* SEND_IF_COND */ #define CMD9 (9) /* SEND_CSD */ #define CMD10 (10) /* SEND_CID */ #define CMD12 (12) /* STOP_TRANSMISSION */ #define ACMD13 (0x80+13) /* SD_STATUS (SDC) */ #define CMD16 (16) /* SET_BLOCKLEN */ #define CMD17 (17) /* READ_SINGLE_BLOCK */ #define CMD18 (18) /* READ_MULTIPLE_BLOCK */ #define CMD23 (23) /* SET_BLOCK_COUNT (MMC) */ #define ACMD23 (0x80+23) /* SET_WR_BLK_ERASE_COUNT (SDC) */ #define CMD24 (24) /* WRITE_BLOCK */ #define CMD25 (25) /* WRITE_MULTIPLE_BLOCK */ #define CMD32 (32) /* ERASE_ER_BLK_START */ #define CMD33 (33) /* ERASE_ER_BLK_END */ #define CMD38 (38) /* ERASE */ #define CMD55 (55) /* APP_CMD */ #define CMD58 (58) /* READ_OCR */ /* MMC card type flags (MMC_GET_TYPE) */ #define CT_MMC 0x01 /* MMC ver 3 */ #define CT_SD1 0x02 /* SD ver 1 */ #define CT_SD2 0x04 /* SD ver 2 */ #define CT_SDC (CT_SD1|CT_SD2) /* SD */ #define CT_BLOCK 0x08 /* Block addressing */ #define CLK_SLOW (100 * KHZ) #define CLK_FAST (50 * MHZ) static volatile DSTATUS Stat = STA_NOINIT; /* Physical drive status */ static BYTE CardType; /* Card type flags */ static inline uint32_t _millis(void) { return to_ms_since_boot(get_absolute_time()); } /*-----------------------------------------------------------------------*/ /* SPI controls (Platform dependent) */ /*-----------------------------------------------------------------------*/ static inline void cs_select(uint cs_pin) { asm volatile("nop \n nop \n nop"); // FIXME gpio_put(cs_pin, 0); asm volatile("nop \n nop \n nop"); // FIXME } static inline void cs_deselect(uint cs_pin) { asm volatile("nop \n nop \n nop"); // FIXME gpio_put(cs_pin, 1); asm volatile("nop \n nop \n nop"); // FIXME } static void FCLK_SLOW(void) { spi_set_baudrate(spi0, CLK_SLOW); } static void FCLK_FAST(void) { spi_set_baudrate(spi0, CLK_FAST); } static void CS_HIGH(void) { cs_deselect(SDCARD_PIN_SPI0_CS); } static void CS_LOW(void) { cs_select(SDCARD_PIN_SPI0_CS); } /* Initialize MMC interface */ static void init_spi(void) { /* GPIO pin configuration */ /* pull up of MISO is MUST (10Kohm external pull up is recommended) */ /* Set drive strength and slew rate if needed to meet wire condition */ gpio_init(SDCARD_PIN_SPI0_SCK); //gpio_pull_up(SDCARD_PIN_SPI0_SCK); //gpio_set_drive_strength(SDCARD_PIN_SPI0_SCK, PADS_BANK0_GPIO0_DRIVE_VALUE_4MA); // 2mA, 4mA (default), 8mA, 12mA //gpio_set_slew_rate(SDCARD_PIN_SPI0_SCK, 0); // 0: SLOW (default), 1: FAST gpio_set_function(SDCARD_PIN_SPI0_SCK, GPIO_FUNC_SPI); gpio_init(SDCARD_PIN_SPI0_MISO); gpio_pull_up(SDCARD_PIN_SPI0_MISO); //gpio_set_schmitt(SDCARD_PIN_SPI0_MISO, 1); // 0: Off, 1: On (default) gpio_set_function(SDCARD_PIN_SPI0_MISO, GPIO_FUNC_SPI); gpio_init(SDCARD_PIN_SPI0_MOSI); gpio_pull_up(SDCARD_PIN_SPI0_MOSI); //gpio_set_drive_strength(SDCARD_PIN_SPI0_MOSI, PADS_BANK0_GPIO0_DRIVE_VALUE_4MA); // 2mA, 4mA (default), 8mA, 12mA //gpio_set_slew_rate(SDCARD_PIN_SPI0_MOSI, 0); // 0: SLOW (default), 1: FAST gpio_set_function(SDCARD_PIN_SPI0_MOSI, GPIO_FUNC_SPI); gpio_init(SDCARD_PIN_SPI0_CS); //gpio_pull_up(SDCARD_PIN_SPI0_CS); //gpio_set_drive_strength(SDCARD_PIN_SPI0_CS, PADS_BANK0_GPIO0_DRIVE_VALUE_4MA); // 2mA, 4mA (default), 8mA, 12mA //gpio_set_slew_rate(SDCARD_PIN_SPI0_CS, 0); // 0: SLOW (default), 1: FAST gpio_set_dir(SDCARD_PIN_SPI0_CS, GPIO_OUT); /* chip _select invalid*/ CS_HIGH(); spi_init(spi0, CLK_SLOW); /* SPI0 parameter config */ spi_set_format(spi0, 8, /* data_bits */ SPI_CPOL_0, /* cpol */ SPI_CPHA_0, /* cpha */ SPI_MSB_FIRST /* order */ ); } /* Exchange a byte */ static BYTE xchg_spi ( BYTE dat /* Data to send */ ) { uint8_t *buff = (uint8_t *) &dat; spi_write_read_blocking(spi0, buff, buff, 1); return (BYTE) *buff; } /* Receive multiple byte */ static void rcvr_spi_multi ( BYTE *buff, /* Pointer to data buffer */ UINT btr /* Number of bytes to receive (even number) */ ) { uint8_t *b = (uint8_t *) buff; spi_read_blocking(spi0, 0xff, b, btr); } /*-----------------------------------------------------------------------*/ /* Wait for card ready */ /*-----------------------------------------------------------------------*/ static int wait_ready ( /* 1:Ready, 0:Timeout */ UINT wt /* Timeout [ms] */ ) { BYTE d; uint32_t t = _millis(); do { d = xchg_spi(0xFF); /* This loop takes a time. Insert rot_rdq() here for multitask envilonment. */ } while (d != 0xFF && _millis() < t + wt); /* Wait for card goes ready or timeout */ return (d == 0xFF) ? 1 : 0; } /*-----------------------------------------------------------------------*/ /* Deselect card and release SPI */ /*-----------------------------------------------------------------------*/ static void deselect (void) { CS_HIGH(); /* Set CS# high */ xchg_spi(0xFF); /* Dummy clock (force DO hi-z for multiple slave SPI) */ } /*-----------------------------------------------------------------------*/ /* Select card and wait for ready */ /*-----------------------------------------------------------------------*/ static int _select (void) /* 1:OK, 0:Timeout */ { CS_LOW(); /* Set CS# low */ xchg_spi(0xFF); /* Dummy clock (force DO enabled) */ if (wait_ready(500)) return 1; /* Wait for card ready */ deselect(); return 0; /* Timeout */ } /*-----------------------------------------------------------------------*/ /* Receive a data packet from the MMC */ /*-----------------------------------------------------------------------*/ static int rcvr_datablock ( /* 1:OK, 0:Error */ BYTE *buff, /* Data buffer */ UINT btr /* Data block length (byte) */ ) { BYTE token; const uint32_t timeout = 200; uint32_t t = _millis(); do { /* Wait for DataStart token in timeout of 200ms */ token = xchg_spi(0xFF); /* This loop will take a time. Insert rot_rdq() here for multitask envilonment. */ } while (token == 0xFF && _millis() < t + timeout); if(token != 0xFE) return 0; /* Function fails if invalid DataStart token or timeout */ rcvr_spi_multi(buff, btr); /* Store trailing data to the buffer */ xchg_spi(0xFF); xchg_spi(0xFF); /* Discard CRC */ return 1; /* Function succeeded */ } /*-----------------------------------------------------------------------*/ /* Send a command packet to the MMC */ /*-----------------------------------------------------------------------*/ static BYTE send_cmd ( /* Return value: R1 resp (bit7==1:Failed to send) */ BYTE cmd, /* Command index */ DWORD arg /* Argument */ ) { BYTE n, res; if (cmd & 0x80) { /* Send a CMD55 prior to ACMD */ cmd &= 0x7F; res = send_cmd(CMD55, 0); if (res > 1) return res; } /* Select the card and wait for ready except to stop multiple block read */ if (cmd != CMD12) { deselect(); if (!_select()) return 0xFF; } /* Send command packet */ xchg_spi(0x40 | cmd); /* Start + command index */ xchg_spi((BYTE)(arg >> 24)); /* Argument[31..24] */ xchg_spi((BYTE)(arg >> 16)); /* Argument[23..16] */ xchg_spi((BYTE)(arg >> 8)); /* Argument[15..8] */ xchg_spi((BYTE)arg); /* Argument[7..0] */ n = 0x01; /* Dummy CRC + Stop */ if (cmd == CMD0) n = 0x95; /* Valid CRC for CMD0(0) */ if (cmd == CMD8) n = 0x87; /* Valid CRC for CMD8(0x1AA) */ xchg_spi(n); /* Receive command resp */ if (cmd == CMD12) xchg_spi(0xFF); /* Diacard following one byte when CMD12 */ n = 10; /* Wait for response (10 bytes max) */ do { res = xchg_spi(0xFF); } while ((res & 0x80) && --n); return res; /* Return received response */ } /*-------------------------------------------------------------------------- Public Functions ---------------------------------------------------------------------------*/ /*-----------------------------------------------------------------------*/ /* Initialize disk drive */ /*-----------------------------------------------------------------------*/ DSTATUS disk_initialize ( BYTE drv /* Physical drive number (0) */ ) { BYTE n, cmd, ty, ocr[4]; const uint32_t timeout = 1000; /* Initialization timeout = 1 sec */ uint32_t t; if (drv) return STA_NOINIT; /* Supports only drive 0 */ init_spi(); /* Initialize SPI */ sleep_ms(10); if (Stat & STA_NODISK) return Stat; /* Is card existing in the soket? */ FCLK_SLOW(); CS_LOW(); for (n = 10; n; n--) xchg_spi(0xFF); /* Send 80 dummy clocks */ ty = 0; if (send_cmd(CMD0, 0) == 1) { /* Put the card SPI/Idle state */ t = _millis(); if (send_cmd(CMD8, 0x1AA) == 1) { /* SDv2? */ for (n = 0; n < 4; n++) ocr[n] = xchg_spi(0xFF); /* Get 32 bit return value of R7 resp */ if (ocr[2] == 0x01 && ocr[3] == 0xAA) { /* Is the card supports vcc of 2.7-3.6V? */ while (_millis() < t + timeout && send_cmd(ACMD41, 1UL << 30)) ; /* Wait for end of initialization with ACMD41(HCS) */ if (_millis() < t + timeout && send_cmd(CMD58, 0) == 0) { /* Check CCS bit in the OCR */ for (n = 0; n < 4; n++) ocr[n] = xchg_spi(0xFF); ty = (ocr[0] & 0x40) ? CT_SD2 | CT_BLOCK : CT_SD2; /* Card id SDv2 */ } } } else { /* Not SDv2 card */ if (send_cmd(ACMD41, 0) <= 1) { /* SDv1 or MMC? */ ty = CT_SD1; cmd = ACMD41; /* SDv1 (ACMD41(0)) */ } else { ty = CT_MMC; cmd = CMD1; /* MMCv3 (CMD1(0)) */ } while (_millis() < t + timeout && send_cmd(cmd, 0)) ; /* Wait for end of initialization */ if (_millis() >= t + timeout || send_cmd(CMD16, 512) != 0) /* Set block length: 512 */ ty = 0; } } CardType = ty; /* Card type */ deselect(); if (ty) { /* OK */ FCLK_FAST(); /* Set fast clock */ Stat &= ~STA_NOINIT; /* Clear STA_NOINIT flag */ } else { /* Failed */ Stat = STA_NOINIT; } return Stat; } /*-----------------------------------------------------------------------*/ /* Get disk status */ /*-----------------------------------------------------------------------*/ DSTATUS disk_status ( BYTE drv /* Physical drive number (0) */ ) { if (drv) return STA_NOINIT; /* Supports only drive 0 */ return Stat; /* Return disk status */ } /*-----------------------------------------------------------------------*/ /* Read sector(s) */ /*-----------------------------------------------------------------------*/ DRESULT disk_read ( BYTE drv, /* Physical drive number (0) */ BYTE *buff, /* Pointer to the data buffer to store read data */ LBA_t sector, /* Start sector number (LBA) */ UINT count /* Number of sectors to read (1..128) */ ) { if (drv || !count) return RES_PARERR; /* Check parameter */ if (Stat & STA_NOINIT) return RES_NOTRDY; /* Check if drive is ready */ if (!(CardType & CT_BLOCK)) sector *= 512; /* LBA ot BA conversion (byte addressing cards) */ if (count == 1) { /* Single sector read */ if ((send_cmd(CMD17, sector) == 0) /* READ_SINGLE_BLOCK */ && rcvr_datablock(buff, 512)) { count = 0; } } else { /* Multiple sector read */ if (send_cmd(CMD18, sector) == 0) { /* READ_MULTIPLE_BLOCK */ do { if (!rcvr_datablock(buff, 512)) break; buff += 512; } while (--count); send_cmd(CMD12, 0); /* STOP_TRANSMISSION */ } } deselect(); return count ? RES_ERROR : RES_OK; /* Return result */ } #if !FF_FS_READONLY && !FF_FS_NORTC /* get the current time */ DWORD get_fattime (void) { return 0; } #endif #if FF_FS_READONLY == 0 /* Transmit multiple byte */ static void xmit_spi_multi ( const BYTE *buff, /* Pointer to data buffer */ UINT btx /* Number of bytes to transmit (even number) */ ) { const uint8_t *b = (const uint8_t *) buff; spi_write_blocking(spi0, b, btx); } /*-----------------------------------------------------------------------*/ /* Transmit a data packet to the MMC */ /*-----------------------------------------------------------------------*/ static int xmit_datablock ( /* 1:OK, 0:Error */ const BYTE *buff, /* 512 byte data block to be transmitted */ BYTE token /* Data/Stop token */ ) { BYTE resp; if (!wait_ready(500)) return 0; xchg_spi(token); /* Xmit data token */ if (token != 0xFD) { /* Is data token */ xmit_spi_multi(buff, 512); /* Xmit the data block to the MMC */ xchg_spi(0xFF); /* CRC (Dummy) */ xchg_spi(0xFF); resp = xchg_spi(0xFF); /* Reveive data response */ if ((resp & 0x1F) != 0x05) /* If not accepted, return with error */ return 0; } return 1; } /*-----------------------------------------------------------------------*/ /* Write sector(s) */ /*-----------------------------------------------------------------------*/ DRESULT disk_write ( BYTE drv, /* Physical drive number (0) */ const BYTE *buff, /* Ponter to the data to write */ LBA_t sector, /* Start sector number (LBA) */ UINT count /* Number of sectors to write (1..128) */ ) { if (drv || !count) return RES_PARERR; /* Check parameter */ if (Stat & STA_NOINIT) return RES_NOTRDY; /* Check drive status */ if (Stat & STA_PROTECT) return RES_WRPRT; /* Check write protect */ if (!(CardType & CT_BLOCK)) sector *= 512; /* LBA ==> BA conversion (byte addressing cards) */ if (!_select()) return RES_NOTRDY; if (count == 1) { /* Single sector write */ if ((send_cmd(CMD24, sector) == 0) /* WRITE_BLOCK */ && xmit_datablock(buff, 0xFE)) { count = 0; } } else { /* Multiple sector write */ if (CardType & CT_SDC) send_cmd(ACMD23, count); /* Predefine number of sectors */ if (send_cmd(CMD25, sector) == 0) { /* WRITE_MULTIPLE_BLOCK */ do { if (!xmit_datablock(buff, 0xFC)) break; buff += 512; } while (--count); if (!xmit_datablock(0, 0xFD)) count = 1; /* STOP_TRAN token */ } } deselect(); return count ? RES_ERROR : RES_OK; /* Return result */ } #endif /*-----------------------------------------------------------------------*/ /* Miscellaneous drive controls other than data read/write */ /*-----------------------------------------------------------------------*/ DRESULT disk_ioctl ( BYTE drv, /* Physical drive number (0) */ BYTE cmd, /* Control command code */ void *buff /* Pointer to the conrtol data */ ) { DRESULT res; BYTE n, csd[16]; DWORD *dp, st, ed, csize; if (drv) return RES_PARERR; /* Check parameter */ if (Stat & STA_NOINIT) return RES_NOTRDY; /* Check if drive is ready */ res = RES_ERROR; switch (cmd) { case CTRL_SYNC : /* Wait for end of internal write process of the drive */ if (_select()) res = RES_OK; break; case GET_SECTOR_COUNT : /* Get drive capacity in unit of sector (DWORD) */ if ((send_cmd(CMD9, 0) == 0) && rcvr_datablock(csd, 16)) { if ((csd[0] >> 6) == 1) { /* SDC ver 2.00 */ csize = csd[9] + ((WORD)csd[8] << 8) + ((DWORD)(csd[7] & 63) << 16) + 1; *(DWORD*)buff = csize << 10; } else { /* SDC ver 1.XX or MMC ver 3 */ n = (csd[5] & 15) + ((csd[10] & 128) >> 7) + ((csd[9] & 3) << 1) + 2; csize = (csd[8] >> 6) + ((WORD)csd[7] << 2) + ((WORD)(csd[6] & 3) << 10) + 1; *(DWORD*)buff = csize << (n - 9); } res = RES_OK; } break; case GET_BLOCK_SIZE : /* Get erase block size in unit of sector (DWORD) */ if (CardType & CT_SD2) { /* SDC ver 2.00 */ if (send_cmd(ACMD13, 0) == 0) { /* Read SD status */ xchg_spi(0xFF); if (rcvr_datablock(csd, 16)) { /* Read partial block */ for (n = 64 - 16; n; n--) xchg_spi(0xFF); /* Purge trailing data */ *(DWORD*)buff = 16UL << (csd[10] >> 4); res = RES_OK; } } } else { /* SDC ver 1.XX or MMC */ if ((send_cmd(CMD9, 0) == 0) && rcvr_datablock(csd, 16)) { /* Read CSD */ if (CardType & CT_SD1) { /* SDC ver 1.XX */ *(DWORD*)buff = (((csd[10] & 63) << 1) + ((WORD)(csd[11] & 128) >> 7) + 1) << ((csd[13] >> 6) - 1); } else { /* MMC */ *(DWORD*)buff = ((WORD)((csd[10] & 124) >> 2) + 1) * (((csd[11] & 3) << 3) + ((csd[11] & 224) >> 5) + 1); } res = RES_OK; } } break; case CTRL_TRIM : /* Erase a block of sectors (used when _USE_ERASE == 1) */ if (!(CardType & CT_SDC)) break; /* Check if the card is SDC */ if (disk_ioctl(drv, MMC_GET_CSD, csd)) break; /* Get CSD */ if (!(csd[0] >> 6) && !(csd[10] & 0x40)) break; /* Check if sector erase can be applied to the card */ dp = buff; st = dp[0]; ed = dp[1]; /* Load sector block */ if (!(CardType & CT_BLOCK)) { st *= 512; ed *= 512; } if (send_cmd(CMD32, st) == 0 && send_cmd(CMD33, ed) == 0 && send_cmd(CMD38, 0) == 0 && wait_ready(30000)) { /* Erase sector block */ res = RES_OK; /* FatFs does not check result of this command */ } break; default: res = RES_PARERR; } deselect(); return res; }