/*-----------------------------------------------------------------------*/ /* Low level disk I/O module skeleton for FatFs (C)ChaN, 2014 */ /*-----------------------------------------------------------------------*/ /* If a working storage control module is available, it should be */ /* attached to the FatFs via a glue function rather than modifying it. */ /* This is an example of glue functions to attach various exsisting */ /* storage control modules to the FatFs module with a defined API. */ /*-----------------------------------------------------------------------*/ #include "diskio.h" /* FatFs lower layer API */ #include "nand.h" #include "sdmmc.h" #define PART_TYPE(pdrv) (DriveInfo[pdrv].type) #define PART_SUBTYPE(pdrv) (DriveInfo[pdrv].subtype) #define TYPE_NONE 0 #define TYPE_SYSNAND NAND_SYSNAND #define TYPE_SDCARD (1UL<<4) #define SUBTYPE_CTRN 0 #define SUBTYPE_CTRN_N 1 #define SUBTYPE_CTRN_NO 2 #define SUBTYPE_TWLN 3 #define SUBTYPE_TWLP 4 #define SUBTYPE_NONE 5 typedef struct { BYTE type; BYTE subtype; } FATpartition; typedef struct { DWORD offset; DWORD size; BYTE keyslot; } SubtypeDesc; FATpartition DriveInfo[4] = { { TYPE_SDCARD, SUBTYPE_NONE }, // 0 - SDCARD { TYPE_SYSNAND, SUBTYPE_CTRN }, // 1 - SYSNAND CTRNAND { TYPE_SYSNAND, SUBTYPE_TWLN }, // 2 - SYSNAND TWLN { TYPE_SYSNAND, SUBTYPE_TWLP }, // 3 - SYSNAND TWLP }; SubtypeDesc SubTypes[5] = { { 0x05C980, 0x17AE80, 0x04 }, // O3DS CTRNAND { 0x05C980, 0x20F680, 0x05 }, // N3DS CTRNAND { 0x05C980, 0x20F680, 0x04 }, // N3DS CTRNAND (downgraded) { 0x000097, 0x047DA9, 0x03 }, // TWLN { 0x04808D, 0x0105B3, 0x03 } // TWLP }; static BYTE nand_type_sys = 0; /*-----------------------------------------------------------------------*/ /* Get Drive Subtype helper */ /*-----------------------------------------------------------------------*/ static inline SubtypeDesc* get_subtype_desc( __attribute__((unused)) BYTE pdrv /* Physical drive number to identify the drive */ ) { BYTE subtype = PART_SUBTYPE(pdrv); if (subtype == SUBTYPE_NONE) { return NULL; } else if (subtype == SUBTYPE_CTRN) { if (nand_type_sys != NAND_TYPE_O3DS) subtype = (nand_type_sys == NAND_TYPE_N3DS) ? SUBTYPE_CTRN_N : SUBTYPE_CTRN_NO; } return &(SubTypes[subtype]); } /*-----------------------------------------------------------------------*/ /* Get Drive Status */ /*-----------------------------------------------------------------------*/ DSTATUS disk_status ( __attribute__((unused)) BYTE pdrv /* Physical drive number to identify the drive */ ) { return RES_OK; } /*-----------------------------------------------------------------------*/ /* Initialize a Drive */ /*-----------------------------------------------------------------------*/ DSTATUS disk_initialize ( __attribute__((unused)) BYTE pdrv /* Physical drive number to identify the drive */ ) { if (pdrv == 0) { // a mounted SD card is the preriquisite for everything else if (sdmmc_sdcard_init() != 0) return STA_NOINIT|STA_NODISK; } else if (pdrv < 4) { nand_type_sys = CheckNandType(); if (!nand_type_sys) return STA_NOINIT|STA_NODISK; } return RES_OK; } /*-----------------------------------------------------------------------*/ /* Read Sector(s) */ /*-----------------------------------------------------------------------*/ DRESULT disk_read ( __attribute__((unused)) BYTE pdrv, /* Physical drive number to identify the drive */ BYTE *buff, /* Data buffer to store read data */ DWORD sector, /* Sector address in LBA */ UINT count /* Number of sectors to read */ ) { BYTE type = PART_TYPE(pdrv); if (type == TYPE_NONE) { return RES_PARERR; } else if (type == TYPE_SDCARD) { if (sdmmc_sdcard_readsectors(sector, count, buff)) return RES_PARERR; } else { SubtypeDesc* subtype = get_subtype_desc(pdrv); BYTE keyslot = subtype->keyslot; DWORD isector = subtype->offset + sector; if (ReadNandSectors(buff, isector, count, keyslot)) return RES_PARERR; } return RES_OK; } /*-----------------------------------------------------------------------*/ /* Write Sector(s) */ /*-----------------------------------------------------------------------*/ #if _USE_WRITE DRESULT disk_write ( __attribute__((unused)) BYTE pdrv, /* Physical drive number to identify the drive */ const BYTE *buff, /* Data to be written */ DWORD sector, /* Sector address in LBA */ UINT count /* Number of sectors to write */ ) { BYTE type = PART_TYPE(pdrv); if (type == TYPE_NONE) { return RES_PARERR; } else if (type == TYPE_SDCARD) { if (sdmmc_sdcard_writesectors(sector, count, (BYTE *)buff)) return RES_PARERR; } else { SubtypeDesc* subtype = get_subtype_desc(pdrv); BYTE keyslot = subtype->keyslot; DWORD isector = subtype->offset + sector; if (WriteNandSectors(buff, isector, count, keyslot)) return RES_PARERR; // unstubbed! } return RES_OK; } #endif /*-----------------------------------------------------------------------*/ /* Miscellaneous Functions */ /*-----------------------------------------------------------------------*/ #if _USE_IOCTL DRESULT disk_ioctl ( __attribute__((unused)) BYTE pdrv, /* Physical drive number (0..) */ __attribute__((unused)) BYTE cmd, /* Control code */ __attribute__((unused)) void *buff /* Buffer to send/receive control data */ ) { BYTE type = PART_TYPE(pdrv); switch (cmd) { case GET_SECTOR_SIZE: *((DWORD*) buff) = 0x200; return RES_OK; case GET_SECTOR_COUNT: if (type == TYPE_SDCARD) { // SD card *((DWORD*) buff) = getMMCDevice(1)->total_size; } else if (type != TYPE_NONE) { // NAND *((DWORD*) buff) = get_subtype_desc(pdrv)->size; } return RES_OK; case GET_BLOCK_SIZE: *((DWORD*) buff) = 0x2000; return RES_OK; case CTRL_SYNC: // nothing else to do here - sdmmc.c handles the rest return RES_OK; } return RES_PARERR; } #endif