/*-----------------------------------------------------------------------*/ /* Low level disk I/O module skeleton for FatFs (C)ChaN, 2016 */ /*-----------------------------------------------------------------------*/ /* 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 "../../storage/emusd.h" #include #include #include #include /* FatFs lower layer API */ #include static bool ensure_partition(BYTE pdrv){ u8 part; switch(pdrv){ case DRIVE_SD: return true; case DRIVE_BOOT1: case DRIVE_BOOT1_1MB: part = EMMC_BOOT1; break; case DRIVE_EMMC: part = EMMC_GPP; break; case DRIVE_EMUSD: return true; default: return false; } if(emmc_storage.partition != part){ return emmc_set_partition(part); } return true; } /*-----------------------------------------------------------------------*/ /* Get Drive Status */ /*-----------------------------------------------------------------------*/ DSTATUS disk_status ( BYTE pdrv /* Physical drive nmuber to identify the drive */ ) { return 0; } /*-----------------------------------------------------------------------*/ /* Inidialize a Drive */ /*-----------------------------------------------------------------------*/ DSTATUS disk_initialize ( BYTE pdrv /* Physical drive nmuber to identify the drive */ ) { return 0; } /*-----------------------------------------------------------------------*/ /* Read Sector(s) */ /*-----------------------------------------------------------------------*/ DRESULT disk_read ( BYTE pdrv, /* Physical drive nmuber to identify the drive */ BYTE *buff, /* Data buffer to store read data */ DWORD sector, /* Start sector in LBA */ UINT count /* Number of sectors to read */ ) { if(!ensure_partition(pdrv)){ return RES_ERROR; } sdmmc_storage_t *storage = &sd_storage; u32 actual_sector = sector; switch(pdrv){ case DRIVE_SD: break; case DRIVE_BOOT1: case DRIVE_EMMC: storage = &emmc_storage; break; case DRIVE_BOOT1_1MB: storage = &emmc_storage; actual_sector = sector + (0x100000 / 512); break; case DRIVE_EMUSD: return emusd_storage_read(sector, count, buff) ? RES_OK : RES_ERROR; break; default: return RES_ERROR; } return sdmmc_storage_read(storage, actual_sector, count, buff) ? RES_OK : RES_ERROR; } /*-----------------------------------------------------------------------*/ /* Write Sector(s) */ /*-----------------------------------------------------------------------*/ DRESULT disk_write ( BYTE pdrv, /* Physical drive nmuber to identify the drive */ const BYTE *buff, /* Data to be written */ DWORD sector, /* Start sector in LBA */ UINT count /* Number of sectors to write */ ) { if(!ensure_partition(pdrv)){ return RES_ERROR; } sdmmc_storage_t *storage = &sd_storage; u32 actual_sector = sector; switch(pdrv){ case DRIVE_SD: break; case DRIVE_BOOT1: case DRIVE_EMMC: storage = &emmc_storage; break; case DRIVE_BOOT1_1MB: storage = &emmc_storage; actual_sector = sector + (0x100000 / 512); break; case DRIVE_EMUSD: return emusd_storage_write(sector, count, (void*)buff) ? RES_OK : RES_ERROR; default: return RES_ERROR; } return sdmmc_storage_write(storage, actual_sector, count, (void*)buff) ? RES_OK : RES_ERROR; } /*-----------------------------------------------------------------------*/ /* Miscellaneous Functions */ /*-----------------------------------------------------------------------*/ DRESULT disk_ioctl ( BYTE pdrv, /* Physical drive nmuber (0..) */ BYTE cmd, /* Control code */ void *buff /* Buffer to send/receive control data */ ) { return RES_OK; }