/* * Copyright (c) 2016 Intel Corporation. * * SPDX-License-Identifier: Apache-2.0 */ #include #include #include #include #include #include #include #include #define SECTOR_SIZE 512 static struct device *flash_dev; /* flash read-copy-erase-write operation */ static u8_t read_copy_buf[CONFIG_DISK_ERASE_BLOCK_SIZE]; static u8_t *fs_buff = read_copy_buf; /* calculate number of blocks required for a given size */ #define GET_NUM_BLOCK(total_size, block_size) \ ((total_size + block_size - 1) / block_size) #define GET_SIZE_TO_BOUNDARY(start, block_size) \ (block_size - (start & (block_size - 1))) static off_t lba_to_address(u32_t sector_num) { off_t flash_addr; flash_addr = CONFIG_DISK_FLASH_START + sector_num * SECTOR_SIZE; __ASSERT(flash_addr < (CONFIG_DISK_FLASH_START + CONFIG_DISK_VOLUME_SIZE), "FS bound error"); return flash_addr; } int disk_access_status(void) { if (!flash_dev) { return DISK_STATUS_NOMEDIA; } return DISK_STATUS_OK; } int disk_access_init(void) { if (flash_dev) { return 0; } flash_dev = device_get_binding(CONFIG_DISK_FLASH_DEV_NAME); if (!flash_dev) { return -ENODEV; } return 0; } int disk_access_read(u8_t *buff, u32_t start_sector, u32_t sector_count) { off_t fl_addr; u32_t remaining; u32_t len; u32_t num_read; fl_addr = lba_to_address(start_sector); remaining = (sector_count * SECTOR_SIZE); len = CONFIG_DISK_FLASH_MAX_RW_SIZE; num_read = GET_NUM_BLOCK(remaining, CONFIG_DISK_FLASH_MAX_RW_SIZE); for (u32_t i = 0; i < num_read; i++) { if (remaining < CONFIG_DISK_FLASH_MAX_RW_SIZE) { len = remaining; } if (flash_read(flash_dev, fl_addr, buff, len) != 0) { return -EIO; } fl_addr += len; buff += len; remaining -= len; } return 0; } /* This performs read-copy into an output buffer */ static int read_copy_flash_block(off_t start_addr, u32_t size, const void *src_buff, u8_t *dest_buff) { off_t fl_addr; u32_t num_read; u32_t offset = 0; /* adjust offset if starting address is not erase-aligned address */ if (start_addr & (CONFIG_DISK_FLASH_ERASE_ALIGNMENT - 1)) { offset = start_addr & (CONFIG_DISK_FLASH_ERASE_ALIGNMENT - 1); } /* align starting address to an aligned address for flash erase-write */ fl_addr = ROUND_DOWN(start_addr, CONFIG_DISK_FLASH_ERASE_ALIGNMENT); num_read = GET_NUM_BLOCK(CONFIG_DISK_ERASE_BLOCK_SIZE, CONFIG_DISK_FLASH_MAX_RW_SIZE); /* read one block from flash */ for (u32_t i = 0; i < num_read; i++) { int rc; rc = flash_read(flash_dev, fl_addr + (CONFIG_DISK_FLASH_MAX_RW_SIZE * i), dest_buff + (CONFIG_DISK_FLASH_MAX_RW_SIZE * i), CONFIG_DISK_FLASH_MAX_RW_SIZE); if (rc != 0) { return -EIO; } } /* overwrite with user data */ memcpy(dest_buff + offset, src_buff, size); return 0; } /* input size is either less or equal to a block size, * CONFIG_DISK_ERASE_BLOCK_SIZE. */ static int update_flash_block(off_t start_addr, u32_t size, const void *buff) { off_t fl_addr; u8_t *src = (u8_t *)buff; u32_t num_write; /* if size is a partial block, perform read-copy with user data */ if (size < CONFIG_DISK_ERASE_BLOCK_SIZE) { int rc; rc = read_copy_flash_block(start_addr, size, buff, fs_buff); if (rc != 0) { return -EIO; } /* now use the local buffer as the source */ src = (u8_t *)fs_buff; } /* always align starting address for flash write operation */ fl_addr = ROUND_DOWN(start_addr, CONFIG_DISK_FLASH_ERASE_ALIGNMENT); /* disable write-protection first before erase */ flash_write_protection_set(flash_dev, false); if (flash_erase(flash_dev, fl_addr, CONFIG_DISK_ERASE_BLOCK_SIZE) != 0) { return -EIO; } /* write data to flash */ num_write = GET_NUM_BLOCK(CONFIG_DISK_ERASE_BLOCK_SIZE, CONFIG_DISK_FLASH_MAX_RW_SIZE); for (u32_t i = 0; i < num_write; i++) { /* flash_write reenabled write-protection so disable it again */ flash_write_protection_set(flash_dev, false); if (flash_write(flash_dev, fl_addr, src, CONFIG_DISK_FLASH_MAX_RW_SIZE) != 0) { return -EIO; } fl_addr += CONFIG_DISK_FLASH_MAX_RW_SIZE; src += CONFIG_DISK_FLASH_MAX_RW_SIZE; } return 0; } int disk_access_write(const u8_t *buff, u32_t start_sector, u32_t sector_count) { off_t fl_addr; u32_t remaining; u32_t size; fl_addr = lba_to_address(start_sector); remaining = (sector_count * SECTOR_SIZE); /* check if start address is erased-aligned address */ if (fl_addr & (CONFIG_DISK_FLASH_ERASE_ALIGNMENT - 1)) { off_t block_bnd; /* not aligned */ /* check if the size goes over flash block boundary */ block_bnd = fl_addr + CONFIG_DISK_ERASE_BLOCK_SIZE; block_bnd = block_bnd & ~(CONFIG_DISK_ERASE_BLOCK_SIZE - 1); if ((fl_addr + remaining) < block_bnd) { /* not over block boundary (a partial block also) */ if (update_flash_block(fl_addr, remaining, buff) != 0) { return -EIO; } return 0; } /* write goes over block boundary */ size = GET_SIZE_TO_BOUNDARY(fl_addr, CONFIG_DISK_ERASE_BLOCK_SIZE); /* write first partial block */ if (update_flash_block(fl_addr, size, buff) != 0) { return -EIO; } fl_addr += size; remaining -= size; buff += size; } /* start is an erase-aligned address */ while (remaining) { int rc; if (remaining < CONFIG_DISK_ERASE_BLOCK_SIZE) { break; } rc = update_flash_block(fl_addr, CONFIG_DISK_ERASE_BLOCK_SIZE, buff); if (rc != 0) { return -EIO; } fl_addr += CONFIG_DISK_ERASE_BLOCK_SIZE; remaining -= CONFIG_DISK_ERASE_BLOCK_SIZE; buff += CONFIG_DISK_ERASE_BLOCK_SIZE; } /* remaining partial block */ if (remaining) { if (update_flash_block(fl_addr, remaining, buff) != 0) { return -EIO; } } return 0; } int disk_access_ioctl(u8_t cmd, void *buff) { switch (cmd) { case DISK_IOCTL_CTRL_SYNC: return 0; case DISK_IOCTL_GET_SECTOR_COUNT: *(u32_t *)buff = CONFIG_DISK_VOLUME_SIZE / SECTOR_SIZE; return 0; case DISK_IOCTL_GET_SECTOR_SIZE: *(u32_t *) buff = SECTOR_SIZE; return 0; case DISK_IOCTL_GET_ERASE_BLOCK_SZ: /* in sectors */ *(u32_t *)buff = CONFIG_DISK_ERASE_BLOCK_SIZE / SECTOR_SIZE; return 0; case DISK_IOCTL_GET_DISK_SIZE: *(u32_t *)buff = CONFIG_DISK_VOLUME_SIZE; return 0; default: break; } return -EINVAL; }