/* * RT-Thread Device Interface for uffs */ #include #include #include "dfs_uffs.h" static int nand_init_flash(uffs_Device *dev) { return UFFS_FLASH_NO_ERR; } static int nand_release_flash(uffs_Device *dev) { return UFFS_FLASH_NO_ERR; } static int nand_erase_block(uffs_Device *dev, unsigned block) { int res; res = rt_mtd_nand_erase_block(RT_MTD_NAND_DEVICE(dev->_private), block); return res == RT_EOK ? UFFS_FLASH_NO_ERR : UFFS_FLASH_IO_ERR; } #if defined(RT_UFFS_USE_CHECK_MARK_FUNCITON) static int nand_check_block(uffs_Device *dev, unsigned block) { int res; res = rt_mtd_nand_check_block(RT_MTD_NAND_DEVICE(dev->_private), block); return res == RT_EOK ? UFFS_FLASH_NO_ERR : UFFS_FLASH_BAD_BLK; } static int nand_mark_badblock(uffs_Device *dev, unsigned block) { int res; res = rt_mtd_nand_mark_badblock(RT_MTD_NAND_DEVICE(dev->_private), block); return res == RT_EOK ? UFFS_FLASH_NO_ERR : UFFS_FLASH_IO_ERR; } #endif #if (RT_CONFIG_UFFS_ECC_MODE == UFFS_ECC_NONE) || (RT_CONFIG_UFFS_ECC_MODE == UFFS_ECC_SOFT) static int nand_read_page( uffs_Device *dev, u32 block, u32 page, u8 *data, int data_len, u8 * ecc, rt_uint8_t *spare, int spare_len) { int res; page = block * dev->attr->pages_per_block + page; if (data == NULL && spare == NULL) { #if defined(RT_UFFS_USE_CHECK_MARK_FUNCITON) RT_ASSERT(0); //should not be here #else /* check block status: bad or good */ rt_uint8_t spare[UFFS_MAX_SPARE_SIZE]; rt_memset(spare, 0, UFFS_MAX_SPARE_SIZE); rt_mtd_nand_read(RT_MTD_NAND_DEVICE(dev->_private), page, RT_NULL, 0, spare, dev->attr->spare_size);//dev->mem.spare_data_size res = spare[dev->attr->block_status_offs] == 0xFF ? UFFS_FLASH_NO_ERR : UFFS_FLASH_BAD_BLK; return res; #endif } rt_mtd_nand_read(RT_MTD_NAND_DEVICE(dev->_private), page, data, data_len, spare, spare_len); return UFFS_FLASH_NO_ERR; } static int nand_write_page( uffs_Device *dev, u32 block, u32 page, const u8 *data, int data_len, const u8 *spare, int spare_len) { int res; RT_ASSERT(UFFS_MAX_SPARE_SIZE >= dev->attr->spare_size); page = block * dev->attr->pages_per_block + page; if (data == NULL && spare == NULL) { #if defined(RT_UFFS_USE_CHECK_MARK_FUNCITON) RT_ASSERT(0); //should not be here #else /* mark bad block */ rt_uint8_t spare[UFFS_MAX_SPARE_SIZE]; rt_memset(spare, 0xFF, UFFS_MAX_SPARE_SIZE); spare[dev->attr->block_status_offs] = 0x00; res = rt_mtd_nand_write(RT_MTD_NAND_DEVICE(dev->_private), page, RT_NULL, 0, spare, dev->attr->spare_size);//dev->mem.spare_data_size if (res != RT_EOK) goto __error; #endif } res = rt_mtd_nand_write(RT_MTD_NAND_DEVICE(dev->_private), page, data, data_len, spare, spare_len); if (res != RT_EOK) goto __error; return UFFS_FLASH_NO_ERR; __error: return UFFS_FLASH_IO_ERR; } const uffs_FlashOps nand_ops = { nand_init_flash, /* InitFlash() */ nand_release_flash, /* ReleaseFlash() */ nand_read_page, /* ReadPage() */ NULL, /* ReadPageWithLayout */ nand_write_page, /* WritePage() */ NULL, /* WirtePageWithLayout */ #if defined(RT_UFFS_USE_CHECK_MARK_FUNCITON) nand_check_block, nand_mark_badblock, #else NULL, /* IsBadBlock(), let UFFS take care of it. */ NULL, /* MarkBadBlock(), let UFFS take care of it. */ #endif nand_erase_block, /* EraseBlock() */ }; void uffs_setup_storage( struct uffs_StorageAttrSt *attr, struct rt_mtd_nand_device * nand) { rt_memset(attr, 0, sizeof(struct uffs_StorageAttrSt)); // attr->total_blocks = nand->end_block - nand->start_block + 1;/* no use */ attr->page_data_size = nand->page_size; /* page data size */ attr->pages_per_block = nand->block_size / nand->page_size ; /* pages per block */ attr->spare_size = nand->oob_size; /* page spare size */ attr->block_status_offs = UFFS_BLOCK_MARK_SPARE_OFFSET; /* block status offset is 5th byte in spare */ attr->ecc_opt = RT_CONFIG_UFFS_ECC_MODE; /* ecc option */ attr->ecc_size = RT_CONFIG_UFFS_ECC_SIZE; /* ecc size */ attr->layout_opt = RT_CONFIG_UFFS_LAYOUT; /* let UFFS do the spare layout */ } #elif RT_CONFIG_UFFS_ECC_MODE == UFFS_ECC_HW_AUTO static int WritePageWithLayout( uffs_Device *dev, u32 block, u32 page, const u8 *data, int data_len, const u8 *ecc, //NULL const uffs_TagStore *ts) { int res; int spare_len; rt_uint8_t spare[UFFS_MAX_SPARE_SIZE]; RT_ASSERT(UFFS_MAX_SPARE_SIZE >= dev->attr->spare_size); page = block * dev->attr->pages_per_block + page; spare_len = dev->mem.spare_data_size; if (data == NULL && ts == NULL) { #if defined(RT_UFFS_USE_CHECK_MARK_FUNCITON) RT_ASSERT(0); //should not be here #else /* mark bad block */ rt_memset(spare, 0xFF, UFFS_MAX_SPARE_SIZE); spare[dev->attr->block_status_offs] = 0x00; res = rt_mtd_nand_write(RT_MTD_NAND_DEVICE(dev->_private), page, RT_NULL, 0, spare, dev->attr->spare_size);//dev->mem.spare_data_size if (res != RT_EOK) goto __error; dev->st.io_write++; return UFFS_FLASH_NO_ERR; #endif } if (data != NULL && data_len != 0) { RT_ASSERT(data_len == dev->attr->page_data_size); dev->st.page_write_count++; dev->st.io_write += data_len; } if (ts != RT_NULL) { uffs_FlashMakeSpare(dev, ts, RT_NULL, (u8 *)spare); dev->st.spare_write_count++; dev->st.io_write += spare_len; } res = rt_mtd_nand_write(RT_MTD_NAND_DEVICE(dev->_private), page, data, data_len, spare, spare_len); if (res != RT_EOK) goto __error; return UFFS_FLASH_NO_ERR; __error: return UFFS_FLASH_IO_ERR; } static URET ReadPageWithLayout( uffs_Device *dev, u32 block, u32 page, u8* data, int data_len, u8 *ecc, //NULL uffs_TagStore *ts, u8 *ecc_store) //NULL { int res = UFFS_FLASH_NO_ERR; int spare_len; rt_uint8_t spare[UFFS_MAX_SPARE_SIZE]; RT_ASSERT(UFFS_MAX_SPARE_SIZE >= dev->attr->spare_size); page = block * dev->attr->pages_per_block + page; spare_len = dev->mem.spare_data_size; if (data == RT_NULL && ts == RT_NULL) { #if defined(RT_UFFS_USE_CHECK_MARK_FUNCITON) RT_ASSERT(0); //should not be here #else /* check block good or bad */ rt_mtd_nand_read(RT_MTD_NAND_DEVICE(dev->_private), page, RT_NULL, 0, spare, dev->attr->spare_size);//dev->mem.spare_data_size dev->st.io_read++; res = spare[dev->attr->block_status_offs] == 0xFF ? UFFS_FLASH_NO_ERR : UFFS_FLASH_BAD_BLK; return res; #endif } if (data != RT_NULL) { dev->st.io_read += data_len; dev->st.page_read_count++; } res = rt_mtd_nand_read(RT_MTD_NAND_DEVICE(dev->_private), page, data, data_len, spare, spare_len); if (res == 0) res = UFFS_FLASH_NO_ERR; else if (res == -1) { //TODO ecc correct, add code to use hardware do ecc correct res = UFFS_FLASH_ECC_OK; } else res = UFFS_FLASH_ECC_FAIL; if (ts != RT_NULL) { // unload ts and ecc from spare, you can modify it if you like uffs_FlashUnloadSpare(dev, (const u8 *)spare, ts, RT_NULL); if ((spare[spare_len - 1] == 0xFF) && (res == UFFS_FLASH_NO_ERR)) res = UFFS_FLASH_NOT_SEALED; dev->st.io_read += spare_len; dev->st.spare_read_count++; } return res; } const uffs_FlashOps nand_ops = { nand_init_flash, /* InitFlash() */ nand_release_flash, /* ReleaseFlash() */ NULL, /* ReadPage() */ ReadPageWithLayout, /* ReadPageWithLayout */ NULL, /* WritePage() */ WritePageWithLayout,/* WirtePageWithLayout */ #if defined(RT_UFFS_USE_CHECK_MARK_FUNCITON) nand_check_block, nand_mark_badblock, #else NULL, /* IsBadBlock(), let UFFS take care of it. */ NULL, /* MarkBadBlock(), let UFFS take care of it. */ #endif nand_erase_block, /* EraseBlock() */ }; const rt_uint8_t k9fxg08_data_layout[UFFS_SPARE_LAYOUT_SIZE] = {0x05, 0x08, 0xFF, 0x00}; const rt_uint8_t k9fxg08_ecc_layout[UFFS_SPARE_LAYOUT_SIZE] = {0x00, 0x04, 0xFF, 0x00}; void uffs_setup_storage( struct uffs_StorageAttrSt *attr, struct rt_mtd_nand_device * nand) { rt_memset(attr, 0, sizeof(struct uffs_StorageAttrSt)); // attr->total_blocks = nand->end_block - nand->start_block + 1;/* no use */ attr->page_data_size = nand->page_size; /* page data size */ attr->pages_per_block = nand->block_size / nand->page_size ; /* pages per block */ attr->spare_size = nand->oob_size; /* page spare size */ attr->block_status_offs = UFFS_BLOCK_MARK_SPARE_OFFSET; /* block status offset is 5th byte in spare */ attr->ecc_opt = RT_CONFIG_UFFS_ECC_MODE; /* ecc option */ attr->ecc_size = RT_CONFIG_UFFS_ECC_SIZE; /* ecc size */ attr->layout_opt = RT_CONFIG_UFFS_LAYOUT; /* let UFFS do the spare layout */ /* initialize _uffs_data_layout and _uffs_ecc_layout */ rt_memcpy(attr->_uffs_data_layout, k9fxg08_data_layout, UFFS_SPARE_LAYOUT_SIZE); rt_memcpy(attr->_uffs_ecc_layout, k9fxg08_ecc_layout, UFFS_SPARE_LAYOUT_SIZE); attr->data_layout = attr->_uffs_data_layout; attr->ecc_layout = attr->_uffs_ecc_layout; } #endif