diff options
Diffstat (limited to 'target/linux/ramips/patches-3.18/0045-mtd-add-mt7621-nand-support.patch')
-rw-r--r-- | target/linux/ramips/patches-3.18/0045-mtd-add-mt7621-nand-support.patch | 4417 |
1 files changed, 4417 insertions, 0 deletions
diff --git a/target/linux/ramips/patches-3.18/0045-mtd-add-mt7621-nand-support.patch b/target/linux/ramips/patches-3.18/0045-mtd-add-mt7621-nand-support.patch new file mode 100644 index 0000000..3999f54 --- /dev/null +++ b/target/linux/ramips/patches-3.18/0045-mtd-add-mt7621-nand-support.patch @@ -0,0 +1,4417 @@ +From 5db075c5dd038fbf4b5a0196e10f4f9658236372 Mon Sep 17 00:00:00 2001 +From: John Crispin <blogic@openwrt.org> +Date: Sun, 27 Jul 2014 11:05:17 +0100 +Subject: [PATCH 45/57] mtd: add mt7621 nand support + +Signed-off-by: John Crispin <blogic@openwrt.org> +--- + drivers/mtd/nand/Kconfig | 6 + + drivers/mtd/nand/Makefile | 1 + + drivers/mtd/nand/bmt.c | 750 ++++++++++++ + drivers/mtd/nand/bmt.h | 80 ++ + drivers/mtd/nand/dev-nand.c | 63 + + drivers/mtd/nand/mt6575_typedefs.h | 340 ++++++ + drivers/mtd/nand/mtk_nand.c | 2304 +++++++++++++++++++++++++++++++++++ + drivers/mtd/nand/mtk_nand.h | 452 +++++++ + drivers/mtd/nand/nand_base.c | 6 +- + drivers/mtd/nand/nand_bbt.c | 19 + + drivers/mtd/nand/nand_def.h | 123 ++ + drivers/mtd/nand/nand_device_list.h | 55 + + drivers/mtd/nand/partition.h | 115 ++ + 13 files changed, 4311 insertions(+), 3 deletions(-) + create mode 100644 drivers/mtd/nand/bmt.c + create mode 100644 drivers/mtd/nand/bmt.h + create mode 100644 drivers/mtd/nand/dev-nand.c + create mode 100644 drivers/mtd/nand/mt6575_typedefs.h + create mode 100644 drivers/mtd/nand/mtk_nand.c + create mode 100644 drivers/mtd/nand/mtk_nand.h + create mode 100644 drivers/mtd/nand/nand_def.h + create mode 100644 drivers/mtd/nand/nand_device_list.h + create mode 100644 drivers/mtd/nand/partition.h + +--- a/drivers/mtd/nand/Kconfig ++++ b/drivers/mtd/nand/Kconfig +@@ -516,4 +516,10 @@ config MTD_NAND_XWAY + Enables support for NAND Flash chips on Lantiq XWAY SoCs. NAND is attached + to the External Bus Unit (EBU). + ++config MTK_MTD_NAND ++ tristate "Support for MTK SoC NAND controller" ++ depends on SOC_MT7621 ++ select MTD_NAND_IDS ++ select MTD_NAND_ECC ++ + endif # MTD_NAND +--- a/drivers/mtd/nand/Makefile ++++ b/drivers/mtd/nand/Makefile +@@ -50,5 +50,6 @@ obj-$(CONFIG_MTD_NAND_JZ4740) += jz4740 + obj-$(CONFIG_MTD_NAND_GPMI_NAND) += gpmi-nand/ + obj-$(CONFIG_MTD_NAND_XWAY) += xway_nand.o + obj-$(CONFIG_MTD_NAND_BCM47XXNFLASH) += bcm47xxnflash/ ++obj-$(CONFIG_MTK_MTD_NAND) += mtk_nand.o bmt.o + + nand-objs := nand_base.o nand_bbt.o nand_timings.o +--- /dev/null ++++ b/drivers/mtd/nand/bmt.c +@@ -0,0 +1,750 @@ ++#include "bmt.h" ++ ++typedef struct ++{ ++ char signature[3]; ++ u8 version; ++ u8 bad_count; // bad block count in pool ++ u8 mapped_count; // mapped block count in pool ++ u8 checksum; ++ u8 reseverd[13]; ++} phys_bmt_header; ++ ++typedef struct ++{ ++ phys_bmt_header header; ++ bmt_entry table[MAX_BMT_SIZE]; ++} phys_bmt_struct; ++ ++typedef struct ++{ ++ char signature[3]; ++} bmt_oob_data; ++ ++static char MAIN_SIGNATURE[] = "BMT"; ++static char OOB_SIGNATURE[] = "bmt"; ++#define SIGNATURE_SIZE (3) ++ ++#define MAX_DAT_SIZE 0x1000 ++#define MAX_OOB_SIZE 0x80 ++ ++static struct mtd_info *mtd_bmt; ++static struct nand_chip *nand_chip_bmt; ++#define BLOCK_SIZE_BMT (1 << nand_chip_bmt->phys_erase_shift) ++#define PAGE_SIZE_BMT (1 << nand_chip_bmt->page_shift) ++ ++#define OFFSET(block) ((block) * BLOCK_SIZE_BMT) ++#define PAGE_ADDR(block) ((block) * BLOCK_SIZE_BMT / PAGE_SIZE_BMT) ++ ++/********************************************************************* ++* Flash is splited into 2 parts, system part is for normal system * ++* system usage, size is system_block_count, another is replace pool * ++* +-------------------------------------------------+ * ++* | system_block_count | bmt_block_count | * ++* +-------------------------------------------------+ * ++*********************************************************************/ ++static u32 total_block_count; // block number in flash ++static u32 system_block_count; ++static int bmt_block_count; // bmt table size ++// static int bmt_count; // block used in bmt ++static int page_per_block; // page per count ++ ++static u32 bmt_block_index; // bmt block index ++static bmt_struct bmt; // dynamic created global bmt table ++ ++static u8 dat_buf[MAX_DAT_SIZE]; ++static u8 oob_buf[MAX_OOB_SIZE]; ++static bool pool_erased; ++ ++/*************************************************************** ++* ++* Interface adaptor for preloader/uboot/kernel ++* These interfaces operate on physical address, read/write ++* physical data. ++* ++***************************************************************/ ++int nand_read_page_bmt(u32 page, u8 * dat, u8 * oob) ++{ ++ return mtk_nand_exec_read_page(mtd_bmt, page, PAGE_SIZE_BMT, dat, oob); ++} ++ ++bool nand_block_bad_bmt(u32 offset) ++{ ++ return mtk_nand_block_bad_hw(mtd_bmt, offset); ++} ++ ++bool nand_erase_bmt(u32 offset) ++{ ++ int status; ++ if (offset < 0x20000) ++ { ++ MSG(INIT, "erase offset: 0x%x\n", offset); ++ } ++ ++ status = mtk_nand_erase_hw(mtd_bmt, offset / PAGE_SIZE_BMT); // as nand_chip structure doesn't have a erase function defined ++ if (status & NAND_STATUS_FAIL) ++ return false; ++ else ++ return true; ++} ++ ++int mark_block_bad_bmt(u32 offset) ++{ ++ return mtk_nand_block_markbad_hw(mtd_bmt, offset); //mark_block_bad_hw(offset); ++} ++ ++bool nand_write_page_bmt(u32 page, u8 * dat, u8 * oob) ++{ ++ if (mtk_nand_exec_write_page(mtd_bmt, page, PAGE_SIZE_BMT, dat, oob)) ++ return false; ++ else ++ return true; ++} ++ ++/*************************************************************** ++* * ++* static internal function * ++* * ++***************************************************************/ ++static void dump_bmt_info(bmt_struct * bmt) ++{ ++ int i; ++ ++ MSG(INIT, "BMT v%d. total %d mapping:\n", bmt->version, bmt->mapped_count); ++ for (i = 0; i < bmt->mapped_count; i++) ++ { ++ MSG(INIT, "\t0x%x -> 0x%x\n", bmt->table[i].bad_index, bmt->table[i].mapped_index); ++ } ++} ++ ++static bool match_bmt_signature(u8 * dat, u8 * oob) ++{ ++ ++ if (memcmp(dat + MAIN_SIGNATURE_OFFSET, MAIN_SIGNATURE, SIGNATURE_SIZE)) ++ { ++ return false; ++ } ++ ++ if (memcmp(oob + OOB_SIGNATURE_OFFSET, OOB_SIGNATURE, SIGNATURE_SIZE)) ++ { ++ MSG(INIT, "main signature match, oob signature doesn't match, but ignore\n"); ++ } ++ return true; ++} ++ ++static u8 cal_bmt_checksum(phys_bmt_struct * phys_table, int bmt_size) ++{ ++ int i; ++ u8 checksum = 0; ++ u8 *dat = (u8 *) phys_table; ++ ++ checksum += phys_table->header.version; ++ checksum += phys_table->header.mapped_count; ++ ++ dat += sizeof(phys_bmt_header); ++ for (i = 0; i < bmt_size * sizeof(bmt_entry); i++) ++ { ++ checksum += dat[i]; ++ } ++ ++ return checksum; ++} ++ ++ ++static int is_block_mapped(int index) ++{ ++ int i; ++ for (i = 0; i < bmt.mapped_count; i++) ++ { ++ if (index == bmt.table[i].mapped_index) ++ return i; ++ } ++ return -1; ++} ++ ++static bool is_page_used(u8 * dat, u8 * oob) ++{ ++ return ((oob[OOB_INDEX_OFFSET] != 0xFF) || (oob[OOB_INDEX_OFFSET + 1] != 0xFF)); ++} ++ ++static bool valid_bmt_data(phys_bmt_struct * phys_table) ++{ ++ int i; ++ u8 checksum = cal_bmt_checksum(phys_table, bmt_block_count); ++ ++ // checksum correct? ++ if (phys_table->header.checksum != checksum) ++ { ++ MSG(INIT, "BMT Data checksum error: %x %x\n", phys_table->header.checksum, checksum); ++ return false; ++ } ++ ++ MSG(INIT, "BMT Checksum is: 0x%x\n", phys_table->header.checksum); ++ ++ // block index correct? ++ for (i = 0; i < phys_table->header.mapped_count; i++) ++ { ++ if (phys_table->table[i].bad_index >= total_block_count || phys_table->table[i].mapped_index >= total_block_count || phys_table->table[i].mapped_index < system_block_count) ++ { ++ MSG(INIT, "index error: bad_index: %d, mapped_index: %d\n", phys_table->table[i].bad_index, phys_table->table[i].mapped_index); ++ return false; ++ } ++ } ++ ++ // pass check, valid bmt. ++ MSG(INIT, "Valid BMT, version v%d\n", phys_table->header.version); ++ return true; ++} ++ ++static void fill_nand_bmt_buffer(bmt_struct * bmt, u8 * dat, u8 * oob) ++{ ++ phys_bmt_struct phys_bmt; ++ ++ dump_bmt_info(bmt); ++ ++ // fill phys_bmt_struct structure with bmt_struct ++ memset(&phys_bmt, 0xFF, sizeof(phys_bmt)); ++ ++ memcpy(phys_bmt.header.signature, MAIN_SIGNATURE, SIGNATURE_SIZE); ++ phys_bmt.header.version = BMT_VERSION; ++ // phys_bmt.header.bad_count = bmt->bad_count; ++ phys_bmt.header.mapped_count = bmt->mapped_count; ++ memcpy(phys_bmt.table, bmt->table, sizeof(bmt_entry) * bmt_block_count); ++ ++ phys_bmt.header.checksum = cal_bmt_checksum(&phys_bmt, bmt_block_count); ++ ++ memcpy(dat + MAIN_SIGNATURE_OFFSET, &phys_bmt, sizeof(phys_bmt)); ++ memcpy(oob + OOB_SIGNATURE_OFFSET, OOB_SIGNATURE, SIGNATURE_SIZE); ++} ++ ++// return valid index if found BMT, else return 0 ++static int load_bmt_data(int start, int pool_size) ++{ ++ int bmt_index = start + pool_size - 1; // find from the end ++ phys_bmt_struct phys_table; ++ int i; ++ ++ MSG(INIT, "[%s]: begin to search BMT from block 0x%x\n", __FUNCTION__, bmt_index); ++ ++ for (bmt_index = start + pool_size - 1; bmt_index >= start; bmt_index--) ++ { ++ if (nand_block_bad_bmt(OFFSET(bmt_index))) ++ { ++ MSG(INIT, "Skip bad block: %d\n", bmt_index); ++ continue; ++ } ++ ++ if (!nand_read_page_bmt(PAGE_ADDR(bmt_index), dat_buf, oob_buf)) ++ { ++ MSG(INIT, "Error found when read block %d\n", bmt_index); ++ continue; ++ } ++ ++ if (!match_bmt_signature(dat_buf, oob_buf)) ++ { ++ continue; ++ } ++ ++ MSG(INIT, "Match bmt signature @ block: 0x%x\n", bmt_index); ++ ++ memcpy(&phys_table, dat_buf + MAIN_SIGNATURE_OFFSET, sizeof(phys_table)); ++ ++ if (!valid_bmt_data(&phys_table)) ++ { ++ MSG(INIT, "BMT data is not correct %d\n", bmt_index); ++ continue; ++ } else ++ { ++ bmt.mapped_count = phys_table.header.mapped_count; ++ bmt.version = phys_table.header.version; ++ // bmt.bad_count = phys_table.header.bad_count; ++ memcpy(bmt.table, phys_table.table, bmt.mapped_count * sizeof(bmt_entry)); ++ ++ MSG(INIT, "bmt found at block: %d, mapped block: %d\n", bmt_index, bmt.mapped_count); ++ ++ for (i = 0; i < bmt.mapped_count; i++) ++ { ++ if (!nand_block_bad_bmt(OFFSET(bmt.table[i].bad_index))) ++ { ++ MSG(INIT, "block 0x%x is not mark bad, should be power lost last time\n", bmt.table[i].bad_index); ++ mark_block_bad_bmt(OFFSET(bmt.table[i].bad_index)); ++ } ++ } ++ ++ return bmt_index; ++ } ++ } ++ ++ MSG(INIT, "bmt block not found!\n"); ++ return 0; ++} ++ ++/************************************************************************* ++* Find an available block and erase. * ++* start_from_end: if true, find available block from end of flash. * ++* else, find from the beginning of the pool * ++* need_erase: if true, all unmapped blocks in the pool will be erased * ++*************************************************************************/ ++static int find_available_block(bool start_from_end) ++{ ++ int i; // , j; ++ int block = system_block_count; ++ int direction; ++ // int avail_index = 0; ++ MSG(INIT, "Try to find_available_block, pool_erase: %d\n", pool_erased); ++ ++ // erase all un-mapped blocks in pool when finding avaliable block ++ if (!pool_erased) ++ { ++ MSG(INIT, "Erase all un-mapped blocks in pool\n"); ++ for (i = 0; i < bmt_block_count; i++) ++ { ++ if (block == bmt_block_index) ++ { ++ MSG(INIT, "Skip bmt block 0x%x\n", block); ++ continue; ++ } ++ ++ if (nand_block_bad_bmt(OFFSET(block + i))) ++ { ++ MSG(INIT, "Skip bad block 0x%x\n", block + i); ++ continue; ++ } ++//if(block==4095) ++//{ ++// continue; ++//} ++ ++ if (is_block_mapped(block + i) >= 0) ++ { ++ MSG(INIT, "Skip mapped block 0x%x\n", block + i); ++ continue; ++ } ++ ++ if (!nand_erase_bmt(OFFSET(block + i))) ++ { ++ MSG(INIT, "Erase block 0x%x failed\n", block + i); ++ mark_block_bad_bmt(OFFSET(block + i)); ++ } ++ } ++ ++ pool_erased = 1; ++ } ++ ++ if (start_from_end) ++ { ++ block = total_block_count - 1; ++ direction = -1; ++ } else ++ { ++ block = system_block_count; ++ direction = 1; ++ } ++ ++ for (i = 0; i < bmt_block_count; i++, block += direction) ++ { ++ if (block == bmt_block_index) ++ { ++ MSG(INIT, "Skip bmt block 0x%x\n", block); ++ continue; ++ } ++ ++ if (nand_block_bad_bmt(OFFSET(block))) ++ { ++ MSG(INIT, "Skip bad block 0x%x\n", block); ++ continue; ++ } ++ ++ if (is_block_mapped(block) >= 0) ++ { ++ MSG(INIT, "Skip mapped block 0x%x\n", block); ++ continue; ++ } ++ ++ MSG(INIT, "Find block 0x%x available\n", block); ++ return block; ++ } ++ ++ return 0; ++} ++ ++static unsigned short get_bad_index_from_oob(u8 * oob_buf) ++{ ++ unsigned short index; ++ memcpy(&index, oob_buf + OOB_INDEX_OFFSET, OOB_INDEX_SIZE); ++ ++ return index; ++} ++ ++void set_bad_index_to_oob(u8 * oob, u16 index) ++{ ++ memcpy(oob + OOB_INDEX_OFFSET, &index, sizeof(index)); ++} ++ ++static int migrate_from_bad(int offset, u8 * write_dat, u8 * write_oob) ++{ ++ int page; ++ int error_block = offset / BLOCK_SIZE_BMT; ++ int error_page = (offset / PAGE_SIZE_BMT) % page_per_block; ++ int to_index; ++ ++ memcpy(oob_buf, write_oob, MAX_OOB_SIZE); ++ ++ to_index = find_available_block(false); ++ ++ if (!to_index) ++ { ++ MSG(INIT, "Cannot find an available block for BMT\n"); ++ return 0; ++ } ++ ++ { // migrate error page first ++ MSG(INIT, "Write error page: 0x%x\n", error_page); ++ if (!write_dat) ++ { ++ nand_read_page_bmt(PAGE_ADDR(error_block) + error_page, dat_buf, NULL); ++ write_dat = dat_buf; ++ } ++ // memcpy(oob_buf, write_oob, MAX_OOB_SIZE); ++ ++ if (error_block < system_block_count) ++ set_bad_index_to_oob(oob_buf, error_block); // if error_block is already a mapped block, original mapping index is in OOB. ++ ++ if (!nand_write_page_bmt(PAGE_ADDR(to_index) + error_page, write_dat, oob_buf)) ++ { ++ MSG(INIT, "Write to page 0x%x fail\n", PAGE_ADDR(to_index) + error_page); ++ mark_block_bad_bmt(to_index); ++ return migrate_from_bad(offset, write_dat, write_oob); ++ } ++ } ++ ++ for (page = 0; page < page_per_block; page++) ++ { ++ if (page != error_page) ++ { ++ nand_read_page_bmt(PAGE_ADDR(error_block) + page, dat_buf, oob_buf); ++ if (is_page_used(dat_buf, oob_buf)) ++ { ++ if (error_block < system_block_count) ++ { ++ set_bad_index_to_oob(oob_buf, error_block); ++ } ++ MSG(INIT, "\tmigrate page 0x%x to page 0x%x\n", PAGE_ADDR(error_block) + page, PAGE_ADDR(to_index) + page); ++ if (!nand_write_page_bmt(PAGE_ADDR(to_index) + page, dat_buf, oob_buf)) ++ { ++ MSG(INIT, "Write to page 0x%x fail\n", PAGE_ADDR(to_index) + page); ++ mark_block_bad_bmt(to_index); ++ return migrate_from_bad(offset, write_dat, write_oob); ++ } ++ } ++ } ++ } ++ ++ MSG(INIT, "Migrate from 0x%x to 0x%x done!\n", error_block, to_index); ++ ++ return to_index; ++} ++ ++static bool write_bmt_to_flash(u8 * dat, u8 * oob) ++{ ++ bool need_erase = true; ++ MSG(INIT, "Try to write BMT\n"); ++ ++ if (bmt_block_index == 0) ++ { ++ // if we don't have index, we don't need to erase found block as it has been erased in find_available_block() ++ need_erase = false; ++ if (!(bmt_block_index = find_available_block(true))) ++ { ++ MSG(INIT, "Cannot find an available block for BMT\n"); ++ return false; ++ } ++ } ++ ++ MSG(INIT, "Find BMT block: 0x%x\n", bmt_block_index); ++ ++ // write bmt to flash ++ if (need_erase) ++ { ++ if (!nand_erase_bmt(OFFSET(bmt_block_index))) ++ { ++ MSG(INIT, "BMT block erase fail, mark bad: 0x%x\n", bmt_block_index); ++ mark_block_bad_bmt(OFFSET(bmt_block_index)); ++ // bmt.bad_count++; ++ ++ bmt_block_index = 0; ++ return write_bmt_to_flash(dat, oob); // recursive call ++ } ++ } ++ ++ if (!nand_write_page_bmt(PAGE_ADDR(bmt_block_index), dat, oob)) ++ { ++ MSG(INIT, "Write BMT data fail, need to write again\n"); ++ mark_block_bad_bmt(OFFSET(bmt_block_index)); ++ // bmt.bad_count++; ++ ++ bmt_block_index = 0; ++ return write_bmt_to_flash(dat, oob); // recursive call ++ } ++ ++ MSG(INIT, "Write BMT data to block 0x%x success\n", bmt_block_index); ++ return true; ++} ++ ++/******************************************************************* ++* Reconstruct bmt, called when found bmt info doesn't match bad ++* block info in flash. ++* ++* Return NULL for failure ++*******************************************************************/ ++bmt_struct *reconstruct_bmt(bmt_struct * bmt) ++{ ++ int i; ++ int index = system_block_count; ++ unsigned short bad_index; ++ int mapped; ++ ++ // init everything in BMT struct ++ bmt->version = BMT_VERSION; ++ bmt->bad_count = 0; ++ bmt->mapped_count = 0; ++ ++ memset(bmt->table, 0, bmt_block_count * sizeof(bmt_entry)); ++ ++ for (i = 0; i < bmt_block_count; i++, index++) ++ { ++ if (nand_block_bad_bmt(OFFSET(index))) ++ { ++ MSG(INIT, "Skip bad block: 0x%x\n", index); ++ // bmt->bad_count++; ++ continue; ++ } ++ ++ MSG(INIT, "read page: 0x%x\n", PAGE_ADDR(index)); ++ nand_read_page_bmt(PAGE_ADDR(index), dat_buf, oob_buf); ++ /* if (mtk_nand_read_page_hw(PAGE_ADDR(index), dat_buf)) ++ { ++ MSG(INIT, "Error when read block %d\n", bmt_block_index); ++ continue; ++ } */ ++ ++ if ((bad_index = get_bad_index_from_oob(oob_buf)) >= system_block_count) ++ { ++ MSG(INIT, "get bad index: 0x%x\n", bad_index); ++ if (bad_index != 0xFFFF) ++ MSG(INIT, "Invalid bad index found in block 0x%x, bad index 0x%x\n", index, bad_index); ++ continue; ++ } ++ ++ MSG(INIT, "Block 0x%x is mapped to bad block: 0x%x\n", index, bad_index); ++ ++ if (!nand_block_bad_bmt(OFFSET(bad_index))) ++ { ++ MSG(INIT, "\tbut block 0x%x is not marked as bad, invalid mapping\n", bad_index); ++ continue; // no need to erase here, it will be erased later when trying to write BMT ++ } ++ ++ if ((mapped = is_block_mapped(bad_index)) >= 0) ++ { ++ MSG(INIT, "bad block 0x%x is mapped to 0x%x, should be caused by power lost, replace with one\n", bmt->table[mapped].bad_index, bmt->table[mapped].mapped_index); ++ bmt->table[mapped].mapped_index = index; // use new one instead. ++ } else ++ { ++ // add mapping to BMT ++ bmt->table[bmt->mapped_count].bad_index = bad_index; ++ bmt->table[bmt->mapped_count].mapped_index = index; ++ bmt->mapped_count++; ++ } ++ ++ MSG(INIT, "Add mapping: 0x%x -> 0x%x to BMT\n", bad_index, index); ++ ++ } ++ ++ MSG(INIT, "Scan replace pool done, mapped block: %d\n", bmt->mapped_count); ++ // dump_bmt_info(bmt); ++ ++ // fill NAND BMT buffer ++ memset(oob_buf, 0xFF, sizeof(oob_buf)); ++ fill_nand_bmt_buffer(bmt, dat_buf, oob_buf); ++ ++ // write BMT back ++ if (!write_bmt_to_flash(dat_buf, oob_buf)) ++ { ++ MSG(INIT, "TRAGEDY: cannot find a place to write BMT!!!!\n"); ++ } ++ ++ return bmt; ++} ++ ++/******************************************************************* ++* [BMT Interface] ++* ++* Description: ++* Init bmt from nand. Reconstruct if not found or data error ++* ++* Parameter: ++* size: size of bmt and replace pool ++* ++* Return: ++* NULL for failure, and a bmt struct for success ++*******************************************************************/ ++bmt_struct *init_bmt(struct nand_chip * chip, int size) ++{ ++ struct mtk_nand_host *host; ++ ++ if (size > 0 && size < MAX_BMT_SIZE) ++ { ++ MSG(INIT, "Init bmt table, size: %d\n", size); ++ bmt_block_count = size; ++ } else ++ { ++ MSG(INIT, "Invalid bmt table size: %d\n", size); ++ return NULL; ++ } ++ nand_chip_bmt = chip; ++ system_block_count = chip->chipsize >> chip->phys_erase_shift; ++ total_block_count = bmt_block_count + system_block_count; ++ page_per_block = BLOCK_SIZE_BMT / PAGE_SIZE_BMT; ++ host = (struct mtk_nand_host *)chip->priv; ++ mtd_bmt = &host->mtd; ++ ++ MSG(INIT, "mtd_bmt: %p, nand_chip_bmt: %p\n", mtd_bmt, nand_chip_bmt); ++ MSG(INIT, "bmt count: %d, system count: %d\n", bmt_block_count, system_block_count); ++ ++ // set this flag, and unmapped block in pool will be erased. ++ pool_erased = 0; ++ memset(bmt.table, 0, size * sizeof(bmt_entry)); ++ if ((bmt_block_index = load_bmt_data(system_block_count, size))) ++ { ++ MSG(INIT, "Load bmt data success @ block 0x%x\n", bmt_block_index); ++ dump_bmt_info(&bmt); ++ return &bmt; ++ } else ++ { ++ MSG(INIT, "Load bmt data fail, need re-construct!\n"); ++#ifndef __UBOOT_NAND__ // BMT is not re-constructed in UBOOT. ++ if (reconstruct_bmt(&bmt)) ++ return &bmt; ++ else ++#endif ++ return NULL; ++ } ++} ++ ++/******************************************************************* ++* [BMT Interface] ++* ++* Description: ++* Update BMT. ++* ++* Parameter: ++* offset: update block/page offset. ++* reason: update reason, see update_reason_t for reason. ++* dat/oob: data and oob buffer for write fail. ++* ++* Return: ++* Return true for success, and false for failure. ++*******************************************************************/ ++bool update_bmt(u32 offset, update_reason_t reason, u8 * dat, u8 * oob) ++{ ++ int map_index; ++ int orig_bad_block = -1; ++ // int bmt_update_index; ++ int i; ++ int bad_index = offset / BLOCK_SIZE_BMT; ++ ++#ifndef MTK_NAND_BMT ++ return false; ++#endif ++ if (reason == UPDATE_WRITE_FAIL) ++ { ++ MSG(INIT, "Write fail, need to migrate\n"); ++ if (!(map_index = migrate_from_bad(offset, dat, oob))) ++ { ++ MSG(INIT, "migrate fail\n"); ++ return false; ++ } ++ } else ++ { ++ if (!(map_index = find_available_block(false))) ++ { ++ MSG(INIT, "Cannot find block in pool\n"); ++ return false; ++ } ++ } ++ ++ // now let's update BMT ++ if (bad_index >= system_block_count) // mapped block become bad, find original bad block ++ { ++ for (i = 0; i < bmt_block_count; i++) ++ { ++ if (bmt.table[i].mapped_index == bad_index) ++ { ++ orig_bad_block = bmt.table[i].bad_index; ++ break; ++ } ++ } ++ // bmt.bad_count++; ++ MSG(INIT, "Mapped block becomes bad, orig bad block is 0x%x\n", orig_bad_block); ++ ++ bmt.table[i].mapped_index = map_index; ++ } else ++ { ++ bmt.table[bmt.mapped_count].mapped_index = map_index; ++ bmt.table[bmt.mapped_count].bad_index = bad_index; ++ bmt.mapped_count++; ++ } ++ ++ memset(oob_buf, 0xFF, sizeof(oob_buf)); ++ fill_nand_bmt_buffer(&bmt, dat_buf, oob_buf); ++ if (!write_bmt_to_flash(dat_buf, oob_buf)) ++ return false; ++ ++ mark_block_bad_bmt(offset); ++ ++ return true; ++} ++ ++/******************************************************************* ++* [BMT Interface] ++* ++* Description: ++* Given an block index, return mapped index if it's mapped, else ++* return given index. ++* ++* Parameter: ++* index: given an block index. This value cannot exceed ++* system_block_count. ++* ++* Return NULL for failure ++*******************************************************************/ ++u16 get_mapping_block_index(int index) ++{ ++ int i; ++#ifndef MTK_NAND_BMT ++ return index; ++#endif ++ if (index > system_block_count) ++ { ++ return index; ++ } ++ ++ for (i = 0; i < bmt.mapped_count; i++) ++ { ++ if (bmt.table[i].bad_index == index) ++ { ++ return bmt.table[i].mapped_index; ++ } ++ } ++ ++ return index; ++} ++#ifdef __KERNEL_NAND__ ++EXPORT_SYMBOL_GPL(init_bmt); ++EXPORT_SYMBOL_GPL(update_bmt); ++EXPORT_SYMBOL_GPL(get_mapping_block_index); ++ ++MODULE_LICENSE("GPL"); ++MODULE_AUTHOR("MediaTek"); ++MODULE_DESCRIPTION("Bad Block mapping management for MediaTek NAND Flash Driver"); ++#endif +--- /dev/null ++++ b/drivers/mtd/nand/bmt.h +@@ -0,0 +1,80 @@ ++#ifndef __BMT_H__ ++#define __BMT_H__ ++ ++#include "nand_def.h" ++ ++#if defined(__PRELOADER_NAND__) ++ ++#include "nand.h" ++ ++#elif defined(__UBOOT_NAND__) ++ ++#include <linux/mtd/nand.h> ++#include "mtk_nand.h" ++ ++#elif defined(__KERNEL_NAND__) ++ ++#include <linux/mtd/mtd.h> ++#include <linux/mtd/nand.h> ++#include <linux/module.h> ++#include "mtk_nand.h" ++ ++#endif ++ ++ ++#define MAX_BMT_SIZE (0x80) ++#define BMT_VERSION (1) // initial version ++ ++#define MAIN_SIGNATURE_OFFSET (0) ++#define OOB_SIGNATURE_OFFSET (1) ++#define OOB_INDEX_OFFSET (29) ++#define OOB_INDEX_SIZE (2) ++#define FAKE_INDEX (0xAAAA) ++ ++typedef struct _bmt_entry_ ++{ ++ u16 bad_index; // bad block index ++ u16 mapped_index; // mapping block index in the replace pool ++} bmt_entry; ++ ++typedef enum ++{ ++ UPDATE_ERASE_FAIL, ++ UPDATE_WRITE_FAIL, ++ UPDATE_UNMAPPED_BLOCK, ++ UPDATE_REASON_COUNT, ++} update_reason_t; ++ ++typedef struct ++{ ++ bmt_entry table[MAX_BMT_SIZE]; ++ u8 version; ++ u8 mapped_count; // mapped block count in pool ++ u8 bad_count; // bad block count in pool. Not used in V1 ++} bmt_struct; ++ ++/*************************************************************** ++* * ++* Interface BMT need to use * ++* * ++***************************************************************/ ++extern bool mtk_nand_exec_read_page(struct mtd_info *mtd, u32 row, u32 page_size, u8 * dat, u8 * oob); ++extern int mtk_nand_block_bad_hw(struct mtd_info *mtd, loff_t ofs); ++extern int mtk_nand_erase_hw(struct mtd_info *mtd, int page); ++extern int mtk_nand_block_markbad_hw(struct mtd_info *mtd, loff_t ofs); ++extern int mtk_nand_exec_write_page(struct mtd_info *mtd, u32 row, u32 page_size, u8 * dat, u8 * oob); ++ ++ ++/*************************************************************** ++* * ++* Different function interface for preloader/uboot/kernel * ++* * ++***************************************************************/ ++void set_bad_index_to_oob(u8 * oob, u16 index); ++ ++ ++bmt_struct *init_bmt(struct nand_chip *nand, int size); ++bool update_bmt(u32 offset, update_reason_t reason, u8 * dat, u8 * oob); ++unsigned short get_mapping_block_index(int index); ++ ++#endif // #ifndef __BMT_H__ +--- /dev/null ++++ b/drivers/mtd/nand/dev-nand.c +@@ -0,0 +1,63 @@ ++#include <linux/init.h> ++#include <linux/kernel.h> ++#include <linux/platform_device.h> ++ ++#include "mt6575_typedefs.h" ++ ++#define RALINK_NAND_CTRL_BASE 0xBE003000 ++#define NFI_base RALINK_NAND_CTRL_BASE ++#define RALINK_NANDECC_CTRL_BASE 0xBE003800 ++#define NFIECC_base RALINK_NANDECC_CTRL_BASE ++#define MT7621_NFI_IRQ_ID SURFBOARDINT_NAND ++#define MT7621_NFIECC_IRQ_ID SURFBOARDINT_NAND_ECC ++ ++#define SURFBOARDINT_NAND 22 ++#define SURFBOARDINT_NAND_ECC 23 ++ ++static struct resource MT7621_resource_nand[] = { ++ { ++ .start = NFI_base, ++ .end = NFI_base + 0x1A0, ++ .flags = IORESOURCE_MEM, ++ }, ++ { ++ .start = NFIECC_base, ++ .end = NFIECC_base + 0x150, ++ .flags = IORESOURCE_MEM, ++ }, ++ { ++ .start = MT7621_NFI_IRQ_ID, ++ .flags = IORESOURCE_IRQ, ++ }, ++ { ++ .start = MT7621_NFIECC_IRQ_ID, ++ .flags = IORESOURCE_IRQ, ++ }, ++}; ++ ++static struct platform_device MT7621_nand_dev = { ++ .name = "MT7621-NAND", ++ .id = 0, ++ .num_resources = ARRAY_SIZE(MT7621_resource_nand), ++ .resource = MT7621_resource_nand, ++ .dev = { ++ .platform_data = &mt7621_nand_hw, ++ }, ++}; ++ ++ ++int __init mtk_nand_register(void) ++{ ++ ++ int retval = 0; ++ ++ retval = platform_device_register(&MT7621_nand_dev); ++ if (retval != 0) { ++ printk(KERN_ERR "register nand device fail\n"); ++ return retval; ++ } ++ ++ ++ return retval; ++} ++arch_initcall(mtk_nand_register); +--- /dev/null ++++ b/drivers/mtd/nand/mt6575_typedefs.h +@@ -0,0 +1,340 @@ ++/* Copyright Statement: ++ * ++ * This software/firmware and related documentation ("MediaTek Software") are ++ * protected under relevant copyright laws. The information contained herein ++ * is confidential and proprietary to MediaTek Inc. and/or its licensors. ++ * Without the prior written permission of MediaTek inc. and/or its licensors, ++ * any reproduction, modification, use or disclosure of MediaTek Software, ++ * and information contained herein, in whole or in part, shall be strictly prohibited. ++ */ ++/* MediaTek Inc. (C) 2010. All rights reserved. ++ * ++ * BY OPENING THIS FILE, RECEIVER HEREBY UNEQUIVOCALLY ACKNOWLEDGES AND AGREES ++ * THAT THE SOFTWARE/FIRMWARE AND ITS DOCUMENTATIONS ("MEDIATEK SOFTWARE") ++ * RECEIVED FROM MEDIATEK AND/OR ITS REPRESENTATIVES ARE PROVIDED TO RECEIVER ON ++ * AN "AS-IS" BASIS ONLY. MEDIATEK EXPRESSLY DISCLAIMS ANY AND ALL WARRANTIES, ++ * EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE IMPLIED WARRANTIES OF ++ * MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE OR NONINFRINGEMENT. ++ * NEITHER DOES MEDIATEK PROVIDE ANY WARRANTY WHATSOEVER WITH RESPECT TO THE ++ * SOFTWARE OF ANY THIRD PARTY WHICH MAY BE USED BY, INCORPORATED IN, OR ++ * SUPPLIED WITH THE MEDIATEK SOFTWARE, AND RECEIVER AGREES TO LOOK ONLY TO SUCH ++ * THIRD PARTY FOR ANY WARRANTY CLAIM RELATING THERETO. RECEIVER EXPRESSLY ACKNOWLEDGES ++ * THAT IT IS RECEIVER'S SOLE RESPONSIBILITY TO OBTAIN FROM ANY THIRD PARTY ALL PROPER LICENSES ++ * CONTAINED IN MEDIATEK SOFTWARE. MEDIATEK SHALL ALSO NOT BE RESPONSIBLE FOR ANY MEDIATEK ++ * SOFTWARE RELEASES MADE TO RECEIVER'S SPECIFICATION OR TO CONFORM TO A PARTICULAR ++ * STANDARD OR OPEN FORUM. RECEIVER'S SOLE AND EXCLUSIVE REMEDY AND MEDIATEK'S ENTIRE AND ++ * CUMULATIVE LIABILITY WITH RESPECT TO THE MEDIATEK SOFTWARE RELEASED HEREUNDER WILL BE, ++ * AT MEDIATEK'S OPTION, TO REVISE OR REPLACE THE MEDIATEK SOFTWARE AT ISSUE, ++ * OR REFUND ANY SOFTWARE LICENSE FEES OR SERVICE CHARGE PAID BY RECEIVER TO ++ * MEDIATEK FOR SUCH MEDIATEK SOFTWARE AT ISSUE. ++ * ++ * The following software/firmware and/or related documentation ("MediaTek Software") ++ * have been modified by MediaTek Inc. All revisions are subject to any receiver's ++ * applicable license agreements with MediaTek Inc. ++ */ ++ ++/***************************************************************************** ++* Copyright Statement: ++* -------------------- ++* This software is protected by Copyright and the information contained ++* herein is confidential. The software may not be copied and the information ++* contained herein may not be used or disclosed except with the written ++* permission of MediaTek Inc. (C) 2008 ++* ++* BY OPENING THIS FILE, BUYER HEREBY UNEQUIVOCALLY ACKNOWLEDGES AND AGREES ++* THAT THE SOFTWARE/FIRMWARE AND ITS DOCUMENTATIONS ("MEDIATEK SOFTWARE") ++* RECEIVED FROM MEDIATEK AND/OR ITS REPRESENTATIVES ARE PROVIDED TO BUYER ON ++* AN "AS-IS" BASIS ONLY. MEDIATEK EXPRESSLY DISCLAIMS ANY AND ALL WARRANTIES, ++* EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE IMPLIED WARRANTIES OF ++* MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE OR NONINFRINGEMENT. ++* NEITHER DOES MEDIATEK PROVIDE ANY WARRANTY WHATSOEVER WITH RESPECT TO THE ++* SOFTWARE OF ANY THIRD PARTY WHICH MAY BE USED BY, INCORPORATED IN, OR ++* SUPPLIED WITH THE MEDIATEK SOFTWARE, AND BUYER AGREES TO LOOK ONLY TO SUCH ++* THIRD PARTY FOR ANY WARRANTY CLAIM RELATING THERETO. MEDIATEK SHALL ALSO ++* NOT BE RESPONSIBLE FOR ANY MEDIATEK SOFTWARE RELEASES MADE TO BUYER'S ++* SPECIFICATION OR TO CONFORM TO A PARTICULAR STANDARD OR OPEN FORUM. ++* ++* BUYER'S SOLE AND EXCLUSIVE REMEDY AND MEDIATEK'S ENTIRE AND CUMULATIVE ++* LIABILITY WITH RESPECT TO THE MEDIATEK SOFTWARE RELEASED HEREUNDER WILL BE, ++* AT MEDIATEK'S OPTION, TO REVISE OR REPLACE THE MEDIATEK SOFTWARE AT ISSUE, ++* OR REFUND ANY SOFTWARE LICENSE FEES OR SERVICE CHARGE PAID BY BUYER TO ++* MEDIATEK FOR SUCH MEDIATEK SOFTWARE AT ISSUE. ++* ++* THE TRANSACTION CONTEMPLATED HEREUNDER SHALL BE CONSTRUED IN ACCORDANCE ++* WITH THE LAWS OF THE STATE OF CALIFORNIA, USA, EXCLUDING ITS CONFLICT OF ++* LAWS PRINCIPLES. ANY DISPUTES, CONTROVERSIES OR CLAIMS ARISING THEREOF AND ++* RELATED THERETO SHALL BE SETTLED BY ARBITRATION IN SAN FRANCISCO, CA, UNDER ++* THE RULES OF THE INTERNATIONAL CHAMBER OF COMMERCE (ICC). ++* ++*****************************************************************************/ ++ ++#ifndef _MT6575_TYPEDEFS_H ++#define _MT6575_TYPEDEFS_H ++ ++#if defined (__KERNEL_NAND__) ++#include <linux/bug.h> ++#else ++#define true 1 ++#define false 0 ++#define bool u8 ++#endif ++ ++// --------------------------------------------------------------------------- ++// Basic Type Definitions ++// --------------------------------------------------------------------------- ++ ++typedef volatile unsigned char *P_kal_uint8; ++typedef volatile unsigned short *P_kal_uint16; ++typedef volatile unsigned int *P_kal_uint32; ++ ++typedef long LONG; ++typedef unsigned char UBYTE; ++typedef short SHORT; ++ ++typedef signed char kal_int8; ++typedef signed short kal_int16; ++typedef signed int kal_int32; ++typedef long long kal_int64; ++typedef unsigned char kal_uint8; ++typedef unsigned short kal_uint16; ++typedef unsigned int kal_uint32; ++typedef unsigned long long kal_uint64; ++typedef char kal_char; ++ ++typedef unsigned int *UINT32P; ++typedef volatile unsigned short *UINT16P; ++typedef volatile unsigned char *UINT8P; ++typedef unsigned char *U8P; ++ ++typedef volatile unsigned char *P_U8; ++typedef volatile signed char *P_S8; ++typedef volatile unsigned short *P_U16; ++typedef volatile signed short *P_S16; ++typedef volatile unsigned int *P_U32; ++typedef volatile signed int *P_S32; ++typedef unsigned long long *P_U64; ++typedef signed long long *P_S64; ++ ++typedef unsigned char U8; ++typedef signed char S8; ++typedef unsigned short U16; ++typedef signed short S16; ++typedef unsigned int U32; ++typedef signed int S32; ++typedef unsigned long long U64; ++typedef signed long long S64; ++//typedef unsigned char bool; ++ ++typedef unsigned char UINT8; ++typedef unsigned short UINT16; ++typedef unsigned int UINT32; ++typedef unsigned short USHORT; ++typedef signed char INT8; ++typedef signed short INT16; ++typedef signed int INT32; ++typedef unsigned int DWORD; ++typedef void VOID; ++typedef unsigned char BYTE; ++typedef float FLOAT; ++ ++typedef char *LPCSTR; ++typedef short *LPWSTR; ++ ++ ++// --------------------------------------------------------------------------- ++// Constants ++// --------------------------------------------------------------------------- ++ ++#define IMPORT EXTERN ++#ifndef __cplusplus ++ #define EXTERN extern ++#else ++ #define EXTERN extern "C" ++#endif ++#define LOCAL static ++#define GLOBAL ++#define EXPORT GLOBAL ++ ++#define EQ == ++#define NEQ != ++#define AND && ++#define OR || ++#define XOR(A,B) ((!(A) AND (B)) OR ((A) AND !(B))) ++ ++#ifndef FALSE ++ #define FALSE (0) ++#endif ++ ++#ifndef TRUE ++ #define TRUE (1) ++#endif ++ ++#ifndef NULL ++ #define NULL (0) ++#endif ++ ++//enum boolean {false, true}; ++enum {RX, TX, NONE}; ++ ++#ifndef BOOL ++typedef unsigned char BOOL; ++#endif ++ ++typedef enum { ++ KAL_FALSE = 0, ++ KAL_TRUE = 1, ++} kal_bool; ++ ++ ++// --------------------------------------------------------------------------- ++// Type Casting ++// --------------------------------------------------------------------------- ++ ++#define AS_INT32(x) (*(INT32 *)((void*)x)) ++#define AS_INT16(x) (*(INT16 *)((void*)x)) ++#define AS_INT8(x) (*(INT8 *)((void*)x)) ++ ++#define AS_UINT32(x) (*(UINT32 *)((void*)x)) ++#define AS_UINT16(x) (*(UINT16 *)((void*)x)) ++#define AS_UINT8(x) (*(UINT8 *)((void*)x)) ++ ++ ++// --------------------------------------------------------------------------- ++// Register Manipulations ++// --------------------------------------------------------------------------- ++ ++#define READ_REGISTER_UINT32(reg) \ ++ (*(volatile UINT32 * const)(reg)) ++ ++#define WRITE_REGISTER_UINT32(reg, val) \ ++ (*(volatile UINT32 * const)(reg)) = (val) ++ ++#define READ_REGISTER_UINT16(reg) \ ++ (*(volatile UINT16 * const)(reg)) ++ ++#define WRITE_REGISTER_UINT16(reg, val) \ ++ (*(volatile UINT16 * const)(reg)) = (val) ++ ++#define READ_REGISTER_UINT8(reg) \ ++ (*(volatile UINT8 * const)(reg)) ++ ++#define WRITE_REGISTER_UINT8(reg, val) \ ++ (*(volatile UINT8 * const)(reg)) = (val) ++ ++#define INREG8(x) READ_REGISTER_UINT8((UINT8*)((void*)(x))) ++#define OUTREG8(x, y) WRITE_REGISTER_UINT8((UINT8*)((void*)(x)), (UINT8)(y)) ++#define SETREG8(x, y) OUTREG8(x, INREG8(x)|(y)) ++#define CLRREG8(x, y) OUTREG8(x, INREG8(x)&~(y)) ++#define MASKREG8(x, y, z) OUTREG8(x, (INREG8(x)&~(y))|(z)) ++ ++#define INREG16(x) READ_REGISTER_UINT16((UINT16*)((void*)(x))) ++#define OUTREG16(x, y) WRITE_REGISTER_UINT16((UINT16*)((void*)(x)),(UINT16)(y)) ++#define SETREG16(x, y) OUTREG16(x, INREG16(x)|(y)) ++#define CLRREG16(x, y) OUTREG16(x, INREG16(x)&~(y)) ++#define MASKREG16(x, y, z) OUTREG16(x, (INREG16(x)&~(y))|(z)) ++ ++#define INREG32(x) READ_REGISTER_UINT32((UINT32*)((void*)(x))) ++#define OUTREG32(x, y) WRITE_REGISTER_UINT32((UINT32*)((void*)(x)), (UINT32)(y)) ++#define SETREG32(x, y) OUTREG32(x, INREG32(x)|(y)) ++#define CLRREG32(x, y) OUTREG32(x, INREG32(x)&~(y)) ++#define MASKREG32(x, y, z) OUTREG32(x, (INREG32(x)&~(y))|(z)) ++ ++ ++#define DRV_Reg8(addr) INREG8(addr) ++#define DRV_WriteReg8(addr, data) OUTREG8(addr, data) ++#define DRV_SetReg8(addr, data) SETREG8(addr, data) ++#define DRV_ClrReg8(addr, data) CLRREG8(addr, data) ++ ++#define DRV_Reg16(addr) INREG16(addr) ++#define DRV_WriteReg16(addr, data) OUTREG16(addr, data) ++#define DRV_SetReg16(addr, data) SETREG16(addr, data) ++#define DRV_ClrReg16(addr, data) CLRREG16(addr, data) ++ ++#define DRV_Reg32(addr) INREG32(addr) ++#define DRV_WriteReg32(addr, data) OUTREG32(addr, data) ++#define DRV_SetReg32(addr, data) SETREG32(addr, data) ++#define DRV_ClrReg32(addr, data) CLRREG32(addr, data) ++ ++// !!! DEPRECATED, WILL BE REMOVED LATER !!! ++#define DRV_Reg(addr) DRV_Reg16(addr) ++#define DRV_WriteReg(addr, data) DRV_WriteReg16(addr, data) ++#define DRV_SetReg(addr, data) DRV_SetReg16(addr, data) ++#define DRV_ClrReg(addr, data) DRV_ClrReg16(addr, data) ++ ++ ++// --------------------------------------------------------------------------- ++// Compiler Time Deduction Macros ++// --------------------------------------------------------------------------- ++ ++#define _MASK_OFFSET_1(x, n) ((x) & 0x1) ? (n) : ++#define _MASK_OFFSET_2(x, n) _MASK_OFFSET_1((x), (n)) _MASK_OFFSET_1((x) >> 1, (n) + 1) ++#define _MASK_OFFSET_4(x, n) _MASK_OFFSET_2((x), (n)) _MASK_OFFSET_2((x) >> 2, (n) + 2) ++#define _MASK_OFFSET_8(x, n) _MASK_OFFSET_4((x), (n)) _MASK_OFFSET_4((x) >> 4, (n) + 4) ++#define _MASK_OFFSET_16(x, n) _MASK_OFFSET_8((x), (n)) _MASK_OFFSET_8((x) >> 8, (n) + 8) ++#define _MASK_OFFSET_32(x, n) _MASK_OFFSET_16((x), (n)) _MASK_OFFSET_16((x) >> 16, (n) + 16) ++ ++#define MASK_OFFSET_ERROR (0xFFFFFFFF) ++ ++#define MASK_OFFSET(x) (_MASK_OFFSET_32(x, 0) MASK_OFFSET_ERROR) ++ ++ ++// --------------------------------------------------------------------------- ++// Assertions ++// --------------------------------------------------------------------------- ++ ++#ifndef ASSERT ++ #define ASSERT(expr) BUG_ON(!(expr)) ++#endif ++ ++#ifndef NOT_IMPLEMENTED ++ #define NOT_IMPLEMENTED() BUG_ON(1) ++#endif ++ ++#define STATIC_ASSERT(pred) STATIC_ASSERT_X(pred, __LINE__) ++#define STATIC_ASSERT_X(pred, line) STATIC_ASSERT_XX(pred, line) ++#define STATIC_ASSERT_XX(pred, line) \ ++ extern char assertion_failed_at_##line[(pred) ? 1 : -1] ++ ++// --------------------------------------------------------------------------- ++// Resolve Compiler Warnings ++// --------------------------------------------------------------------------- ++ ++#define NOT_REFERENCED(x) { (x) = (x); } ++ ++ ++// --------------------------------------------------------------------------- ++// Utilities ++// --------------------------------------------------------------------------- ++ ++#define MAXIMUM(A,B) (((A)>(B))?(A):(B)) ++#define MINIMUM(A,B) (((A)<(B))?(A):(B)) ++ ++#define ARY_SIZE(x) (sizeof((x)) / sizeof((x[0]))) ++#define DVT_DELAYMACRO(u4Num) \ ++{ \ ++ UINT32 u4Count = 0 ; \ ++ for (u4Count = 0; u4Count < u4Num; u4Count++ ); \ ++} \ ++ ++#define A68351B 0 ++#define B68351B 1 ++#define B68351D 2 ++#define B68351E 3 ++#define UNKNOWN_IC_VERSION 0xFF ++ ++/* NAND driver */ ++struct mtk_nand_host_hw { ++ unsigned int nfi_bus_width; /* NFI_BUS_WIDTH */ ++ unsigned int nfi_access_timing; /* NFI_ACCESS_TIMING */ ++ unsigned int nfi_cs_num; /* NFI_CS_NUM */ ++ unsigned int nand_sec_size; /* NAND_SECTOR_SIZE */ ++ unsigned int nand_sec_shift; /* NAND_SECTOR_SHIFT */ ++ unsigned int nand_ecc_size; ++ unsigned int nand_ecc_bytes; ++ unsigned int nand_ecc_mode; ++}; ++extern struct mtk_nand_host_hw mt7621_nand_hw; ++extern unsigned int CFG_BLOCKSIZE; ++ ++#endif // _MT6575_TYPEDEFS_H ++ +--- /dev/null ++++ b/drivers/mtd/nand/mtk_nand.c +@@ -0,0 +1,2304 @@ ++/****************************************************************************** ++* mtk_nand.c - MTK NAND Flash Device Driver ++ * ++* Copyright 2009-2012 MediaTek Co.,Ltd. ++ * ++* DESCRIPTION: ++* This file provid the other drivers nand relative functions ++ * ++* modification history ++* ---------------------------------------- ++* v3.0, 11 Feb 2010, mtk ++* ---------------------------------------- ++******************************************************************************/ ++#include "nand_def.h" ++#include <linux/slab.h> ++#include <linux/init.h> ++#include <linux/module.h> ++#include <linux/delay.h> ++#include <linux/errno.h> ++#include <linux/sched.h> ++#include <linux/types.h> ++#include <linux/wait.h> ++#include <linux/spinlock.h> ++#include <linux/interrupt.h> ++#include <linux/mtd/mtd.h> ++#include <linux/mtd/nand.h> ++#include <linux/mtd/partitions.h> ++#include <linux/mtd/nand_ecc.h> ++#include <linux/dma-mapping.h> ++#include <linux/jiffies.h> ++#include <linux/platform_device.h> ++#include <linux/proc_fs.h> ++#include <linux/time.h> ++#include <linux/mm.h> ++#include <asm/io.h> ++#include <asm/cacheflush.h> ++#include <asm/uaccess.h> ++#include <linux/miscdevice.h> ++#include "mtk_nand.h" ++#include "nand_device_list.h" ++ ++#include "bmt.h" ++#include "partition.h" ++ ++unsigned int CFG_BLOCKSIZE; ++ ++static int shift_on_bbt = 0; ++extern void nand_bbt_set(struct mtd_info *mtd, int page, int flag); ++extern int nand_bbt_get(struct mtd_info *mtd, int page); ++int mtk_nand_read_oob_hw(struct mtd_info *mtd, struct nand_chip *chip, int page); ++ ++static const char * const probe_types[] = { "cmdlinepart", "ofpart", NULL }; ++ ++#define NAND_CMD_STATUS_MULTI 0x71 ++ ++void show_stack(struct task_struct *tsk, unsigned long *sp); ++extern void mt_irq_set_sens(unsigned int irq, unsigned int sens); ++extern void mt_irq_set_polarity(unsigned int irq,unsigned int polarity); ++ ++struct mtk_nand_host mtk_nand_host; /* include mtd_info and nand_chip structs */ ++struct mtk_nand_host_hw mt7621_nand_hw = { ++ .nfi_bus_width = 8, ++ .nfi_access_timing = NFI_DEFAULT_ACCESS_TIMING, ++ .nfi_cs_num = NFI_CS_NUM, ++ .nand_sec_size = 512, ++ .nand_sec_shift = 9, ++ .nand_ecc_size = 2048, ++ .nand_ecc_bytes = 32, ++ .nand_ecc_mode = NAND_ECC_HW, ++}; ++ ++ ++/******************************************************************************* ++ * Gloable Varible Definition ++ *******************************************************************************/ ++ ++#define NFI_ISSUE_COMMAND(cmd, col_addr, row_addr, col_num, row_num) \ ++ do { \ ++ DRV_WriteReg(NFI_CMD_REG16,cmd);\ ++ while (DRV_Reg32(NFI_STA_REG32) & STA_CMD_STATE);\ ++ DRV_WriteReg32(NFI_COLADDR_REG32, col_addr);\ ++ DRV_WriteReg32(NFI_ROWADDR_REG32, row_addr);\ ++ DRV_WriteReg(NFI_ADDRNOB_REG16, col_num | (row_num<<ADDR_ROW_NOB_SHIFT));\ ++ while (DRV_Reg32(NFI_STA_REG32) & STA_ADDR_STATE);\ ++ }while(0); ++ ++//------------------------------------------------------------------------------- ++static struct NAND_CMD g_kCMD; ++static u32 g_u4ChipVer; ++bool g_bInitDone; ++static bool g_bcmdstatus; ++static u32 g_value = 0; ++static int g_page_size; ++ ++BOOL g_bHwEcc = true; ++ ++ ++static u8 *local_buffer_16_align; // 16 byte aligned buffer, for HW issue ++static u8 local_buffer[4096 + 512]; ++ ++extern void nand_release_device(struct mtd_info *mtd); ++extern int nand_get_device(struct nand_chip *chip, struct mtd_info *mtd, int new_state); ++ ++#if defined(MTK_NAND_BMT) ++static bmt_struct *g_bmt; ++#endif ++struct mtk_nand_host *host; ++extern struct mtd_partition g_pasStatic_Partition[]; ++int part_num = NUM_PARTITIONS; ++int manu_id; ++int dev_id; ++ ++static u8 local_oob_buf[NAND_MAX_OOBSIZE]; ++ ++static u8 nand_badblock_offset = 0; ++ ++void nand_enable_clock(void) ++{ ++ //enable_clock(MT65XX_PDN_PERI_NFI, "NAND"); ++} ++ ++void nand_disable_clock(void) ++{ ++ //disable_clock(MT65XX_PDN_PERI_NFI, "NAND"); ++} ++ ++static struct nand_ecclayout nand_oob_16 = { ++ .eccbytes = 8, ++ .eccpos = {8, 9, 10, 11, 12, 13, 14, 15}, ++ .oobfree = {{1, 6}, {0, 0}} ++}; ++ ++struct nand_ecclayout nand_oob_64 = { ++ .eccbytes = 32, ++ .eccpos = {32, 33, 34, 35, 36, 37, 38, 39, ++ 40, 41, 42, 43, 44, 45, 46, 47, ++ 48, 49, 50, 51, 52, 53, 54, 55, ++ 56, 57, 58, 59, 60, 61, 62, 63}, ++ .oobfree = {{1, 7}, {9, 7}, {17, 7}, {25, 6}, {0, 0}} ++}; ++ ++struct nand_ecclayout nand_oob_128 = { ++ .eccbytes = 64, ++ .eccpos = { ++ 64, 65, 66, 67, 68, 69, 70, 71, ++ 72, 73, 74, 75, 76, 77, 78, 79, ++ 80, 81, 82, 83, 84, 85, 86, 86, ++ 88, 89, 90, 91, 92, 93, 94, 95, ++ 96, 97, 98, 99, 100, 101, 102, 103, ++ 104, 105, 106, 107, 108, 109, 110, 111, ++ 112, 113, 114, 115, 116, 117, 118, 119, ++ 120, 121, 122, 123, 124, 125, 126, 127}, ++ .oobfree = {{1, 7}, {9, 7}, {17, 7}, {25, 7}, {33, 7}, {41, 7}, {49, 7}, {57, 6}} ++}; ++ ++flashdev_info devinfo; ++ ++void dump_nfi(void) ++{ ++} ++ ++void dump_ecc(void) ++{ ++} ++ ++u32 ++nand_virt_to_phys_add(u32 va) ++{ ++ u32 pageOffset = (va & (PAGE_SIZE - 1)); ++ pgd_t *pgd; ++ pmd_t *pmd; ++ pte_t *pte; ++ u32 pa; ++ ++ if (virt_addr_valid(va)) ++ return __virt_to_phys(va); ++ ++ if (NULL == current) { ++ printk(KERN_ERR "[nand_virt_to_phys_add] ERROR ,current is NULL! \n"); ++ return 0; ++ } ++ ++ if (NULL == current->mm) { ++ printk(KERN_ERR "[nand_virt_to_phys_add] ERROR current->mm is NULL! tgid=0x%x, name=%s \n", current->tgid, current->comm); ++ return 0; ++ } ++ ++ pgd = pgd_offset(current->mm, va); /* what is tsk->mm */ ++ if (pgd_none(*pgd) || pgd_bad(*pgd)) { ++ printk(KERN_ERR "[nand_virt_to_phys_add] ERROR, va=0x%x, pgd invalid! \n", va); ++ return 0; ++ } ++ ++ pmd = pmd_offset((pud_t *)pgd, va); ++ if (pmd_none(*pmd) || pmd_bad(*pmd)) { ++ printk(KERN_ERR "[nand_virt_to_phys_add] ERROR, va=0x%x, pmd invalid! \n", va); ++ return 0; ++ } ++ ++ pte = pte_offset_map(pmd, va); ++ if (pte_present(*pte)) { ++ pa = (pte_val(*pte) & (PAGE_MASK)) | pageOffset; ++ return pa; ++ } ++ ++ printk(KERN_ERR "[nand_virt_to_phys_add] ERROR va=0x%x, pte invalid! \n", va); ++ return 0; ++} ++EXPORT_SYMBOL(nand_virt_to_phys_add); ++ ++bool ++get_device_info(u16 id, u32 ext_id, flashdev_info * pdevinfo) ++{ ++ u32 index; ++ for (index = 0; gen_FlashTable[index].id != 0; index++) { ++ if (id == gen_FlashTable[index].id && ext_id == gen_FlashTable[index].ext_id) { ++ pdevinfo->id = gen_FlashTable[index].id; ++ pdevinfo->ext_id = gen_FlashTable[index].ext_id; ++ pdevinfo->blocksize = gen_FlashTable[index].blocksize; ++ pdevinfo->addr_cycle = gen_FlashTable[index].addr_cycle; ++ pdevinfo->iowidth = gen_FlashTable[index].iowidth; ++ pdevinfo->timmingsetting = gen_FlashTable[index].timmingsetting; ++ pdevinfo->advancedmode = gen_FlashTable[index].advancedmode; ++ pdevinfo->pagesize = gen_FlashTable[index].pagesize; ++ pdevinfo->sparesize = gen_FlashTable[index].sparesize; ++ pdevinfo->totalsize = gen_FlashTable[index].totalsize; ++ memcpy(pdevinfo->devciename, gen_FlashTable[index].devciename, sizeof(pdevinfo->devciename)); ++ printk(KERN_INFO "Device found in MTK table, ID: %x, EXT_ID: %x\n", id, ext_id); ++ ++ goto find; ++ } ++ } ++ ++find: ++ if (0 == pdevinfo->id) { ++ printk(KERN_INFO "Device not found, ID: %x\n", id); ++ return false; ++ } else { ++ return true; ++ } ++} ++ ++static void ++ECC_Config(struct mtk_nand_host_hw *hw,u32 ecc_bit) ++{ ++ u32 u4ENCODESize; ++ u32 u4DECODESize; ++ u32 ecc_bit_cfg = ECC_CNFG_ECC4; ++ ++ switch(ecc_bit){ ++ case 4: ++ ecc_bit_cfg = ECC_CNFG_ECC4; ++ break; ++ case 8: ++ ecc_bit_cfg = ECC_CNFG_ECC8; ++ break; ++ case 10: ++ ecc_bit_cfg = ECC_CNFG_ECC10; ++ break; ++ case 12: ++ ecc_bit_cfg = ECC_CNFG_ECC12; ++ break; ++ default: ++ break; ++ } ++ DRV_WriteReg16(ECC_DECCON_REG16, DEC_DE); ++ do { ++ } while (!DRV_Reg16(ECC_DECIDLE_REG16)); ++ ++ DRV_WriteReg16(ECC_ENCCON_REG16, ENC_DE); ++ do { ++ } while (!DRV_Reg32(ECC_ENCIDLE_REG32)); ++ ++ /* setup FDM register base */ ++ DRV_WriteReg32(ECC_FDMADDR_REG32, NFI_FDM0L_REG32); ++ ++ /* Sector + FDM */ ++ u4ENCODESize = (hw->nand_sec_size + 8) << 3; ++ /* Sector + FDM + YAFFS2 meta data bits */ ++ u4DECODESize = ((hw->nand_sec_size + 8) << 3) + ecc_bit * 13; ++ ++ /* configure ECC decoder && encoder */ ++ DRV_WriteReg32(ECC_DECCNFG_REG32, ecc_bit_cfg | DEC_CNFG_NFI | DEC_CNFG_EMPTY_EN | (u4DECODESize << DEC_CNFG_CODE_SHIFT)); ++ ++ DRV_WriteReg32(ECC_ENCCNFG_REG32, ecc_bit_cfg | ENC_CNFG_NFI | (u4ENCODESize << ENC_CNFG_MSG_SHIFT)); ++ NFI_SET_REG32(ECC_DECCNFG_REG32, DEC_CNFG_EL); ++} ++ ++static void ++ECC_Decode_Start(void) ++{ ++ while (!(DRV_Reg16(ECC_DECIDLE_REG16) & DEC_IDLE)) ++ ; ++ DRV_WriteReg16(ECC_DECCON_REG16, DEC_EN); ++} ++ ++static void ++ECC_Decode_End(void) ++{ ++ while (!(DRV_Reg16(ECC_DECIDLE_REG16) & DEC_IDLE)) ++ ; ++ DRV_WriteReg16(ECC_DECCON_REG16, DEC_DE); ++} ++ ++static void ++ECC_Encode_Start(void) ++{ ++ while (!(DRV_Reg32(ECC_ENCIDLE_REG32) & ENC_IDLE)) ++ ; ++ mb(); ++ DRV_WriteReg16(ECC_ENCCON_REG16, ENC_EN); ++} ++ ++static void ++ECC_Encode_End(void) ++{ ++ /* wait for device returning idle */ ++ while (!(DRV_Reg32(ECC_ENCIDLE_REG32) & ENC_IDLE)) ; ++ mb(); ++ DRV_WriteReg16(ECC_ENCCON_REG16, ENC_DE); ++} ++ ++static bool ++mtk_nand_check_bch_error(struct mtd_info *mtd, u8 * pDataBuf, u32 u4SecIndex, u32 u4PageAddr) ++{ ++ bool bRet = true; ++ u16 u2SectorDoneMask = 1 << u4SecIndex; ++ u32 u4ErrorNumDebug, i, u4ErrNum; ++ u32 timeout = 0xFFFF; ++ // int el; ++ u32 au4ErrBitLoc[6]; ++ u32 u4ErrByteLoc, u4BitOffset; ++ u32 u4ErrBitLoc1th, u4ErrBitLoc2nd; ++ ++ //4 // Wait for Decode Done ++ while (0 == (u2SectorDoneMask & DRV_Reg16(ECC_DECDONE_REG16))) { ++ timeout--; ++ if (0 == timeout) ++ return false; ++ } ++ /* We will manually correct the error bits in the last sector, not all the sectors of the page! */ ++ memset(au4ErrBitLoc, 0x0, sizeof(au4ErrBitLoc)); ++ u4ErrorNumDebug = DRV_Reg32(ECC_DECENUM_REG32); ++ u4ErrNum = DRV_Reg32(ECC_DECENUM_REG32) >> (u4SecIndex << 2); ++ u4ErrNum &= 0xF; ++ ++ if (u4ErrNum) { ++ if (0xF == u4ErrNum) { ++ mtd->ecc_stats.failed++; ++ bRet = false; ++ //printk(KERN_ERR"UnCorrectable at PageAddr=%d\n", u4PageAddr); ++ } else { ++ for (i = 0; i < ((u4ErrNum + 1) >> 1); ++i) { ++ au4ErrBitLoc[i] = DRV_Reg32(ECC_DECEL0_REG32 + i); ++ u4ErrBitLoc1th = au4ErrBitLoc[i] & 0x1FFF; ++ if (u4ErrBitLoc1th < 0x1000) { ++ u4ErrByteLoc = u4ErrBitLoc1th / 8; ++ u4BitOffset = u4ErrBitLoc1th % 8; ++ pDataBuf[u4ErrByteLoc] = pDataBuf[u4ErrByteLoc] ^ (1 << u4BitOffset); ++ mtd->ecc_stats.corrected++; ++ } else { ++ mtd->ecc_stats.failed++; ++ } ++ u4ErrBitLoc2nd = (au4ErrBitLoc[i] >> 16) & 0x1FFF; ++ if (0 != u4ErrBitLoc2nd) { ++ if (u4ErrBitLoc2nd < 0x1000) { ++ u4ErrByteLoc = u4ErrBitLoc2nd / 8; ++ u4BitOffset = u4ErrBitLoc2nd % 8; ++ pDataBuf[u4ErrByteLoc] = pDataBuf[u4ErrByteLoc] ^ (1 << u4BitOffset); ++ mtd->ecc_stats.corrected++; ++ } else { ++ mtd->ecc_stats.failed++; ++ //printk(KERN_ERR"UnCorrectable High ErrLoc=%d\n", au4ErrBitLoc[i]); ++ } ++ } ++ } ++ } ++ if (0 == (DRV_Reg16(ECC_DECFER_REG16) & (1 << u4SecIndex))) ++ bRet = false; ++ } ++ return bRet; ++} ++ ++static bool ++mtk_nand_RFIFOValidSize(u16 u2Size) ++{ ++ u32 timeout = 0xFFFF; ++ while (FIFO_RD_REMAIN(DRV_Reg16(NFI_FIFOSTA_REG16)) < u2Size) { ++ timeout--; ++ if (0 == timeout) ++ return false; ++ } ++ return true; ++} ++ ++static bool ++mtk_nand_WFIFOValidSize(u16 u2Size) ++{ ++ u32 timeout = 0xFFFF; ++ ++ while (FIFO_WR_REMAIN(DRV_Reg16(NFI_FIFOSTA_REG16)) > u2Size) { ++ timeout--; ++ if (0 == timeout) ++ return false; ++ } ++ return true; ++} ++ ++static bool ++mtk_nand_status_ready(u32 u4Status) ++{ ++ u32 timeout = 0xFFFF; ++ ++ while ((DRV_Reg32(NFI_STA_REG32) & u4Status) != 0) { ++ timeout--; ++ if (0 == timeout) ++ return false; ++ } ++ return true; ++} ++ ++static bool ++mtk_nand_reset(void) ++{ ++ int timeout = 0xFFFF; ++ if (DRV_Reg16(NFI_MASTERSTA_REG16)) { ++ mb(); ++ DRV_WriteReg16(NFI_CON_REG16, CON_FIFO_FLUSH | CON_NFI_RST); ++ while (DRV_Reg16(NFI_MASTERSTA_REG16)) { ++ timeout--; ++ if (!timeout) ++ MSG(INIT, "Wait for NFI_MASTERSTA timeout\n"); ++ } ++ } ++ /* issue reset operation */ ++ mb(); ++ DRV_WriteReg16(NFI_CON_REG16, CON_FIFO_FLUSH | CON_NFI_RST); ++ ++ return mtk_nand_status_ready(STA_NFI_FSM_MASK | STA_NAND_BUSY) && mtk_nand_RFIFOValidSize(0) && mtk_nand_WFIFOValidSize(0); ++} ++ ++static void ++mtk_nand_set_mode(u16 u2OpMode) ++{ ++ u16 u2Mode = DRV_Reg16(NFI_CNFG_REG16); ++ u2Mode &= ~CNFG_OP_MODE_MASK; ++ u2Mode |= u2OpMode; ++ DRV_WriteReg16(NFI_CNFG_REG16, u2Mode); ++} ++ ++static void ++mtk_nand_set_autoformat(bool bEnable) ++{ ++ if (bEnable) ++ NFI_SET_REG16(NFI_CNFG_REG16, CNFG_AUTO_FMT_EN); ++ else ++ NFI_CLN_REG16(NFI_CNFG_REG16, CNFG_AUTO_FMT_EN); ++} ++ ++static void ++mtk_nand_configure_fdm(u16 u2FDMSize) ++{ ++ NFI_CLN_REG16(NFI_PAGEFMT_REG16, PAGEFMT_FDM_MASK | PAGEFMT_FDM_ECC_MASK); ++ NFI_SET_REG16(NFI_PAGEFMT_REG16, u2FDMSize << PAGEFMT_FDM_SHIFT); ++ NFI_SET_REG16(NFI_PAGEFMT_REG16, u2FDMSize << PAGEFMT_FDM_ECC_SHIFT); ++} ++ ++static void ++mtk_nand_configure_lock(void) ++{ ++ u32 u4WriteColNOB = 2; ++ u32 u4WriteRowNOB = 3; ++ u32 u4EraseColNOB = 0; ++ u32 u4EraseRowNOB = 3; ++ DRV_WriteReg16(NFI_LOCKANOB_REG16, ++ (u4WriteColNOB << PROG_CADD_NOB_SHIFT) | (u4WriteRowNOB << PROG_RADD_NOB_SHIFT) | (u4EraseColNOB << ERASE_CADD_NOB_SHIFT) | (u4EraseRowNOB << ERASE_RADD_NOB_SHIFT)); ++ ++ if (CHIPVER_ECO_1 == g_u4ChipVer) { ++ int i; ++ for (i = 0; i < 16; ++i) { ++ DRV_WriteReg32(NFI_LOCK00ADD_REG32 + (i << 1), 0xFFFFFFFF); ++ DRV_WriteReg32(NFI_LOCK00FMT_REG32 + (i << 1), 0xFFFFFFFF); ++ } ++ //DRV_WriteReg16(NFI_LOCKANOB_REG16, 0x0); ++ DRV_WriteReg32(NFI_LOCKCON_REG32, 0xFFFFFFFF); ++ DRV_WriteReg16(NFI_LOCK_REG16, NFI_LOCK_ON); ++ } ++} ++ ++static bool ++mtk_nand_pio_ready(void) ++{ ++ int count = 0; ++ while (!(DRV_Reg16(NFI_PIO_DIRDY_REG16) & 1)) { ++ count++; ++ if (count > 0xffff) { ++ printk("PIO_DIRDY timeout\n"); ++ return false; ++ } ++ } ++ ++ return true; ++} ++ ++static bool ++mtk_nand_set_command(u16 command) ++{ ++ mb(); ++ DRV_WriteReg16(NFI_CMD_REG16, command); ++ return mtk_nand_status_ready(STA_CMD_STATE); ++} ++ ++static bool ++mtk_nand_set_address(u32 u4ColAddr, u32 u4RowAddr, u16 u2ColNOB, u16 u2RowNOB) ++{ ++ mb(); ++ DRV_WriteReg32(NFI_COLADDR_REG32, u4ColAddr); ++ DRV_WriteReg32(NFI_ROWADDR_REG32, u4RowAddr); ++ DRV_WriteReg16(NFI_ADDRNOB_REG16, u2ColNOB | (u2RowNOB << ADDR_ROW_NOB_SHIFT)); ++ return mtk_nand_status_ready(STA_ADDR_STATE); ++} ++ ++static bool ++mtk_nand_check_RW_count(u16 u2WriteSize) ++{ ++ u32 timeout = 0xFFFF; ++ u16 u2SecNum = u2WriteSize >> 9; ++ ++ while (ADDRCNTR_CNTR(DRV_Reg16(NFI_ADDRCNTR_REG16)) < u2SecNum) { ++ timeout--; ++ if (0 == timeout) { ++ printk(KERN_INFO "[%s] timeout\n", __FUNCTION__); ++ return false; ++ } ++ } ++ return true; ++} ++ ++static bool ++mtk_nand_ready_for_read(struct nand_chip *nand, u32 u4RowAddr, u32 u4ColAddr, bool full, u8 * buf) ++{ ++ /* Reset NFI HW internal state machine and flush NFI in/out FIFO */ ++ bool bRet = false; ++ u16 sec_num = 1 << (nand->page_shift - 9); ++ u32 col_addr = u4ColAddr; ++ u32 colnob = 2, rownob = devinfo.addr_cycle - 2; ++ if (nand->options & NAND_BUSWIDTH_16) ++ col_addr /= 2; ++ ++ if (!mtk_nand_reset()) ++ goto cleanup; ++ if (g_bHwEcc) { ++ NFI_SET_REG16(NFI_CNFG_REG16, CNFG_HW_ECC_EN); ++ } else { ++ NFI_CLN_REG16(NFI_CNFG_REG16, CNFG_HW_ECC_EN); ++ } ++ ++ mtk_nand_set_mode(CNFG_OP_READ); ++ NFI_SET_REG16(NFI_CNFG_REG16, CNFG_READ_EN); ++ DRV_WriteReg16(NFI_CON_REG16, sec_num << CON_NFI_SEC_SHIFT); ++ ++ if (full) { ++ NFI_CLN_REG16(NFI_CNFG_REG16, CNFG_AHB); ++ ++ if (g_bHwEcc) ++ NFI_SET_REG16(NFI_CNFG_REG16, CNFG_HW_ECC_EN); ++ else ++ NFI_CLN_REG16(NFI_CNFG_REG16, CNFG_HW_ECC_EN); ++ } else { ++ NFI_CLN_REG16(NFI_CNFG_REG16, CNFG_HW_ECC_EN); ++ NFI_CLN_REG16(NFI_CNFG_REG16, CNFG_AHB); ++ } ++ ++ mtk_nand_set_autoformat(full); ++ if (full) ++ if (g_bHwEcc) ++ ECC_Decode_Start(); ++ if (!mtk_nand_set_command(NAND_CMD_READ0)) ++ goto cleanup; ++ if (!mtk_nand_set_address(col_addr, u4RowAddr, colnob, rownob)) ++ goto cleanup; ++ if (!mtk_nand_set_command(NAND_CMD_READSTART)) ++ goto cleanup; ++ if (!mtk_nand_status_ready(STA_NAND_BUSY)) ++ goto cleanup; ++ ++ bRet = true; ++ ++cleanup: ++ return bRet; ++} ++ ++static bool ++mtk_nand_ready_for_write(struct nand_chip *nand, u32 u4RowAddr, u32 col_addr, bool full, u8 * buf) ++{ ++ bool bRet = false; ++ u32 sec_num = 1 << (nand->page_shift - 9); ++ u32 colnob = 2, rownob = devinfo.addr_cycle - 2; ++ if (nand->options & NAND_BUSWIDTH_16) ++ col_addr /= 2; ++ ++ /* Reset NFI HW internal state machine and flush NFI in/out FIFO */ ++ if (!mtk_nand_reset()) ++ return false; ++ ++ mtk_nand_set_mode(CNFG_OP_PRGM); ++ ++ NFI_CLN_REG16(NFI_CNFG_REG16, CNFG_READ_EN); ++ ++ DRV_WriteReg16(NFI_CON_REG16, sec_num << CON_NFI_SEC_SHIFT); ++ ++ if (full) { ++ NFI_CLN_REG16(NFI_CNFG_REG16, CNFG_AHB); ++ if (g_bHwEcc) ++ NFI_SET_REG16(NFI_CNFG_REG16, CNFG_HW_ECC_EN); ++ else ++ NFI_CLN_REG16(NFI_CNFG_REG16, CNFG_HW_ECC_EN); ++ } else { ++ NFI_CLN_REG16(NFI_CNFG_REG16, CNFG_HW_ECC_EN); ++ NFI_CLN_REG16(NFI_CNFG_REG16, CNFG_AHB); ++ } ++ ++ mtk_nand_set_autoformat(full); ++ ++ if (full) ++ if (g_bHwEcc) ++ ECC_Encode_Start(); ++ ++ if (!mtk_nand_set_command(NAND_CMD_SEQIN)) ++ goto cleanup; ++ //1 FIXED ME: For Any Kind of AddrCycle ++ if (!mtk_nand_set_address(col_addr, u4RowAddr, colnob, rownob)) ++ goto cleanup; ++ ++ if (!mtk_nand_status_ready(STA_NAND_BUSY)) ++ goto cleanup; ++ ++ bRet = true; ++ ++cleanup: ++ return bRet; ++} ++ ++static bool ++mtk_nand_check_dececc_done(u32 u4SecNum) ++{ ++ u32 timeout, dec_mask; ++ ++ timeout = 0xffff; ++ dec_mask = (1 << u4SecNum) - 1; ++ while ((dec_mask != DRV_Reg(ECC_DECDONE_REG16)) && timeout > 0) ++ timeout--; ++ if (timeout == 0) { ++ MSG(VERIFY, "ECC_DECDONE: timeout\n"); ++ return false; ++ } ++ return true; ++} ++ ++static bool ++mtk_nand_mcu_read_data(u8 * buf, u32 length) ++{ ++ int timeout = 0xffff; ++ u32 i; ++ u32 *buf32 = (u32 *) buf; ++ if ((u32) buf % 4 || length % 4) ++ NFI_SET_REG16(NFI_CNFG_REG16, CNFG_BYTE_RW); ++ else ++ NFI_CLN_REG16(NFI_CNFG_REG16, CNFG_BYTE_RW); ++ ++ //DRV_WriteReg32(NFI_STRADDR_REG32, 0); ++ mb(); ++ NFI_SET_REG16(NFI_CON_REG16, CON_NFI_BRD); ++ ++ if ((u32) buf % 4 || length % 4) { ++ for (i = 0; (i < (length)) && (timeout > 0);) { ++ if (DRV_Reg16(NFI_PIO_DIRDY_REG16) & 1) { ++ *buf++ = (u8) DRV_Reg32(NFI_DATAR_REG32); ++ i++; ++ } else { ++ timeout--; ++ } ++ if (0 == timeout) { ++ printk(KERN_ERR "[%s] timeout\n", __FUNCTION__); ++ dump_nfi(); ++ return false; ++ } ++ } ++ } else { ++ for (i = 0; (i < (length >> 2)) && (timeout > 0);) { ++ if (DRV_Reg16(NFI_PIO_DIRDY_REG16) & 1) { ++ *buf32++ = DRV_Reg32(NFI_DATAR_REG32); ++ i++; ++ } else { ++ timeout--; ++ } ++ if (0 == timeout) { ++ printk(KERN_ERR "[%s] timeout\n", __FUNCTION__); ++ dump_nfi(); ++ return false; ++ } ++ } ++ } ++ return true; ++} ++ ++static bool ++mtk_nand_read_page_data(struct mtd_info *mtd, u8 * pDataBuf, u32 u4Size) ++{ ++ return mtk_nand_mcu_read_data(pDataBuf, u4Size); ++} ++ ++static bool ++mtk_nand_mcu_write_data(struct mtd_info *mtd, const u8 * buf, u32 length) ++{ ++ u32 timeout = 0xFFFF; ++ u32 i; ++ u32 *pBuf32; ++ NFI_CLN_REG16(NFI_CNFG_REG16, CNFG_BYTE_RW); ++ mb(); ++ NFI_SET_REG16(NFI_CON_REG16, CON_NFI_BWR); ++ pBuf32 = (u32 *) buf; ++ ++ if ((u32) buf % 4 || length % 4) ++ NFI_SET_REG16(NFI_CNFG_REG16, CNFG_BYTE_RW); ++ else ++ NFI_CLN_REG16(NFI_CNFG_REG16, CNFG_BYTE_RW); ++ ++ if ((u32) buf % 4 || length % 4) { ++ for (i = 0; (i < (length)) && (timeout > 0);) { ++ if (DRV_Reg16(NFI_PIO_DIRDY_REG16) & 1) { ++ DRV_WriteReg32(NFI_DATAW_REG32, *buf++); ++ i++; ++ } else { ++ timeout--; ++ } ++ if (0 == timeout) { ++ printk(KERN_ERR "[%s] timeout\n", __FUNCTION__); ++ dump_nfi(); ++ return false; ++ } ++ } ++ } else { ++ for (i = 0; (i < (length >> 2)) && (timeout > 0);) { ++ if (DRV_Reg16(NFI_PIO_DIRDY_REG16) & 1) { ++ DRV_WriteReg32(NFI_DATAW_REG32, *pBuf32++); ++ i++; ++ } else { ++ timeout--; ++ } ++ if (0 == timeout) { ++ printk(KERN_ERR "[%s] timeout\n", __FUNCTION__); ++ dump_nfi(); ++ return false; ++ } ++ } ++ } ++ ++ return true; ++} ++ ++static bool ++mtk_nand_write_page_data(struct mtd_info *mtd, u8 * buf, u32 size) ++{ ++ return mtk_nand_mcu_write_data(mtd, buf, size); ++} ++ ++static void ++mtk_nand_read_fdm_data(u8 * pDataBuf, u32 u4SecNum) ++{ ++ u32 i; ++ u32 *pBuf32 = (u32 *) pDataBuf; ++ ++ if (pBuf32) { ++ for (i = 0; i < u4SecNum; ++i) { ++ *pBuf32++ = DRV_Reg32(NFI_FDM0L_REG32 + (i << 1)); ++ *pBuf32++ = DRV_Reg32(NFI_FDM0M_REG32 + (i << 1)); ++ } ++ } ++} ++ ++static u8 fdm_buf[64]; ++static void ++mtk_nand_write_fdm_data(struct nand_chip *chip, u8 * pDataBuf, u32 u4SecNum) ++{ ++ u32 i, j; ++ u8 checksum = 0; ++ bool empty = true; ++ struct nand_oobfree *free_entry; ++ u32 *pBuf32; ++ ++ memcpy(fdm_buf, pDataBuf, u4SecNum * 8); ++ ++ free_entry = chip->ecc.layout->oobfree; ++ for (i = 0; i < MTD_MAX_OOBFREE_ENTRIES && free_entry[i].length; i++) { ++ for (j = 0; j < free_entry[i].length; j++) { ++ if (pDataBuf[free_entry[i].offset + j] != 0xFF) ++ empty = false; ++ checksum ^= pDataBuf[free_entry[i].offset + j]; ++ } ++ } ++ ++ if (!empty) { ++ fdm_buf[free_entry[i - 1].offset + free_entry[i - 1].length] = checksum; ++ } ++ ++ pBuf32 = (u32 *) fdm_buf; ++ for (i = 0; i < u4SecNum; ++i) { ++ DRV_WriteReg32(NFI_FDM0L_REG32 + (i << 1), *pBuf32++); ++ DRV_WriteReg32(NFI_FDM0M_REG32 + (i << 1), *pBuf32++); ++ } ++} ++ ++static void ++mtk_nand_stop_read(void) ++{ ++ NFI_CLN_REG16(NFI_CON_REG16, CON_NFI_BRD); ++ mtk_nand_reset(); ++ if (g_bHwEcc) ++ ECC_Decode_End(); ++ DRV_WriteReg16(NFI_INTR_EN_REG16, 0); ++} ++ ++static void ++mtk_nand_stop_write(void) ++{ ++ NFI_CLN_REG16(NFI_CON_REG16, CON_NFI_BWR); ++ if (g_bHwEcc) ++ ECC_Encode_End(); ++ DRV_WriteReg16(NFI_INTR_EN_REG16, 0); ++} ++ ++bool ++mtk_nand_exec_read_page(struct mtd_info *mtd, u32 u4RowAddr, u32 u4PageSize, u8 * pPageBuf, u8 * pFDMBuf) ++{ ++ u8 *buf; ++ bool bRet = true; ++ struct nand_chip *nand = mtd->priv; ++ u32 u4SecNum = u4PageSize >> 9; ++ ++ if (((u32) pPageBuf % 16) && local_buffer_16_align) ++ buf = local_buffer_16_align; ++ else ++ buf = pPageBuf; ++ if (mtk_nand_ready_for_read(nand, u4RowAddr, 0, true, buf)) { ++ int j; ++ for (j = 0 ; j < u4SecNum; j++) { ++ if (!mtk_nand_read_page_data(mtd, buf+j*512, 512)) ++ bRet = false; ++ if(g_bHwEcc && !mtk_nand_check_dececc_done(j+1)) ++ bRet = false; ++ if(g_bHwEcc && !mtk_nand_check_bch_error(mtd, buf+j*512, j, u4RowAddr)) ++ bRet = false; ++ } ++ if (!mtk_nand_status_ready(STA_NAND_BUSY)) ++ bRet = false; ++ ++ mtk_nand_read_fdm_data(pFDMBuf, u4SecNum); ++ mtk_nand_stop_read(); ++ } ++ ++ if (buf == local_buffer_16_align) ++ memcpy(pPageBuf, buf, u4PageSize); ++ ++ return bRet; ++} ++ ++int ++mtk_nand_exec_write_page(struct mtd_info *mtd, u32 u4RowAddr, u32 u4PageSize, u8 * pPageBuf, u8 * pFDMBuf) ++{ ++ struct nand_chip *chip = mtd->priv; ++ u32 u4SecNum = u4PageSize >> 9; ++ u8 *buf; ++ u8 status; ++ ++ MSG(WRITE, "mtk_nand_exec_write_page, page: 0x%x\n", u4RowAddr); ++ ++ if (((u32) pPageBuf % 16) && local_buffer_16_align) { ++ printk(KERN_INFO "Data buffer not 16 bytes aligned: %p\n", pPageBuf); ++ memcpy(local_buffer_16_align, pPageBuf, mtd->writesize); ++ buf = local_buffer_16_align; ++ } else ++ buf = pPageBuf; ++ ++ if (mtk_nand_ready_for_write(chip, u4RowAddr, 0, true, buf)) { ++ mtk_nand_write_fdm_data(chip, pFDMBuf, u4SecNum); ++ (void)mtk_nand_write_page_data(mtd, buf, u4PageSize); ++ (void)mtk_nand_check_RW_count(u4PageSize); ++ mtk_nand_stop_write(); ++ (void)mtk_nand_set_command(NAND_CMD_PAGEPROG); ++ while (DRV_Reg32(NFI_STA_REG32) & STA_NAND_BUSY) ; ++ } ++ ++ status = chip->waitfunc(mtd, chip); ++ if (status & NAND_STATUS_FAIL) ++ return -EIO; ++ return 0; ++} ++ ++static int ++get_start_end_block(struct mtd_info *mtd, int block, int *start_blk, int *end_blk) ++{ ++ struct nand_chip *chip = mtd->priv; ++ int i; ++ ++ *start_blk = 0; ++ for (i = 0; i <= part_num; i++) ++ { ++ if (i == part_num) ++ { ++ // try the last reset partition ++ *end_blk = (chip->chipsize >> chip->phys_erase_shift) - 1; ++ if (*start_blk <= *end_blk) ++ { ++ if ((block >= *start_blk) && (block <= *end_blk)) ++ break; ++ } ++ } ++ // skip All partition entry ++ else if (g_pasStatic_Partition[i].size == MTDPART_SIZ_FULL) ++ { ++ continue; ++ } ++ *end_blk = *start_blk + (g_pasStatic_Partition[i].size >> chip->phys_erase_shift) - 1; ++ if ((block >= *start_blk) && (block <= *end_blk)) ++ break; ++ *start_blk = *end_blk + 1; ++ } ++ if (*start_blk > *end_blk) ++ { ++ return -1; ++ } ++ return 0; ++} ++ ++static int ++block_remap(struct mtd_info *mtd, int block) ++{ ++ struct nand_chip *chip = mtd->priv; ++ int start_blk, end_blk; ++ int j, block_offset; ++ int bad_block = 0; ++ ++ if (chip->bbt == NULL) { ++ printk("ERROR!! no bbt table for block_remap\n"); ++ return -1; ++ } ++ ++ if (get_start_end_block(mtd, block, &start_blk, &end_blk) < 0) { ++ printk("ERROR!! can not find start_blk and end_blk\n"); ++ return -1; ++ } ++ ++ block_offset = block - start_blk; ++ for (j = start_blk; j <= end_blk;j++) { ++ if (((chip->bbt[j >> 2] >> ((j<<1) & 0x6)) & 0x3) == 0x0) { ++ if (!block_offset) ++ break; ++ block_offset--; ++ } else { ++ bad_block++; ++ } ++ } ++ if (j <= end_blk) { ++ return j; ++ } else { ++ // remap to the bad block ++ for (j = end_blk; bad_block > 0; j--) ++ { ++ if (((chip->bbt[j >> 2] >> ((j<<1) & 0x6)) & 0x3) != 0x0) ++ { ++ bad_block--; ++ if (bad_block <= block_offset) ++ return j; ++ } ++ } ++ } ++ ++ printk("Error!! block_remap error\n"); ++ return -1; ++} ++ ++int ++check_block_remap(struct mtd_info *mtd, int block) ++{ ++ if (shift_on_bbt) ++ return block_remap(mtd, block); ++ else ++ return block; ++} ++EXPORT_SYMBOL(check_block_remap); ++ ++ ++static int ++write_next_on_fail(struct mtd_info *mtd, char *write_buf, int page, int * to_blk) ++{ ++ struct nand_chip *chip = mtd->priv; ++ int i, j, to_page = 0, first_page; ++ char *buf, *oob; ++ int start_blk = 0, end_blk; ++ int mapped_block; ++ int page_per_block_bit = chip->phys_erase_shift - chip->page_shift; ++ int block = page >> page_per_block_bit; ++ ++ // find next available block in the same MTD partition ++ mapped_block = block_remap(mtd, block); ++ if (mapped_block == -1) ++ return NAND_STATUS_FAIL; ++ ++ get_start_end_block(mtd, block, &start_blk, &end_blk); ++ ++ buf = kzalloc(mtd->writesize + mtd->oobsize, GFP_KERNEL | GFP_DMA); ++ if (buf == NULL) ++ return -1; ++ ++ oob = buf + mtd->writesize; ++ for ((*to_blk) = block + 1; (*to_blk) <= end_blk ; (*to_blk)++) { ++ if (nand_bbt_get(mtd, (*to_blk) << page_per_block_bit) == 0) { ++ int status; ++ status = mtk_nand_erase_hw(mtd, (*to_blk) << page_per_block_bit); ++ if (status & NAND_STATUS_FAIL) { ++ mtk_nand_block_markbad_hw(mtd, (*to_blk) << chip->phys_erase_shift); ++ nand_bbt_set(mtd, (*to_blk) << page_per_block_bit, 0x3); ++ } else { ++ /* good block */ ++ to_page = (*to_blk) << page_per_block_bit; ++ break; ++ } ++ } ++ } ++ ++ if (!to_page) { ++ kfree(buf); ++ return -1; ++ } ++ ++ first_page = (page >> page_per_block_bit) << page_per_block_bit; ++ for (i = 0; i < (1 << page_per_block_bit); i++) { ++ if ((first_page + i) != page) { ++ mtk_nand_read_oob_hw(mtd, chip, (first_page+i)); ++ for (j = 0; j < mtd->oobsize; j++) ++ if (chip->oob_poi[j] != (unsigned char)0xff) ++ break; ++ if (j < mtd->oobsize) { ++ mtk_nand_exec_read_page(mtd, (first_page+i), mtd->writesize, buf, oob); ++ memset(oob, 0xff, mtd->oobsize); ++ if (mtk_nand_exec_write_page(mtd, to_page + i, mtd->writesize, (u8 *)buf, oob) != 0) { ++ int ret, new_blk = 0; ++ nand_bbt_set(mtd, to_page, 0x3); ++ ret = write_next_on_fail(mtd, buf, to_page + i, &new_blk); ++ if (ret) { ++ kfree(buf); ++ mtk_nand_block_markbad_hw(mtd, to_page << chip->page_shift); ++ return ret; ++ } ++ mtk_nand_block_markbad_hw(mtd, to_page << chip->page_shift); ++ *to_blk = new_blk; ++ to_page = ((*to_blk) << page_per_block_bit); ++ } ++ } ++ } else { ++ memset(chip->oob_poi, 0xff, mtd->oobsize); ++ if (mtk_nand_exec_write_page(mtd, to_page + i, mtd->writesize, (u8 *)write_buf, chip->oob_poi) != 0) { ++ int ret, new_blk = 0; ++ nand_bbt_set(mtd, to_page, 0x3); ++ ret = write_next_on_fail(mtd, write_buf, to_page + i, &new_blk); ++ if (ret) { ++ kfree(buf); ++ mtk_nand_block_markbad_hw(mtd, to_page << chip->page_shift); ++ return ret; ++ } ++ mtk_nand_block_markbad_hw(mtd, to_page << chip->page_shift); ++ *to_blk = new_blk; ++ to_page = ((*to_blk) << page_per_block_bit); ++ } ++ } ++ } ++ ++ kfree(buf); ++ ++ return 0; ++} ++ ++static int ++mtk_nand_write_page(struct mtd_info *mtd, struct nand_chip *chip, uint32_t offset, ++ int data_len, const u8 * buf, int oob_required, int page, int cached, int raw) ++{ ++ int page_per_block = 1 << (chip->phys_erase_shift - chip->page_shift); ++ int block = page / page_per_block; ++ u16 page_in_block = page % page_per_block; ++ int mapped_block = block; ++ ++#if defined(MTK_NAND_BMT) ++ mapped_block = get_mapping_block_index(block); ++ // write bad index into oob ++ if (mapped_block != block) ++ set_bad_index_to_oob(chip->oob_poi, block); ++ else ++ set_bad_index_to_oob(chip->oob_poi, FAKE_INDEX); ++#else ++ if (shift_on_bbt) { ++ mapped_block = block_remap(mtd, block); ++ if (mapped_block == -1) ++ return NAND_STATUS_FAIL; ++ if (nand_bbt_get(mtd, mapped_block << (chip->phys_erase_shift - chip->page_shift)) != 0x0) ++ return NAND_STATUS_FAIL; ++ } ++#endif ++ do { ++ if (mtk_nand_exec_write_page(mtd, page_in_block + mapped_block * page_per_block, mtd->writesize, (u8 *)buf, chip->oob_poi)) { ++ MSG(INIT, "write fail at block: 0x%x, page: 0x%x\n", mapped_block, page_in_block); ++#if defined(MTK_NAND_BMT) ++ if (update_bmt((page_in_block + mapped_block * page_per_block) << chip->page_shift, UPDATE_WRITE_FAIL, (u8 *) buf, chip->oob_poi)) { ++ MSG(INIT, "Update BMT success\n"); ++ return 0; ++ } else { ++ MSG(INIT, "Update BMT fail\n"); ++ return -EIO; ++ } ++#else ++ { ++ int new_blk; ++ nand_bbt_set(mtd, page_in_block + mapped_block * page_per_block, 0x3); ++ if (write_next_on_fail(mtd, (char *)buf, page_in_block + mapped_block * page_per_block, &new_blk) != 0) ++ { ++ mtk_nand_block_markbad_hw(mtd, (page_in_block + mapped_block * page_per_block) << chip->page_shift); ++ return NAND_STATUS_FAIL; ++ } ++ mtk_nand_block_markbad_hw(mtd, (page_in_block + mapped_block * page_per_block) << chip->page_shift); ++ break; ++ } ++#endif ++ } else ++ break; ++ } while(1); ++ ++ return 0; ++} ++ ++static void ++mtk_nand_command_bp(struct mtd_info *mtd, unsigned int command, int column, int page_addr) ++{ ++ struct nand_chip *nand = mtd->priv; ++ ++ switch (command) { ++ case NAND_CMD_SEQIN: ++ memset(g_kCMD.au1OOB, 0xFF, sizeof(g_kCMD.au1OOB)); ++ g_kCMD.pDataBuf = NULL; ++ g_kCMD.u4RowAddr = page_addr; ++ g_kCMD.u4ColAddr = column; ++ break; ++ ++ case NAND_CMD_PAGEPROG: ++ if (g_kCMD.pDataBuf || (0xFF != g_kCMD.au1OOB[nand_badblock_offset])) { ++ u8 *pDataBuf = g_kCMD.pDataBuf ? g_kCMD.pDataBuf : nand->buffers->databuf; ++ mtk_nand_exec_write_page(mtd, g_kCMD.u4RowAddr, mtd->writesize, pDataBuf, g_kCMD.au1OOB); ++ g_kCMD.u4RowAddr = (u32) - 1; ++ g_kCMD.u4OOBRowAddr = (u32) - 1; ++ } ++ break; ++ ++ case NAND_CMD_READOOB: ++ g_kCMD.u4RowAddr = page_addr; ++ g_kCMD.u4ColAddr = column + mtd->writesize; ++ break; ++ ++ case NAND_CMD_READ0: ++ g_kCMD.u4RowAddr = page_addr; ++ g_kCMD.u4ColAddr = column; ++ break; ++ ++ case NAND_CMD_ERASE1: ++ nand->state=FL_ERASING; ++ (void)mtk_nand_reset(); ++ mtk_nand_set_mode(CNFG_OP_ERASE); ++ (void)mtk_nand_set_command(NAND_CMD_ERASE1); ++ (void)mtk_nand_set_address(0, page_addr, 0, devinfo.addr_cycle - 2); ++ break; ++ ++ case NAND_CMD_ERASE2: ++ (void)mtk_nand_set_command(NAND_CMD_ERASE2); ++ while (DRV_Reg32(NFI_STA_REG32) & STA_NAND_BUSY) ++ ; ++ break; ++ ++ case NAND_CMD_STATUS: ++ (void)mtk_nand_reset(); ++ NFI_CLN_REG16(NFI_CNFG_REG16, CNFG_BYTE_RW); ++ mtk_nand_set_mode(CNFG_OP_SRD); ++ mtk_nand_set_mode(CNFG_READ_EN); ++ NFI_CLN_REG16(NFI_CNFG_REG16, CNFG_AHB); ++ NFI_CLN_REG16(NFI_CNFG_REG16, CNFG_HW_ECC_EN); ++ (void)mtk_nand_set_command(NAND_CMD_STATUS); ++ NFI_CLN_REG16(NFI_CON_REG16, CON_NFI_NOB_MASK); ++ mb(); ++ DRV_WriteReg16(NFI_CON_REG16, CON_NFI_SRD | (1 << CON_NFI_NOB_SHIFT)); ++ g_bcmdstatus = true; ++ break; ++ ++ case NAND_CMD_RESET: ++ (void)mtk_nand_reset(); ++ DRV_WriteReg16(NFI_INTR_EN_REG16, INTR_RST_DONE_EN); ++ (void)mtk_nand_set_command(NAND_CMD_RESET); ++ DRV_WriteReg16(NFI_BASE+0x44, 0xF1); ++ while(!(DRV_Reg16(NFI_INTR_REG16)&INTR_RST_DONE_EN)) ++ ; ++ break; ++ ++ case NAND_CMD_READID: ++ mtk_nand_reset(); ++ /* Disable HW ECC */ ++ NFI_CLN_REG16(NFI_CNFG_REG16, CNFG_HW_ECC_EN); ++ NFI_CLN_REG16(NFI_CNFG_REG16, CNFG_AHB); ++ NFI_SET_REG16(NFI_CNFG_REG16, CNFG_READ_EN | CNFG_BYTE_RW); ++ (void)mtk_nand_reset(); ++ mb(); ++ mtk_nand_set_mode(CNFG_OP_SRD); ++ (void)mtk_nand_set_command(NAND_CMD_READID); ++ (void)mtk_nand_set_address(0, 0, 1, 0); ++ DRV_WriteReg16(NFI_CON_REG16, CON_NFI_SRD); ++ while (DRV_Reg32(NFI_STA_REG32) & STA_DATAR_STATE) ++ ; ++ break; ++ ++ default: ++ BUG(); ++ break; ++ } ++} ++ ++static void ++mtk_nand_select_chip(struct mtd_info *mtd, int chip) ++{ ++ if ((chip == -1) && (false == g_bInitDone)) { ++ struct nand_chip *nand = mtd->priv; ++ struct mtk_nand_host *host = nand->priv; ++ struct mtk_nand_host_hw *hw = host->hw; ++ u32 spare_per_sector = mtd->oobsize / (mtd->writesize / 512); ++ u32 ecc_bit = 4; ++ u32 spare_bit = PAGEFMT_SPARE_16; ++ ++ if (spare_per_sector >= 28) { ++ spare_bit = PAGEFMT_SPARE_28; ++ ecc_bit = 12; ++ spare_per_sector = 28; ++ } else if (spare_per_sector >= 27) { ++ spare_bit = PAGEFMT_SPARE_27; ++ ecc_bit = 8; ++ spare_per_sector = 27; ++ } else if (spare_per_sector >= 26) { ++ spare_bit = PAGEFMT_SPARE_26; ++ ecc_bit = 8; ++ spare_per_sector = 26; ++ } else if (spare_per_sector >= 16) { ++ spare_bit = PAGEFMT_SPARE_16; ++ ecc_bit = 4; ++ spare_per_sector = 16; ++ } else { ++ MSG(INIT, "[NAND]: NFI not support oobsize: %x\n", spare_per_sector); ++ ASSERT(0); ++ } ++ mtd->oobsize = spare_per_sector*(mtd->writesize/512); ++ MSG(INIT, "[NAND]select ecc bit:%d, sparesize :%d spare_per_sector=%d\n",ecc_bit,mtd->oobsize,spare_per_sector); ++ /* Setup PageFormat */ ++ if (4096 == mtd->writesize) { ++ NFI_SET_REG16(NFI_PAGEFMT_REG16, (spare_bit << PAGEFMT_SPARE_SHIFT) | PAGEFMT_4K); ++ nand->cmdfunc = mtk_nand_command_bp; ++ } else if (2048 == mtd->writesize) { ++ NFI_SET_REG16(NFI_PAGEFMT_REG16, (spare_bit << PAGEFMT_SPARE_SHIFT) | PAGEFMT_2K); ++ nand->cmdfunc = mtk_nand_command_bp; ++ } ++ ECC_Config(hw,ecc_bit); ++ g_bInitDone = true; ++ } ++ switch (chip) { ++ case -1: ++ break; ++ case 0: ++ case 1: ++ /* Jun Shen, 2011.04.13 */ ++ /* Note: MT6577 EVB NAND is mounted on CS0, but FPGA is CS1 */ ++ DRV_WriteReg16(NFI_CSEL_REG16, chip); ++ /* Jun Shen, 2011.04.13 */ ++ break; ++ } ++} ++ ++static uint8_t ++mtk_nand_read_byte(struct mtd_info *mtd) ++{ ++ uint8_t retval = 0; ++ ++ if (!mtk_nand_pio_ready()) { ++ printk("pio ready timeout\n"); ++ retval = false; ++ } ++ ++ if (g_bcmdstatus) { ++ retval = DRV_Reg8(NFI_DATAR_REG32); ++ NFI_CLN_REG16(NFI_CON_REG16, CON_NFI_NOB_MASK); ++ mtk_nand_reset(); ++ if (g_bHwEcc) { ++ NFI_SET_REG16(NFI_CNFG_REG16, CNFG_HW_ECC_EN); ++ } else { ++ NFI_CLN_REG16(NFI_CNFG_REG16, CNFG_HW_ECC_EN); ++ } ++ g_bcmdstatus = false; ++ } else ++ retval = DRV_Reg8(NFI_DATAR_REG32); ++ ++ return retval; ++} ++ ++static void ++mtk_nand_read_buf(struct mtd_info *mtd, uint8_t * buf, int len) ++{ ++ struct nand_chip *nand = (struct nand_chip *)mtd->priv; ++ struct NAND_CMD *pkCMD = &g_kCMD; ++ u32 u4ColAddr = pkCMD->u4ColAddr; ++ u32 u4PageSize = mtd->writesize; ++ ++ if (u4ColAddr < u4PageSize) { ++ if ((u4ColAddr == 0) && (len >= u4PageSize)) { ++ mtk_nand_exec_read_page(mtd, pkCMD->u4RowAddr, u4PageSize, buf, pkCMD->au1OOB); ++ if (len > u4PageSize) { ++ u32 u4Size = min(len - u4PageSize, sizeof(pkCMD->au1OOB)); ++ memcpy(buf + u4PageSize, pkCMD->au1OOB, u4Size); ++ } ++ } else { ++ mtk_nand_exec_read_page(mtd, pkCMD->u4RowAddr, u4PageSize, nand->buffers->databuf, pkCMD->au1OOB); ++ memcpy(buf, nand->buffers->databuf + u4ColAddr, len); ++ } ++ pkCMD->u4OOBRowAddr = pkCMD->u4RowAddr; ++ } else { ++ u32 u4Offset = u4ColAddr - u4PageSize; ++ u32 u4Size = min(len - u4Offset, sizeof(pkCMD->au1OOB)); ++ if (pkCMD->u4OOBRowAddr != pkCMD->u4RowAddr) { ++ mtk_nand_exec_read_page(mtd, pkCMD->u4RowAddr, u4PageSize, nand->buffers->databuf, pkCMD->au1OOB); ++ pkCMD->u4OOBRowAddr = pkCMD->u4RowAddr; ++ } ++ memcpy(buf, pkCMD->au1OOB + u4Offset, u4Size); ++ } ++ pkCMD->u4ColAddr += len; ++} ++ ++static void ++mtk_nand_write_buf(struct mtd_info *mtd, const uint8_t * buf, int len) ++{ ++ struct NAND_CMD *pkCMD = &g_kCMD; ++ u32 u4ColAddr = pkCMD->u4ColAddr; ++ u32 u4PageSize = mtd->writesize; ++ int i4Size, i; ++ ++ if (u4ColAddr >= u4PageSize) { ++ u32 u4Offset = u4ColAddr - u4PageSize; ++ u8 *pOOB = pkCMD->au1OOB + u4Offset; ++ i4Size = min(len, (int)(sizeof(pkCMD->au1OOB) - u4Offset)); ++ for (i = 0; i < i4Size; i++) { ++ pOOB[i] &= buf[i]; ++ } ++ } else { ++ pkCMD->pDataBuf = (u8 *) buf; ++ } ++ ++ pkCMD->u4ColAddr += len; ++} ++ ++static int ++mtk_nand_write_page_hwecc(struct mtd_info *mtd, struct nand_chip *chip, const uint8_t * buf, int oob_required) ++{ ++ mtk_nand_write_buf(mtd, buf, mtd->writesize); ++ mtk_nand_write_buf(mtd, chip->oob_poi, mtd->oobsize); ++ return 0; ++} ++ ++static int ++mtk_nand_read_page_hwecc(struct mtd_info *mtd, struct nand_chip *chip, uint8_t * buf, int oob_required, int page) ++{ ++ struct NAND_CMD *pkCMD = &g_kCMD; ++ u32 u4ColAddr = pkCMD->u4ColAddr; ++ u32 u4PageSize = mtd->writesize; ++ ++ if (u4ColAddr == 0) { ++ mtk_nand_exec_read_page(mtd, pkCMD->u4RowAddr, u4PageSize, buf, chip->oob_poi); ++ pkCMD->u4ColAddr += u4PageSize + mtd->oobsize; ++ } ++ ++ return 0; ++} ++ ++static int ++mtk_nand_read_page(struct mtd_info *mtd, struct nand_chip *chip, u8 * buf, int page) ++{ ++ int page_per_block = 1 << (chip->phys_erase_shift - chip->page_shift); ++ int block = page / page_per_block; ++ u16 page_in_block = page % page_per_block; ++ int mapped_block = block; ++ ++#if defined (MTK_NAND_BMT) ++ mapped_block = get_mapping_block_index(block); ++ if (mtk_nand_exec_read_page(mtd, page_in_block + mapped_block * page_per_block, ++ mtd->writesize, buf, chip->oob_poi)) ++ return 0; ++#else ++ if (shift_on_bbt) { ++ mapped_block = block_remap(mtd, block); ++ if (mapped_block == -1) ++ return NAND_STATUS_FAIL; ++ if (nand_bbt_get(mtd, mapped_block << (chip->phys_erase_shift - chip->page_shift)) != 0x0) ++ return NAND_STATUS_FAIL; ++ } ++ ++ if (mtk_nand_exec_read_page(mtd, page_in_block + mapped_block * page_per_block, mtd->writesize, buf, chip->oob_poi)) ++ return 0; ++ else ++ return -EIO; ++#endif ++} ++ ++int ++mtk_nand_erase_hw(struct mtd_info *mtd, int page) ++{ ++ struct nand_chip *chip = (struct nand_chip *)mtd->priv; ++ ++ chip->erase_cmd(mtd, page); ++ ++ return chip->waitfunc(mtd, chip); ++} ++ ++static int ++mtk_nand_erase(struct mtd_info *mtd, int page) ++{ ++ // get mapping ++ struct nand_chip *chip = mtd->priv; ++ int page_per_block = 1 << (chip->phys_erase_shift - chip->page_shift); ++ int page_in_block = page % page_per_block; ++ int block = page / page_per_block; ++ int mapped_block = block; ++ ++#if defined(MTK_NAND_BMT) ++ mapped_block = get_mapping_block_index(block); ++#else ++ if (shift_on_bbt) { ++ mapped_block = block_remap(mtd, block); ++ if (mapped_block == -1) ++ return NAND_STATUS_FAIL; ++ if (nand_bbt_get(mtd, mapped_block << (chip->phys_erase_shift - chip->page_shift)) != 0x0) ++ return NAND_STATUS_FAIL; ++ } ++#endif ++ ++ do { ++ int status = mtk_nand_erase_hw(mtd, page_in_block + page_per_block * mapped_block); ++ ++ if (status & NAND_STATUS_FAIL) { ++#if defined (MTK_NAND_BMT) ++ if (update_bmt( (page_in_block + mapped_block * page_per_block) << chip->page_shift, ++ UPDATE_ERASE_FAIL, NULL, NULL)) ++ { ++ MSG(INIT, "Erase fail at block: 0x%x, update BMT success\n", mapped_block); ++ return 0; ++ } else { ++ MSG(INIT, "Erase fail at block: 0x%x, update BMT fail\n", mapped_block); ++ return NAND_STATUS_FAIL; ++ } ++#else ++ mtk_nand_block_markbad_hw(mtd, (page_in_block + mapped_block * page_per_block) << chip->page_shift); ++ nand_bbt_set(mtd, page_in_block + mapped_block * page_per_block, 0x3); ++ if (shift_on_bbt) { ++ mapped_block = block_remap(mtd, block); ++ if (mapped_block == -1) ++ return NAND_STATUS_FAIL; ++ if (nand_bbt_get(mtd, mapped_block << (chip->phys_erase_shift - chip->page_shift)) != 0x0) ++ return NAND_STATUS_FAIL; ++ } else ++ return NAND_STATUS_FAIL; ++#endif ++ } else ++ break; ++ } while(1); ++ ++ return 0; ++} ++ ++static int ++mtk_nand_read_oob_raw(struct mtd_info *mtd, uint8_t * buf, int page_addr, int len) ++{ ++ struct nand_chip *chip = (struct nand_chip *)mtd->priv; ++ u32 col_addr = 0; ++ u32 sector = 0; ++ int res = 0; ++ u32 colnob = 2, rawnob = devinfo.addr_cycle - 2; ++ int randomread = 0; ++ int read_len = 0; ++ int sec_num = 1<<(chip->page_shift-9); ++ int spare_per_sector = mtd->oobsize/sec_num; ++ ++ if (len > NAND_MAX_OOBSIZE || len % OOB_AVAI_PER_SECTOR || !buf) { ++ printk(KERN_WARNING "[%s] invalid parameter, len: %d, buf: %p\n", __FUNCTION__, len, buf); ++ return -EINVAL; ++ } ++ if (len > spare_per_sector) ++ randomread = 1; ++ if (!randomread || !(devinfo.advancedmode & RAMDOM_READ)) { ++ while (len > 0) { ++ read_len = min(len, spare_per_sector); ++ col_addr = NAND_SECTOR_SIZE + sector * (NAND_SECTOR_SIZE + spare_per_sector); // TODO: Fix this hard-code 16 ++ if (!mtk_nand_ready_for_read(chip, page_addr, col_addr, false, NULL)) { ++ printk(KERN_WARNING "mtk_nand_ready_for_read return failed\n"); ++ res = -EIO; ++ goto error; ++ } ++ if (!mtk_nand_mcu_read_data(buf + spare_per_sector * sector, read_len)) { ++ printk(KERN_WARNING "mtk_nand_mcu_read_data return failed\n"); ++ res = -EIO; ++ goto error; ++ } ++ mtk_nand_check_RW_count(read_len); ++ mtk_nand_stop_read(); ++ sector++; ++ len -= read_len; ++ } ++ } else { ++ col_addr = NAND_SECTOR_SIZE; ++ if (chip->options & NAND_BUSWIDTH_16) ++ col_addr /= 2; ++ if (!mtk_nand_reset()) ++ goto error; ++ mtk_nand_set_mode(0x6000); ++ NFI_SET_REG16(NFI_CNFG_REG16, CNFG_READ_EN); ++ DRV_WriteReg16(NFI_CON_REG16, 4 << CON_NFI_SEC_SHIFT); ++ ++ NFI_CLN_REG16(NFI_CNFG_REG16, CNFG_AHB); ++ NFI_CLN_REG16(NFI_CNFG_REG16, CNFG_HW_ECC_EN); ++ ++ mtk_nand_set_autoformat(false); ++ ++ if (!mtk_nand_set_command(NAND_CMD_READ0)) ++ goto error; ++ //1 FIXED ME: For Any Kind of AddrCycle ++ if (!mtk_nand_set_address(col_addr, page_addr, colnob, rawnob)) ++ goto error; ++ if (!mtk_nand_set_command(NAND_CMD_READSTART)) ++ goto error; ++ if (!mtk_nand_status_ready(STA_NAND_BUSY)) ++ goto error; ++ read_len = min(len, spare_per_sector); ++ if (!mtk_nand_mcu_read_data(buf + spare_per_sector * sector, read_len)) { ++ printk(KERN_WARNING "mtk_nand_mcu_read_data return failed first 16\n"); ++ res = -EIO; ++ goto error; ++ } ++ sector++; ++ len -= read_len; ++ mtk_nand_stop_read(); ++ while (len > 0) { ++ read_len = min(len, spare_per_sector); ++ if (!mtk_nand_set_command(0x05)) ++ goto error; ++ col_addr = NAND_SECTOR_SIZE + sector * (NAND_SECTOR_SIZE + spare_per_sector); ++ if (chip->options & NAND_BUSWIDTH_16) ++ col_addr /= 2; ++ DRV_WriteReg32(NFI_COLADDR_REG32, col_addr); ++ DRV_WriteReg16(NFI_ADDRNOB_REG16, 2); ++ DRV_WriteReg16(NFI_CON_REG16, 4 << CON_NFI_SEC_SHIFT); ++ if (!mtk_nand_status_ready(STA_ADDR_STATE)) ++ goto error; ++ if (!mtk_nand_set_command(0xE0)) ++ goto error; ++ if (!mtk_nand_status_ready(STA_NAND_BUSY)) ++ goto error; ++ if (!mtk_nand_mcu_read_data(buf + spare_per_sector * sector, read_len)) { ++ printk(KERN_WARNING "mtk_nand_mcu_read_data return failed first 16\n"); ++ res = -EIO; ++ goto error; ++ } ++ mtk_nand_stop_read(); ++ sector++; ++ len -= read_len; ++ } ++ } ++error: ++ NFI_CLN_REG16(NFI_CON_REG16, CON_NFI_BRD); ++ return res; ++} ++ ++static int ++mtk_nand_write_oob_raw(struct mtd_info *mtd, const uint8_t * buf, int page_addr, int len) ++{ ++ struct nand_chip *chip = mtd->priv; ++ u32 col_addr = 0; ++ u32 sector = 0; ++ int write_len = 0; ++ int status; ++ int sec_num = 1<<(chip->page_shift-9); ++ int spare_per_sector = mtd->oobsize/sec_num; ++ ++ if (len > NAND_MAX_OOBSIZE || len % OOB_AVAI_PER_SECTOR || !buf) { ++ printk(KERN_WARNING "[%s] invalid parameter, len: %d, buf: %p\n", __FUNCTION__, len, buf); ++ return -EINVAL; ++ } ++ ++ while (len > 0) { ++ write_len = min(len, spare_per_sector); ++ col_addr = sector * (NAND_SECTOR_SIZE + spare_per_sector) + NAND_SECTOR_SIZE; ++ if (!mtk_nand_ready_for_write(chip, page_addr, col_addr, false, NULL)) ++ return -EIO; ++ if (!mtk_nand_mcu_write_data(mtd, buf + sector * spare_per_sector, write_len)) ++ return -EIO; ++ (void)mtk_nand_check_RW_count(write_len); ++ NFI_CLN_REG16(NFI_CON_REG16, CON_NFI_BWR); ++ (void)mtk_nand_set_command(NAND_CMD_PAGEPROG); ++ while (DRV_Reg32(NFI_STA_REG32) & STA_NAND_BUSY) ++ ; ++ status = chip->waitfunc(mtd, chip); ++ if (status & NAND_STATUS_FAIL) { ++ printk(KERN_INFO "status: %d\n", status); ++ return -EIO; ++ } ++ len -= write_len; ++ sector++; ++ } ++ ++ return 0; ++} ++ ++static int ++mtk_nand_write_oob_hw(struct mtd_info *mtd, struct nand_chip *chip, int page) ++{ ++ int i, iter; ++ int sec_num = 1<<(chip->page_shift-9); ++ int spare_per_sector = mtd->oobsize/sec_num; ++ ++ memcpy(local_oob_buf, chip->oob_poi, mtd->oobsize); ++ ++ // copy ecc data ++ for (i = 0; i < chip->ecc.layout->eccbytes; i++) { ++ iter = (i / (spare_per_sector-OOB_AVAI_PER_SECTOR)) * spare_per_sector + OOB_AVAI_PER_SECTOR + i % (spare_per_sector-OOB_AVAI_PER_SECTOR); ++ local_oob_buf[iter] = chip->oob_poi[chip->ecc.layout->eccpos[i]]; ++ } ++ ++ // copy FDM data ++ for (i = 0; i < sec_num; i++) ++ memcpy(&local_oob_buf[i * spare_per_sector], &chip->oob_poi[i * OOB_AVAI_PER_SECTOR], OOB_AVAI_PER_SECTOR); ++ ++ return mtk_nand_write_oob_raw(mtd, local_oob_buf, page, mtd->oobsize); ++} ++ ++static int mtk_nand_write_oob(struct mtd_info *mtd, struct nand_chip *chip, int page) ++{ ++ int page_per_block = 1 << (chip->phys_erase_shift - chip->page_shift); ++ int block = page / page_per_block; ++ u16 page_in_block = page % page_per_block; ++ int mapped_block = block; ++ ++#if defined(MTK_NAND_BMT) ++ mapped_block = get_mapping_block_index(block); ++ // write bad index into oob ++ if (mapped_block != block) ++ set_bad_index_to_oob(chip->oob_poi, block); ++ else ++ set_bad_index_to_oob(chip->oob_poi, FAKE_INDEX); ++#else ++ if (shift_on_bbt) ++ { ++ mapped_block = block_remap(mtd, block); ++ if (mapped_block == -1) ++ return NAND_STATUS_FAIL; ++ if (nand_bbt_get(mtd, mapped_block << (chip->phys_erase_shift - chip->page_shift)) != 0x0) ++ return NAND_STATUS_FAIL; ++ } ++#endif ++ do { ++ if (mtk_nand_write_oob_hw(mtd, chip, page_in_block + mapped_block * page_per_block /* page */)) { ++ MSG(INIT, "write oob fail at block: 0x%x, page: 0x%x\n", mapped_block, page_in_block); ++#if defined(MTK_NAND_BMT) ++ if (update_bmt((page_in_block + mapped_block * page_per_block) << chip->page_shift, ++ UPDATE_WRITE_FAIL, NULL, chip->oob_poi)) ++ { ++ MSG(INIT, "Update BMT success\n"); ++ return 0; ++ } else { ++ MSG(INIT, "Update BMT fail\n"); ++ return -EIO; ++ } ++#else ++ mtk_nand_block_markbad_hw(mtd, (page_in_block + mapped_block * page_per_block) << chip->page_shift); ++ nand_bbt_set(mtd, page_in_block + mapped_block * page_per_block, 0x3); ++ if (shift_on_bbt) { ++ mapped_block = block_remap(mtd, mapped_block); ++ if (mapped_block == -1) ++ return NAND_STATUS_FAIL; ++ if (nand_bbt_get(mtd, mapped_block << (chip->phys_erase_shift - chip->page_shift)) != 0x0) ++ return NAND_STATUS_FAIL; ++ } else { ++ return NAND_STATUS_FAIL; ++ } ++#endif ++ } else ++ break; ++ } while (1); ++ ++ return 0; ++} ++ ++int ++mtk_nand_block_markbad_hw(struct mtd_info *mtd, loff_t offset) ++{ ++ struct nand_chip *chip = mtd->priv; ++ int block = (int)offset >> chip->phys_erase_shift; ++ int page = block * (1 << (chip->phys_erase_shift - chip->page_shift)); ++ u8 buf[8]; ++ ++ memset(buf, 0xFF, 8); ++ buf[0] = 0; ++ return mtk_nand_write_oob_raw(mtd, buf, page, 8); ++} ++ ++static int ++mtk_nand_block_markbad(struct mtd_info *mtd, loff_t offset) ++{ ++ struct nand_chip *chip = mtd->priv; ++ int block = (int)offset >> chip->phys_erase_shift; ++ int ret; ++ int mapped_block = block; ++ ++ nand_get_device(chip, mtd, FL_WRITING); ++ ++#if defined(MTK_NAND_BMT) ++ mapped_block = get_mapping_block_index(block); ++ ret = mtk_nand_block_markbad_hw(mtd, mapped_block << chip->phys_erase_shift); ++#else ++ if (shift_on_bbt) { ++ mapped_block = block_remap(mtd, block); ++ if (mapped_block == -1) { ++ printk("NAND mark bad failed\n"); ++ nand_release_device(mtd); ++ return NAND_STATUS_FAIL; ++ } ++ } ++ ret = mtk_nand_block_markbad_hw(mtd, mapped_block << chip->phys_erase_shift); ++#endif ++ nand_release_device(mtd); ++ ++ return ret; ++} ++ ++int ++mtk_nand_read_oob_hw(struct mtd_info *mtd, struct nand_chip *chip, int page) ++{ ++ int i; ++ u8 iter = 0; ++ ++ int sec_num = 1<<(chip->page_shift-9); ++ int spare_per_sector = mtd->oobsize/sec_num; ++ ++ if (mtk_nand_read_oob_raw(mtd, chip->oob_poi, page, mtd->oobsize)) { ++ printk(KERN_ERR "[%s]mtk_nand_read_oob_raw return failed\n", __FUNCTION__); ++ return -EIO; ++ } ++ ++ // adjust to ecc physical layout to memory layout ++ /*********************************************************/ ++ /* FDM0 | ECC0 | FDM1 | ECC1 | FDM2 | ECC2 | FDM3 | ECC3 */ ++ /* 8B | 8B | 8B | 8B | 8B | 8B | 8B | 8B */ ++ /*********************************************************/ ++ ++ memcpy(local_oob_buf, chip->oob_poi, mtd->oobsize); ++ // copy ecc data ++ for (i = 0; i < chip->ecc.layout->eccbytes; i++) { ++ iter = (i / (spare_per_sector-OOB_AVAI_PER_SECTOR)) * spare_per_sector + OOB_AVAI_PER_SECTOR + i % (spare_per_sector-OOB_AVAI_PER_SECTOR); ++ chip->oob_poi[chip->ecc.layout->eccpos[i]] = local_oob_buf[iter]; ++ } ++ ++ // copy FDM data ++ for (i = 0; i < sec_num; i++) { ++ memcpy(&chip->oob_poi[i * OOB_AVAI_PER_SECTOR], &local_oob_buf[i * spare_per_sector], OOB_AVAI_PER_SECTOR); ++ } ++ ++ return 0; ++} ++ ++static int ++mtk_nand_read_oob(struct mtd_info *mtd, struct nand_chip *chip, int page) ++{ ++ int page_per_block = 1 << (chip->phys_erase_shift - chip->page_shift); ++ int block = page / page_per_block; ++ u16 page_in_block = page % page_per_block; ++ int mapped_block = block; ++ ++#if defined (MTK_NAND_BMT) ++ mapped_block = get_mapping_block_index(block); ++ mtk_nand_read_oob_hw(mtd, chip, page_in_block + mapped_block * page_per_block); ++#else ++ if (shift_on_bbt) { ++ mapped_block = block_remap(mtd, block); ++ if (mapped_block == -1) ++ return NAND_STATUS_FAIL; ++ // allow to read oob even if the block is bad ++ } ++ if (mtk_nand_read_oob_hw(mtd, chip, page_in_block + mapped_block * page_per_block)!=0) ++ return -1; ++#endif ++ return 0; ++} ++ ++int ++mtk_nand_block_bad_hw(struct mtd_info *mtd, loff_t ofs) ++{ ++ struct nand_chip *chip = (struct nand_chip *)mtd->priv; ++ int page_addr = (int)(ofs >> chip->page_shift); ++ unsigned int page_per_block = 1 << (chip->phys_erase_shift - chip->page_shift); ++ unsigned char oob_buf[8]; ++ ++ page_addr &= ~(page_per_block - 1); ++ if (mtk_nand_read_oob_raw(mtd, oob_buf, page_addr, sizeof(oob_buf))) { ++ printk(KERN_WARNING "mtk_nand_read_oob_raw return error\n"); ++ return 1; ++ } ++ ++ if (oob_buf[0] != 0xff) { ++ printk(KERN_WARNING "Bad block detected at 0x%x, oob_buf[0] is 0x%x\n", page_addr, oob_buf[0]); ++ // dump_nfi(); ++ return 1; ++ } ++ ++ return 0; ++} ++ ++static int ++mtk_nand_block_bad(struct mtd_info *mtd, loff_t ofs, int getchip) ++{ ++ int chipnr = 0; ++ struct nand_chip *chip = (struct nand_chip *)mtd->priv; ++ int block = (int)ofs >> chip->phys_erase_shift; ++ int mapped_block = block; ++ int ret; ++ ++ if (getchip) { ++ chipnr = (int)(ofs >> chip->chip_shift); ++ nand_get_device(chip, mtd, FL_READING); ++ /* Select the NAND device */ ++ chip->select_chip(mtd, chipnr); ++ } ++ ++#if defined(MTK_NAND_BMT) ++ mapped_block = get_mapping_block_index(block); ++#else ++ if (shift_on_bbt) { ++ mapped_block = block_remap(mtd, block); ++ if (mapped_block == -1) { ++ if (getchip) ++ nand_release_device(mtd); ++ return NAND_STATUS_FAIL; ++ } ++ } ++#endif ++ ++ ret = mtk_nand_block_bad_hw(mtd, mapped_block << chip->phys_erase_shift); ++#if defined (MTK_NAND_BMT) ++ if (ret) { ++ MSG(INIT, "Unmapped bad block: 0x%x\n", mapped_block); ++ if (update_bmt(mapped_block << chip->phys_erase_shift, UPDATE_UNMAPPED_BLOCK, NULL, NULL)) { ++ MSG(INIT, "Update BMT success\n"); ++ ret = 0; ++ } else { ++ MSG(INIT, "Update BMT fail\n"); ++ ret = 1; ++ } ++ } ++#endif ++ ++ if (getchip) ++ nand_release_device(mtd); ++ ++ return ret; ++} ++ ++#ifdef CONFIG_MTD_NAND_VERIFY_WRITE ++char gacBuf[4096 + 288]; ++ ++static int ++mtk_nand_verify_buf(struct mtd_info *mtd, const uint8_t * buf, int len) ++{ ++ struct nand_chip *chip = (struct nand_chip *)mtd->priv; ++ struct NAND_CMD *pkCMD = &g_kCMD; ++ u32 u4PageSize = mtd->writesize; ++ u32 *pSrc, *pDst; ++ int i; ++ ++ mtk_nand_exec_read_page(mtd, pkCMD->u4RowAddr, u4PageSize, gacBuf, gacBuf + u4PageSize); ++ ++ pSrc = (u32 *) buf; ++ pDst = (u32 *) gacBuf; ++ len = len / sizeof(u32); ++ for (i = 0; i < len; ++i) { ++ if (*pSrc != *pDst) { ++ MSG(VERIFY, "mtk_nand_verify_buf page fail at page %d\n", pkCMD->u4RowAddr); ++ return -1; ++ } ++ pSrc++; ++ pDst++; ++ } ++ ++ pSrc = (u32 *) chip->oob_poi; ++ pDst = (u32 *) (gacBuf + u4PageSize); ++ ++ if ((pSrc[0] != pDst[0]) || (pSrc[1] != pDst[1]) || (pSrc[2] != pDst[2]) || (pSrc[3] != pDst[3]) || (pSrc[4] != pDst[4]) || (pSrc[5] != pDst[5])) { ++ // TODO: Ask Designer Why? ++ //(pSrc[6] != pDst[6]) || (pSrc[7] != pDst[7])) ++ MSG(VERIFY, "mtk_nand_verify_buf oob fail at page %d\n", pkCMD->u4RowAddr); ++ MSG(VERIFY, "0x%x 0x%x 0x%x 0x%x 0x%x 0x%x 0x%x 0x%x\n", pSrc[0], pSrc[1], pSrc[2], pSrc[3], pSrc[4], pSrc[5], pSrc[6], pSrc[7]); ++ MSG(VERIFY, "0x%x 0x%x 0x%x 0x%x 0x%x 0x%x 0x%x 0x%x\n", pDst[0], pDst[1], pDst[2], pDst[3], pDst[4], pDst[5], pDst[6], pDst[7]); ++ return -1; ++ } ++ return 0; ++} ++#endif ++ ++static void ++mtk_nand_init_hw(struct mtk_nand_host *host) { ++ struct mtk_nand_host_hw *hw = host->hw; ++ u32 data; ++ ++ data = DRV_Reg32(RALINK_SYSCTL_BASE+0x60); ++ data &= ~((0x3<<18)|(0x3<<16)); ++ data |= ((0x2<<18) |(0x2<<16)); ++ DRV_WriteReg32(RALINK_SYSCTL_BASE+0x60, data); ++ ++ MSG(INIT, "Enable NFI Clock\n"); ++ nand_enable_clock(); ++ ++ g_bInitDone = false; ++ g_kCMD.u4OOBRowAddr = (u32) - 1; ++ ++ /* Set default NFI access timing control */ ++ DRV_WriteReg32(NFI_ACCCON_REG32, hw->nfi_access_timing); ++ DRV_WriteReg16(NFI_CNFG_REG16, 0); ++ DRV_WriteReg16(NFI_PAGEFMT_REG16, 0); ++ ++ /* Reset the state machine and data FIFO, because flushing FIFO */ ++ (void)mtk_nand_reset(); ++ ++ /* Set the ECC engine */ ++ if (hw->nand_ecc_mode == NAND_ECC_HW) { ++ MSG(INIT, "%s : Use HW ECC\n", MODULE_NAME); ++ if (g_bHwEcc) ++ NFI_SET_REG32(NFI_CNFG_REG16, CNFG_HW_ECC_EN); ++ ECC_Config(host->hw,4); ++ mtk_nand_configure_fdm(8); ++ mtk_nand_configure_lock(); ++ } ++ ++ NFI_SET_REG16(NFI_IOCON_REG16, 0x47); ++} ++ ++static int mtk_nand_dev_ready(struct mtd_info *mtd) ++{ ++ return !(DRV_Reg32(NFI_STA_REG32) & STA_NAND_BUSY); ++} ++ ++#define FACT_BBT_BLOCK_NUM 32 // use the latest 32 BLOCK for factory bbt table ++#define FACT_BBT_OOB_SIGNATURE 1 ++#define FACT_BBT_SIGNATURE_LEN 7 ++const u8 oob_signature[] = "mtknand"; ++static u8 *fact_bbt = 0; ++static u32 bbt_size = 0; ++ ++static int ++read_fact_bbt(struct mtd_info *mtd, unsigned int page) ++{ ++ struct nand_chip *chip = mtd->priv; ++ ++ // read oob ++ if (mtk_nand_read_oob_hw(mtd, chip, page)==0) ++ { ++ if (chip->oob_poi[nand_badblock_offset] != 0xFF) ++ { ++ printk("Bad Block on Page %x\n", page); ++ return -1; ++ } ++ if (memcmp(&chip->oob_poi[FACT_BBT_OOB_SIGNATURE], oob_signature, FACT_BBT_SIGNATURE_LEN) != 0) ++ { ++ printk("compare signature failed %x\n", page); ++ return -1; ++ } ++ if (mtk_nand_exec_read_page(mtd, page, mtd->writesize, chip->buffers->databuf, chip->oob_poi)) ++ { ++ printk("Signature matched and data read!\n"); ++ memcpy(fact_bbt, chip->buffers->databuf, (bbt_size <= mtd->writesize)? bbt_size:mtd->writesize); ++ return 0; ++ } ++ ++ } ++ printk("failed at page %x\n", page); ++ return -1; ++} ++ ++static int ++load_fact_bbt(struct mtd_info *mtd) ++{ ++ struct nand_chip *chip = mtd->priv; ++ int i; ++ u32 total_block; ++ ++ total_block = 1 << (chip->chip_shift - chip->phys_erase_shift); ++ bbt_size = total_block >> 2; ++ ++ if ((!fact_bbt) && (bbt_size)) ++ fact_bbt = (u8 *)kmalloc(bbt_size, GFP_KERNEL); ++ if (!fact_bbt) ++ return -1; ++ ++ for (i = total_block - 1; i >= (total_block - FACT_BBT_BLOCK_NUM); i--) ++ { ++ if (read_fact_bbt(mtd, i << (chip->phys_erase_shift - chip->page_shift)) == 0) ++ { ++ printk("load_fact_bbt success %d\n", i); ++ return 0; ++ } ++ ++ } ++ printk("load_fact_bbt failed\n"); ++ return -1; ++} ++ ++static int ++mtk_nand_probe(struct platform_device *pdev) ++{ ++ struct mtd_part_parser_data ppdata; ++ struct mtk_nand_host_hw *hw; ++ struct mtd_info *mtd; ++ struct nand_chip *nand_chip; ++ u8 ext_id1, ext_id2, ext_id3; ++ int err = 0; ++ int id; ++ u32 ext_id; ++ int i; ++ u32 data; ++ ++ data = DRV_Reg32(RALINK_SYSCTL_BASE+0x60); ++ data &= ~((0x3<<18)|(0x3<<16)); ++ data |= ((0x2<<18) |(0x2<<16)); ++ DRV_WriteReg32(RALINK_SYSCTL_BASE+0x60, data); ++ ++ hw = &mt7621_nand_hw, ++ BUG_ON(!hw); ++ /* Allocate memory for the device structure (and zero it) */ ++ host = kzalloc(sizeof(struct mtk_nand_host), GFP_KERNEL); ++ if (!host) { ++ MSG(INIT, "mtk_nand: failed to allocate device structure.\n"); ++ return -ENOMEM; ++ } ++ ++ /* Allocate memory for 16 byte aligned buffer */ ++ local_buffer_16_align = local_buffer + 16 - ((u32) local_buffer % 16); ++ printk(KERN_INFO "Allocate 16 byte aligned buffer: %p\n", local_buffer_16_align); ++ host->hw = hw; ++ ++ /* init mtd data structure */ ++ nand_chip = &host->nand_chip; ++ nand_chip->priv = host; /* link the private data structures */ ++ ++ mtd = &host->mtd; ++ mtd->priv = nand_chip; ++ mtd->owner = THIS_MODULE; ++ mtd->name = "MT7621-NAND"; ++ ++ hw->nand_ecc_mode = NAND_ECC_HW; ++ ++ /* Set address of NAND IO lines */ ++ nand_chip->IO_ADDR_R = (void __iomem *)NFI_DATAR_REG32; ++ nand_chip->IO_ADDR_W = (void __iomem *)NFI_DATAW_REG32; ++ nand_chip->chip_delay = 20; /* 20us command delay time */ ++ nand_chip->ecc.mode = hw->nand_ecc_mode; /* enable ECC */ ++ nand_chip->ecc.strength = 1; ++ nand_chip->read_byte = mtk_nand_read_byte; ++ nand_chip->read_buf = mtk_nand_read_buf; ++ nand_chip->write_buf = mtk_nand_write_buf; ++#ifdef CONFIG_MTD_NAND_VERIFY_WRITE ++ nand_chip->verify_buf = mtk_nand_verify_buf; ++#endif ++ nand_chip->select_chip = mtk_nand_select_chip; ++ nand_chip->dev_ready = mtk_nand_dev_ready; ++ nand_chip->cmdfunc = mtk_nand_command_bp; ++ nand_chip->ecc.read_page = mtk_nand_read_page_hwecc; ++ nand_chip->ecc.write_page = mtk_nand_write_page_hwecc; ++ ++ nand_chip->ecc.layout = &nand_oob_64; ++ nand_chip->ecc.size = hw->nand_ecc_size; //2048 ++ nand_chip->ecc.bytes = hw->nand_ecc_bytes; //32 ++ ++ // For BMT, we need to revise driver architecture ++ nand_chip->write_page = mtk_nand_write_page; ++ nand_chip->ecc.write_oob = mtk_nand_write_oob; ++ nand_chip->block_markbad = mtk_nand_block_markbad; // need to add nand_get_device()/nand_release_device(). ++ // nand_chip->erase = mtk_nand_erase; ++ // nand_chip->read_page = mtk_nand_read_page; ++ nand_chip->ecc.read_oob = mtk_nand_read_oob; ++ nand_chip->block_bad = mtk_nand_block_bad; ++ ++ //Qwert:Add for Uboot ++ mtk_nand_init_hw(host); ++ /* Select the device */ ++ nand_chip->select_chip(mtd, NFI_DEFAULT_CS); ++ ++ /* ++ * Reset the chip, required by some chips (e.g. Micron MT29FxGxxxxx) ++ * after power-up ++ */ ++ nand_chip->cmdfunc(mtd, NAND_CMD_RESET, -1, -1); ++ ++ memset(&devinfo, 0 , sizeof(flashdev_info)); ++ ++ /* Send the command for reading device ID */ ++ ++ nand_chip->cmdfunc(mtd, NAND_CMD_READID, 0x00, -1); ++ ++ /* Read manufacturer and device IDs */ ++ manu_id = nand_chip->read_byte(mtd); ++ dev_id = nand_chip->read_byte(mtd); ++ id = dev_id | (manu_id << 8); ++ ext_id1 = nand_chip->read_byte(mtd); ++ ext_id2 = nand_chip->read_byte(mtd); ++ ext_id3 = nand_chip->read_byte(mtd); ++ ext_id = ext_id1 << 16 | ext_id2 << 8 | ext_id3; ++ if (!get_device_info(id, ext_id, &devinfo)) { ++ u32 chip_mode = RALINK_REG(RALINK_SYSCTL_BASE+0x010)&0x0F; ++ MSG(INIT, "Not Support this Device! \r\n"); ++ memset(&devinfo, 0 , sizeof(flashdev_info)); ++ MSG(INIT, "chip_mode=%08X\n",chip_mode); ++ ++ /* apply bootstrap first */ ++ devinfo.addr_cycle = 5; ++ devinfo.iowidth = 8; ++ ++ switch (chip_mode) { ++ case 10: ++ devinfo.pagesize = 2048; ++ devinfo.sparesize = 128; ++ devinfo.totalsize = 128; ++ devinfo.blocksize = 128; ++ break; ++ case 11: ++ devinfo.pagesize = 4096; ++ devinfo.sparesize = 128; ++ devinfo.totalsize = 1024; ++ devinfo.blocksize = 256; ++ break; ++ case 12: ++ devinfo.pagesize = 4096; ++ devinfo.sparesize = 224; ++ devinfo.totalsize = 2048; ++ devinfo.blocksize = 512; ++ break; ++ default: ++ case 1: ++ devinfo.pagesize = 2048; ++ devinfo.sparesize = 64; ++ devinfo.totalsize = 128; ++ devinfo.blocksize = 128; ++ break; ++ } ++ ++ devinfo.timmingsetting = NFI_DEFAULT_ACCESS_TIMING; ++ devinfo.devciename[0] = 'U'; ++ devinfo.advancedmode = 0; ++ } ++ mtd->writesize = devinfo.pagesize; ++ mtd->erasesize = (devinfo.blocksize<<10); ++ mtd->oobsize = devinfo.sparesize; ++ ++ nand_chip->chipsize = (devinfo.totalsize<<20); ++ nand_chip->page_shift = ffs(mtd->writesize) - 1; ++ nand_chip->pagemask = (nand_chip->chipsize >> nand_chip->page_shift) - 1; ++ nand_chip->phys_erase_shift = ffs(mtd->erasesize) - 1; ++ nand_chip->chip_shift = ffs(nand_chip->chipsize) - 1;//0x1C;//ffs(nand_chip->chipsize) - 1; ++ nand_chip->oob_poi = nand_chip->buffers->databuf + mtd->writesize; ++ nand_chip->badblockpos = 0; ++ ++ if (devinfo.pagesize == 4096) ++ nand_chip->ecc.layout = &nand_oob_128; ++ else if (devinfo.pagesize == 2048) ++ nand_chip->ecc.layout = &nand_oob_64; ++ else if (devinfo.pagesize == 512) ++ nand_chip->ecc.layout = &nand_oob_16; ++ ++ nand_chip->ecc.layout->eccbytes = devinfo.sparesize-OOB_AVAI_PER_SECTOR*(devinfo.pagesize/NAND_SECTOR_SIZE); ++ for (i = 0; i < nand_chip->ecc.layout->eccbytes; i++) ++ nand_chip->ecc.layout->eccpos[i]=OOB_AVAI_PER_SECTOR*(devinfo.pagesize/NAND_SECTOR_SIZE)+i; ++ ++ MSG(INIT, "Support this Device in MTK table! %x \r\n", id); ++ hw->nfi_bus_width = devinfo.iowidth; ++ DRV_WriteReg32(NFI_ACCCON_REG32, devinfo.timmingsetting); ++ ++ /* 16-bit bus width */ ++ if (hw->nfi_bus_width == 16) { ++ MSG(INIT, "%s : Set the 16-bit I/O settings!\n", MODULE_NAME); ++ nand_chip->options |= NAND_BUSWIDTH_16; ++ } ++ mtd->oobsize = devinfo.sparesize; ++ hw->nfi_cs_num = 1; ++ ++ /* Scan to find existance of the device */ ++ if (nand_scan(mtd, hw->nfi_cs_num)) { ++ MSG(INIT, "%s : nand_scan fail.\n", MODULE_NAME); ++ err = -ENXIO; ++ goto out; ++ } ++ ++ g_page_size = mtd->writesize; ++ platform_set_drvdata(pdev, host); ++ if (hw->nfi_bus_width == 16) { ++ NFI_SET_REG16(NFI_PAGEFMT_REG16, PAGEFMT_DBYTE_EN); ++ } ++ ++ nand_chip->select_chip(mtd, 0); ++#if defined(MTK_NAND_BMT) ++ nand_chip->chipsize -= (BMT_POOL_SIZE) << nand_chip->phys_erase_shift; ++#endif ++ mtd->size = nand_chip->chipsize; ++ ++ CFG_BLOCKSIZE = mtd->erasesize; ++ ++#if defined(MTK_NAND_BMT) ++ if (!g_bmt) { ++ if (!(g_bmt = init_bmt(nand_chip, BMT_POOL_SIZE))) { ++ MSG(INIT, "Error: init bmt failed\n"); ++ return 0; ++ } ++ } ++#endif ++ ++ ppdata.of_node = pdev->dev.of_node; ++ err = mtd_device_parse_register(mtd, probe_types, &ppdata, ++ NULL, 0); ++ if (!err) { ++ MSG(INIT, "[mtk_nand] probe successfully!\n"); ++ nand_disable_clock(); ++ shift_on_bbt = 1; ++ if (load_fact_bbt(mtd) == 0) { ++ int i; ++ for (i = 0; i < 0x100; i++) ++ nand_chip->bbt[i] |= fact_bbt[i]; ++ } ++ ++ return err; ++ } ++ ++out: ++ MSG(INIT, "[NFI] mtk_nand_probe fail, err = %d!\n", err); ++ nand_release(mtd); ++ platform_set_drvdata(pdev, NULL); ++ kfree(host); ++ nand_disable_clock(); ++ return err; ++} ++ ++static int ++mtk_nand_remove(struct platform_device *pdev) ++{ ++ struct mtk_nand_host *host = platform_get_drvdata(pdev); ++ struct mtd_info *mtd = &host->mtd; ++ ++ nand_release(mtd); ++ kfree(host); ++ nand_disable_clock(); ++ ++ return 0; ++} ++ ++static const struct of_device_id mt7621_nand_match[] = { ++ { .compatible = "mtk,mt7621-nand" }, ++ {}, ++}; ++MODULE_DEVICE_TABLE(of, mt7621_nand_match); ++ ++static struct platform_driver mtk_nand_driver = { ++ .probe = mtk_nand_probe, ++ .remove = mtk_nand_remove, ++ .driver = { ++ .name = "MT7621-NAND", ++ .owner = THIS_MODULE, ++ .of_match_table = mt7621_nand_match, ++ }, ++}; ++ ++static int __init ++mtk_nand_init(void) ++{ ++ printk("MediaTek Nand driver init, version %s\n", VERSION); ++ ++ return platform_driver_register(&mtk_nand_driver); ++} ++ ++static void __exit ++mtk_nand_exit(void) ++{ ++ platform_driver_unregister(&mtk_nand_driver); ++} ++ ++module_init(mtk_nand_init); ++module_exit(mtk_nand_exit); ++MODULE_LICENSE("GPL"); +--- /dev/null ++++ b/drivers/mtd/nand/mtk_nand.h +@@ -0,0 +1,452 @@ ++#ifndef __MTK_NAND_H ++#define __MTK_NAND_H ++ ++#define RALINK_NAND_CTRL_BASE 0xBE003000 ++#define RALINK_SYSCTL_BASE 0xBE000000 ++#define RALINK_NANDECC_CTRL_BASE 0xBE003800 ++/******************************************************************************* ++ * NFI Register Definition ++ *******************************************************************************/ ++ ++#define NFI_CNFG_REG16 ((volatile P_U16)(NFI_BASE+0x0000)) ++#define NFI_PAGEFMT_REG16 ((volatile P_U16)(NFI_BASE+0x0004)) ++#define NFI_CON_REG16 ((volatile P_U16)(NFI_BASE+0x0008)) ++#define NFI_ACCCON_REG32 ((volatile P_U32)(NFI_BASE+0x000C)) ++#define NFI_INTR_EN_REG16 ((volatile P_U16)(NFI_BASE+0x0010)) ++#define NFI_INTR_REG16 ((volatile P_U16)(NFI_BASE+0x0014)) ++ ++#define NFI_CMD_REG16 ((volatile P_U16)(NFI_BASE+0x0020)) ++ ++#define NFI_ADDRNOB_REG16 ((volatile P_U16)(NFI_BASE+0x0030)) ++#define NFI_COLADDR_REG32 ((volatile P_U32)(NFI_BASE+0x0034)) ++#define NFI_ROWADDR_REG32 ((volatile P_U32)(NFI_BASE+0x0038)) ++ ++#define NFI_STRDATA_REG16 ((volatile P_U16)(NFI_BASE+0x0040)) ++ ++#define NFI_DATAW_REG32 ((volatile P_U32)(NFI_BASE+0x0050)) ++#define NFI_DATAR_REG32 ((volatile P_U32)(NFI_BASE+0x0054)) ++#define NFI_PIO_DIRDY_REG16 ((volatile P_U16)(NFI_BASE+0x0058)) ++ ++#define NFI_STA_REG32 ((volatile P_U32)(NFI_BASE+0x0060)) ++#define NFI_FIFOSTA_REG16 ((volatile P_U16)(NFI_BASE+0x0064)) ++#define NFI_LOCKSTA_REG16 ((volatile P_U16)(NFI_BASE+0x0068)) ++ ++#define NFI_ADDRCNTR_REG16 ((volatile P_U16)(NFI_BASE+0x0070)) ++ ++#define NFI_STRADDR_REG32 ((volatile P_U32)(NFI_BASE+0x0080)) ++#define NFI_BYTELEN_REG16 ((volatile P_U16)(NFI_BASE+0x0084)) ++ ++#define NFI_CSEL_REG16 ((volatile P_U16)(NFI_BASE+0x0090)) ++#define NFI_IOCON_REG16 ((volatile P_U16)(NFI_BASE+0x0094)) ++ ++#define NFI_FDM0L_REG32 ((volatile P_U32)(NFI_BASE+0x00A0)) ++#define NFI_FDM0M_REG32 ((volatile P_U32)(NFI_BASE+0x00A4)) ++ ++#define NFI_LOCK_REG16 ((volatile P_U16)(NFI_BASE+0x0100)) ++#define NFI_LOCKCON_REG32 ((volatile P_U32)(NFI_BASE+0x0104)) ++#define NFI_LOCKANOB_REG16 ((volatile P_U16)(NFI_BASE+0x0108)) ++#define NFI_LOCK00ADD_REG32 ((volatile P_U32)(NFI_BASE+0x0110)) ++#define NFI_LOCK00FMT_REG32 ((volatile P_U32)(NFI_BASE+0x0114)) ++#define NFI_LOCK01ADD_REG32 ((volatile P_U32)(NFI_BASE+0x0118)) ++#define NFI_LOCK01FMT_REG32 ((volatile P_U32)(NFI_BASE+0x011C)) ++#define NFI_LOCK02ADD_REG32 ((volatile P_U32)(NFI_BASE+0x0120)) ++#define NFI_LOCK02FMT_REG32 ((volatile P_U32)(NFI_BASE+0x0124)) ++#define NFI_LOCK03ADD_REG32 ((volatile P_U32)(NFI_BASE+0x0128)) ++#define NFI_LOCK03FMT_REG32 ((volatile P_U32)(NFI_BASE+0x012C)) ++#define NFI_LOCK04ADD_REG32 ((volatile P_U32)(NFI_BASE+0x0130)) ++#define NFI_LOCK04FMT_REG32 ((volatile P_U32)(NFI_BASE+0x0134)) ++#define NFI_LOCK05ADD_REG32 ((volatile P_U32)(NFI_BASE+0x0138)) ++#define NFI_LOCK05FMT_REG32 ((volatile P_U32)(NFI_BASE+0x013C)) ++#define NFI_LOCK06ADD_REG32 ((volatile P_U32)(NFI_BASE+0x0140)) ++#define NFI_LOCK06FMT_REG32 ((volatile P_U32)(NFI_BASE+0x0144)) ++#define NFI_LOCK07ADD_REG32 ((volatile P_U32)(NFI_BASE+0x0148)) ++#define NFI_LOCK07FMT_REG32 ((volatile P_U32)(NFI_BASE+0x014C)) ++#define NFI_LOCK08ADD_REG32 ((volatile P_U32)(NFI_BASE+0x0150)) ++#define NFI_LOCK08FMT_REG32 ((volatile P_U32)(NFI_BASE+0x0154)) ++#define NFI_LOCK09ADD_REG32 ((volatile P_U32)(NFI_BASE+0x0158)) ++#define NFI_LOCK09FMT_REG32 ((volatile P_U32)(NFI_BASE+0x015C)) ++#define NFI_LOCK10ADD_REG32 ((volatile P_U32)(NFI_BASE+0x0160)) ++#define NFI_LOCK10FMT_REG32 ((volatile P_U32)(NFI_BASE+0x0164)) ++#define NFI_LOCK11ADD_REG32 ((volatile P_U32)(NFI_BASE+0x0168)) ++#define NFI_LOCK11FMT_REG32 ((volatile P_U32)(NFI_BASE+0x016C)) ++#define NFI_LOCK12ADD_REG32 ((volatile P_U32)(NFI_BASE+0x0170)) ++#define NFI_LOCK12FMT_REG32 ((volatile P_U32)(NFI_BASE+0x0174)) ++#define NFI_LOCK13ADD_REG32 ((volatile P_U32)(NFI_BASE+0x0178)) ++#define NFI_LOCK13FMT_REG32 ((volatile P_U32)(NFI_BASE+0x017C)) ++#define NFI_LOCK14ADD_REG32 ((volatile P_U32)(NFI_BASE+0x0180)) ++#define NFI_LOCK14FMT_REG32 ((volatile P_U32)(NFI_BASE+0x0184)) ++#define NFI_LOCK15ADD_REG32 ((volatile P_U32)(NFI_BASE+0x0188)) ++#define NFI_LOCK15FMT_REG32 ((volatile P_U32)(NFI_BASE+0x018C)) ++ ++#define NFI_FIFODATA0_REG32 ((volatile P_U32)(NFI_BASE+0x0190)) ++#define NFI_FIFODATA1_REG32 ((volatile P_U32)(NFI_BASE+0x0194)) ++#define NFI_FIFODATA2_REG32 ((volatile P_U32)(NFI_BASE+0x0198)) ++#define NFI_FIFODATA3_REG32 ((volatile P_U32)(NFI_BASE+0x019C)) ++#define NFI_MASTERSTA_REG16 ((volatile P_U16)(NFI_BASE+0x0210)) ++ ++ ++/******************************************************************************* ++ * NFI Register Field Definition ++ *******************************************************************************/ ++ ++/* NFI_CNFG */ ++#define CNFG_AHB (0x0001) ++#define CNFG_READ_EN (0x0002) ++#define CNFG_DMA_BURST_EN (0x0004) ++#define CNFG_BYTE_RW (0x0040) ++#define CNFG_HW_ECC_EN (0x0100) ++#define CNFG_AUTO_FMT_EN (0x0200) ++#define CNFG_OP_IDLE (0x0000) ++#define CNFG_OP_READ (0x1000) ++#define CNFG_OP_SRD (0x2000) ++#define CNFG_OP_PRGM (0x3000) ++#define CNFG_OP_ERASE (0x4000) ++#define CNFG_OP_RESET (0x5000) ++#define CNFG_OP_CUST (0x6000) ++#define CNFG_OP_MODE_MASK (0x7000) ++#define CNFG_OP_MODE_SHIFT (12) ++ ++/* NFI_PAGEFMT */ ++#define PAGEFMT_512 (0x0000) ++#define PAGEFMT_2K (0x0001) ++#define PAGEFMT_4K (0x0002) ++ ++#define PAGEFMT_PAGE_MASK (0x0003) ++ ++#define PAGEFMT_DBYTE_EN (0x0008) ++ ++#define PAGEFMT_SPARE_16 (0x0000) ++#define PAGEFMT_SPARE_26 (0x0001) ++#define PAGEFMT_SPARE_27 (0x0002) ++#define PAGEFMT_SPARE_28 (0x0003) ++#define PAGEFMT_SPARE_MASK (0x0030) ++#define PAGEFMT_SPARE_SHIFT (4) ++ ++#define PAGEFMT_FDM_MASK (0x0F00) ++#define PAGEFMT_FDM_SHIFT (8) ++ ++#define PAGEFMT_FDM_ECC_MASK (0xF000) ++#define PAGEFMT_FDM_ECC_SHIFT (12) ++ ++/* NFI_CON */ ++#define CON_FIFO_FLUSH (0x0001) ++#define CON_NFI_RST (0x0002) ++#define CON_NFI_SRD (0x0010) ++ ++#define CON_NFI_NOB_MASK (0x0060) ++#define CON_NFI_NOB_SHIFT (5) ++ ++#define CON_NFI_BRD (0x0100) ++#define CON_NFI_BWR (0x0200) ++ ++#define CON_NFI_SEC_MASK (0xF000) ++#define CON_NFI_SEC_SHIFT (12) ++ ++/* NFI_ACCCON */ ++#define ACCCON_SETTING () ++ ++/* NFI_INTR_EN */ ++#define INTR_RD_DONE_EN (0x0001) ++#define INTR_WR_DONE_EN (0x0002) ++#define INTR_RST_DONE_EN (0x0004) ++#define INTR_ERASE_DONE_EN (0x0008) ++#define INTR_BSY_RTN_EN (0x0010) ++#define INTR_ACC_LOCK_EN (0x0020) ++#define INTR_AHB_DONE_EN (0x0040) ++#define INTR_ALL_INTR_DE (0x0000) ++#define INTR_ALL_INTR_EN (0x007F) ++ ++/* NFI_INTR */ ++#define INTR_RD_DONE (0x0001) ++#define INTR_WR_DONE (0x0002) ++#define INTR_RST_DONE (0x0004) ++#define INTR_ERASE_DONE (0x0008) ++#define INTR_BSY_RTN (0x0010) ++#define INTR_ACC_LOCK (0x0020) ++#define INTR_AHB_DONE (0x0040) ++ ++/* NFI_ADDRNOB */ ++#define ADDR_COL_NOB_MASK (0x0003) ++#define ADDR_COL_NOB_SHIFT (0) ++#define ADDR_ROW_NOB_MASK (0x0030) ++#define ADDR_ROW_NOB_SHIFT (4) ++ ++/* NFI_STA */ ++#define STA_READ_EMPTY (0x00001000) ++#define STA_ACC_LOCK (0x00000010) ++#define STA_CMD_STATE (0x00000001) ++#define STA_ADDR_STATE (0x00000002) ++#define STA_DATAR_STATE (0x00000004) ++#define STA_DATAW_STATE (0x00000008) ++ ++#define STA_NAND_FSM_MASK (0x1F000000) ++#define STA_NAND_BUSY (0x00000100) ++#define STA_NAND_BUSY_RETURN (0x00000200) ++#define STA_NFI_FSM_MASK (0x000F0000) ++#define STA_NFI_OP_MASK (0x0000000F) ++ ++/* NFI_FIFOSTA */ ++#define FIFO_RD_EMPTY (0x0040) ++#define FIFO_RD_FULL (0x0080) ++#define FIFO_WR_FULL (0x8000) ++#define FIFO_WR_EMPTY (0x4000) ++#define FIFO_RD_REMAIN(x) (0x1F&(x)) ++#define FIFO_WR_REMAIN(x) ((0x1F00&(x))>>8) ++ ++/* NFI_ADDRCNTR */ ++#define ADDRCNTR_CNTR(x) ((0xF000&(x))>>12) ++#define ADDRCNTR_OFFSET(x) (0x03FF&(x)) ++ ++/* NFI_LOCK */ ++#define NFI_LOCK_ON (0x0001) ++ ++/* NFI_LOCKANOB */ ++#define PROG_RADD_NOB_MASK (0x7000) ++#define PROG_RADD_NOB_SHIFT (12) ++#define PROG_CADD_NOB_MASK (0x0300) ++#define PROG_CADD_NOB_SHIFT (8) ++#define ERASE_RADD_NOB_MASK (0x0070) ++#define ERASE_RADD_NOB_SHIFT (4) ++#define ERASE_CADD_NOB_MASK (0x0007) ++#define ERASE_CADD_NOB_SHIFT (0) ++ ++/******************************************************************************* ++ * ECC Register Definition ++ *******************************************************************************/ ++ ++#define ECC_ENCCON_REG16 ((volatile P_U16)(NFIECC_BASE+0x0000)) ++#define ECC_ENCCNFG_REG32 ((volatile P_U32)(NFIECC_BASE+0x0004)) ++#define ECC_ENCDIADDR_REG32 ((volatile P_U32)(NFIECC_BASE+0x0008)) ++#define ECC_ENCIDLE_REG32 ((volatile P_U32)(NFIECC_BASE+0x000C)) ++#define ECC_ENCPAR0_REG32 ((volatile P_U32)(NFIECC_BASE+0x0010)) ++#define ECC_ENCPAR1_REG32 ((volatile P_U32)(NFIECC_BASE+0x0014)) ++#define ECC_ENCPAR2_REG32 ((volatile P_U32)(NFIECC_BASE+0x0018)) ++#define ECC_ENCPAR3_REG32 ((volatile P_U32)(NFIECC_BASE+0x001C)) ++#define ECC_ENCPAR4_REG32 ((volatile P_U32)(NFIECC_BASE+0x0020)) ++#define ECC_ENCSTA_REG32 ((volatile P_U32)(NFIECC_BASE+0x0024)) ++#define ECC_ENCIRQEN_REG16 ((volatile P_U16)(NFIECC_BASE+0x0028)) ++#define ECC_ENCIRQSTA_REG16 ((volatile P_U16)(NFIECC_BASE+0x002C)) ++ ++#define ECC_DECCON_REG16 ((volatile P_U16)(NFIECC_BASE+0x0100)) ++#define ECC_DECCNFG_REG32 ((volatile P_U32)(NFIECC_BASE+0x0104)) ++#define ECC_DECDIADDR_REG32 ((volatile P_U32)(NFIECC_BASE+0x0108)) ++#define ECC_DECIDLE_REG16 ((volatile P_U16)(NFIECC_BASE+0x010C)) ++#define ECC_DECFER_REG16 ((volatile P_U16)(NFIECC_BASE+0x0110)) ++#define ECC_DECENUM_REG32 ((volatile P_U32)(NFIECC_BASE+0x0114)) ++#define ECC_DECDONE_REG16 ((volatile P_U16)(NFIECC_BASE+0x0118)) ++#define ECC_DECEL0_REG32 ((volatile P_U32)(NFIECC_BASE+0x011C)) ++#define ECC_DECEL1_REG32 ((volatile P_U32)(NFIECC_BASE+0x0120)) ++#define ECC_DECEL2_REG32 ((volatile P_U32)(NFIECC_BASE+0x0124)) ++#define ECC_DECEL3_REG32 ((volatile P_U32)(NFIECC_BASE+0x0128)) ++#define ECC_DECEL4_REG32 ((volatile P_U32)(NFIECC_BASE+0x012C)) ++#define ECC_DECEL5_REG32 ((volatile P_U32)(NFIECC_BASE+0x0130)) ++#define ECC_DECIRQEN_REG16 ((volatile P_U16)(NFIECC_BASE+0x0134)) ++#define ECC_DECIRQSTA_REG16 ((volatile P_U16)(NFIECC_BASE+0x0138)) ++#define ECC_FDMADDR_REG32 ((volatile P_U32)(NFIECC_BASE+0x013C)) ++#define ECC_DECFSM_REG32 ((volatile P_U32)(NFIECC_BASE+0x0140)) ++#define ECC_SYNSTA_REG32 ((volatile P_U32)(NFIECC_BASE+0x0144)) ++#define ECC_DECNFIDI_REG32 ((volatile P_U32)(NFIECC_BASE+0x0148)) ++#define ECC_SYN0_REG32 ((volatile P_U32)(NFIECC_BASE+0x014C)) ++ ++/******************************************************************************* ++ * ECC register definition ++ *******************************************************************************/ ++/* ECC_ENCON */ ++#define ENC_EN (0x0001) ++#define ENC_DE (0x0000) ++ ++/* ECC_ENCCNFG */ ++#define ECC_CNFG_ECC4 (0x0000) ++#define ECC_CNFG_ECC6 (0x0001) ++#define ECC_CNFG_ECC8 (0x0002) ++#define ECC_CNFG_ECC10 (0x0003) ++#define ECC_CNFG_ECC12 (0x0004) ++#define ECC_CNFG_ECC_MASK (0x00000007) ++ ++#define ENC_CNFG_NFI (0x0010) ++#define ENC_CNFG_MODE_MASK (0x0010) ++ ++#define ENC_CNFG_META6 (0x10300000) ++#define ENC_CNFG_META8 (0x10400000) ++ ++#define ENC_CNFG_MSG_MASK (0x1FFF0000) ++#define ENC_CNFG_MSG_SHIFT (0x10) ++ ++/* ECC_ENCIDLE */ ++#define ENC_IDLE (0x0001) ++ ++/* ECC_ENCSTA */ ++#define STA_FSM (0x001F) ++#define STA_COUNT_PS (0xFF10) ++#define STA_COUNT_MS (0x3FFF0000) ++ ++/* ECC_ENCIRQEN */ ++#define ENC_IRQEN (0x0001) ++ ++/* ECC_ENCIRQSTA */ ++#define ENC_IRQSTA (0x0001) ++ ++/* ECC_DECCON */ ++#define DEC_EN (0x0001) ++#define DEC_DE (0x0000) ++ ++/* ECC_ENCCNFG */ ++#define DEC_CNFG_ECC4 (0x0000) ++//#define DEC_CNFG_ECC6 (0x0001) ++//#define DEC_CNFG_ECC12 (0x0002) ++#define DEC_CNFG_NFI (0x0010) ++//#define DEC_CNFG_META6 (0x10300000) ++//#define DEC_CNFG_META8 (0x10400000) ++ ++#define DEC_CNFG_FER (0x01000) ++#define DEC_CNFG_EL (0x02000) ++#define DEC_CNFG_CORRECT (0x03000) ++#define DEC_CNFG_TYPE_MASK (0x03000) ++ ++#define DEC_CNFG_EMPTY_EN (0x80000000) ++ ++#define DEC_CNFG_CODE_MASK (0x1FFF0000) ++#define DEC_CNFG_CODE_SHIFT (0x10) ++ ++/* ECC_DECIDLE */ ++#define DEC_IDLE (0x0001) ++ ++/* ECC_DECFER */ ++#define DEC_FER0 (0x0001) ++#define DEC_FER1 (0x0002) ++#define DEC_FER2 (0x0004) ++#define DEC_FER3 (0x0008) ++#define DEC_FER4 (0x0010) ++#define DEC_FER5 (0x0020) ++#define DEC_FER6 (0x0040) ++#define DEC_FER7 (0x0080) ++ ++/* ECC_DECENUM */ ++#define ERR_NUM0 (0x0000000F) ++#define ERR_NUM1 (0x000000F0) ++#define ERR_NUM2 (0x00000F00) ++#define ERR_NUM3 (0x0000F000) ++#define ERR_NUM4 (0x000F0000) ++#define ERR_NUM5 (0x00F00000) ++#define ERR_NUM6 (0x0F000000) ++#define ERR_NUM7 (0xF0000000) ++ ++/* ECC_DECDONE */ ++#define DEC_DONE0 (0x0001) ++#define DEC_DONE1 (0x0002) ++#define DEC_DONE2 (0x0004) ++#define DEC_DONE3 (0x0008) ++#define DEC_DONE4 (0x0010) ++#define DEC_DONE5 (0x0020) ++#define DEC_DONE6 (0x0040) ++#define DEC_DONE7 (0x0080) ++ ++/* ECC_DECIRQEN */ ++#define DEC_IRQEN (0x0001) ++ ++/* ECC_DECIRQSTA */ ++#define DEC_IRQSTA (0x0001) ++ ++#define CHIPVER_ECO_1 (0x8a00) ++#define CHIPVER_ECO_2 (0x8a01) ++ ++//#define NAND_PFM ++ ++/******************************************************************************* ++ * Data Structure Definition ++ *******************************************************************************/ ++struct mtk_nand_host ++{ ++ struct nand_chip nand_chip; ++ struct mtd_info mtd; ++ struct mtk_nand_host_hw *hw; ++}; ++ ++struct NAND_CMD ++{ ++ u32 u4ColAddr; ++ u32 u4RowAddr; ++ u32 u4OOBRowAddr; ++ u8 au1OOB[288]; ++ u8* pDataBuf; ++#ifdef NAND_PFM ++ u32 pureReadOOB; ++ u32 pureReadOOBNum; ++#endif ++}; ++ ++/* ++ * ECC layout control structure. Exported to userspace for ++ * diagnosis and to allow creation of raw images ++struct nand_ecclayout { ++ uint32_t eccbytes; ++ uint32_t eccpos[64]; ++ uint32_t oobavail; ++ struct nand_oobfree oobfree[MTD_MAX_OOBFREE_ENTRIES]; ++}; ++*/ ++#define __DEBUG_NAND 1 /* Debug information on/off */ ++ ++/* Debug message event */ ++#define DBG_EVT_NONE 0x00000000 /* No event */ ++#define DBG_EVT_INIT 0x00000001 /* Initial related event */ ++#define DBG_EVT_VERIFY 0x00000002 /* Verify buffer related event */ ++#define DBG_EVT_PERFORMANCE 0x00000004 /* Performance related event */ ++#define DBG_EVT_READ 0x00000008 /* Read related event */ ++#define DBG_EVT_WRITE 0x00000010 /* Write related event */ ++#define DBG_EVT_ERASE 0x00000020 /* Erase related event */ ++#define DBG_EVT_BADBLOCK 0x00000040 /* Badblock related event */ ++#define DBG_EVT_POWERCTL 0x00000080 /* Suspend/Resume related event */ ++ ++#define DBG_EVT_ALL 0xffffffff ++ ++#define DBG_EVT_MASK (DBG_EVT_INIT) ++ ++#if __DEBUG_NAND ++#define MSG(evt, fmt, args...) \ ++do { \ ++ if ((DBG_EVT_##evt) & DBG_EVT_MASK) { \ ++ printk(fmt, ##args); \ ++ } \ ++} while(0) ++ ++#define MSG_FUNC_ENTRY(f) MSG(FUC, "<FUN_ENT>: %s\n", __FUNCTION__) ++#else ++#define MSG(evt, fmt, args...) do{}while(0) ++#define MSG_FUNC_ENTRY(f) do{}while(0) ++#endif ++ ++#define RAMDOM_READ 1<<0 ++#define CACHE_READ 1<<1 ++ ++typedef struct ++{ ++ u16 id; //deviceid+menuid ++ u32 ext_id; ++ u8 addr_cycle; ++ u8 iowidth; ++ u16 totalsize; ++ u16 blocksize; ++ u16 pagesize; ++ u16 sparesize; ++ u32 timmingsetting; ++ char devciename[14]; ++ u32 advancedmode; // ++}flashdev_info,*pflashdev_info; ++ ++/* NAND driver */ ++#if 0 ++struct mtk_nand_host_hw { ++ unsigned int nfi_bus_width; /* NFI_BUS_WIDTH */ ++ unsigned int nfi_access_timing; /* NFI_ACCESS_TIMING */ ++ unsigned int nfi_cs_num; /* NFI_CS_NUM */ ++ unsigned int nand_sec_size; /* NAND_SECTOR_SIZE */ ++ unsigned int nand_sec_shift; /* NAND_SECTOR_SHIFT */ ++ unsigned int nand_ecc_size; ++ unsigned int nand_ecc_bytes; ++ unsigned int nand_ecc_mode; ++}; ++extern struct mtk_nand_host_hw mt7621_nand_hw; ++extern u32 CFG_BLOCKSIZE; ++#endif ++#endif +--- a/drivers/mtd/nand/nand_base.c ++++ b/drivers/mtd/nand/nand_base.c +@@ -93,7 +93,7 @@ static struct nand_ecclayout nand_oob_12 + .length = 78} } + }; + +-static int nand_get_device(struct mtd_info *mtd, int new_state); ++int nand_get_device(struct mtd_info *mtd, int new_state); + + static int nand_do_write_oob(struct mtd_info *mtd, loff_t to, + struct mtd_oob_ops *ops); +@@ -131,7 +131,7 @@ static int check_offs_len(struct mtd_inf + * + * Release chip lock and wake up anyone waiting on the device. + */ +-static void nand_release_device(struct mtd_info *mtd) ++void nand_release_device(struct mtd_info *mtd) + { + struct nand_chip *chip = mtd->priv; + +@@ -803,7 +803,7 @@ static void panic_nand_get_device(struct + * + * Get the device and lock it for exclusive access + */ +-static int ++int + nand_get_device(struct mtd_info *mtd, int new_state) + { + struct nand_chip *chip = mtd->priv; +--- a/drivers/mtd/nand/nand_bbt.c ++++ b/drivers/mtd/nand/nand_bbt.c +@@ -1372,4 +1372,23 @@ int nand_markbad_bbt(struct mtd_info *mt + return ret; + } + ++void nand_bbt_set(struct mtd_info *mtd, int page, int flag) ++{ ++ struct nand_chip *this = mtd->priv; ++ int block; ++ ++ block = (int)(page >> (this->bbt_erase_shift - this->page_shift - 1)); ++ this->bbt[block >> 3] &= ~(0x03 << (block & 0x6)); ++ this->bbt[block >> 3] |= (flag & 0x3) << (block & 0x6); ++} ++ ++int nand_bbt_get(struct mtd_info *mtd, int page) ++{ ++ struct nand_chip *this = mtd->priv; ++ int block; ++ ++ block = (int)(page >> (this->bbt_erase_shift - this->page_shift - 1)); ++ return (this->bbt[block >> 3] >> (block & 0x06)) & 0x03; ++} ++ + EXPORT_SYMBOL(nand_scan_bbt); +--- /dev/null ++++ b/drivers/mtd/nand/nand_def.h +@@ -0,0 +1,123 @@ ++#ifndef __NAND_DEF_H__ ++#define __NAND_DEF_H__ ++ ++#define VERSION "v2.1 Fix AHB virt2phys error" ++#define MODULE_NAME "# MTK NAND #" ++#define PROCNAME "driver/nand" ++ ++#undef TESTTIME ++//#define __UBOOT_NAND__ 1 ++#define __KERNEL_NAND__ 1 ++//#define __PRELOADER_NAND__ 1 ++//#define PMT 1 ++//#define _MTK_NAND_DUMMY_DRIVER ++//#define CONFIG_BADBLOCK_CHECK 1 ++//#ifdef CONFIG_BADBLOCK_CHECK ++//#define MTK_NAND_BMT 1 ++//#endif ++#define ECC_ENABLE 1 ++#define MANUAL_CORRECT 1 ++//#define __INTERNAL_USE_AHB_MODE__ (0) ++#define SKIP_BAD_BLOCK ++#define FACT_BBT ++ ++#ifndef NAND_OTP_SUPPORT ++#define NAND_OTP_SUPPORT 0 ++#endif ++ ++/******************************************************************************* ++ * Macro definition ++ *******************************************************************************/ ++//#define NFI_SET_REG32(reg, value) (DRV_WriteReg32(reg, DRV_Reg32(reg) | (value))) ++//#define NFI_SET_REG16(reg, value) (DRV_WriteReg16(reg, DRV_Reg16(reg) | (value))) ++//#define NFI_CLN_REG32(reg, value) (DRV_WriteReg32(reg, DRV_Reg32(reg) & (~(value)))) ++//#define NFI_CLN_REG16(reg, value) (DRV_WriteReg16(reg, DRV_Reg16(reg) & (~(value)))) ++ ++#if defined (__KERNEL_NAND__) ++#define NFI_SET_REG32(reg, value) \ ++do { \ ++ g_value = (DRV_Reg32(reg) | (value));\ ++ DRV_WriteReg32(reg, g_value); \ ++} while(0) ++ ++#define NFI_SET_REG16(reg, value) \ ++do { \ ++ g_value = (DRV_Reg16(reg) | (value));\ ++ DRV_WriteReg16(reg, g_value); \ ++} while(0) ++ ++#define NFI_CLN_REG32(reg, value) \ ++do { \ ++ g_value = (DRV_Reg32(reg) & (~(value)));\ ++ DRV_WriteReg32(reg, g_value); \ ++} while(0) ++ ++#define NFI_CLN_REG16(reg, value) \ ++do { \ ++ g_value = (DRV_Reg16(reg) & (~(value)));\ ++ DRV_WriteReg16(reg, g_value); \ ++} while(0) ++#endif ++ ++#define NFI_WAIT_STATE_DONE(state) do{;}while (__raw_readl(NFI_STA_REG32) & state) ++#define NFI_WAIT_TO_READY() do{;}while (!(__raw_readl(NFI_STA_REG32) & STA_BUSY2READY)) ++ ++ ++#define NAND_SECTOR_SIZE (512) ++#define OOB_PER_SECTOR (16) ++#define OOB_AVAI_PER_SECTOR (8) ++ ++#ifndef PART_SIZE_BMTPOOL ++#define BMT_POOL_SIZE (80) ++#else ++#define BMT_POOL_SIZE (PART_SIZE_BMTPOOL) ++#endif ++ ++#define PMT_POOL_SIZE (2) ++ ++#define TIMEOUT_1 0x1fff ++#define TIMEOUT_2 0x8ff ++#define TIMEOUT_3 0xffff ++#define TIMEOUT_4 0xffff//5000 //PIO ++ ++ ++/* temporarity definiation */ ++#if !defined (__KERNEL_NAND__) ++#define KERN_INFO ++#define KERN_WARNING ++#define KERN_ERR ++#define PAGE_SIZE (4096) ++#endif ++#define AddStorageTrace //AddStorageTrace ++#define STORAGE_LOGGER_MSG_NAND 0 ++#define NFI_BASE RALINK_NAND_CTRL_BASE ++#define NFIECC_BASE RALINK_NANDECC_CTRL_BASE ++ ++#ifdef __INTERNAL_USE_AHB_MODE__ ++#define MT65xx_POLARITY_LOW 0 ++#define MT65XX_PDN_PERI_NFI 0 ++#define MT65xx_EDGE_SENSITIVE 0 ++#define MT6575_NFI_IRQ_ID (58) ++#endif ++ ++#if defined (__KERNEL_NAND__) ++#define RALINK_REG(x) (*((volatile u32 *)(x))) ++#define __virt_to_phys(x) virt_to_phys((volatile void*)x) ++#else ++#define CONFIG_MTD_NAND_VERIFY_WRITE (1) ++#define printk printf ++#define ra_dbg printf ++#define BUG() //BUG() ++#define BUG_ON(x) //BUG_ON() ++#define NUM_PARTITIONS 1 ++#endif ++ ++#define NFI_DEFAULT_ACCESS_TIMING (0x30C77fff) //(0x44333) ++ ++//uboot only support 1 cs ++#define NFI_CS_NUM (1) ++#define NFI_DEFAULT_CS (0) ++ ++#include "mt6575_typedefs.h" ++ ++#endif /* __NAND_DEF_H__ */ +--- /dev/null ++++ b/drivers/mtd/nand/nand_device_list.h +@@ -0,0 +1,55 @@ ++/* Copyright Statement: ++ * ++ * This software/firmware and related documentation ("MediaTek Software") are ++ * protected under relevant copyright laws. The information contained herein ++ * is confidential and proprietary to MediaTek Inc. and/or its licensors. ++ * Without the prior written permission of MediaTek inc. and/or its licensors, ++ * any reproduction, modification, use or disclosure of MediaTek Software, ++ * and information contained herein, in whole or in part, shall be strictly prohibited. ++ */ ++/* MediaTek Inc. (C) 2010. All rights reserved. ++ * ++ * BY OPENING THIS FILE, RECEIVER HEREBY UNEQUIVOCALLY ACKNOWLEDGES AND AGREES ++ * THAT THE SOFTWARE/FIRMWARE AND ITS DOCUMENTATIONS ("MEDIATEK SOFTWARE") ++ * RECEIVED FROM MEDIATEK AND/OR ITS REPRESENTATIVES ARE PROVIDED TO RECEIVER ON ++ * AN "AS-IS" BASIS ONLY. MEDIATEK EXPRESSLY DISCLAIMS ANY AND ALL WARRANTIES, ++ * EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE IMPLIED WARRANTIES OF ++ * MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE OR NONINFRINGEMENT. ++ * NEITHER DOES MEDIATEK PROVIDE ANY WARRANTY WHATSOEVER WITH RESPECT TO THE ++ * SOFTWARE OF ANY THIRD PARTY WHICH MAY BE USED BY, INCORPORATED IN, OR ++ * SUPPLIED WITH THE MEDIATEK SOFTWARE, AND RECEIVER AGREES TO LOOK ONLY TO SUCH ++ * THIRD PARTY FOR ANY WARRANTY CLAIM RELATING THERETO. RECEIVER EXPRESSLY ACKNOWLEDGES ++ * THAT IT IS RECEIVER'S SOLE RESPONSIBILITY TO OBTAIN FROM ANY THIRD PARTY ALL PROPER LICENSES ++ * CONTAINED IN MEDIATEK SOFTWARE. MEDIATEK SHALL ALSO NOT BE RESPONSIBLE FOR ANY MEDIATEK ++ * SOFTWARE RELEASES MADE TO RECEIVER'S SPECIFICATION OR TO CONFORM TO A PARTICULAR ++ * STANDARD OR OPEN FORUM. RECEIVER'S SOLE AND EXCLUSIVE REMEDY AND MEDIATEK'S ENTIRE AND ++ * CUMULATIVE LIABILITY WITH RESPECT TO THE MEDIATEK SOFTWARE RELEASED HEREUNDER WILL BE, ++ * AT MEDIATEK'S OPTION, TO REVISE OR REPLACE THE MEDIATEK SOFTWARE AT ISSUE, ++ * OR REFUND ANY SOFTWARE LICENSE FEES OR SERVICE CHARGE PAID BY RECEIVER TO ++ * MEDIATEK FOR SUCH MEDIATEK SOFTWARE AT ISSUE. ++ * ++ * The following software/firmware and/or related documentation ("MediaTek Software") ++ * have been modified by MediaTek Inc. All revisions are subject to any receiver's ++ * applicable license agreements with MediaTek Inc. ++ */ ++ ++#ifndef __NAND_DEVICE_LIST_H__ ++#define __NAND_DEVICE_LIST_H__ ++ ++static const flashdev_info gen_FlashTable[]={ ++ {0x20BC, 0x105554, 5, 16, 512, 128, 2048, 64, 0x1123, "EHD013151MA_5", 0}, ++ {0xECBC, 0x005554, 5, 16, 512, 128, 2048, 64, 0x1123, "K524G2GACB_A0", 0}, ++ {0x2CBC, 0x905556, 5, 16, 512, 128, 2048, 64, 0x21044333, "MT29C4G96MAZA", 0}, ++ {0xADBC, 0x905554, 5, 16, 512, 128, 2048, 64, 0x10801011, "H9DA4GH4JJAMC", 0}, ++ {0x01F1, 0x801D01, 4, 8, 128, 128, 2048, 64, 0x30C77fff, "S34ML01G100TF", 0}, ++ {0x92F1, 0x8095FF, 4, 8, 128, 128, 2048, 64, 0x30C77fff, "F59L1G81A", 0}, ++ {0xECD3, 0x519558, 5, 8, 1024, 128, 2048, 64, 0x44333, "K9K8G8000", 0}, ++ {0xC2F1, 0x801DC2, 4, 8, 128, 128, 2048, 64, 0x30C77fff, "MX30LF1G08AA", 0}, ++ {0x98D3, 0x902676, 5, 8, 1024, 256, 4096, 224, 0x00C25332, "TC58NVG3S0F", 0}, ++ {0x01DA, 0x909546, 5, 8, 256, 128, 2048, 128, 0x30C77fff, "S34ML02G200TF", 0}, ++ {0x01DC, 0x909556, 5, 8, 512, 128, 2048, 128, 0x30C77fff, "S34ML04G200TF", 0}, ++ {0x0000, 0x000000, 0, 0, 0, 0, 0, 0, 0, "xxxxxxxxxx", 0}, ++}; ++ ++ ++#endif +--- /dev/null ++++ b/drivers/mtd/nand/partition.h +@@ -0,0 +1,115 @@ ++/* Copyright Statement: ++ * ++ * This software/firmware and related documentation ("MediaTek Software") are ++ * protected under relevant copyright laws. The information contained herein ++ * is confidential and proprietary to MediaTek Inc. and/or its licensors. ++ * Without the prior written permission of MediaTek inc. and/or its licensors, ++ * any reproduction, modification, use or disclosure of MediaTek Software, ++ * and information contained herein, in whole or in part, shall be strictly prohibited. ++ */ ++/* MediaTek Inc. (C) 2010. All rights reserved. ++ * ++ * BY OPENING THIS FILE, RECEIVER HEREBY UNEQUIVOCALLY ACKNOWLEDGES AND AGREES ++ * THAT THE SOFTWARE/FIRMWARE AND ITS DOCUMENTATIONS ("MEDIATEK SOFTWARE") ++ * RECEIVED FROM MEDIATEK AND/OR ITS REPRESENTATIVES ARE PROVIDED TO RECEIVER ON ++ * AN "AS-IS" BASIS ONLY. MEDIATEK EXPRESSLY DISCLAIMS ANY AND ALL WARRANTIES, ++ * EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE IMPLIED WARRANTIES OF ++ * MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE OR NONINFRINGEMENT. ++ * NEITHER DOES MEDIATEK PROVIDE ANY WARRANTY WHATSOEVER WITH RESPECT TO THE ++ * SOFTWARE OF ANY THIRD PARTY WHICH MAY BE USED BY, INCORPORATED IN, OR ++ * SUPPLIED WITH THE MEDIATEK SOFTWARE, AND RECEIVER AGREES TO LOOK ONLY TO SUCH ++ * THIRD PARTY FOR ANY WARRANTY CLAIM RELATING THERETO. RECEIVER EXPRESSLY ACKNOWLEDGES ++ * THAT IT IS RECEIVER'S SOLE RESPONSIBILITY TO OBTAIN FROM ANY THIRD PARTY ALL PROPER LICENSES ++ * CONTAINED IN MEDIATEK SOFTWARE. MEDIATEK SHALL ALSO NOT BE RESPONSIBLE FOR ANY MEDIATEK ++ * SOFTWARE RELEASES MADE TO RECEIVER'S SPECIFICATION OR TO CONFORM TO A PARTICULAR ++ * STANDARD OR OPEN FORUM. RECEIVER'S SOLE AND EXCLUSIVE REMEDY AND MEDIATEK'S ENTIRE AND ++ * CUMULATIVE LIABILITY WITH RESPECT TO THE MEDIATEK SOFTWARE RELEASED HEREUNDER WILL BE, ++ * AT MEDIATEK'S OPTION, TO REVISE OR REPLACE THE MEDIATEK SOFTWARE AT ISSUE, ++ * OR REFUND ANY SOFTWARE LICENSE FEES OR SERVICE CHARGE PAID BY RECEIVER TO ++ * MEDIATEK FOR SUCH MEDIATEK SOFTWARE AT ISSUE. ++ * ++ * The following software/firmware and/or related documentation ("MediaTek Software") ++ * have been modified by MediaTek Inc. All revisions are subject to any receiver's ++ * applicable license agreements with MediaTek Inc. ++ */ ++ ++#include <linux/mtd/mtd.h> ++#include <linux/mtd/nand.h> ++#include <linux/mtd/partitions.h> ++ ++#define RECONFIG_PARTITION_SIZE 1 ++ ++#define MTD_BOOT_PART_SIZE 0x80000 ++#define MTD_CONFIG_PART_SIZE 0x20000 ++#define MTD_FACTORY_PART_SIZE 0x20000 ++ ++extern unsigned int CFG_BLOCKSIZE; ++#define LARGE_MTD_BOOT_PART_SIZE (CFG_BLOCKSIZE<<2) ++#define LARGE_MTD_CONFIG_PART_SIZE (CFG_BLOCKSIZE<<2) ++#define LARGE_MTD_FACTORY_PART_SIZE (CFG_BLOCKSIZE<<1) ++ ++/*=======================================================================*/ ++/* NAND PARTITION Mapping */ ++/*=======================================================================*/ ++//#ifdef CONFIG_MTD_PARTITIONS ++static struct mtd_partition g_pasStatic_Partition[] = { ++ { ++ name: "ALL", ++ size: MTDPART_SIZ_FULL, ++ offset: 0, ++ }, ++ /* Put your own partition definitions here */ ++ { ++ name: "Bootloader", ++ size: MTD_BOOT_PART_SIZE, ++ offset: 0, ++ }, { ++ name: "Config", ++ size: MTD_CONFIG_PART_SIZE, ++ offset: MTDPART_OFS_APPEND ++ }, { ++ name: "Factory", ++ size: MTD_FACTORY_PART_SIZE, ++ offset: MTDPART_OFS_APPEND ++#ifdef CONFIG_RT2880_ROOTFS_IN_FLASH ++ }, { ++ name: "Kernel", ++ size: MTD_KERN_PART_SIZE, ++ offset: MTDPART_OFS_APPEND, ++ }, { ++ name: "RootFS", ++ size: MTD_ROOTFS_PART_SIZE, ++ offset: MTDPART_OFS_APPEND, ++#ifdef CONFIG_ROOTFS_IN_FLASH_NO_PADDING ++ }, { ++ name: "Kernel_RootFS", ++ size: MTD_KERN_PART_SIZE + MTD_ROOTFS_PART_SIZE, ++ offset: MTD_BOOT_PART_SIZE + MTD_CONFIG_PART_SIZE + MTD_FACTORY_PART_SIZE, ++#endif ++#else //CONFIG_RT2880_ROOTFS_IN_RAM ++ }, { ++ name: "Kernel", ++ size: 0x10000, ++ offset: MTDPART_OFS_APPEND, ++#endif ++#ifdef CONFIG_DUAL_IMAGE ++ }, { ++ name: "Kernel2", ++ size: MTD_KERN2_PART_SIZE, ++ offset: MTD_KERN2_PART_OFFSET, ++#ifdef CONFIG_RT2880_ROOTFS_IN_FLASH ++ }, { ++ name: "RootFS2", ++ size: MTD_ROOTFS2_PART_SIZE, ++ offset: MTD_ROOTFS2_PART_OFFSET, ++#endif ++#endif ++ } ++ ++}; ++ ++#define NUM_PARTITIONS ARRAY_SIZE(g_pasStatic_Partition) ++extern int part_num; // = NUM_PARTITIONS; ++//#endif ++#undef RECONFIG_PARTITION_SIZE ++ |