// SPDX-License-Identifier: GPL-2.0
/* Copyright (c) 2018 Rockchip Electronics Co. Ltd. */
#define pr_fmt(fmt) "nandc: " fmt
#include <linux/delay.h>
#include <linux/kernel.h>
#include <linux/slab.h>
#include "flash.h"
#include "flash_com.h"
#include "nandc.h"
#include "rkflash_debug.h"
#define FLASH_STRESS_TEST_EN 0
static u8 id_byte[MAX_FLASH_NUM][8];
static u8 die_cs_index[MAX_FLASH_NUM];
static u8 g_nand_max_die;
static u16 g_totle_block;
static u8 g_nand_flash_ecc_bits;
static u8 g_nand_idb_res_blk_num;
static u8 g_nand_ecc_en;
static struct NAND_PARA_INFO_T nand_para = {
2,
{0x98, 0xF1, 0, 0, 0, 0},
TOSHIBA,
1,
4,
64,
1,
1,
1024,
0x100,
LSB_0,
RR_NONE,
16,
40,
1,
0,
BBF_1,
MPM_0,
{0}
}; /* TC58NVG0S3HTA00 */
static void flash_read_id_raw(u8 cs, u8 *buf)
{
u8 *ptr = (u8 *)buf;
nandc_flash_reset(cs);
nandc_flash_cs(cs);
nandc_writel(READ_ID_CMD, NANDC_CHIP_CMD(cs));
nandc_writel(0x00, NANDC_CHIP_ADDR(cs));
nandc_delayns(200);
ptr[0] = nandc_readl(NANDC_CHIP_DATA(cs));
ptr[1] = nandc_readl(NANDC_CHIP_DATA(cs));
ptr[2] = nandc_readl(NANDC_CHIP_DATA(cs));
ptr[3] = nandc_readl(NANDC_CHIP_DATA(cs));
ptr[4] = nandc_readl(NANDC_CHIP_DATA(cs));
ptr[5] = nandc_readl(NANDC_CHIP_DATA(cs));
ptr[6] = nandc_readl(NANDC_CHIP_DATA(cs));
ptr[7] = nandc_readl(NANDC_CHIP_DATA(cs));
nandc_flash_de_cs(cs);
if (ptr[0] != 0xFF && ptr[0] && ptr[1] != 0xFF)
rkflash_print_error("No.%d FLASH ID:%x %x %x %x %x %x\n",
cs + 1, ptr[0], ptr[1], ptr[2],
ptr[3], ptr[4], ptr[5]);
}
static void flash_bch_sel(u8 bits)
{
g_nand_flash_ecc_bits = bits;
nandc_bch_sel(bits);
}
static void flash_set_sector(u8 num)
{
nand_para.sec_per_page = num;
}
static __maybe_unused void flash_timing_cfg(u32 ahb_khz)
{
nandc_time_cfg(nand_para.access_freq);
}
static void flash_read_cmd(u8 cs, u32 page_addr)
{
nandc_writel(READ_CMD >> 8, NANDC_CHIP_CMD(cs));
nandc_writel(0x00, NANDC_CHIP_ADDR(cs));
nandc_writel(0x00, NANDC_CHIP_ADDR(cs));
nandc_writel(page_addr & 0x00ff, NANDC_CHIP_ADDR(cs));
nandc_writel(page_addr >> 8, NANDC_CHIP_ADDR(cs));
nandc_writel(page_addr >> 16, NANDC_CHIP_ADDR(cs));
nandc_writel(READ_CMD & 0x00ff, NANDC_CHIP_CMD(cs));
}
static void flash_prog_first_cmd(u8 cs, u32 page_addr)
{
nandc_writel(PAGE_PROG_CMD >> 8, NANDC_CHIP_CMD(cs));
nandc_writel(0x00, NANDC_CHIP_ADDR(cs));
nandc_writel(0x00, NANDC_CHIP_ADDR(cs));
nandc_writel(page_addr & 0x00ff, NANDC_CHIP_ADDR(cs));
nandc_writel(page_addr >> 8, NANDC_CHIP_ADDR(cs));
nandc_writel(page_addr >> 16, NANDC_CHIP_ADDR(cs));
}
static void flash_erase_cmd(u8 cs, u32 page_addr)
{
nandc_writel(BLOCK_ERASE_CMD >> 8, NANDC_CHIP_CMD(cs));
nandc_writel(page_addr & 0x00ff, NANDC_CHIP_ADDR(cs));
nandc_writel(page_addr >> 8, NANDC_CHIP_ADDR(cs));
nandc_writel(page_addr >> 16, NANDC_CHIP_ADDR(cs));
nandc_writel(BLOCK_ERASE_CMD & 0x00ff, NANDC_CHIP_CMD(cs));
}
static void flash_prog_second_cmd(u8 cs, u32 page_addr)
{
usleep_range(100, 120);
nandc_writel(PAGE_PROG_CMD & 0x00ff, NANDC_CHIP_CMD(cs));
}
static u32 flash_read_status(u8 cs, u32 page_addr)
{
nandc_writel(READ_STATUS_CMD, NANDC_CHIP_CMD(cs));
nandc_delayns(80);
return nandc_readl(NANDC_CHIP_DATA(cs));
}
static void flash_read_random_dataout_cmd(u8 cs, u32 col_addr)
{
nandc_writel(READ_DP_OUT_CMD >> 8, NANDC_CHIP_CMD(cs));
nandc_writel(col_addr & 0x00ff, NANDC_CHIP_ADDR(cs));
nandc_writel(col_addr >> 8, NANDC_CHIP_ADDR(cs));
nandc_writel(READ_DP_OUT_CMD & 0x00ff, NANDC_CHIP_CMD(cs));
}
static u32 flash_read_ecc(u8 cs)
{
u32 ecc0, ecc1;
nandc_writel(READ_ECC_STATUS_CMD, NANDC_CHIP_CMD(cs));
nandc_delayns(80);
ecc0 = nandc_readl(NANDC_CHIP_DATA(cs)) & 0xF;
ecc1 = nandc_readl(NANDC_CHIP_DATA(cs)) & 0xF;
if (ecc1 > ecc0)
ecc0 = ecc1;
ecc1 = nandc_readl(NANDC_CHIP_DATA(cs)) & 0xF;
if (ecc1 > ecc0)
ecc0 = ecc1;
ecc1 = nandc_readl(NANDC_CHIP_DATA(cs)) & 0xF;
if (ecc1 > ecc0)
ecc0 = ecc1;
return ecc0;
}
static u32 flash_read_page_raw(u8 cs, u32 page_addr, u32 *p_data, u32 *p_spare)
{
u32 error_ecc_bits, ret;
u32 sec_per_page = nand_para.sec_per_page;
u32 nand_ecc = 0;
nandc_wait_flash_ready(cs);
nandc_flash_cs(cs);
flash_read_cmd(cs, page_addr);
nandc_wait_flash_ready(cs);
flash_read_random_dataout_cmd(cs, 0);
nandc_wait_flash_ready(cs);
error_ecc_bits = nandc_xfer_data(cs, NANDC_READ, sec_per_page,
p_data, p_spare);
nandc_flash_de_cs(cs);
if (error_ecc_bits != NAND_STS_ECC_ERR) {
if (error_ecc_bits >= (u32)nand_para.ecc_bits - 3) {
ret = NAND_STS_REFRESH;
} else {
ret = NAND_STS_OK;
if (g_nand_ecc_en) {
nand_ecc = flash_read_ecc(cs);
if (nand_ecc >= 6) {
rkflash_print_error("%s nand ecc %x ecc %d\n",
__func__, page_addr, nand_ecc);
ret = NAND_STS_REFRESH;
}
}
}
} else {
ret = NAND_STS_ECC_ERR;
}
if (nand_ecc > 4 || error_ecc_bits > 4)
rkflash_print_info("%s %x %x nandc ecc= %d, internal ecc= %d\n",
__func__, cs, page_addr, error_ecc_bits, nand_ecc);
return ret;
}
static u32 flash_read_page(u8 cs, u32 page_addr, u32 *p_data, u32 *p_spare)
{
u32 ret, i = 0;
ret = flash_read_page_raw(cs, page_addr, p_data, p_spare);
if (ret == NAND_STS_ECC_ERR) {
for (; i < 50; i++) {
ret = flash_read_page_raw(cs, page_addr, p_data, p_spare);
if (ret != NAND_STS_ECC_ERR) {
ret = NAND_STS_REFRESH;
break;
}
}
rkflash_print_error("%s %x err_ecc %d\n",
__func__, page_addr, ret);
}
rkflash_print_dio("%s %x %x retry=%x\n",
__func__, page_addr, p_data[0], i);
return ret;
}
static u32 flash_prog_page(u8 cs, u32 page_addr, u32 *p_data, u32 *p_spare)
{
u32 status;
u32 sec_per_page = nand_para.sec_per_page;
rkflash_print_dio("%s %x %x\n", __func__, page_addr, p_data[0]);
nandc_wait_flash_ready(cs);
nandc_flash_cs(cs);
flash_prog_first_cmd(cs, page_addr);
nandc_xfer_data(cs, NANDC_WRITE, sec_per_page, p_data, p_spare);
flash_prog_second_cmd(cs, page_addr);
nandc_wait_flash_ready(cs);
status = flash_read_status(cs, page_addr);
nandc_flash_de_cs(cs);
status &= 0x01;
if (status)
rkflash_print_info("%s addr=%x status=%x\n",
__func__, page_addr, status);
return status;
}
static u32 flash_erase_block(u8 cs, u32 page_addr)
{
u32 status;
rkflash_print_dio("%s %x\n", __func__, page_addr);
nandc_wait_flash_ready(cs);
nandc_flash_cs(cs);
flash_erase_cmd(cs, page_addr);
nandc_wait_flash_ready(cs);
status = flash_read_status(cs, page_addr);
nandc_flash_de_cs(cs);
status &= 0x01;
if (status)
rkflash_print_info("%s pageadd=%x status=%x\n",
__func__, page_addr, status);
return status;
}
static void flash_read_spare(u8 cs, u32 page_addr, u8 *spare)
{
u32 col = nand_para.sec_per_page << 9;
nandc_writel(READ_CMD >> 8, NANDC_CHIP_CMD(cs));
nandc_writel(col, NANDC_CHIP_ADDR(cs));
nandc_writel(col >> 8, NANDC_CHIP_ADDR(cs));
nandc_writel(page_addr & 0x00ff, NANDC_CHIP_ADDR(cs));
nandc_writel(page_addr >> 8, NANDC_CHIP_ADDR(cs));
nandc_writel(page_addr >> 16, NANDC_CHIP_ADDR(cs));
nandc_writel(READ_CMD & 0x00ff, NANDC_CHIP_CMD(cs));
nandc_wait_flash_ready(cs);
*spare = nandc_readl(NANDC_CHIP_DATA(cs));
}
/*
* Read the 1st page's 1st spare byte of a phy_blk
* If not FF, it's bad blk
*/
static s32 flash_get_bad_blk_list(u16 *table, u32 die)
{
u16 blk;
u32 bad_cnt, page_addr0, page_addr1, page_addr2;
u32 blk_per_die;
u8 bad_flag0, bad_flag1, bad_flag2;
bad_cnt = 0;
blk_per_die = nand_para.plane_per_die * nand_para.blk_per_plane;
for (blk = 0; blk < blk_per_die; blk++) {
bad_flag0 = 0xFF;
bad_flag1 = 0xFF;
bad_flag2 = 0xFF;
page_addr0 = (blk + blk_per_die * die) *
nand_para.page_per_blk + 0;
page_addr1 = page_addr0 + 1;
page_addr2 = page_addr0 + nand_para.page_per_blk - 1;
flash_read_spare(die, page_addr0, &bad_flag0);
flash_read_spare(die, page_addr1, &bad_flag1);
flash_read_spare(die, page_addr2, &bad_flag2);
if (bad_flag0 != 0xFF ||
bad_flag1 != 0xFF ||
bad_flag2 != 0xFF) {
table[bad_cnt++] = blk;
rkflash_print_error("die[%d], bad_blk[%d]\n", die, blk);
}
}
return bad_cnt;
}
static void flash_die_info_init(void)
{
u32 cs;
g_nand_max_die = 0;
for (cs = 0; cs < MAX_FLASH_NUM; cs++) {
if (nand_para.nand_id[1] == id_byte[cs][1]) {
die_cs_index[g_nand_max_die] = cs;
g_nand_max_die++;
}
}
g_totle_block = g_nand_max_die * nand_para.plane_per_die *
nand_para.blk_per_plane;
}
static void flash_show_info(void)
{
rkflash_print_info("No.0 FLASH ID: %x %x %x %x %x %x\n",
nand_para.nand_id[0],
nand_para.nand_id[1],
nand_para.nand_id[2],
nand_para.nand_id[3],
nand_para.nand_id[4],
nand_para.nand_id[5]);
rkflash_print_info("die_per_chip: %x\n", nand_para.die_per_chip);
rkflash_print_info("sec_per_page: %x\n", nand_para.sec_per_page);
rkflash_print_info("page_per_blk: %x\n", nand_para.page_per_blk);
rkflash_print_info("cell: %x\n", nand_para.cell);
rkflash_print_info("plane_per_die: %x\n", nand_para.plane_per_die);
rkflash_print_info("blk_per_plane: %x\n", nand_para.blk_per_plane);
rkflash_print_info("TotleBlock: %x\n", g_totle_block);
rkflash_print_info("die gap: %x\n", nand_para.die_gap);
rkflash_print_info("lsb_mode: %x\n", nand_para.lsb_mode);
rkflash_print_info("read_retry_mode: %x\n", nand_para.read_retry_mode);
rkflash_print_info("ecc_bits: %x\n", nand_para.ecc_bits);
rkflash_print_info("Use ecc_bits: %x\n", g_nand_flash_ecc_bits);
rkflash_print_info("access_freq: %x\n", nand_para.access_freq);
rkflash_print_info("opt_mode: %x\n", nand_para.opt_mode);
rkflash_print_info("Cache read enable: %x\n",
nand_para.operation_opt & NAND_CACHE_READ_EN ? 1 : 0);
rkflash_print_info("Cache random read enable: %x\n",
nand_para.operation_opt &
NAND_CACHE_RANDOM_READ_EN ? 1 : 0);
rkflash_print_info("Cache prog enable: %x\n",
nand_para.operation_opt & NAND_CACHE_PROG_EN ? 1 : 0);
rkflash_print_info("multi read enable: %x\n",
nand_para.operation_opt & NAND_MULTI_READ_EN ? 1 : 0);
rkflash_print_info("multi prog enable: %x\n",
nand_para.operation_opt & NAND_MULTI_PROG_EN ? 1 : 0);
rkflash_print_info("interleave enable: %x\n",
nand_para.operation_opt & NAND_INTERLEAVE_EN ? 1 : 0);
rkflash_print_info("read retry enable: %x\n",
nand_para.operation_opt & NAND_READ_RETRY_EN ? 1 : 0);
rkflash_print_info("randomizer enable: %x\n",
nand_para.operation_opt & NAND_RANDOMIZER_EN ? 1 : 0);
rkflash_print_info("SDR enable: %x\n",
nand_para.operation_opt & NAND_SDR_EN ? 1 : 0);
rkflash_print_info("ONFI enable: %x\n",
nand_para.operation_opt & NAND_ONFI_EN ? 1 : 0);
rkflash_print_info("TOGGLE enable: %x\n",
nand_para.operation_opt & NAND_TOGGLE_EN ? 1 : 0);
rkflash_print_info("g_nand_idb_res_blk_num: %x\n", g_nand_idb_res_blk_num);
}
static void flash_ftl_ops_init(void)
{
u8 nandc_ver = nandc_get_version();
/* para init */
g_nand_phy_info.nand_type = nand_para.cell;
g_nand_phy_info.die_num = nand_para.die_per_chip;
g_nand_phy_info.plane_per_die = nand_para.plane_per_die;
g_nand_phy_info.blk_per_plane = nand_para.blk_per_plane;
g_nand_phy_info.page_per_blk = nand_para.page_per_blk;
g_nand_phy_info.page_per_slc_blk = nand_para.page_per_blk /
nand_para.cell;
g_nand_phy_info.byte_per_sec = 512;
g_nand_phy_info.sec_per_page = nand_para.sec_per_page;
g_nand_phy_info.sec_per_blk = nand_para.sec_per_page *
nand_para.page_per_blk;
g_nand_phy_info.reserved_blk = 8;
g_nand_phy_info.blk_per_die = nand_para.plane_per_die *
nand_para.blk_per_plane;
g_nand_phy_info.ecc_bits = nand_para.ecc_bits;
/* driver register */
g_nand_ops.get_bad_blk_list = flash_get_bad_blk_list;
g_nand_ops.erase_blk = flash_erase_block;
g_nand_ops.prog_page = flash_prog_page;
g_nand_ops.read_page = flash_read_page;
if (nandc_ver == 9) {
g_nand_ops.bch_sel = flash_bch_sel;
g_nand_ops.set_sec_num = flash_set_sector;
}
}
void nandc_flash_reset(u8 cs)
{
nandc_flash_cs(cs);
nandc_writel(RESET_CMD, NANDC_CHIP_CMD(cs));
nandc_wait_flash_ready(cs);
nandc_flash_de_cs(cs);
}
u32 nandc_flash_init(void __iomem *nandc_addr)
{
u32 cs;
rkflash_print_error("...%s enter...\n", __func__);
g_nand_idb_res_blk_num = MAX_IDB_RESERVED_BLOCK;
g_nand_ecc_en = 0;
nandc_init(nandc_addr);
for (cs = 0; cs < MAX_FLASH_NUM; cs++) {
flash_read_id_raw(cs, id_byte[cs]);
if (cs == 0) {
if (id_byte[0][0] == 0xFF ||
id_byte[0][0] == 0 ||
id_byte[0][1] == 0xFF)
return FTL_NO_FLASH;
if (id_byte[0][1] != 0xF1 &&
id_byte[0][1] != 0xDA &&
id_byte[0][1] != 0xD1 &&
id_byte[0][1] != 0x95 &&
id_byte[0][1] != 0xDC &&
id_byte[0][1] != 0xD3 &&
id_byte[0][1] != 0x48 &&
id_byte[0][1] != 0xA1 &&
id_byte[0][1] != 0xAA &&
id_byte[0][1] != 0xAC &&
id_byte[0][1] != 0x6A) {
pr_err("The device not support yet!\n");
return FTL_UNSUPPORTED_FLASH;
}
}
}
if (id_byte[0][0] == 0x98 && (id_byte[0][4] & 0x80))
g_nand_ecc_en = 1;
nand_para.nand_id[1] = id_byte[0][1];
if (id_byte[0][1] == 0xDA || id_byte[0][1] == 0xAA || id_byte[0][1] == 0x6A) {
nand_para.plane_per_die = 2;
nand_para.nand_id[1] = id_byte[0][1];
} else if (id_byte[0][1] == 0xDC || id_byte[0][1] == 0xAC) {
nand_para.nand_id[1] = id_byte[0][1];
if ((id_byte[0][0] == 0x2C && id_byte[0][3] == 0xA6) ||
(id_byte[0][0] == 0xC2 && id_byte[0][3] == 0xA2)) {
nand_para.plane_per_die = 2;
nand_para.sec_per_page = 8;
} else if ((id_byte[0][0] == 0x98 && id_byte[0][3] == 0x26) ||
(id_byte[0][0] == 0xC8 && ((id_byte[0][3] & 0x3) == 1))) {
nand_para.blk_per_plane = 1024;
nand_para.sec_per_page = 8;
nand_para.plane_per_die = 2;
} else {
nand_para.plane_per_die = 2;
nand_para.blk_per_plane = 2048;
}
} else if (id_byte[0][1] == 0x48) {
nand_para.sec_per_page = 8;
nand_para.page_per_blk = 128;
nand_para.plane_per_die = 2;
nand_para.blk_per_plane = 2048;
} else if (id_byte[0][1] == 0xD3) {
nand_para.sec_per_page = 8;
nand_para.page_per_blk = 64;
nand_para.plane_per_die = 2;
nand_para.blk_per_plane = 2048;
}
flash_die_info_init();
flash_bch_sel(nand_para.ecc_bits);
flash_show_info();
flash_ftl_ops_init();
return 0;
}
void nandc_flash_get_id(u8 cs, void *buf)
{
memcpy(buf, id_byte[cs], 5);
}
u32 nandc_flash_deinit(void)
{
return 0;
}
Orange Pi5 kernel
Deprecated Linux kernel 5.10.110 for OrangePi 5/5B/5+ boards
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