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/*
* This file is part of the flashrom project.
*
* Copyright (C) 2014 Google LLC.
*
* This program is free software; you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation; either version 2 of the License, or
* (at your option) any later version.
*
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*/
/*
* s25f.c - Helper functions for Spansion S25FL and S25FS SPI flash chips.
* Uses 24 bit addressing for the FS chips and 32 bit addressing for the FL
* chips (which is required by the overlayed sector size devices).
* TODO: Implement fancy hybrid sector architecture helpers.
*/
#include <string.h>
#include "chipdrivers.h"
#include "spi.h"
/*
* RDAR and WRAR are supported on chips which have more than one set of status
* and control registers and take an address of the register to read/write.
* WRR, RDSR2, and RDCR are used on chips with a more limited set of control/
* status registers.
*
* WRR is somewhat peculiar. It shares the same opcode as JEDEC_WRSR, and if
* given one data byte (following the opcode) it acts the same way. If it's
* given two data bytes, the first data byte overwrites status register 1
* and the second data byte overwrites config register 1.
*/
#define CMD_WRR 0x01
#define CMD_WRDI 0x04
#define CMD_RDSR2 0x07 /* note: read SR1 with JEDEC RDSR opcode */
#define CMD_RDCR 0x35
#define CMD_RDAR 0x65
#define CMD_WRAR 0x71
/* TODO: For now, commands which use an address assume 24-bit addressing */
#define CMD_WRR_LEN 3
#define CMD_WRDI_LEN 1
#define CMD_RDAR_LEN 4
#define CMD_WRAR_LEN 5
#define CMD_RSTEN 0x66
#define CMD_RST 0x99
#define CR1NV_ADDR 0x000002
#define CR1_BPNV_O (1 << 3)
#define CR1_TBPROT_O (1 << 5)
#define CR3NV_ADDR 0x000004
#define CR3NV_20H_NV (1 << 3)
/* See "Embedded Algorithm Performance Tables for additional timing specs. */
#define T_W 145 * 1000 /* NV register write time (145ms) */
#define T_RPH 35 /* Reset pulse hold time (35us) */
#define S25FS_T_SE 145 * 1000 /* Sector Erase Time (145ms) */
#define S25FL_T_SE 130 * 1000 /* Sector Erase Time (130ms) */
static int s25f_legacy_software_reset(const struct flashctx *flash)
{
struct spi_command cmds[] = {
{
.writecnt = 1,
.writearr = (const uint8_t[]){ CMD_RSTEN },
.readcnt = 0,
.readarr = NULL,
}, {
.writecnt = 1,
.writearr = (const uint8_t[]){ 0xf0 },
.readcnt = 0,
.readarr = NULL,
}, {
.writecnt = 0,
.writearr = NULL,
.readcnt = 0,
.readarr = NULL,
}};
int result = spi_send_multicommand(flash, cmds);
if (result) {
msg_cerr("%s failed during command execution\n", __func__);
return result;
}
/* Allow time for reset command to execute. The datasheet specifies
* Trph = 35us, double that to be safe. */
programmer_delay(T_RPH * 2);
return 0;
}
/* "Legacy software reset" is disabled by default on S25FS, use this instead. */
static int s25fs_software_reset(struct flashctx *flash)
{
struct spi_command cmds[] = {
{
.writecnt = 1,
.writearr = (const uint8_t[]){ CMD_RSTEN },
.readcnt = 0,
.readarr = NULL,
}, {
.writecnt = 1,
.writearr = (const uint8_t[]){ CMD_RST },
.readcnt = 0,
.readarr = NULL,
}, {
.writecnt = 0,
.writearr = NULL,
.readcnt = 0,
.readarr = NULL,
}};
int result = spi_send_multicommand(flash, cmds);
if (result) {
msg_cerr("%s failed during command execution\n", __func__);
return result;
}
/* Allow time for reset command to execute. Double tRPH to be safe. */
programmer_delay(T_RPH * 2);
return 0;
}
static int s25f_poll_status(const struct flashctx *flash)
{
while (true) {
uint8_t tmp;
if (spi_read_register(flash, STATUS1, &tmp))
return -1;
if ((tmp & SPI_SR_WIP) == 0)
break;
/*
* The WIP bit on S25F chips remains set to 1 if erase or
* programming errors occur, so we must check for those
* errors here. If an error is encountered, do a software
* reset to clear WIP and other volatile bits, otherwise
* the chip will be unresponsive to further commands.
*/
if (tmp & SPI_SR_ERA_ERR) {
msg_cerr("Erase error occurred\n");
s25f_legacy_software_reset(flash);
return -1;
}
if (tmp & (1 << 6)) {
msg_cerr("Programming error occurred\n");
s25f_legacy_software_reset(flash);
return -1;
}
programmer_delay(1000 * 10);
}
return 0;
}
/* "Read Any Register" instruction only supported on S25FS */
static int s25fs_read_cr(const struct flashctx *flash, uint32_t addr)
{
uint8_t cfg;
/* By default, 8 dummy cycles are necessary for variable-latency
commands such as RDAR (see CR2NV[3:0]). */
uint8_t read_cr_cmd[] = {
CMD_RDAR,
(addr >> 16) & 0xff,
(addr >> 8) & 0xff,
(addr & 0xff),
0x00, 0x00, 0x00, 0x00,
0x00, 0x00, 0x00, 0x00,
};
int result = spi_send_command(flash, sizeof(read_cr_cmd), 1, read_cr_cmd, &cfg);
if (result) {
msg_cerr("%s failed during command execution at address 0x%x\n",
__func__, addr);
return -1;
}
return cfg;
}
/* "Write Any Register" instruction only supported on S25FS */
static int s25fs_write_cr(const struct flashctx *flash,
uint32_t addr, uint8_t data)
{
struct spi_command cmds[] = {
{
.writecnt = JEDEC_WREN_OUTSIZE,
.writearr = (const uint8_t[]){ JEDEC_WREN },
.readcnt = 0,
.readarr = NULL,
}, {
.writecnt = CMD_WRAR_LEN,
.writearr = (const uint8_t[]){
CMD_WRAR,
(addr >> 16) & 0xff,
(addr >> 8) & 0xff,
(addr & 0xff),
data
},
.readcnt = 0,
.readarr = NULL,
}, {
.writecnt = 0,
.writearr = NULL,
.readcnt = 0,
.readarr = NULL,
}};
int result = spi_send_multicommand(flash, cmds);
if (result) {
msg_cerr("%s failed during command execution at address 0x%x\n",
__func__, addr);
return -1;
}
programmer_delay(T_W);
return s25f_poll_status(flash);
}
static int s25fs_restore_cr3nv(struct flashctx *flash, uint8_t cfg)
{
int ret = 0;
msg_cdbg("Restoring CR3NV value to 0x%02x\n", cfg);
ret |= s25fs_write_cr(flash, CR3NV_ADDR, cfg);
ret |= s25fs_software_reset(flash);
return ret;
}
int s25fs_block_erase_d8(struct flashctx *flash, unsigned int addr, unsigned int blocklen)
{
static int cr3nv_checked = 0;
struct spi_command erase_cmds[] = {
{
.writecnt = JEDEC_WREN_OUTSIZE,
.writearr = (const uint8_t[]){ JEDEC_WREN },
.readcnt = 0,
.readarr = NULL,
}, {
.writecnt = JEDEC_BE_D8_OUTSIZE,
.writearr = (const uint8_t[]){
JEDEC_BE_D8,
(addr >> 16) & 0xff,
(addr >> 8) & 0xff,
(addr & 0xff)
},
.readcnt = 0,
.readarr = NULL,
}, {
.writecnt = 0,
.writearr = NULL,
.readcnt = 0,
.readarr = NULL,
}};
/* Check if hybrid sector architecture is in use and, if so,
* switch to uniform sectors. */
if (!cr3nv_checked) {
uint8_t cfg = s25fs_read_cr(flash, CR3NV_ADDR);
if (!(cfg & CR3NV_20H_NV)) {
s25fs_write_cr(flash, CR3NV_ADDR, cfg | CR3NV_20H_NV);
s25fs_software_reset(flash);
cfg = s25fs_read_cr(flash, CR3NV_ADDR);
if (!(cfg & CR3NV_20H_NV)) {
msg_cerr("%s: Unable to enable uniform "
"block sizes.\n", __func__);
return 1;
}
msg_cdbg("\n%s: CR3NV updated (0x%02x -> 0x%02x)\n",
__func__, cfg,
s25fs_read_cr(flash, CR3NV_ADDR));
/* Restore CR3V when flashrom exits */
register_chip_restore(s25fs_restore_cr3nv, flash, cfg);
}
cr3nv_checked = 1;
}
int result = spi_send_multicommand(flash, erase_cmds);
if (result) {
msg_cerr("%s failed during command execution at address 0x%x\n",
__func__, addr);
return result;
}
programmer_delay(S25FS_T_SE);
return s25f_poll_status(flash);
}
int s25fl_block_erase(struct flashctx *flash, unsigned int addr, unsigned int blocklen)
{
struct spi_command erase_cmds[] = {
{
.writecnt = JEDEC_WREN_OUTSIZE,
.writearr = (const uint8_t[]){
JEDEC_WREN
},
.readcnt = 0,
.readarr = NULL,
}, {
.writecnt = JEDEC_BE_DC_OUTSIZE,
.writearr = (const uint8_t[]){
JEDEC_BE_DC,
(addr >> 24) & 0xff,
(addr >> 16) & 0xff,
(addr >> 8) & 0xff,
(addr & 0xff)
},
.readcnt = 0,
.readarr = NULL,
}, {
.writecnt = 0,
.readcnt = 0,
}
};
int result = spi_send_multicommand(flash, erase_cmds);
if (result) {
msg_cerr("%s failed during command execution at address 0x%x\n",
__func__, addr);
return result;
}
programmer_delay(S25FL_T_SE);
return s25f_poll_status(flash);
}
int probe_spi_big_spansion(struct flashctx *flash)
{
uint8_t cmd = JEDEC_RDID;
uint8_t dev_id[6]; /* We care only about 6 first bytes */
if (spi_send_command(flash, sizeof(cmd), sizeof(dev_id), &cmd, dev_id))
return 0;
msg_gdbg("Read id bytes: ");
for (size_t i = 0; i < sizeof(dev_id); i++)
msg_gdbg(" 0x%02x", dev_id[i]);
msg_gdbg(".\n");
/*
* The structure of the RDID output is as follows:
*
* offset value meaning
* 00h 01h Manufacturer ID for Spansion
* 01h 20h 128 Mb capacity
* 01h 02h 256 Mb capacity
* 02h 18h 128 Mb capacity
* 02h 19h 256 Mb capacity
* 03h 4Dh Full size of the RDID output (ignored)
* 04h 00h FS: 256-kB physical sectors
* 04h 01h FS: 64-kB physical sectors
* 04h 00h FL: 256-kB physical sectors
* 04h 01h FL: Mix of 64-kB and 4KB overlayed sectors
* 05h 80h FL family
* 05h 81h FS family
*
* Need to use bytes 1, 2, 4, and 5 to properly identify one of eight
* possible chips:
*
* 2 types * 2 possible sizes * 2 possible sector layouts
*
*/
uint32_t model_id =
dev_id[1] << 24 |
dev_id[2] << 16 |
dev_id[4] << 8 |
dev_id[5] << 0;
if (dev_id[0] == flash->chip->manufacture_id && model_id == flash->chip->model_id)
return 1;
return 0;
}
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