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u-boot/board/toradex/common/tdx-cfg-block.c
Francesco Dolcini 4f0c33c46d toradex: tdx-cfg-block: Use official SKU names 
Up to now in the code we named Toradex SKUs in a slightly different way
compared to the official product name, start using the official names
from now on to avoid misunderstanding.

This has also the nice benefit of the string being shorter, allowing
to fit nicely in 80 columns even adding the product ID when printing
the hardware information.

Signed-off-by: Francesco Dolcini <francesco.dolcini@toradex.com>
2022-07-25 16:12:00 +02:00

903 lines
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// SPDX-License-Identifier: GPL-2.0+
/*
* Copyright (c) 2016-2020 Toradex
*/
#include <common.h>
#include <asm/global_data.h>
#include "tdx-cfg-block.h"
#include "tdx-eeprom.h"
#include <command.h>
#include <asm/cache.h>
#include <cli.h>
#include <console.h>
#include <env.h>
#include <flash.h>
#include <malloc.h>
#include <mmc.h>
#include <nand.h>
#include <asm/mach-types.h>
DECLARE_GLOBAL_DATA_PTR;
#define TAG_VALID 0xcf01
#define TAG_MAC 0x0000
#define TAG_CAR_SERIAL 0x0021
#define TAG_HW 0x0008
#define TAG_INVALID 0xffff
#define TAG_FLAG_VALID 0x1
#define TDX_EEPROM_ID_MODULE 0
#define TDX_EEPROM_ID_CARRIER 1
#if defined(CONFIG_TDX_CFG_BLOCK_IS_IN_MMC)
#define TDX_CFG_BLOCK_MAX_SIZE 512
#elif defined(CONFIG_TDX_CFG_BLOCK_IS_IN_NAND)
#define TDX_CFG_BLOCK_MAX_SIZE 64
#elif defined(CONFIG_TDX_CFG_BLOCK_IS_IN_NOR)
#define TDX_CFG_BLOCK_MAX_SIZE 64
#elif defined(CONFIG_TDX_CFG_BLOCK_IS_IN_EEPROM)
#define TDX_CFG_BLOCK_MAX_SIZE 64
#else
#error Toradex config block location not set
#endif
#ifdef CONFIG_TDX_CFG_BLOCK_EXTRA
#define TDX_CFG_BLOCK_EXTRA_MAX_SIZE 64
#endif
struct toradex_tag {
u32 len:14;
u32 flags:2;
u32 id:16;
};
bool valid_cfgblock;
struct toradex_hw tdx_hw_tag;
struct toradex_eth_addr tdx_eth_addr;
u32 tdx_serial;
#ifdef CONFIG_TDX_CFG_BLOCK_EXTRA
u32 tdx_car_serial;
bool valid_cfgblock_carrier;
struct toradex_hw tdx_car_hw_tag;
#endif
#define TARGET_IS_ENABLED(x) IS_ENABLED(CONFIG_TARGET_ ## x)
const struct toradex_som toradex_modules[] = {
[0] = { "UNKNOWN MODULE", 0 },
[1] = { "Colibri PXA270 312MHz", 0 },
[2] = { "Colibri PXA270 520MHz", 0 },
[3] = { "Colibri PXA320 806MHz", 0 },
[4] = { "Colibri PXA300 208MHz", 0 },
[5] = { "Colibri PXA310 624MHz", 0 },
[6] = { "Colibri PXA320IT 806MHz", 0 },
[7] = { "Colibri PXA300 208MHz XT", 0 },
[8] = { "Colibri PXA270 312MHz", 0 },
[9] = { "Colibri PXA270 520MHz", 0 },
[10] = { "Colibri VF50 128MB", TARGET_IS_ENABLED(COLIBRI_VF) },
[11] = { "Colibri VF61 256MB", TARGET_IS_ENABLED(COLIBRI_VF) },
[12] = { "Colibri VF61 256MB IT", TARGET_IS_ENABLED(COLIBRI_VF) },
[13] = { "Colibri VF50 128MB IT", TARGET_IS_ENABLED(COLIBRI_VF) },
[14] = { "Colibri iMX6S 256MB", TARGET_IS_ENABLED(COLIBRI_IMX6) },
[15] = { "Colibri iMX6DL 512MB", TARGET_IS_ENABLED(COLIBRI_IMX6) },
[16] = { "Colibri iMX6S 256MB IT", TARGET_IS_ENABLED(COLIBRI_IMX6) },
[17] = { "Colibri iMX6DL 512MB IT", TARGET_IS_ENABLED(COLIBRI_IMX6) },
[18] = { "UNKNOWN MODULE", 0 },
[19] = { "UNKNOWN MODULE", 0 },
[20] = { "Colibri T20 256MB", TARGET_IS_ENABLED(COLIBRI_T20) },
[21] = { "Colibri T20 512MB", TARGET_IS_ENABLED(COLIBRI_T20) },
[22] = { "Colibri T20 512MB IT", TARGET_IS_ENABLED(COLIBRI_T20) },
[23] = { "Colibri T30 1GB", TARGET_IS_ENABLED(COLIBRI_T30) },
[24] = { "Colibri T20 256MB IT", TARGET_IS_ENABLED(COLIBRI_T20) },
[25] = { "Apalis T30 2GB", TARGET_IS_ENABLED(APALIS_T30) },
[26] = { "Apalis T30 1GB", TARGET_IS_ENABLED(APALIS_T30) },
[27] = { "Apalis iMX6Q 1GB", TARGET_IS_ENABLED(APALIS_IMX6) },
[28] = { "Apalis iMX6Q 2GB IT", TARGET_IS_ENABLED(APALIS_IMX6) },
[29] = { "Apalis iMX6D 512MB", TARGET_IS_ENABLED(APALIS_IMX6) },
[30] = { "Colibri T30 1GB IT", TARGET_IS_ENABLED(COLIBRI_T30) },
[31] = { "Apalis T30 1GB IT", TARGET_IS_ENABLED(APALIS_T30) },
[32] = { "Colibri iMX7S 256MB", TARGET_IS_ENABLED(COLIBRI_IMX7) },
[33] = { "Colibri iMX7D 512MB", TARGET_IS_ENABLED(COLIBRI_IMX7) },
[34] = { "Apalis TK1 2GB", TARGET_IS_ENABLED(APALIS_TK1) },
[35] = { "Apalis iMX6D 1GB IT", TARGET_IS_ENABLED(APALIS_IMX6) },
[36] = { "Colibri iMX6ULL 256MB", TARGET_IS_ENABLED(COLIBRI_IMX6ULL) },
[37] = { "Apalis iMX8QM 4GB WB IT", TARGET_IS_ENABLED(APALIS_IMX8) },
[38] = { "Colibri iMX8QXP 2GB WB IT", TARGET_IS_ENABLED(COLIBRI_IMX8X) },
[39] = { "Colibri iMX7D 1GB", TARGET_IS_ENABLED(COLIBRI_IMX7) },
[40] = { "Colibri iMX6ULL 512MB WB IT", TARGET_IS_ENABLED(COLIBRI_IMX6ULL) },
[41] = { "Colibri iMX7D 512MB EPDC", TARGET_IS_ENABLED(COLIBRI_IMX7) },
[42] = { "Apalis TK1 4GB", TARGET_IS_ENABLED(APALIS_TK1) },
[43] = { "Colibri T20 512MB IT SETEK", TARGET_IS_ENABLED(COLIBRI_T20) },
[44] = { "Colibri iMX6ULL 512MB IT", TARGET_IS_ENABLED(COLIBRI_IMX6ULL) },
[45] = { "Colibri iMX6ULL 512MB WB", TARGET_IS_ENABLED(COLIBRI_IMX6ULL) },
[46] = { "Apalis iMX8QXP 2GB WB IT", 0 },
[47] = { "Apalis iMX8QM 4GB IT", TARGET_IS_ENABLED(APALIS_IMX8) },
[48] = { "Apalis iMX8QP 2GB WB", TARGET_IS_ENABLED(APALIS_IMX8) },
[49] = { "Apalis iMX8QP 2GB", TARGET_IS_ENABLED(APALIS_IMX8) },
[50] = { "Colibri iMX8QXP 2GB IT", TARGET_IS_ENABLED(COLIBRI_IMX8X) },
[51] = { "Colibri iMX8DX 1GB WB", TARGET_IS_ENABLED(COLIBRI_IMX8X) },
[52] = { "Colibri iMX8DX 1GB", TARGET_IS_ENABLED(COLIBRI_IMX8X) },
[53] = { "Apalis iMX8QXP 2GB ECC IT", 0 },
[54] = { "Apalis iMX8DXP 1GB", TARGET_IS_ENABLED(APALIS_IMX8) },
[55] = { "Verdin iMX8M Mini Quad 2GB WB IT", TARGET_IS_ENABLED(VERDIN_IMX8MM) },
[56] = { "Verdin iMX8M Nano Quad 1GB WB", 0 },
[57] = { "Verdin iMX8M Mini DualLite 1GB", TARGET_IS_ENABLED(VERDIN_IMX8MM) },
[58] = { "Verdin iMX8M Plus Quad 4GB WB IT", TARGET_IS_ENABLED(VERDIN_IMX8MP) },
[59] = { "Verdin iMX8M Mini Quad 2GB IT", TARGET_IS_ENABLED(VERDIN_IMX8MM) },
[60] = { "Verdin iMX8M Mini DualLite 1GB WB IT", TARGET_IS_ENABLED(VERDIN_IMX8MM) },
[61] = { "Verdin iMX8M Plus Quad 2GB", TARGET_IS_ENABLED(VERDIN_IMX8MP) },
[62] = { "Colibri iMX6ULL 1GB IT", TARGET_IS_ENABLED(COLIBRI_IMX6ULL) },
[63] = { "Verdin iMX8M Plus Quad 4GB IT", TARGET_IS_ENABLED(VERDIN_IMX8MP) },
[64] = { "Verdin iMX8M Plus Quad 2GB WB IT", TARGET_IS_ENABLED(VERDIN_IMX8MP) },
[65] = { "Verdin iMX8M Plus QuadLite 1GB IT", TARGET_IS_ENABLED(VERDIN_IMX8MP) },
[66] = { "Verdin iMX8M Plus Quad 8GB WB", TARGET_IS_ENABLED(VERDIN_IMX8MP) },
[67] = { "Apalis iMX8QM 8GB WB IT", TARGET_IS_ENABLED(APALIS_IMX8) },
[68] = { "Verdin iMX8M Mini Quad 2GB WB IT", TARGET_IS_ENABLED(VERDIN_IMX8MM) },
};
const char * const toradex_carrier_boards[] = {
[0] = "UNKNOWN CARRIER BOARD",
[155] = "Dahlia",
[156] = "Verdin Development Board",
};
const char * const toradex_display_adapters[] = {
[0] = "UNKNOWN DISPLAY ADAPTER",
[157] = "Verdin DSI to HDMI Adapter",
[159] = "Verdin DSI to LVDS Adapter",
};
const u32 toradex_ouis[] = {
[0] = 0x00142dUL,
[1] = 0x8c06cbUL,
};
static u32 get_serial_from_mac(struct toradex_eth_addr *eth_addr)
{
int i;
u32 oui = ntohl(eth_addr->oui) >> 8;
u32 nic = ntohl(eth_addr->nic) >> 8;
for (i = 0; i < ARRAY_SIZE(toradex_ouis); i++) {
if (toradex_ouis[i] == oui)
break;
}
return (u32)((i << 24) + nic);
}
void get_mac_from_serial(u32 tdx_serial, struct toradex_eth_addr *eth_addr)
{
u8 oui_index = tdx_serial >> 24;
u32 nic = tdx_serial & GENMASK(23, 0);
u32 oui;
if (oui_index >= ARRAY_SIZE(toradex_ouis)) {
puts("Can't find OUI for this serial#\n");
oui_index = 0;
}
oui = toradex_ouis[oui_index];
eth_addr->oui = htonl(oui << 8);
eth_addr->nic = htonl(nic << 8);
}
#ifdef CONFIG_TDX_CFG_BLOCK_IS_IN_MMC
static int tdx_cfg_block_mmc_storage(u8 *config_block, int write)
{
struct mmc *mmc;
int dev = CONFIG_TDX_CFG_BLOCK_DEV;
int offset = CONFIG_TDX_CFG_BLOCK_OFFSET;
uint part = CONFIG_TDX_CFG_BLOCK_PART;
uint blk_start;
int ret = 0;
/* Read production parameter config block from eMMC */
mmc = find_mmc_device(dev);
if (!mmc) {
puts("No MMC card found\n");
ret = -ENODEV;
goto out;
}
if (mmc_init(mmc)) {
puts("MMC init failed\n");
return -EINVAL;
}
if (part != mmc_get_blk_desc(mmc)->hwpart) {
if (blk_select_hwpart_devnum(IF_TYPE_MMC, dev, part)) {
puts("MMC partition switch failed\n");
ret = -ENODEV;
goto out;
}
}
if (offset < 0)
offset += mmc->capacity;
blk_start = ALIGN(offset, mmc->write_bl_len) / mmc->write_bl_len;
if (!write) {
/* Careful reads a whole block of 512 bytes into config_block */
if (blk_dread(mmc_get_blk_desc(mmc), blk_start, 1,
(unsigned char *)config_block) != 1) {
ret = -EIO;
goto out;
}
} else {
/* Just writing one 512 byte block */
if (blk_dwrite(mmc_get_blk_desc(mmc), blk_start, 1,
(unsigned char *)config_block) != 1) {
ret = -EIO;
goto out;
}
}
out:
/* Switch back to regular eMMC user partition */
blk_select_hwpart_devnum(IF_TYPE_MMC, 0, 0);
return ret;
}
#endif
#ifdef CONFIG_TDX_CFG_BLOCK_IS_IN_NAND
static int read_tdx_cfg_block_from_nand(unsigned char *config_block)
{
size_t size = TDX_CFG_BLOCK_MAX_SIZE;
struct mtd_info *mtd = get_nand_dev_by_index(0);
if (!mtd)
return -ENODEV;
/* Read production parameter config block from NAND page */
return nand_read_skip_bad(mtd, CONFIG_TDX_CFG_BLOCK_OFFSET,
&size, NULL, TDX_CFG_BLOCK_MAX_SIZE,
config_block);
}
static int write_tdx_cfg_block_to_nand(unsigned char *config_block)
{
size_t size = TDX_CFG_BLOCK_MAX_SIZE;
/* Write production parameter config block to NAND page */
return nand_write_skip_bad(get_nand_dev_by_index(0),
CONFIG_TDX_CFG_BLOCK_OFFSET,
&size, NULL, TDX_CFG_BLOCK_MAX_SIZE,
config_block, WITH_WR_VERIFY);
}
#endif
#ifdef CONFIG_TDX_CFG_BLOCK_IS_IN_NOR
static int read_tdx_cfg_block_from_nor(unsigned char *config_block)
{
/* Read production parameter config block from NOR flash */
memcpy(config_block, (void *)CONFIG_TDX_CFG_BLOCK_OFFSET,
TDX_CFG_BLOCK_MAX_SIZE);
return 0;
}
static int write_tdx_cfg_block_to_nor(unsigned char *config_block)
{
/* Write production parameter config block to NOR flash */
return flash_write((void *)config_block, CONFIG_TDX_CFG_BLOCK_OFFSET,
TDX_CFG_BLOCK_MAX_SIZE);
}
#endif
#ifdef CONFIG_TDX_CFG_BLOCK_IS_IN_EEPROM
static int read_tdx_cfg_block_from_eeprom(unsigned char *config_block)
{
return read_tdx_eeprom_data(TDX_EEPROM_ID_MODULE, 0x0, config_block,
TDX_CFG_BLOCK_MAX_SIZE);
}
static int write_tdx_cfg_block_to_eeprom(unsigned char *config_block)
{
return write_tdx_eeprom_data(TDX_EEPROM_ID_MODULE, 0x0, config_block,
TDX_CFG_BLOCK_MAX_SIZE);
}
#endif
int read_tdx_cfg_block(void)
{
int ret = 0;
u8 *config_block = NULL;
struct toradex_tag *tag;
size_t size = TDX_CFG_BLOCK_MAX_SIZE;
int offset;
/* Allocate RAM area for config block */
config_block = memalign(ARCH_DMA_MINALIGN, size);
if (!config_block) {
printf("Not enough malloc space available!\n");
return -ENOMEM;
}
memset(config_block, 0, size);
#if defined(CONFIG_TDX_CFG_BLOCK_IS_IN_MMC)
ret = tdx_cfg_block_mmc_storage(config_block, 0);
#elif defined(CONFIG_TDX_CFG_BLOCK_IS_IN_NAND)
ret = read_tdx_cfg_block_from_nand(config_block);
#elif defined(CONFIG_TDX_CFG_BLOCK_IS_IN_NOR)
ret = read_tdx_cfg_block_from_nor(config_block);
#elif defined(CONFIG_TDX_CFG_BLOCK_IS_IN_EEPROM)
ret = read_tdx_cfg_block_from_eeprom(config_block);
#else
ret = -EINVAL;
#endif
if (ret)
goto out;
/* Expect a valid tag first */
tag = (struct toradex_tag *)config_block;
if (tag->flags != TAG_FLAG_VALID || tag->id != TAG_VALID) {
valid_cfgblock = false;
ret = -EINVAL;
goto out;
}
valid_cfgblock = true;
offset = 4;
/*
* check if there is enough space for storing tag and value of the
* biggest element
*/
while (offset + sizeof(struct toradex_tag) +
sizeof(struct toradex_hw) < TDX_CFG_BLOCK_MAX_SIZE) {
tag = (struct toradex_tag *)(config_block + offset);
offset += 4;
if (tag->id == TAG_INVALID)
break;
if (tag->flags == TAG_FLAG_VALID) {
switch (tag->id) {
case TAG_MAC:
memcpy(&tdx_eth_addr, config_block + offset,
6);
tdx_serial = get_serial_from_mac(&tdx_eth_addr);
break;
case TAG_HW:
memcpy(&tdx_hw_tag, config_block + offset, 8);
break;
}
}
/* Get to next tag according to current tags length */
offset += tag->len * 4;
}
/* Cap product id to avoid issues with a yet unknown one */
if (tdx_hw_tag.prodid >= ARRAY_SIZE(toradex_modules))
tdx_hw_tag.prodid = 0;
out:
free(config_block);
return ret;
}
static int parse_assembly_string(char *string_to_parse, u16 *assembly)
{
if (string_to_parse[3] >= 'A' && string_to_parse[3] <= 'Z')
*assembly = string_to_parse[3] - 'A';
else if (string_to_parse[3] == '#')
*assembly = dectoul(&string_to_parse[4], NULL);
else
return -EINVAL;
return 0;
}
static int get_cfgblock_interactive(void)
{
char message[CONFIG_SYS_CBSIZE];
int len = 0;
int ret = 0;
unsigned int prodid;
int i;
printf("Enabled modules:\n");
for (i = 0; i < ARRAY_SIZE(toradex_modules); i++) {
if (toradex_modules[i].is_enabled)
printf(" %04d %s\n", i, toradex_modules[i].name);
}
sprintf(message, "Enter the module ID: ");
len = cli_readline(message);
prodid = dectoul(console_buffer, NULL);
if (prodid >= ARRAY_SIZE(toradex_modules) || !toradex_modules[prodid].is_enabled) {
printf("Parsing module id failed\n");
return -1;
}
tdx_hw_tag.prodid = prodid;
len = 0;
while (len < 4) {
sprintf(message, "Enter the module version (e.g. V1.1B or V1.1#26): V");
len = cli_readline(message);
}
tdx_hw_tag.ver_major = console_buffer[0] - '0';
tdx_hw_tag.ver_minor = console_buffer[2] - '0';
ret = parse_assembly_string(console_buffer, &tdx_hw_tag.ver_assembly);
if (ret) {
printf("Parsing module version failed\n");
return ret;
}
while (len < 8) {
sprintf(message, "Enter module serial number: ");
len = cli_readline(message);
}
tdx_serial = dectoul(console_buffer, NULL);
return 0;
}
static int get_cfgblock_barcode(char *barcode, struct toradex_hw *tag,
u32 *serial)
{
char revision[3] = {barcode[6], barcode[7], '\0'};
if (strlen(barcode) < 16) {
printf("Argument too short, barcode is 16 chars long\n");
return -1;
}
/* Get hardware information from the first 8 digits */
tag->ver_major = barcode[4] - '0';
tag->ver_minor = barcode[5] - '0';
tag->ver_assembly = dectoul(revision, NULL);
barcode[4] = '\0';
tag->prodid = dectoul(barcode, NULL);
/* Parse second part of the barcode (serial number */
barcode += 8;
*serial = dectoul(barcode, NULL);
return 0;
}
static int write_tag(u8 *config_block, int *offset, int tag_id,
u8 *tag_data, size_t tag_data_size)
{
struct toradex_tag *tag;
if (!offset || !config_block)
return -EINVAL;
tag = (struct toradex_tag *)(config_block + *offset);
tag->id = tag_id;
tag->flags = TAG_FLAG_VALID;
/* len is provided as number of 32bit values after the tag */
tag->len = (tag_data_size + sizeof(u32) - 1) / sizeof(u32);
*offset += sizeof(struct toradex_tag);
if (tag_data && tag_data_size) {
memcpy(config_block + *offset, tag_data,
tag_data_size);
*offset += tag_data_size;
}
return 0;
}
#ifdef CONFIG_TDX_CFG_BLOCK_EXTRA
int read_tdx_cfg_block_carrier(void)
{
int ret = 0;
u8 *config_block = NULL;
struct toradex_tag *tag;
size_t size = TDX_CFG_BLOCK_EXTRA_MAX_SIZE;
int offset;
/* Allocate RAM area for carrier config block */
config_block = memalign(ARCH_DMA_MINALIGN, size);
if (!config_block) {
printf("Not enough malloc space available!\n");
return -ENOMEM;
}
memset(config_block, 0, size);
ret = read_tdx_eeprom_data(TDX_EEPROM_ID_CARRIER, 0x0, config_block,
size);
if (ret)
return ret;
/* Expect a valid tag first */
tag = (struct toradex_tag *)config_block;
if (tag->flags != TAG_FLAG_VALID || tag->id != TAG_VALID) {
valid_cfgblock_carrier = false;
ret = -EINVAL;
goto out;
}
valid_cfgblock_carrier = true;
offset = 4;
while (offset + sizeof(struct toradex_tag) +
sizeof(struct toradex_hw) < TDX_CFG_BLOCK_MAX_SIZE) {
tag = (struct toradex_tag *)(config_block + offset);
offset += 4;
if (tag->id == TAG_INVALID)
break;
if (tag->flags == TAG_FLAG_VALID) {
switch (tag->id) {
case TAG_CAR_SERIAL:
memcpy(&tdx_car_serial, config_block + offset,
sizeof(tdx_car_serial));
break;
case TAG_HW:
memcpy(&tdx_car_hw_tag, config_block +
offset, 8);
break;
}
}
/* Get to next tag according to current tags length */
offset += tag->len * 4;
}
out:
free(config_block);
return ret;
}
int check_pid8_sanity(char *pid8)
{
char s_carrierid_verdin_dev[5];
char s_carrierid_dahlia[5];
sprintf(s_carrierid_verdin_dev, "0%d", VERDIN_DEVELOPMENT_BOARD);
sprintf(s_carrierid_dahlia, "0%d", DAHLIA);
/* sane value check, first 4 chars which represent carrier id */
if (!strncmp(pid8, s_carrierid_verdin_dev, 4))
return 0;
if (!strncmp(pid8, s_carrierid_dahlia, 4))
return 0;
return -EINVAL;
}
int try_migrate_tdx_cfg_block_carrier(void)
{
char pid8[8];
int offset = 0;
int ret = CMD_RET_SUCCESS;
size_t size = TDX_CFG_BLOCK_EXTRA_MAX_SIZE;
u8 *config_block;
memset(pid8, 0x0, 8);
ret = read_tdx_eeprom_data(TDX_EEPROM_ID_CARRIER, 0x0, (u8 *)pid8, 8);
if (ret)
return ret;
if (check_pid8_sanity(pid8))
return -EINVAL;
/* Allocate RAM area for config block */
config_block = memalign(ARCH_DMA_MINALIGN, size);
if (!config_block) {
printf("Not enough malloc space available!\n");
return CMD_RET_FAILURE;
}
memset(config_block, 0xff, size);
/* we try parse PID8 concatenating zeroed serial number */
tdx_car_hw_tag.ver_major = pid8[4] - '0';
tdx_car_hw_tag.ver_minor = pid8[5] - '0';
tdx_car_hw_tag.ver_assembly = pid8[7] - '0';
pid8[4] = '\0';
tdx_car_hw_tag.prodid = dectoul(pid8, NULL);
/* Valid Tag */
write_tag(config_block, &offset, TAG_VALID, NULL, 0);
/* Product Tag */
write_tag(config_block, &offset, TAG_HW, (u8 *)&tdx_car_hw_tag,
sizeof(tdx_car_hw_tag));
/* Serial Tag */
write_tag(config_block, &offset, TAG_CAR_SERIAL, (u8 *)&tdx_car_serial,
sizeof(tdx_car_serial));
memset(config_block + offset, 0, 32 - offset);
ret = write_tdx_eeprom_data(TDX_EEPROM_ID_CARRIER, 0x0, config_block,
size);
if (ret) {
printf("Failed to write Toradex Extra config block: %d\n",
ret);
ret = CMD_RET_FAILURE;
goto out;
}
printf("Successfully migrated to Toradex Config Block from PID8\n");
out:
free(config_block);
return ret;
}
static int get_cfgblock_carrier_interactive(void)
{
char message[CONFIG_SYS_CBSIZE];
int len;
int ret = 0;
printf("Supported carrier boards:\n");
printf("CARRIER BOARD NAME\t\t [ID]\n");
for (int i = 0; i < ARRAY_SIZE(toradex_carrier_boards); i++)
if (toradex_carrier_boards[i])
printf("%s \t\t [%d]\n", toradex_carrier_boards[i], i);
sprintf(message, "Choose your carrier board (provide ID): ");
len = cli_readline(message);
tdx_car_hw_tag.prodid = dectoul(console_buffer, NULL);
do {
sprintf(message, "Enter carrier board version (e.g. V1.1B or V1.1#26): V");
len = cli_readline(message);
} while (len < 4);
tdx_car_hw_tag.ver_major = console_buffer[0] - '0';
tdx_car_hw_tag.ver_minor = console_buffer[2] - '0';
ret = parse_assembly_string(console_buffer, &tdx_car_hw_tag.ver_assembly);
if (ret) {
printf("Parsing module version failed\n");
return ret;
}
while (len < 8) {
sprintf(message, "Enter carrier board serial number: ");
len = cli_readline(message);
}
tdx_car_serial = dectoul(console_buffer, NULL);
return 0;
}
static int do_cfgblock_carrier_create(struct cmd_tbl *cmdtp, int flag, int argc,
char * const argv[])
{
u8 *config_block;
size_t size = TDX_CFG_BLOCK_EXTRA_MAX_SIZE;
int offset = 0;
int ret = CMD_RET_SUCCESS;
int err;
int force_overwrite = 0;
if (argc >= 3) {
if (argv[2][0] == '-' && argv[2][1] == 'y')
force_overwrite = 1;
}
/* Allocate RAM area for config block */
config_block = memalign(ARCH_DMA_MINALIGN, size);
if (!config_block) {
printf("Not enough malloc space available!\n");
return CMD_RET_FAILURE;
}
memset(config_block, 0xff, size);
read_tdx_cfg_block_carrier();
if (valid_cfgblock_carrier && !force_overwrite) {
char message[CONFIG_SYS_CBSIZE];
sprintf(message, "A valid Toradex Carrier config block is present, still recreate? [y/N] ");
if (!cli_readline(message))
goto out;
if (console_buffer[0] != 'y' &&
console_buffer[0] != 'Y')
goto out;
}
if (argc < 3 || (force_overwrite && argc < 4)) {
err = get_cfgblock_carrier_interactive();
} else {
if (force_overwrite)
err = get_cfgblock_barcode(argv[3], &tdx_car_hw_tag,
&tdx_car_serial);
else
err = get_cfgblock_barcode(argv[2], &tdx_car_hw_tag,
&tdx_car_serial);
}
if (err) {
ret = CMD_RET_FAILURE;
goto out;
}
/* Valid Tag */
write_tag(config_block, &offset, TAG_VALID, NULL, 0);
/* Product Tag */
write_tag(config_block, &offset, TAG_HW, (u8 *)&tdx_car_hw_tag,
sizeof(tdx_car_hw_tag));
/* Serial Tag */
write_tag(config_block, &offset, TAG_CAR_SERIAL, (u8 *)&tdx_car_serial,
sizeof(tdx_car_serial));
memset(config_block + offset, 0, 32 - offset);
err = write_tdx_eeprom_data(TDX_EEPROM_ID_CARRIER, 0x0, config_block,
size);
if (err) {
printf("Failed to write Toradex Extra config block: %d\n",
ret);
ret = CMD_RET_FAILURE;
goto out;
}
printf("Toradex Extra config block successfully written\n");
out:
free(config_block);
return ret;
}
#endif /* CONFIG_TDX_CFG_BLOCK_EXTRA */
static int do_cfgblock_create(struct cmd_tbl *cmdtp, int flag, int argc,
char * const argv[])
{
u8 *config_block;
size_t size = TDX_CFG_BLOCK_MAX_SIZE;
int offset = 0;
int ret = CMD_RET_SUCCESS;
int err;
int force_overwrite = 0;
if (argc >= 3) {
#ifdef CONFIG_TDX_CFG_BLOCK_EXTRA
if (!strcmp(argv[2], "carrier"))
return do_cfgblock_carrier_create(cmdtp, flag,
--argc, ++argv);
#endif /* CONFIG_TDX_CFG_BLOCK_EXTRA */
if (argv[2][0] == '-' && argv[2][1] == 'y')
force_overwrite = 1;
}
/* Allocate RAM area for config block */
config_block = memalign(ARCH_DMA_MINALIGN, size);
if (!config_block) {
printf("Not enough malloc space available!\n");
return CMD_RET_FAILURE;
}
memset(config_block, 0xff, size);
read_tdx_cfg_block();
if (valid_cfgblock) {
#if defined(CONFIG_TDX_CFG_BLOCK_IS_IN_NAND)
/*
* On NAND devices, recreation is only allowed if the page is
* empty (config block invalid...)
*/
printf("NAND erase block %d need to be erased before creating a Toradex config block\n",
CONFIG_TDX_CFG_BLOCK_OFFSET /
get_nand_dev_by_index(0)->erasesize);
goto out;
#elif defined(CONFIG_TDX_CFG_BLOCK_IS_IN_NOR)
/*
* On NOR devices, recreation is only allowed if the sector is
* empty and write protection is off (config block invalid...)
*/
printf("NOR sector at offset 0x%02x need to be erased and unprotected before creating a Toradex config block\n",
CONFIG_TDX_CFG_BLOCK_OFFSET);
goto out;
#else
if (!force_overwrite) {
char message[CONFIG_SYS_CBSIZE];
sprintf(message,
"A valid Toradex config block is present, still recreate? [y/N] ");
if (!cli_readline(message))
goto out;
if (console_buffer[0] != 'y' &&
console_buffer[0] != 'Y')
goto out;
}
#endif
}
/* Parse new Toradex config block data... */
if (argc < 3 || (force_overwrite && argc < 4)) {
err = get_cfgblock_interactive();
} else {
if (force_overwrite)
err = get_cfgblock_barcode(argv[3], &tdx_hw_tag,
&tdx_serial);
else
err = get_cfgblock_barcode(argv[2], &tdx_hw_tag,
&tdx_serial);
}
if (err) {
ret = CMD_RET_FAILURE;
goto out;
}
/* Convert serial number to MAC address (the storage format) */
get_mac_from_serial(tdx_serial, &tdx_eth_addr);
/* Valid Tag */
write_tag(config_block, &offset, TAG_VALID, NULL, 0);
/* Product Tag */
write_tag(config_block, &offset, TAG_HW, (u8 *)&tdx_hw_tag,
sizeof(tdx_hw_tag));
/* MAC Tag */
write_tag(config_block, &offset, TAG_MAC, (u8 *)&tdx_eth_addr,
sizeof(tdx_eth_addr));
memset(config_block + offset, 0, 32 - offset);
#if defined(CONFIG_TDX_CFG_BLOCK_IS_IN_MMC)
err = tdx_cfg_block_mmc_storage(config_block, 1);
#elif defined(CONFIG_TDX_CFG_BLOCK_IS_IN_NAND)
err = write_tdx_cfg_block_to_nand(config_block);
#elif defined(CONFIG_TDX_CFG_BLOCK_IS_IN_NOR)
err = write_tdx_cfg_block_to_nor(config_block);
#elif defined(CONFIG_TDX_CFG_BLOCK_IS_IN_EEPROM)
err = write_tdx_cfg_block_to_eeprom(config_block);
#else
err = -EINVAL;
#endif
if (err) {
printf("Failed to write Toradex config block: %d\n", ret);
ret = CMD_RET_FAILURE;
goto out;
}
printf("Toradex config block successfully written\n");
out:
free(config_block);
return ret;
}
static int do_cfgblock(struct cmd_tbl *cmdtp, int flag, int argc,
char *const argv[])
{
int ret;
if (argc < 2)
return CMD_RET_USAGE;
if (!strcmp(argv[1], "create")) {
return do_cfgblock_create(cmdtp, flag, argc, argv);
} else if (!strcmp(argv[1], "reload")) {
ret = read_tdx_cfg_block();
if (ret) {
printf("Failed to reload Toradex config block: %d\n",
ret);
return CMD_RET_FAILURE;
}
return CMD_RET_SUCCESS;
}
return CMD_RET_USAGE;
}
U_BOOT_CMD(
cfgblock, 5, 0, do_cfgblock,
"Toradex config block handling commands",
"create [-y] [barcode] - (Re-)create Toradex config block\n"
"create carrier [-y] [barcode] - (Re-)create Toradex Carrier config block\n"
"cfgblock reload - Reload Toradex config block from flash"
);
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