rockbox/utils/imxtools/sbtools/sb1.c

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/***************************************************************************
* __________ __ ___.
* Open \______ \ ____ ____ | | _\_ |__ _______ ___
* Source | _// _ \_/ ___\| |/ /| __ \ / _ \ \/ /
* Jukebox | | ( <_> ) \___| < | \_\ ( <_> > < <
* Firmware |____|_ /\____/ \___ >__|_ \|___ /\____/__/\_ \
* \/ \/ \/ \/ \/
* $Id$
*
* Copyright (C) 2012 Amaury Pouly
*
* 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 software is distributed on an "AS IS" basis, WITHOUT WARRANTY OF ANY
* KIND, either express or implied.
*
****************************************************************************/
#include <stdio.h>
#include <time.h>
#include <stdlib.h>
#include <ctype.h>
#include "misc.h"
#include "crypto.h"
#include "sb1.h"
static int sdram_size_table[] = {2, 8, 16, 32, 64};
#define NR_SDRAM_ENTRIES (int)(sizeof(sdram_size_table) / sizeof(sdram_size_table[0]))
int sb1_sdram_size_by_index(int index)
{
if(index < 0 || index >= NR_SDRAM_ENTRIES)
return -1;
return sdram_size_table[index];
}
int sb1_sdram_index_by_size(int size)
{
for(int i = 0; i < NR_SDRAM_ENTRIES; i++)
if(sdram_size_table[i] == size)
return i;
return -1;
}
static uint16_t swap16(uint16_t t)
{
return (t << 8) | (t >> 8);
}
static void fix_version(struct sb1_version_t *ver)
{
ver->major = swap16(ver->major);
ver->minor = swap16(ver->minor);
ver->revision = swap16(ver->revision);
}
enum sb1_error_t sb1_write_file(struct sb1_file_t *sb, const char *filename)
{
if(sb->key.method != CRYPTO_XOR_KEY)
return SB1_NO_VALID_KEY;
/* compute image size (without userdata) */
uint32_t image_size = 0;
image_size += sizeof(struct sb1_header_t);
for(int i = 0; i < sb->nr_insts; i++)
{
switch(sb->insts[i].cmd)
{
case SB1_INST_LOAD:
image_size += 8 + ROUND_UP(sb->insts[i].size, 4);
break;
case SB1_INST_FILL:
case SB1_INST_JUMP:
case SB1_INST_CALL:
image_size += 12;
break;
case SB1_INST_MODE:
case SB1_INST_SDRAM:
image_size += 8;
break;
default:
bugp("Internal error: unknown SB instruction: %#x\n", sb->insts[i].cmd);
}
}
// now take crypto marks and sector size into account:
// there is one crypto mark per sector, ie 4 bytes for 508 = 512 (sector)
image_size += 4 * ((image_size + SECTOR_SIZE - 5) / (SECTOR_SIZE - 4));
image_size = ROUND_UP(image_size, SECTOR_SIZE);
/* allocate buffer and fill it (ignoring crypto for now) */
void *buf = xmalloc(image_size);
struct sb1_header_t *header = buf;
memset(buf, 0, image_size);
header->rom_version = sb->rom_version;
header->image_size = image_size + sb->userdata_size;
header->header_size = sizeof(struct sb1_header_t);
header->userdata_offset = sb->userdata ? image_size : 0;
memcpy(&header->product_ver, &sb->product_ver, sizeof(sb->product_ver));
fix_version(&header->product_ver);
memcpy(&header->component_ver, &sb->component_ver, sizeof(sb->component_ver));
fix_version(&header->component_ver);
header->drive_tag = sb->drive_tag;
strncpy((void *)header->signature, "STMP", 4);
struct sb1_cmd_header_t *cmd = (void *)(header + 1);
for(int i = 0; i < sb->nr_insts; i++)
{
int bytes = 0;
int size = 0;
switch(sb->insts[i].cmd)
{
case SB1_INST_LOAD:
bytes = sb->insts[i].size;
cmd->addr = sb->insts[i].addr;
memcpy(cmd + 1, sb->insts[i].data, sb->insts[i].size);
memset((void *)(cmd + 1) + sb->insts[i].size, 0,
bytes - sb->insts[i].size);
break;
case SB1_INST_FILL:
bytes = sb->insts[i].size;
size = 2;
memcpy(cmd + 1, &sb->insts[i].pattern, 4);
cmd->addr = sb->insts[i].addr;
break;
case SB1_INST_JUMP:
case SB1_INST_CALL:
bytes = 4;
cmd->addr = sb->insts[i].addr;
memcpy(cmd + 1, &sb->insts[i].argument, 4);
break;
case SB1_INST_MODE:
bytes = 0;
cmd->addr = sb->insts[i].mode;
break;
case SB1_INST_SDRAM:
bytes = 0;
cmd->addr = SB1_MK_ADDR_SDRAM(sb->insts[i].sdram.chip_select,
sb->insts[i].sdram.size_index);
break;
default:
bugp("Internal error: unknown SB instruction: %#x\n", sb->insts[i].cmd);
}
/* handle most common cases */
if(size == 0)
size = ROUND_UP(bytes, 4) / 4 + 1;
cmd->cmd = SB1_MK_CMD(sb->insts[i].cmd, sb->insts[i].datatype,
bytes, sb->insts[i].critical,
size);
cmd = (void *)cmd + 4 + size * 4;
}
/* move everything to prepare crypto marks (start at the end !) */
for(int i = image_size / SECTOR_SIZE - 1; i >= 0; i--)
memmove(buf + i * SECTOR_SIZE, buf + i * (SECTOR_SIZE - 4), SECTOR_SIZE - 4);
union xorcrypt_key_t key[2];
memcpy(key, sb->key.u.xor_key, sizeof(sb->key.u.xor_key));
void *ptr = header + 1;
int offset = header->header_size;
for(unsigned i = 0; i < image_size / SECTOR_SIZE; i++)
{
int size = SECTOR_SIZE - 4 - offset;
uint32_t mark = xor_encrypt(key, ptr, size);
*(uint32_t *)(ptr + size) = mark;
ptr += size + 4;
offset = 0;
}
FILE *fd = fopen(filename, "wb");
if(fd == NULL)
return SB1_OPEN_ERROR;
if(fwrite(buf, image_size, 1, fd) != 1)
{
free(buf);
return SB1_WRITE_ERROR;
}
free(buf);
if(sb->userdata)
fwrite(sb->userdata, sb->userdata_size, 1, fd);
fclose(fd);
return SB1_SUCCESS;
}
struct sb1_file_t *sb1_read_file(const char *filename, void *u,
generic_printf_t cprintf, enum sb1_error_t *err)
{
return sb1_read_file_ex(filename, 0, -1, u, cprintf, err);
}
struct sb1_file_t *sb1_read_file_ex(const char *filename, size_t offset, size_t size, void *u,
generic_printf_t cprintf, enum sb1_error_t *err)
{
#define fatal(e, ...) \
do { if(err) *err = e; \
cprintf(u, true, GREY, __VA_ARGS__); \
free(buf); \
return NULL; } while(0)
FILE *f = fopen(filename, "rb");
void *buf = NULL;
if(f == NULL)
fatal(SB1_OPEN_ERROR, "Cannot open file for reading\n");
fseek(f, 0, SEEK_END);
size_t read_size = ftell(f);
fseek(f, offset, SEEK_SET);
if(size != (size_t)-1)
read_size = size;
buf = xmalloc(read_size);
if(fread(buf, read_size, 1, f) != 1)
{
fclose(f);
fatal(SB1_READ_ERROR, "Cannot read file\n");
}
fclose(f);
struct sb1_file_t *ret = sb1_read_memory(buf, read_size, u, cprintf, err);
free(buf);
return ret;
#undef fatal
}
static const char *sb1_cmd_name(int cmd)
{
switch(cmd)
{
case SB1_INST_LOAD: return "load";
case SB1_INST_FILL: return "fill";
case SB1_INST_JUMP: return "jump";
case SB1_INST_CALL: return "call";
case SB1_INST_MODE: return "mode";
case SB1_INST_SDRAM: return "sdram";
default: return "unknown";
}
}
static const char *sb1_datatype_name(int cmd)
{
switch(cmd)
{
case SB1_DATATYPE_UINT32: return "uint32";
case SB1_DATATYPE_UINT16: return "uint16";
case SB1_DATATYPE_UINT8: return "uint8";
default: return "unknown";
}
}
/* Quick and dirty way to check a key is valid.
* We don't do any form of format checking because we are trying to bruteforce
* the key anyway. Assume buffer is of size SECTOR_SIZE */
bool sb1_is_key_valid_fast(void *buffer, union xorcrypt_key_t _key[2])
{
struct sb1_header_t *header = (struct sb1_header_t *)buffer;
union xorcrypt_key_t key[2];
uint8_t sector[SECTOR_SIZE];
/* copy key and data because it's modified by the crypto code */
memcpy(key, _key, sizeof(key));
memcpy(sector, header + 1, SECTOR_SIZE - header->header_size);
/* try to decrypt the first sector */
uint32_t mark = xor_decrypt(key, sector, SECTOR_SIZE - 4 - header->header_size);
/* copy key again it's modified by the crypto code */
return mark == *(uint32_t *)&sector[SECTOR_SIZE - 4 - header->header_size];
}
bool sb1_brute_force(const char *filename, void *u, generic_printf_t cprintf,
enum sb1_error_t *err, struct crypto_key_t *key)
{
#define printf(c, ...) cprintf(u, false, c, __VA_ARGS__)
uint8_t sector[SECTOR_SIZE];
FILE *f = fopen(filename, "rb");
if(f == NULL)
{
printf("Cannot open file '%s' for reading: %m\n", filename);
*err = SB1_OPEN_ERROR;
return false;
}
if(fread(sector, sizeof(sector), 1, f) != 1)
{
printf("Cannot read file '%s': %m\n", filename);
*err = SB1_READ_ERROR;
fclose(f);
return false;
}
fclose(f);
printf(BLUE, "Brute forcing key...\n");
time_t start_time = time(NULL);
uint32_t laserfuse[3] = {0, 0, 0};
unsigned last_print = 0;
do
{
for(int i = 0; i < 0x10000; i++)
{
laserfuse[2] = (i & 0xff00) << 8 | (i & 0xff);
xor_generate_key(laserfuse, key->u.xor_key);
if(g_debug)
{
printf(GREEN, "Trying key");
printf(GREEN, "[");
printf(RED, "%08x", laserfuse[0]);
printf(GREEN, ",");
printf(RED, "%08x", laserfuse[1]);
printf(GREEN, ",");
printf(RED, "%08x", laserfuse[2]);
printf(GREEN, "]:");
for(int j = 0; j < 32; j++)
printf(YELLOW, " %08x", key->u.xor_key[j / 16].k[j % 16]);
}
if(sb1_is_key_valid_fast(sector, key->u.xor_key))
{
if(g_debug)
printf(RED, " Ok\n");
return true;
}
else
{
if(g_debug)
printf(RED, " No\n");
}
}
laserfuse[0]++;
if(laserfuse[0] / 1000 != last_print)
{
time_t cur_time = time(NULL);
float key_per_sec = laserfuse[0] / (float)(cur_time - start_time);
float tot = 0x1000000LL / key_per_sec;
time_t eta_time = start_time + tot;
printf(YELLOW, "%llu", laserfuse[0] * 0x10000LL);
printf(GREEN, " out of ");
printf(BLUE, "%llu", 0x1000000LL * 0x10000LL);
printf(GREEN, " tested (");
printf(RED, "%f%%", laserfuse[0] / (float)0x1000000LL * 100.0);
printf(GREEN, "), ");
printf(YELLOW, "%d", cur_time - start_time);
printf(GREEN, " seconds elapsed, ");
printf(BLUE, "%d", eta_time - cur_time);
printf(GREEN, " seconds remaining, [");
printf(RED, "%f", key_per_sec);
printf(GREEN, " keys/s], ETA ");
printf(YELLOW, "%s", ctime(&eta_time));
last_print = laserfuse[0] / 1000;
}
}while(laserfuse[0] != 0);
*err = SB1_NO_VALID_KEY;
return false;
#undef printf
}
struct sb1_file_t *sb1_read_memory(void *_buf, size_t filesize, void *u,
generic_printf_t cprintf, enum sb1_error_t *err)
{
struct sb1_file_t *file = NULL;
uint8_t *buf = _buf;
#define printf(c, ...) cprintf(u, false, c, __VA_ARGS__)
#define fatal(e, ...) \
do { if(err) *err = e; \
cprintf(u, true, GREY, __VA_ARGS__); \
sb1_free(file); \
return NULL; } while(0)
#define print_hex(c, p, len, nl) \
do { printf(c, ""); print_hex(p, len, nl); } while(0)
file = xmalloc(sizeof(struct sb1_file_t));
memset(file, 0, sizeof(struct sb1_file_t));
struct sb1_header_t *header = (struct sb1_header_t *)buf;
if(memcmp(header->signature, "STMP", 4) != 0)
fatal(SB1_FORMAT_ERROR, "Bad signature\n");
if(header->image_size > filesize)
fatal(SB1_FORMAT_ERROR, "File too small (should be at least %d bytes)\n",
header->image_size);
if(header->header_size != sizeof(struct sb1_header_t))
fatal(SB1_FORMAT_ERROR, "Bad header size\n");
printf(BLUE, "Basic info:\n");
printf(GREEN, " ROM version: ");
printf(YELLOW, "%x\n", header->rom_version);
printf(GREEN, " Userdata offset: ");
printf(YELLOW, "%x\n", header->userdata_offset);
printf(GREEN, " Pad: ");
printf(YELLOW, "%x\n", header->pad2);
struct sb1_version_t product_ver = header->product_ver;
fix_version(&product_ver);
struct sb1_version_t component_ver = header->component_ver;
fix_version(&component_ver);
printf(GREEN, " Product version: ");
printf(YELLOW, "%X.%X.%X\n", product_ver.major, product_ver.minor, product_ver.revision);
printf(GREEN, " Component version: ");
printf(YELLOW, "%X.%X.%X\n", component_ver.major, component_ver.minor, component_ver.revision);
printf(GREEN, " Drive tag: ");
printf(YELLOW, "%x\n", header->drive_tag);
/* copy rom version, padding and drive tag */
/* copy versions */
memcpy(&file->product_ver, &product_ver, sizeof(product_ver));
memcpy(&file->component_ver, &component_ver, sizeof(component_ver));
file->rom_version = header->rom_version;
file->pad2 = header->pad2;
file->drive_tag = header->drive_tag;
/* reduce size w.r.t to userdata part */
uint32_t userdata_size = 0;
if(header->userdata_offset != 0)
{
userdata_size = header->image_size - header->userdata_offset;
header->image_size -= userdata_size;
}
if(header->image_size % SECTOR_SIZE)
{
if(!g_force)
printf(GREY, "Image size is not a multiple of sector size\n");
else
fatal(SB1_FORMAT_ERROR, "Image size is not a multiple of sector size\n");
}
/* find key */
union xorcrypt_key_t key[2];
memset(key, 0, sizeof(key));
bool valid_key = false;
uint8_t sector[SECTOR_SIZE];
for(int i = 0; i < g_nr_keys; i++)
{
if(!g_key_array[i].method == CRYPTO_XOR_KEY)
continue;
/* copy key and data because it's modified by the crypto code */
memcpy(key, g_key_array[i].u.xor_key, sizeof(key));
memcpy(sector, header + 1, SECTOR_SIZE - header->header_size);
/* try to decrypt the first sector */
uint32_t mark = xor_decrypt(key, sector, SECTOR_SIZE - 4 - header->header_size);
/* copy key again it's modified by the crypto code */
memcpy(key, g_key_array[i].u.xor_key, sizeof(key));
if(mark != *(uint32_t *)&sector[SECTOR_SIZE - 4 - header->header_size])
continue;
/* found ! */
valid_key = true;
break;
}
if(!valid_key)
{
if(!g_force)
fatal(SB1_NO_VALID_KEY, "No valid key found\n");
printf(GREY, "No valid key found: forced to continue but this will fail\n");
}
printf(BLUE, "Crypto\n");
for(int i = 0; i < 2; i++)
{
printf(RED, " Key %d\n", i);
printf(OFF, " ");
for(int j = 0; j < 64; j++)
{
printf(YELLOW, "%02x ", key[i].key[j]);
if((j + 1) % 16 == 0)
{
printf(OFF, "\n");
if(j + 1 != 64)
printf(OFF, " ");
}
}
}
memcpy(file->key.u.xor_key, key, sizeof(key));
/* decrypt image in-place (and removing crypto markers) */
void *ptr = header + 1;
void *copy_ptr = header + 1;
int offset = header->header_size;
for(unsigned i = 0; i < header->image_size / SECTOR_SIZE; i++)
{
int size = SECTOR_SIZE - 4 - offset;
uint32_t mark = xor_decrypt(key, ptr, size);
if(mark != *(uint32_t *)(ptr + size) && !g_force)
fatal(SB1_CHECKSUM_ERROR, "Crypto mark mismatch\n");
memmove(copy_ptr, ptr, size);
ptr += size + 4;
copy_ptr += size;
offset = 0;
}
/* reduce image size given the removed marks */
header->image_size -= header->image_size / SECTOR_SIZE;
printf(BLUE, "Commands\n");
struct sb1_cmd_header_t *cmd = (void *)(header + 1);
while((void *)cmd < (void *)header + header->image_size)
{
printf(GREEN, " Command");
printf(YELLOW, " %#x\n", cmd->cmd);
printf(YELLOW, " Size:");
printf(RED, " %#x\n", SB1_CMD_SIZE(cmd->cmd));
printf(YELLOW, " Critical:");
printf(RED, " %d\n", SB1_CMD_CRITICAL(cmd->cmd));
printf(YELLOW, " Data Type:");
printf(RED, " %#x ", SB1_CMD_DATATYPE(cmd->cmd));
printf(GREEN, "(%s)\n", sb1_datatype_name(SB1_CMD_DATATYPE(cmd->cmd)));
printf(YELLOW, " Bytes:");
printf(RED, " %#x\n", SB1_CMD_BYTES(cmd->cmd));
printf(YELLOW, " Boot:");
printf(RED, " %#x ", SB1_CMD_BOOT(cmd->cmd));
printf(GREEN, "(%s)\n", sb1_cmd_name(SB1_CMD_BOOT(cmd->cmd)));
/* copy command */
struct sb1_inst_t inst;
memset(&inst, 0, sizeof(inst));
inst.cmd = SB1_CMD_BOOT(cmd->cmd);
inst.critical = SB1_CMD_CRITICAL(cmd->cmd);
inst.datatype = SB1_CMD_DATATYPE(cmd->cmd);
inst.size = SB1_CMD_BYTES(cmd->cmd);
switch(SB1_CMD_BOOT(cmd->cmd))
{
case SB1_INST_SDRAM:
inst.sdram.chip_select = SB1_ADDR_SDRAM_CS(cmd->addr);
inst.sdram.size_index = SB1_ADDR_SDRAM_SZ(cmd->addr);
printf(YELLOW, " Ram:");
printf(RED, " %#x", inst.addr);
printf(GREEN, " (Chip Select=%d, Size=%d)\n", SB1_ADDR_SDRAM_CS(cmd->addr),
sb1_sdram_size_by_index(SB1_ADDR_SDRAM_SZ(cmd->addr)));
break;
case SB1_INST_MODE:
inst.mode = cmd->addr;
printf(YELLOW, " Mode:");
printf(RED, " %#x\n", inst.mode);
break;
case SB1_INST_LOAD:
inst.data = malloc(inst.size);
memcpy(inst.data, cmd + 1, inst.size);
inst.addr = cmd->addr;
printf(YELLOW, " Addr:");
printf(RED, " %#x\n", inst.addr);
break;
case SB1_INST_FILL:
inst.addr = cmd->addr;
inst.pattern = *(uint32_t *)(cmd + 1);
printf(YELLOW, " Addr:");
printf(RED, " %#x\n", cmd->addr);
printf(YELLOW, " Pattern:");
printf(RED, " %#x\n", inst.pattern);
break;
case SB1_INST_CALL:
case SB1_INST_JUMP:
inst.addr = cmd->addr;
inst.argument = *(uint32_t *)(cmd + 1);
printf(YELLOW, " Addr:");
printf(RED, " %#x\n", cmd->addr);
printf(YELLOW, " Argument:");
printf(RED, " %#x\n", inst.pattern);
break;
default:
printf(GREY, "WARNING: unknown SB command !\n");
break;
}
file->insts = augment_array(file->insts, sizeof(inst), file->nr_insts, &inst, 1);
file->nr_insts++;
/* last instruction ? */
if(SB1_CMD_BOOT(cmd->cmd) == SB1_INST_JUMP ||
SB1_CMD_BOOT(cmd->cmd) == SB1_INST_MODE)
break;
cmd = (void *)cmd + 4 + 4 * SB1_CMD_SIZE(cmd->cmd);
}
/* copy userdata */
file->userdata_size = userdata_size;
if(userdata_size > 0)
{
file->userdata = malloc(userdata_size);
memcpy(file->userdata, (void *)header + header->userdata_offset, userdata_size);
}
return file;
#undef printf
#undef fatal
#undef print_hex
}
void sb1_free(struct sb1_file_t *file)
{
if(!file) return;
for(int i = 0; i < file->nr_insts; i++)
free(file->insts[i].data);
free(file->insts);
free(file->userdata);
free(file);
}
void sb1_dump(struct sb1_file_t *file, void *u, generic_printf_t cprintf)
{
#define printf(c, ...) cprintf(u, false, c, __VA_ARGS__)
#define print_hex(c, p, len, nl) \
do { printf(c, ""); print_hex(p, len, nl); } while(0)
#define TREE RED
#define HEADER GREEN
#define TEXT YELLOW
#define TEXT2 BLUE
#define TEXT3 RED
#define SEP OFF
printf(BLUE, "SB1 File\n");
printf(TREE, "+-");
printf(HEADER, "Rom Ver: ");
printf(TEXT, "%x\n", file->rom_version);
printf(TREE, "+-");
printf(HEADER, "Pad: ");
printf(TEXT, "%x\n", file->pad2);
printf(TREE, "+-");
printf(HEADER, "Drive Tag: ");
printf(TEXT, "%x\n", file->drive_tag);
printf(TREE, "+-");
printf(HEADER, "Product Version: ");
printf(TEXT, "%X.%X.%X\n", file->product_ver.major, file->product_ver.minor,
file->product_ver.revision);
printf(TREE, "+-");
printf(HEADER, "Component Version: ");
printf(TEXT, "%X.%X.%X\n", file->component_ver.major, file->component_ver.minor,
file->component_ver.revision);
for(int j = 0; j < file->nr_insts; j++)
{
struct sb1_inst_t *inst = &file->insts[j];
printf(TREE, "+-");
printf(HEADER, "Command\n");
printf(TREE, "| +-");
switch(inst->cmd)
{
case SB1_INST_CALL:
case SB1_INST_JUMP:
printf(HEADER, "%s", inst->cmd == SB1_INST_CALL ? "CALL" : "JUMP");
printf(SEP, " | ");
printf(TEXT3, "crit=%d", inst->critical);
printf(SEP, " | ");
printf(TEXT, "addr=0x%08x\n", inst->addr);
break;
case SB1_INST_LOAD:
printf(HEADER, "LOAD");
printf(SEP, " | ");
printf(TEXT3, "crit=%d", inst->critical);
printf(SEP, " | ");
printf(TEXT, "addr=0x%08x", inst->addr);
printf(SEP, " | ");
printf(TEXT2, "len=0x%08x\n", inst->size);
break;
case SB1_INST_FILL:
printf(HEADER, "FILL");
printf(SEP, " | ");
printf(TEXT3, "crit=%d", inst->critical);
printf(SEP, " | ");
printf(TEXT, "addr=0x%08x", inst->addr);
printf(SEP, " | ");
printf(TEXT2, "len=0x%08x", inst->size);
printf(SEP, " | ");
printf(TEXT2, "pattern=0x%08x\n", inst->pattern);
break;
case SB1_INST_MODE:
printf(HEADER, "MODE");
printf(SEP, " | ");
printf(TEXT3, "crit=%d", inst->critical);
printf(SEP, " | ");
printf(TEXT, "mode=0x%08x\n", inst->addr);
break;
case SB1_INST_SDRAM:
printf(HEADER, "SRAM");
printf(SEP, " | ");
printf(TEXT3, "crit=%d", inst->critical);
printf(SEP, " | ");
printf(TEXT, "chip_select=%d", inst->sdram.chip_select);
printf(SEP, " | ");
printf(TEXT2, "chip_size=%d\n", sb1_sdram_size_by_index(inst->sdram.size_index));
break;
default:
printf(GREY, "[Unknown instruction %x]\n", inst->cmd);
break;
}
}
#undef printf
#undef print_hex
}
static struct crypto_key_t g_default_xor_key =
{
.method = CRYPTO_XOR_KEY,
.u.xor_key =
{
{.k = {0x67ECAEF6, 0xB31FB961, 0x118A9F4C, 0xA32A97DA,
0x6CC39617, 0x5BC00314, 0x9D430685, 0x4D7DB502,
0xA347685E, 0x3C87E86C, 0x8987AAA0, 0x24B78EF1,
0x893B9605, 0x9BB8C2BE, 0x6D9544E2, 0x375B525C}},
{.k = {0x3F424704, 0x53B5A331, 0x6AD345A5, 0x20DCEC51,
0x743C8D3B, 0x444B3792, 0x0AF429569, 0xB7EE1111,
0x583BF768, 0x9683BF9A, 0x0B032D799, 0xFE4E78ED,
0xF20D08C2, 0xFA0BE4A2, 0x4D89C317, 0x887B2D6F}}
}
};
void sb1_get_default_key(struct crypto_key_t *key)
{
memcpy(key, &g_default_xor_key, sizeof(g_default_xor_key));
/* decrypt the xor key which is xor'ed */
for(int i = 0; i < 2; i++)
for(int j = 0; j < 16; j++)
key->u.xor_key[i].k[j] ^= 0xaa55aa55;
}