Refactor firm.c as well as other files

This commit is contained in:
TuxSH 2016-06-12 22:14:52 +02:00
parent edfd63e1f7
commit 2943dcb2e9
9 changed files with 380 additions and 347 deletions

View File

@ -16,258 +16,258 @@
#ifndef __thumb__ #ifndef __thumb__
#define BSWAP32(x) {\ #define BSWAP32(x) {\
__asm__\ __asm__\
(\ (\
"eor r1, %1, %1, ror #16\n\t"\ "eor r1, %1, %1, ror #16\n\t"\
"bic r1, r1, #0xFF0000\n\t"\ "bic r1, r1, #0xFF0000\n\t"\
"mov %0, %1, ror #8\n\t"\ "mov %0, %1, ror #8\n\t"\
"eor %0, %0, r1, lsr #8\n\t"\ "eor %0, %0, r1, lsr #8\n\t"\
:"=r"(x)\ :"=r"(x)\
:"0"(x)\ :"0"(x)\
:"r1"\ :"r1"\
);\ );\
}; };
#define ADD_u128_u32(u128_0, u128_1, u128_2, u128_3, u32_0) {\ #define ADD_u128_u32(u128_0, u128_1, u128_2, u128_3, u32_0) {\
__asm__\ __asm__\
(\ (\
"adds %0, %4\n\t"\ "adds %0, %4\n\t"\
"addcss %1, %1, #1\n\t"\ "addcss %1, %1, #1\n\t"\
"addcss %2, %2, #1\n\t"\ "addcss %2, %2, #1\n\t"\
"addcs %3, %3, #1\n\t"\ "addcs %3, %3, #1\n\t"\
: "+r"(u128_0), "+r"(u128_1), "+r"(u128_2), "+r"(u128_3)\ : "+r"(u128_0), "+r"(u128_1), "+r"(u128_2), "+r"(u128_3)\
: "r"(u32_0)\ : "r"(u32_0)\
: "cc"\ : "cc"\
);\ );\
} }
#else #else
#define BSWAP32(x) {x = __builtin_bswap32(x);} #define BSWAP32(x) {x = __builtin_bswap32(x);}
#define ADD_u128_u32(u128_0, u128_1, u128_2, u128_3, u32_0) {\ #define ADD_u128_u32(u128_0, u128_1, u128_2, u128_3, u32_0) {\
__asm__\ __asm__\
(\ (\
"mov r4, #0\n\t"\ "mov r4, #0\n\t"\
"add %0, %0, %4\n\t"\ "add %0, %0, %4\n\t"\
"adc %1, %1, r4\n\t"\ "adc %1, %1, r4\n\t"\
"adc %2, %2, r4\n\t"\ "adc %2, %2, r4\n\t"\
"adc %3, %3, r4\n\t"\ "adc %3, %3, r4\n\t"\
: "+r"(u128_0), "+r"(u128_1), "+r"(u128_2), "+r"(u128_3)\ : "+r"(u128_0), "+r"(u128_1), "+r"(u128_2), "+r"(u128_3)\
: "r"(u32_0)\ : "r"(u32_0)\
: "cc", "r4"\ : "cc", "r4"\
);\ );\
} }
#endif /*__thumb__*/ #endif /*__thumb__*/
static void aes_setkey(u8 keyslot, const void *key, u32 keyType, u32 mode) static void aes_setkey(u8 keyslot, const void *key, u32 keyType, u32 mode)
{ {
if(keyslot <= 0x03) return; // Ignore TWL keys for now if(keyslot <= 0x03) return; // Ignore TWL keys for now
u32 *key32 = (u32 *)key; u32 *key32 = (u32 *)key;
*REG_AESCNT = (*REG_AESCNT & ~(AES_CNT_INPUT_ENDIAN | AES_CNT_INPUT_ORDER)) | mode; *REG_AESCNT = (*REG_AESCNT & ~(AES_CNT_INPUT_ENDIAN | AES_CNT_INPUT_ORDER)) | mode;
*REG_AESKEYCNT = (*REG_AESKEYCNT >> 6 << 6) | keyslot | AES_KEYCNT_WRITE; *REG_AESKEYCNT = (*REG_AESKEYCNT >> 6 << 6) | keyslot | AES_KEYCNT_WRITE;
REG_AESKEYFIFO[keyType] = key32[0]; REG_AESKEYFIFO[keyType] = key32[0];
REG_AESKEYFIFO[keyType] = key32[1]; REG_AESKEYFIFO[keyType] = key32[1];
REG_AESKEYFIFO[keyType] = key32[2]; REG_AESKEYFIFO[keyType] = key32[2];
REG_AESKEYFIFO[keyType] = key32[3]; REG_AESKEYFIFO[keyType] = key32[3];
} }
static void aes_use_keyslot(u8 keyslot) static void aes_use_keyslot(u8 keyslot)
{ {
if(keyslot > 0x3F) if(keyslot > 0x3F)
return; return;
*REG_AESKEYSEL = keyslot; *REG_AESKEYSEL = keyslot;
*REG_AESCNT = *REG_AESCNT | 0x04000000; /* mystery bit */ *REG_AESCNT = *REG_AESCNT | 0x04000000; /* mystery bit */
} }
static void aes_setiv(const void *iv, u32 mode) static void aes_setiv(const void *iv, u32 mode)
{ {
const u32 *iv32 = (const u32 *)iv; const u32 *iv32 = (const u32 *)iv;
*REG_AESCNT = (*REG_AESCNT & ~(AES_CNT_INPUT_ENDIAN | AES_CNT_INPUT_ORDER)) | mode; *REG_AESCNT = (*REG_AESCNT & ~(AES_CNT_INPUT_ENDIAN | AES_CNT_INPUT_ORDER)) | mode;
// Word order for IV can't be changed in REG_AESCNT and always default to reversed // Word order for IV can't be changed in REG_AESCNT and always default to reversed
if(mode & AES_INPUT_NORMAL) if(mode & AES_INPUT_NORMAL)
{ {
REG_AESCTR[0] = iv32[3]; REG_AESCTR[0] = iv32[3];
REG_AESCTR[1] = iv32[2]; REG_AESCTR[1] = iv32[2];
REG_AESCTR[2] = iv32[1]; REG_AESCTR[2] = iv32[1];
REG_AESCTR[3] = iv32[0]; REG_AESCTR[3] = iv32[0];
} }
else else
{ {
REG_AESCTR[0] = iv32[0]; REG_AESCTR[0] = iv32[0];
REG_AESCTR[1] = iv32[1]; REG_AESCTR[1] = iv32[1];
REG_AESCTR[2] = iv32[2]; REG_AESCTR[2] = iv32[2];
REG_AESCTR[3] = iv32[3]; REG_AESCTR[3] = iv32[3];
} }
} }
static void aes_advctr(void *ctr, u32 val, u32 mode) static void aes_advctr(void *ctr, u32 val, u32 mode)
{ {
u32 *ctr32 = (u32 *)ctr; u32 *ctr32 = (u32 *)ctr;
int i; int i;
if(mode & AES_INPUT_BE) if(mode & AES_INPUT_BE)
{ {
for(i = 0; i < 4; ++i) // Endian swap for(i = 0; i < 4; ++i) // Endian swap
BSWAP32(ctr32[i]); BSWAP32(ctr32[i]);
} }
if(mode & AES_INPUT_NORMAL) if(mode & AES_INPUT_NORMAL)
{ {
ADD_u128_u32(ctr32[3], ctr32[2], ctr32[1], ctr32[0], val); ADD_u128_u32(ctr32[3], ctr32[2], ctr32[1], ctr32[0], val);
} }
else else
{ {
ADD_u128_u32(ctr32[0], ctr32[1], ctr32[2], ctr32[3], val); ADD_u128_u32(ctr32[0], ctr32[1], ctr32[2], ctr32[3], val);
} }
if(mode & AES_INPUT_BE) if(mode & AES_INPUT_BE)
{ {
for(i = 0; i < 4; ++i) // Endian swap for(i = 0; i < 4; ++i) // Endian swap
BSWAP32(ctr32[i]); BSWAP32(ctr32[i]);
} }
} }
static void aes_change_ctrmode(void *ctr, u32 fromMode, u32 toMode) static void aes_change_ctrmode(void *ctr, u32 fromMode, u32 toMode)
{ {
u32 *ctr32 = (u32 *)ctr; u32 *ctr32 = (u32 *)ctr;
int i; int i;
if((fromMode ^ toMode) & AES_CNT_INPUT_ENDIAN) if((fromMode ^ toMode) & AES_CNT_INPUT_ENDIAN)
{ {
for(i = 0; i < 4; ++i) for(i = 0; i < 4; ++i)
BSWAP32(ctr32[i]); BSWAP32(ctr32[i]);
} }
if((fromMode ^ toMode) & AES_CNT_INPUT_ORDER) if((fromMode ^ toMode) & AES_CNT_INPUT_ORDER)
{ {
u32 temp = ctr32[0]; u32 temp = ctr32[0];
ctr32[0] = ctr32[3]; ctr32[0] = ctr32[3];
ctr32[3] = temp; ctr32[3] = temp;
temp = ctr32[1]; temp = ctr32[1];
ctr32[1] = ctr32[2]; ctr32[1] = ctr32[2];
ctr32[2] = temp; ctr32[2] = temp;
} }
} }
static void aes_batch(void *dst, const void *src, u32 blockCount) static void aes_batch(void *dst, const void *src, u32 blockCount)
{ {
*REG_AESBLKCNT = blockCount << 16; *REG_AESBLKCNT = blockCount << 16;
*REG_AESCNT |= AES_CNT_START; *REG_AESCNT |= AES_CNT_START;
const u32 *src32 = (const u32 *)src; const u32 *src32 = (const u32 *)src;
u32 *dst32 = (u32 *)dst; u32 *dst32 = (u32 *)dst;
u32 wbc = blockCount; u32 wbc = blockCount;
u32 rbc = blockCount; u32 rbc = blockCount;
while(rbc) while(rbc)
{ {
if(wbc && ((*REG_AESCNT & 0x1F) <= 0xC)) // There's space for at least 4 ints if(wbc && ((*REG_AESCNT & 0x1F) <= 0xC)) // There's space for at least 4 ints
{ {
*REG_AESWRFIFO = *src32++; *REG_AESWRFIFO = *src32++;
*REG_AESWRFIFO = *src32++; *REG_AESWRFIFO = *src32++;
*REG_AESWRFIFO = *src32++; *REG_AESWRFIFO = *src32++;
*REG_AESWRFIFO = *src32++; *REG_AESWRFIFO = *src32++;
wbc--; wbc--;
} }
if(rbc && ((*REG_AESCNT & (0x1F << 0x5)) >= (0x4 << 0x5))) // At least 4 ints available for read if(rbc && ((*REG_AESCNT & (0x1F << 0x5)) >= (0x4 << 0x5))) // At least 4 ints available for read
{ {
*dst32++ = *REG_AESRDFIFO; *dst32++ = *REG_AESRDFIFO;
*dst32++ = *REG_AESRDFIFO; *dst32++ = *REG_AESRDFIFO;
*dst32++ = *REG_AESRDFIFO; *dst32++ = *REG_AESRDFIFO;
*dst32++ = *REG_AESRDFIFO; *dst32++ = *REG_AESRDFIFO;
rbc--; rbc--;
} }
} }
} }
static void aes(void *dst, const void *src, u32 blockCount, void *iv, u32 mode, u32 ivMode) static void aes(void *dst, const void *src, u32 blockCount, void *iv, u32 mode, u32 ivMode)
{ {
*REG_AESCNT = mode | *REG_AESCNT = mode |
AES_CNT_INPUT_ORDER | AES_CNT_OUTPUT_ORDER | AES_CNT_INPUT_ORDER | AES_CNT_OUTPUT_ORDER |
AES_CNT_INPUT_ENDIAN | AES_CNT_OUTPUT_ENDIAN | AES_CNT_INPUT_ENDIAN | AES_CNT_OUTPUT_ENDIAN |
AES_CNT_FLUSH_READ | AES_CNT_FLUSH_WRITE; AES_CNT_FLUSH_READ | AES_CNT_FLUSH_WRITE;
u32 blocks; u32 blocks;
while(blockCount != 0) while(blockCount != 0)
{ {
if((mode & AES_ALL_MODES) != AES_ECB_ENCRYPT_MODE if((mode & AES_ALL_MODES) != AES_ECB_ENCRYPT_MODE
&& (mode & AES_ALL_MODES) != AES_ECB_DECRYPT_MODE) && (mode & AES_ALL_MODES) != AES_ECB_DECRYPT_MODE)
aes_setiv(iv, ivMode); aes_setiv(iv, ivMode);
blocks = (blockCount >= 0xFFFF) ? 0xFFFF : blockCount; blocks = (blockCount >= 0xFFFF) ? 0xFFFF : blockCount;
// Save the last block for the next decryption CBC batch's iv // Save the last block for the next decryption CBC batch's iv
if((mode & AES_ALL_MODES) == AES_CBC_DECRYPT_MODE) if((mode & AES_ALL_MODES) == AES_CBC_DECRYPT_MODE)
{ {
memcpy(iv, src + (blocks - 1) * AES_BLOCK_SIZE, AES_BLOCK_SIZE); memcpy(iv, src + (blocks - 1) * AES_BLOCK_SIZE, AES_BLOCK_SIZE);
aes_change_ctrmode(iv, AES_INPUT_BE | AES_INPUT_NORMAL, ivMode); aes_change_ctrmode(iv, AES_INPUT_BE | AES_INPUT_NORMAL, ivMode);
} }
// Process the current batch // Process the current batch
aes_batch(dst, src, blocks); aes_batch(dst, src, blocks);
// Save the last block for the next encryption CBC batch's iv // Save the last block for the next encryption CBC batch's iv
if((mode & AES_ALL_MODES) == AES_CBC_ENCRYPT_MODE) if((mode & AES_ALL_MODES) == AES_CBC_ENCRYPT_MODE)
{ {
memcpy(iv, dst + (blocks - 1) * AES_BLOCK_SIZE, AES_BLOCK_SIZE); memcpy(iv, dst + (blocks - 1) * AES_BLOCK_SIZE, AES_BLOCK_SIZE);
aes_change_ctrmode(iv, AES_INPUT_BE | AES_INPUT_NORMAL, ivMode); aes_change_ctrmode(iv, AES_INPUT_BE | AES_INPUT_NORMAL, ivMode);
} }
// Advance counter for CTR mode // Advance counter for CTR mode
else if((mode & AES_ALL_MODES) == AES_CTR_MODE) else if((mode & AES_ALL_MODES) == AES_CTR_MODE)
aes_advctr(iv, blocks, ivMode); aes_advctr(iv, blocks, ivMode);
src += blocks * AES_BLOCK_SIZE; src += blocks * AES_BLOCK_SIZE;
dst += blocks * AES_BLOCK_SIZE; dst += blocks * AES_BLOCK_SIZE;
blockCount -= blocks; blockCount -= blocks;
} }
} }
static void sha_wait_idle() static void sha_wait_idle()
{ {
while(*REG_SHA_CNT & 1); while(*REG_SHA_CNT & 1);
} }
static void sha(void *res, const void *src, u32 size, u32 mode) static void sha(void *res, const void *src, u32 size, u32 mode)
{ {
sha_wait_idle(); sha_wait_idle();
*REG_SHA_CNT = mode | SHA_CNT_OUTPUT_ENDIAN | SHA_NORMAL_ROUND; *REG_SHA_CNT = mode | SHA_CNT_OUTPUT_ENDIAN | SHA_NORMAL_ROUND;
const u32 *src32 = (const u32 *)src; const u32 *src32 = (const u32 *)src;
int i; int i;
while(size >= 0x40) while(size >= 0x40)
{ {
sha_wait_idle(); sha_wait_idle();
for(i = 0; i < 4; ++i) for(i = 0; i < 4; ++i)
{ {
*REG_SHA_INFIFO = *src32++; *REG_SHA_INFIFO = *src32++;
*REG_SHA_INFIFO = *src32++; *REG_SHA_INFIFO = *src32++;
*REG_SHA_INFIFO = *src32++; *REG_SHA_INFIFO = *src32++;
*REG_SHA_INFIFO = *src32++; *REG_SHA_INFIFO = *src32++;
} }
size -= 0x40; size -= 0x40;
} }
sha_wait_idle(); sha_wait_idle();
memcpy((void *)REG_SHA_INFIFO, src32, size); memcpy((void *)REG_SHA_INFIFO, src32, size);
*REG_SHA_CNT = (*REG_SHA_CNT & ~SHA_NORMAL_ROUND) | SHA_FINAL_ROUND; *REG_SHA_CNT = (*REG_SHA_CNT & ~SHA_NORMAL_ROUND) | SHA_FINAL_ROUND;
while(*REG_SHA_CNT & SHA_FINAL_ROUND); while(*REG_SHA_CNT & SHA_FINAL_ROUND);
sha_wait_idle(); sha_wait_idle();
u32 hashSize = SHA_256_HASH_SIZE; u32 hashSize = SHA_256_HASH_SIZE;
if(mode == SHA_224_MODE) if(mode == SHA_224_MODE)
hashSize = SHA_224_HASH_SIZE; hashSize = SHA_224_HASH_SIZE;
else if(mode == SHA_1_MODE) else if(mode == SHA_1_MODE)
hashSize = SHA_1_HASH_SIZE; hashSize = SHA_1_HASH_SIZE;
memcpy(res, (void *)REG_SHA_HASH, hashSize); memcpy(res, (void *)REG_SHA_HASH, hashSize);
} }
/**************************************************************** /****************************************************************
@ -289,7 +289,7 @@ void ctrNandInit(void)
sha(shaSum, cid, 0x10, SHA_256_MODE); sha(shaSum, cid, 0x10, SHA_256_MODE);
memcpy(nandCTR, shaSum, 0x10); memcpy(nandCTR, shaSum, 0x10);
if(console) if(isN3DS)
{ {
u8 keyY0x5[0x10] = {0x4D, 0x80, 0x4F, 0x4E, 0x99, 0x90, 0x19, 0x46, 0x13, 0xA2, 0x04, 0xAC, 0x58, 0x44, 0x60, 0xBE}; u8 keyY0x5[0x10] = {0x4D, 0x80, 0x4F, 0x4E, 0x99, 0x90, 0x19, 0x46, 0x13, 0xA2, 0x04, 0xAC, 0x58, 0x44, 0x60, 0xBE};
aes_setkey(0x05, keyY0x5, AES_KEYY, AES_INPUT_BE | AES_INPUT_NORMAL); aes_setkey(0x05, keyY0x5, AES_KEYY, AES_INPUT_BE | AES_INPUT_NORMAL);
@ -312,7 +312,7 @@ u32 ctrNandRead(u32 sector, u32 sectorCount, u8 *outbuf)
//Read //Read
u32 result; u32 result;
if(!firmSource) if(firmSource == FIRMWARE_SYSNAND)
result = sdmmc_nand_readsectors(sector + fatStart, sectorCount, outbuf); result = sdmmc_nand_readsectors(sector + fatStart, sectorCount, outbuf);
else else
{ {
@ -368,7 +368,7 @@ void arm9Loader(u8 *arm9Section, u32 mode)
key2[0x10] = {0x42, 0x3F, 0x81, 0x7A, 0x23, 0x52, 0x58, 0x31, 0x6E, 0x75, 0x8E, 0x3A, 0x39, 0x43, 0x2E, 0xD0}; key2[0x10] = {0x42, 0x3F, 0x81, 0x7A, 0x23, 0x52, 0x58, 0x31, 0x6E, 0x75, 0x8E, 0x3A, 0x39, 0x43, 0x2E, 0xD0};
u8 keyX[0x10]; u8 keyX[0x10];
aes_setkey(0x11, mode == 1 ? key2 : key1, AES_KEYNORMAL, AES_INPUT_BE | AES_INPUT_NORMAL); aes_setkey(0x11, mode == 2 ? key2 : key1, AES_KEYNORMAL, AES_INPUT_BE | AES_INPUT_NORMAL);
aes_use_keyslot(0x11); aes_use_keyslot(0x11);
aes(keyX, arm9Section + 0x60, 1, NULL, AES_ECB_DECRYPT_MODE, 0); aes(keyX, arm9Section + 0x60, 1, NULL, AES_ECB_DECRYPT_MODE, 0);
aes_setkey(arm9BinSlot, keyX, AES_KEYX, AES_INPUT_BE | AES_INPUT_NORMAL); aes_setkey(arm9BinSlot, keyX, AES_KEYX, AES_INPUT_BE | AES_INPUT_NORMAL);
@ -382,7 +382,7 @@ void arm9Loader(u8 *arm9Section, u32 mode)
aes(arm9Section + 0x800, arm9Section + 0x800, arm9BinSize / AES_BLOCK_SIZE, arm9BinCTR, AES_CTR_MODE, AES_INPUT_BE | AES_INPUT_NORMAL); aes(arm9Section + 0x800, arm9Section + 0x800, arm9BinSize / AES_BLOCK_SIZE, arm9BinCTR, AES_CTR_MODE, AES_INPUT_BE | AES_INPUT_NORMAL);
//Set >=9.6 KeyXs //Set >=9.6 KeyXs
if(mode == 1) if(mode == 2)
{ {
u8 keyData[0x10] = {0xDD, 0xDA, 0xA4, 0xC6, 0x2C, 0xC4, 0x50, 0xE9, 0xDA, 0xB6, 0x9B, 0x0D, 0x9D, 0x2A, 0x21, 0x98}, u8 keyData[0x10] = {0xDD, 0xDA, 0xA4, 0xC6, 0x2C, 0xC4, 0x50, 0xE9, 0xDA, 0xB6, 0x9B, 0x0D, 0x9D, 0x2A, 0x21, 0x98},
decKey[0x10]; decKey[0x10];

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@ -9,77 +9,78 @@
#include "types.h" #include "types.h"
/**************************AES****************************/ /**************************AES****************************/
#define REG_AESCNT ((vu32 *)0x10009000) #define REG_AESCNT ((vu32 *)0x10009000)
#define REG_AESBLKCNT ((vu32 *)0x10009004) #define REG_AESBLKCNT ((vu32 *)0x10009004)
#define REG_AESWRFIFO ((vu32 *)0x10009008) #define REG_AESWRFIFO ((vu32 *)0x10009008)
#define REG_AESRDFIFO ((vu32 *)0x1000900C) #define REG_AESRDFIFO ((vu32 *)0x1000900C)
#define REG_AESKEYSEL ((vu8 *)0x10009010) #define REG_AESKEYSEL ((vu8 *)0x10009010)
#define REG_AESKEYCNT ((vu8 *)0x10009011) #define REG_AESKEYCNT ((vu8 *)0x10009011)
#define REG_AESCTR ((vu32 *)0x10009020) #define REG_AESCTR ((vu32 *)0x10009020)
#define REG_AESKEYFIFO ((vu32 *)0x10009100) #define REG_AESKEYFIFO ((vu32 *)0x10009100)
#define REG_AESKEYXFIFO ((vu32 *)0x10009104) #define REG_AESKEYXFIFO ((vu32 *)0x10009104)
#define REG_AESKEYYFIFO ((vu32 *)0x10009108) #define REG_AESKEYYFIFO ((vu32 *)0x10009108)
#define AES_CCM_DECRYPT_MODE (0u << 27) #define AES_CCM_DECRYPT_MODE (0u << 27)
#define AES_CCM_ENCRYPT_MODE (1u << 27) #define AES_CCM_ENCRYPT_MODE (1u << 27)
#define AES_CTR_MODE (2u << 27) #define AES_CTR_MODE (2u << 27)
#define AES_CTR_MODE (2u << 27) #define AES_CTR_MODE (2u << 27)
#define AES_CBC_DECRYPT_MODE (4u << 27) #define AES_CBC_DECRYPT_MODE (4u << 27)
#define AES_CBC_ENCRYPT_MODE (5u << 27) #define AES_CBC_ENCRYPT_MODE (5u << 27)
#define AES_ECB_DECRYPT_MODE (6u << 27) #define AES_ECB_DECRYPT_MODE (6u << 27)
#define AES_ECB_ENCRYPT_MODE (7u << 27) #define AES_ECB_ENCRYPT_MODE (7u << 27)
#define AES_ALL_MODES (7u << 27) #define AES_ALL_MODES (7u << 27)
#define AES_CNT_START 0x80000000 #define AES_CNT_START 0x80000000
#define AES_CNT_INPUT_ORDER 0x02000000 #define AES_CNT_INPUT_ORDER 0x02000000
#define AES_CNT_OUTPUT_ORDER 0x01000000 #define AES_CNT_OUTPUT_ORDER 0x01000000
#define AES_CNT_INPUT_ENDIAN 0x00800000 #define AES_CNT_INPUT_ENDIAN 0x00800000
#define AES_CNT_OUTPUT_ENDIAN 0x00400000 #define AES_CNT_OUTPUT_ENDIAN 0x00400000
#define AES_CNT_FLUSH_READ 0x00000800 #define AES_CNT_FLUSH_READ 0x00000800
#define AES_CNT_FLUSH_WRITE 0x00000400 #define AES_CNT_FLUSH_WRITE 0x00000400
#define AES_INPUT_BE (AES_CNT_INPUT_ENDIAN) #define AES_INPUT_BE (AES_CNT_INPUT_ENDIAN)
#define AES_INPUT_LE 0 #define AES_INPUT_LE 0
#define AES_INPUT_NORMAL (AES_CNT_INPUT_ORDER) #define AES_INPUT_NORMAL (AES_CNT_INPUT_ORDER)
#define AES_INPUT_REVERSED 0 #define AES_INPUT_REVERSED 0
#define AES_BLOCK_SIZE 0x10 #define AES_BLOCK_SIZE 0x10
#define AES_KEYCNT_WRITE (1 << 0x7) #define AES_KEYCNT_WRITE (1 << 0x7)
#define AES_KEYNORMAL 0 #define AES_KEYNORMAL 0
#define AES_KEYX 1 #define AES_KEYX 1
#define AES_KEYY 2 #define AES_KEYY 2
/**************************SHA****************************/ /**************************SHA****************************/
#define REG_SHA_CNT ((vu32 *)0x1000A000) #define REG_SHA_CNT ((vu32 *)0x1000A000)
#define REG_SHA_BLKCNT ((vu32 *)0x1000A004) #define REG_SHA_BLKCNT ((vu32 *)0x1000A004)
#define REG_SHA_HASH ((vu32 *)0x1000A040) #define REG_SHA_HASH ((vu32 *)0x1000A040)
#define REG_SHA_INFIFO ((vu32 *)0x1000A080) #define REG_SHA_INFIFO ((vu32 *)0x1000A080)
#define SHA_CNT_STATE 0x00000003 #define SHA_CNT_STATE 0x00000003
#define SHA_CNT_UNK2 0x00000004 #define SHA_CNT_UNK2 0x00000004
#define SHA_CNT_OUTPUT_ENDIAN 0x00000008 #define SHA_CNT_OUTPUT_ENDIAN 0x00000008
#define SHA_CNT_MODE 0x00000030 #define SHA_CNT_MODE 0x00000030
#define SHA_CNT_ENABLE 0x00010000 #define SHA_CNT_ENABLE 0x00010000
#define SHA_CNT_ACTIVE 0x00020000 #define SHA_CNT_ACTIVE 0x00020000
#define SHA_HASH_READY 0x00000000 #define SHA_HASH_READY 0x00000000
#define SHA_NORMAL_ROUND 0x00000001 #define SHA_NORMAL_ROUND 0x00000001
#define SHA_FINAL_ROUND 0x00000002 #define SHA_FINAL_ROUND 0x00000002
#define SHA_OUTPUT_BE SHA_CNT_OUTPUT_ENDIAN #define SHA_OUTPUT_BE SHA_CNT_OUTPUT_ENDIAN
#define SHA_OUTPUT_LE 0 #define SHA_OUTPUT_LE 0
#define SHA_256_MODE 0 #define SHA_256_MODE 0
#define SHA_224_MODE 0x00000010 #define SHA_224_MODE 0x00000010
#define SHA_1_MODE 0x00000020 #define SHA_1_MODE 0x00000020
#define SHA_256_HASH_SIZE (256 / 8) #define SHA_256_HASH_SIZE (256 / 8)
#define SHA_224_HASH_SIZE (224 / 8) #define SHA_224_HASH_SIZE (224 / 8)
#define SHA_1_HASH_SIZE (160 / 8) #define SHA_1_HASH_SIZE (160 / 8)
extern u32 emuOffset, console, firmSource; extern u32 emuOffset, isN3DS;
extern FirmwareSource firmSource;
void ctrNandInit(void); void ctrNandInit(void);
u32 ctrNandRead(u32 sector, u32 sectorCount, u8 *outbuf); u32 ctrNandRead(u32 sector, u32 sectorCount, u8 *outbuf);

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@ -7,12 +7,12 @@
#include "fatfs/sdmmc/sdmmc.h" #include "fatfs/sdmmc/sdmmc.h"
#include "../build/emunandpatch.h" #include "../build/emunandpatch.h"
void locateEmuNAND(u32 *off, u32 *head, u32 *emuNAND) void locateEmuNAND(u32 *off, u32 *head, FirmwareSource *emuNAND)
{ {
static u8 *const temp = (u8 *)0x24300000; static u8 *const temp = (u8 *)0x24300000;
const u32 nandSize = getMMCDevice(0)->total_size; const u32 nandSize = getMMCDevice(0)->total_size;
u32 nandOffset = *emuNAND == 1 ? 0 : u32 nandOffset = *emuNAND == FIRMWARE_EMUNAND ? 0 :
(nandSize > 0x200000 ? 0x400000 : 0x200000); (nandSize > 0x200000 ? 0x400000 : 0x200000);
//Check for RedNAND //Check for RedNAND
@ -35,7 +35,7 @@ void locateEmuNAND(u32 *off, u32 *head, u32 *emuNAND)
or to SysNAND if there isn't any */ or to SysNAND if there isn't any */
else else
{ {
(*emuNAND)--; *emuNAND = (*emuNAND == FIRMWARE_EMUNAND2) ? FIRMWARE_EMUNAND : FIRMWARE_SYSNAND;
if(*emuNAND) locateEmuNAND(off, head, emuNAND); if(*emuNAND) locateEmuNAND(off, head, emuNAND);
} }
} }

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@ -8,5 +8,5 @@
#define NCSD_MAGIC 0x4453434E #define NCSD_MAGIC 0x4453434E
void locateEmuNAND(u32 *off, u32 *head, u32 *emuNAND); void locateEmuNAND(u32 *off, u32 *head, FirmwareSource *emuNAND);
void patchEmuNAND(u8 *arm9Section, u32 arm9SectionSize, u8 *process9Offset, u32 process9Size, u32 emuOffset, u32 emuHeader, u32 branchAdditive); void patchEmuNAND(u8 *arm9Section, u32 arm9SectionSize, u8 *process9Offset, u32 process9Size, u32 emuOffset, u32 emuHeader, u32 branchAdditive);

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@ -19,24 +19,26 @@ static firmHeader *const firm = (firmHeader *)0x24000000;
static const firmSectionHeader *section; static const firmSectionHeader *section;
u32 config, u32 config,
console, isN3DS,
firmSource,
emuOffset; emuOffset;
FirmwareSource firmSource;
void main(void) void main(void)
{ {
u32 bootType, u32 isFirmlaunch,
firmType,
nandType,
a9lhMode,
updatedSys, updatedSys,
needConfig,
newConfig, newConfig,
emuHeader, emuHeader,
chronoStarted = 0; nbChronoStarted = 0;
FirmwareType firmType;
FirmwareSource nandType;
ConfigurationStatus needConfig;
A9LHMode a9lhMode;
//Detect the console being used //Detect the console being used
console = PDN_MPCORE_CFG == 7; isN3DS = PDN_MPCORE_CFG == 7;
//Mount filesystems. CTRNAND will be mounted only if/when needed //Mount filesystems. CTRNAND will be mounted only if/when needed
mountFs(); mountFs();
@ -44,22 +46,22 @@ void main(void)
const char configPath[] = "/luma/config.bin"; const char configPath[] = "/luma/config.bin";
//Attempt to read the configuration file //Attempt to read the configuration file
needConfig = fileRead(&config, configPath) ? 1 : 2; needConfig = fileRead(&config, configPath) ? MODIFY_CONFIGURATION : CREATE_CONFIGURATION;
//Determine if this is a firmlaunch boot //Determine if this is a firmlaunch boot
if(*(vu8 *)0x23F00005) if(*(vu8 *)0x23F00005)
{ {
if(needConfig == 2) mcuReboot(); if(needConfig == CREATE_CONFIGURATION) mcuReboot();
bootType = 1; isFirmlaunch = 1;
//'0' = NATIVE_FIRM, '1' = TWL_FIRM, '2' = AGB_FIRM //'0' = NATIVE_FIRM, '1' = TWL_FIRM, '2' = AGB_FIRM
firmType = *(vu8 *)0x23F00009 == '3' ? 3 : *(vu8 *)0x23F00005 - '0'; firmType = *(vu8 *)0x23F00009 == '3' ? SAFE_FIRM : (FirmwareType)(*(vu8 *)0x23F00005 - '0');
nandType = BOOTCONFIG(0, 3); nandType = (FirmwareSource)BOOTCONFIG(0, 3);
firmSource = BOOTCONFIG(2, 1); firmSource = (FirmwareSource)BOOTCONFIG(2, 1);
a9lhMode = BOOTCONFIG(3, 1); a9lhMode = (A9LHMode)BOOTCONFIG(3, 1);
updatedSys = a9lhMode && CONFIG(1); updatedSys = a9lhMode != NO_A9LH && CONFIG(1);
} }
else else
{ {
@ -67,14 +69,14 @@ void main(void)
u32 pressed = HID_PAD; u32 pressed = HID_PAD;
//If no configuration file exists or SELECT is held, load configuration menu //If no configuration file exists or SELECT is held, load configuration menu
if(needConfig == 2 || ((pressed & BUTTON_SELECT) && !(pressed & BUTTON_L1))) if(needConfig == CREATE_CONFIGURATION || ((pressed & BUTTON_SELECT) && !(pressed & BUTTON_L1)))
{ {
configureCFW(configPath); configureCFW(configPath);
//Zero the last booted FIRM flag //Zero the last booted FIRM flag
CFG_BOOTENV = 0; CFG_BOOTENV = 0;
chronoStarted = 1; nbChronoStarted = 1;
chrono(0); chrono(0);
chrono(2); chrono(2);
@ -82,8 +84,8 @@ void main(void)
pressed = HID_PAD; pressed = HID_PAD;
} }
bootType = 0; isFirmlaunch = 0;
firmType = 0; firmType = NATIVE_FIRM;
//Determine if booting with A9LH //Determine if booting with A9LH
u32 a9lhBoot = !PDN_SPI_CNT; u32 a9lhBoot = !PDN_SPI_CNT;
@ -91,31 +93,28 @@ void main(void)
//Determine if A9LH is installed and the user has an updated sysNAND //Determine if A9LH is installed and the user has an updated sysNAND
if(a9lhBoot || CONFIG(2)) if(a9lhBoot || CONFIG(2))
{ {
a9lhMode = 1; a9lhMode = A9LH_WITH_NFIRM_FIRMPROT;
updatedSys = CONFIG(1); updatedSys = CONFIG(1);
} }
else else
{ {
a9lhMode = 0; a9lhMode = NO_A9LH;
updatedSys = 0; updatedSys = 0;
} }
newConfig = a9lhMode << 3; newConfig = (u32)a9lhMode << 3;
if(a9lhBoot) if(a9lhBoot)
{ {
//Retrieve the last booted FIRM
u32 previousFirm = CFG_BOOTENV;
//If it's a MCU reboot, try to force boot options //If it's a MCU reboot, try to force boot options
if(previousFirm) if(CFG_BOOTENV)
{ {
//Always force a sysNAND boot when quitting AGB_FIRM //Always force a sysNAND boot when quitting AGB_FIRM
if(previousFirm == 7) if(CFG_BOOTENV == 7)
{ {
nandType = 0; nandType = FIRMWARE_SYSNAND;
firmSource = updatedSys ? 0 : BOOTCONFIG(2, 1); firmSource = updatedSys ? FIRMWARE_SYSNAND : (FirmwareSource)BOOTCONFIG(2, 1);
needConfig = 0; needConfig = DONT_CONFIGURE;
//Flag to prevent multiple boot options-forcing //Flag to prevent multiple boot options-forcing
newConfig |= 1 << 4; newConfig |= 1 << 4;
@ -125,19 +124,19 @@ void main(void)
or the no-forcing flag is set */ or the no-forcing flag is set */
else if(!pressed && !BOOTCONFIG(4, 1)) else if(!pressed && !BOOTCONFIG(4, 1))
{ {
nandType = BOOTCONFIG(0, 3); nandType = (FirmwareSource)BOOTCONFIG(0, 3);
firmSource = BOOTCONFIG(2, 1); firmSource = (FirmwareSource)BOOTCONFIG(2, 1);
needConfig = 0; needConfig = DONT_CONFIGURE;
} }
} }
//If the SAFE MODE combo is held, force a sysNAND boot //If the SAFE MODE combo is held, force a sysNAND boot
else if(pressed == SAFE_MODE) else if(pressed == SAFE_MODE)
{ {
a9lhMode = 2; a9lhMode = A9LH_WITH_SFIRM_FIRMPROT;
nandType = 0; nandType = FIRMWARE_SYSNAND;
firmSource = 0; firmSource = FIRMWARE_SYSNAND;
needConfig = 0; needConfig = DONT_CONFIGURE;
} }
} }
@ -152,45 +151,45 @@ void main(void)
//If screens are inited or the corresponding option is set, load splash screen //If screens are inited or the corresponding option is set, load splash screen
if((PDN_GPU_CNT != 1 || CONFIG(7)) && loadSplash()) if((PDN_GPU_CNT != 1 || CONFIG(7)) && loadSplash())
{ {
chronoStarted = 2; nbChronoStarted = 2;
chrono(0); chrono(0);
} }
//If R is pressed, boot the non-updated NAND with the FIRM of the opposite one //If R is pressed, boot the non-updated NAND with the FIRM of the opposite one
if(pressed & BUTTON_R1) if(pressed & BUTTON_R1)
{ {
nandType = updatedSys; nandType = (updatedSys) ? FIRMWARE_EMUNAND : FIRMWARE_SYSNAND;
firmSource = !nandType; firmSource = (updatedSys) ? FIRMWARE_SYSNAND : FIRMWARE_EMUNAND;
} }
/* Else, boot the NAND the user set to autoboot or the opposite one, depending on L, /* Else, boot the NAND the user set to autoboot or the opposite one, depending on L,
with their own FIRM */ with their own FIRM */
else else
{ {
nandType = CONFIG(0) != !(pressed & BUTTON_L1); nandType = (CONFIG(0) != !(pressed & BUTTON_L1)) ? FIRMWARE_EMUNAND : FIRMWARE_SYSNAND;
firmSource = nandType; firmSource = nandType;
} }
/* If we're booting emuNAND the second emuNAND is set as default and B isn't pressed, /* If we're booting emuNAND the second emuNAND is set as default and B isn't pressed,
or vice-versa, boot the second emuNAND */ or vice-versa, boot the second emuNAND */
if(nandType && (CONFIG(3) == !(pressed & BUTTON_B))) nandType = 2; if(nandType != FIRMWARE_SYSNAND && (CONFIG(3) == !(pressed & BUTTON_B))) nandType = FIRMWARE_EMUNAND2;
} }
} }
//If we need to boot emuNAND, make sure it exists //If we need to boot emuNAND, make sure it exists
if(nandType) if(nandType != FIRMWARE_SYSNAND)
{ {
locateEmuNAND(&emuOffset, &emuHeader, &nandType); locateEmuNAND(&emuOffset, &emuHeader, &nandType);
if(!nandType) firmSource = 0; if(nandType == FIRMWARE_SYSNAND) firmSource = FIRMWARE_SYSNAND;
} }
//Same if we're using emuNAND as the FIRM source //Same if we're using emuNAND as the FIRM source
else if(firmSource) else if(firmSource != FIRMWARE_SYSNAND)
locateEmuNAND(&emuOffset, &emuHeader, &firmSource); locateEmuNAND(&emuOffset, &emuHeader, &firmSource);
if(!bootType) if(!isFirmlaunch)
{ {
newConfig |= nandType | (firmSource << 2); newConfig |= (u32)nandType | ((u32)firmSource << 2);
/* If the boot configuration is different from previously, overwrite it. /* If the boot configuration is different from previously, overwrite it.
Just the no-forcing flag being set is not enough */ Just the no-forcing flag being set is not enough */
@ -203,14 +202,14 @@ void main(void)
} }
} }
loadFirm(firmType, !firmType && updatedSys == !firmSource); loadFirm(firmType, firmType == NATIVE_FIRM && firmSource == ((updatedSys) ? FIRMWARE_SYSNAND : FIRMWARE_EMUNAND));
switch(firmType) switch(firmType)
{ {
case 0: case NATIVE_FIRM:
patchNativeFirm(nandType, emuHeader, a9lhMode); patchNativeFirm(nandType, emuHeader, a9lhMode);
break; break;
case 3: case SAFE_FIRM:
patchSafeFirm(); patchSafeFirm();
break; break;
default: default:
@ -218,22 +217,22 @@ void main(void)
break; break;
} }
if(chronoStarted) if(nbChronoStarted)
{ {
if(chronoStarted == 2) chrono(3); if(nbChronoStarted == 2) chrono(3);
stopChrono(); stopChrono();
} }
launchFirm(firmType, bootType); launchFirm(firmType, isFirmlaunch);
} }
static inline void loadFirm(u32 firmType, u32 externalFirm) static inline void loadFirm(FirmwareType firmType, u32 externalFirm)
{ {
section = firm->section; section = firm->section;
u32 externalFirmLoaded = externalFirm && u32 externalFirmLoaded = externalFirm &&
fileRead(firm, "/luma/firmware.bin") && fileRead(firm, "/luma/firmware.bin") &&
(((u32)section[2].address >> 8) & 0xFF) == (console ? 0x60 : 0x68); (((u32)section[2].address >> 8) & 0xFF) == (isN3DS ? 0x60 : 0x68);
/* If the conditions to load the external FIRM aren't met, or reading fails, or the FIRM /* If the conditions to load the external FIRM aren't met, or reading fails, or the FIRM
doesn't match the console, load FIRM from CTRNAND */ doesn't match the console, load FIRM from CTRNAND */
@ -244,42 +243,45 @@ static inline void loadFirm(u32 firmType, u32 externalFirm)
{ "00000202", "20000202" }, { "00000202", "20000202" },
{ "00000003", "20000003" }}; { "00000003", "20000003" }};
firmRead(firm, firmFolders[firmType][console]); firmRead(firm, firmFolders[(u32)firmType][isN3DS]);
decryptExeFs((u8 *)firm); decryptExeFs((u8 *)firm);
} }
} }
static inline void patchNativeFirm(u32 nandType, u32 emuHeader, u32 a9lhMode) static inline void patchNativeFirm(FirmwareSource nandType, u32 emuHeader, A9LHMode a9lhMode)
{ {
u8 *arm9Section = (u8 *)firm + section[2].offset; u8 *arm9Section = (u8 *)firm + section[2].offset;
u32 nativeFirmType; u32 is90Firm;
if(console) if(isN3DS)
{ {
//Determine the NATIVE_FIRM version u32 a9lVersion;
//Determine the NATIVE_FIRM/arm9loader version
switch(arm9Section[0x53]) switch(arm9Section[0x53])
{ {
case 0xFF: case 0xFF:
nativeFirmType = 0; a9lVersion = 0;
break; break;
case '1': case '1':
nativeFirmType = 2; a9lVersion = 1;
break; break;
default: default:
nativeFirmType = 1; a9lVersion = 2;
break; break;
} }
//Decrypt ARM9Bin and patch ARM9 entrypoint to skip arm9loader //Decrypt ARM9Bin and patch ARM9 entrypoint to skip arm9loader
arm9Loader(arm9Section, nativeFirmType); arm9Loader(arm9Section, a9lVersion);
firm->arm9Entry = (u8 *)0x801B01C; firm->arm9Entry = (u8 *)0x801B01C;
is90Firm = a9lVersion == 0;
} }
else else
{ {
//Determine if we're booting the 9.0 FIRM //Determine if we're booting the 9.0 FIRM
u8 firm90Hash[0x10] = {0x27, 0x2D, 0xFE, 0xEB, 0xAF, 0x3F, 0x6B, 0x3B, 0xF5, 0xDE, 0x4C, 0x41, 0xDE, 0x95, 0x27, 0x6A}; u8 firm90Hash[0x10] = {0x27, 0x2D, 0xFE, 0xEB, 0xAF, 0x3F, 0x6B, 0x3B, 0xF5, 0xDE, 0x4C, 0x41, 0xDE, 0x95, 0x27, 0x6A};
nativeFirmType = memcmp(section[2].hash, firm90Hash, 0x10) != 0; is90Firm = memcmp(section[2].hash, firm90Hash, 0x10) == 0;
} }
//Find the Process9 .code location, size and memory address //Find the Process9 .code location, size and memory address
@ -298,12 +300,12 @@ static inline void patchNativeFirm(u32 nandType, u32 emuHeader, u32 a9lhMode)
} }
//Apply FIRM0/1 writes patches on sysNAND to protect A9LH //Apply FIRM0/1 writes patches on sysNAND to protect A9LH
else if(a9lhMode) patchFirmWrites(process9Offset, process9Size); else if(a9lhMode != NO_A9LH) patchFirmWrites(process9Offset, process9Size);
//Apply firmlaunch patches, not on 9.0 FIRM as it breaks firmlaunchhax //Apply firmlaunch patches, not on 9.0 FIRM as it breaks firmlaunchhax
if(nativeFirmType || a9lhMode == 2) patchFirmlaunches(process9Offset, process9Size, process9MemAddr); if(!is90Firm || a9lhMode == A9LH_WITH_SFIRM_FIRMPROT) patchFirmlaunches(process9Offset, process9Size, process9MemAddr);
if(nativeFirmType == 1) if(!is90Firm)
{ {
//Apply anti-anti-DG patches for >= 11.0 firmwares //Apply anti-anti-DG patches for >= 11.0 firmwares
patchTitleInstallMinVersionCheck(process9Offset, process9Size); patchTitleInstallMinVersionCheck(process9Offset, process9Size);
@ -313,23 +315,23 @@ static inline void patchNativeFirm(u32 nandType, u32 emuHeader, u32 a9lhMode)
} }
} }
static inline void patchLegacyFirm(u32 firmType) static inline void patchLegacyFirm(FirmwareType firmType)
{ {
//On N3DS, decrypt ARM9Bin and patch ARM9 entrypoint to skip arm9loader //On N3DS, decrypt ARM9Bin and patch ARM9 entrypoint to skip arm9loader
if(console) if(isN3DS)
{ {
arm9Loader((u8 *)firm + section[3].offset, 0); arm9Loader((u8 *)firm + section[3].offset, 0);
firm->arm9Entry = (u8 *)0x801301C; firm->arm9Entry = (u8 *)0x801301C;
} }
applyLegacyFirmPatches((u8 *)firm, firmType, console); applyLegacyFirmPatches((u8 *)firm, firmType, isN3DS);
} }
static inline void patchSafeFirm(void) static inline void patchSafeFirm(void)
{ {
u8 *arm9Section = (u8 *)firm + section[2].offset; u8 *arm9Section = (u8 *)firm + section[2].offset;
if(console) if(isN3DS)
{ {
//Decrypt ARM9Bin and patch ARM9 entrypoint to skip arm9loader //Decrypt ARM9Bin and patch ARM9 entrypoint to skip arm9loader
arm9Loader(arm9Section, 0); arm9Loader(arm9Section, 0);
@ -352,11 +354,11 @@ static inline void copySection0AndInjectLoader(void)
memcpy(section[0].address + loaderOffset + injector_size, arm11Section0 + loaderOffset + loaderSize, section[0].size - (loaderOffset + loaderSize)); memcpy(section[0].address + loaderOffset + injector_size, arm11Section0 + loaderOffset + loaderSize, section[0].size - (loaderOffset + loaderSize));
} }
static inline void launchFirm(u32 firmType, u32 bootType) static inline void launchFirm(FirmwareType firmType, u32 isFirmlaunch)
{ {
//If we're booting NATIVE_FIRM, section0 needs to be copied separately to inject 3ds_injector //If we're booting NATIVE_FIRM, section0 needs to be copied separately to inject 3ds_injector
u32 sectionNum; u32 sectionNum;
if(!firmType) if(firmType == NATIVE_FIRM)
{ {
copySection0AndInjectLoader(); copySection0AndInjectLoader();
sectionNum = 1; sectionNum = 1;
@ -369,7 +371,7 @@ static inline void launchFirm(u32 firmType, u32 bootType)
//Determine the ARM11 entry to use //Determine the ARM11 entry to use
vu32 *arm11; vu32 *arm11;
if(bootType) arm11 = (u32 *)0x1FFFFFFC; if(isFirmlaunch) arm11 = (u32 *)0x1FFFFFFC;
else else
{ {
deinitScreens(); deinitScreens();

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@ -28,9 +28,23 @@ typedef struct firmHeader {
firmSectionHeader section[4]; firmSectionHeader section[4];
} firmHeader; } firmHeader;
static inline void loadFirm(u32 firmType, u32 externalFirm); typedef enum ConfigurationStatus
static inline void patchNativeFirm(u32 nandType, u32 emuHeader, u32 a9lhMode); {
static inline void patchLegacyFirm(u32 firmType); DONT_CONFIGURE = 0,
MODIFY_CONFIGURATION = 1,
CREATE_CONFIGURATION = 2
} ConfigurationStatus;
typedef enum A9LHMode
{
NO_A9LH = 0,
A9LH_WITH_NFIRM_FIRMPROT = 1,
A9LH_WITH_SFIRM_FIRMPROT = 2
} A9LHMode;
static inline void loadFirm(FirmwareType firmType, u32 externalFirm);
static inline void patchNativeFirm(FirmwareSource nandType, u32 emuHeader, A9LHMode a9lhMode);
static inline void patchLegacyFirm(FirmwareType firmType);
static inline void patchSafeFirm(void); static inline void patchSafeFirm(void);
static inline void copySection0AndInjectLoader(void); static inline void copySection0AndInjectLoader(void);
static inline void launchFirm(u32 sectionNum, u32 bootType); static inline void launchFirm(FirmwareType firmType, u32 isFirmlaunch);

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@ -121,7 +121,7 @@ void patchTitleInstallMinVersionCheck(u8 *pos, u32 size)
if(off != NULL) off[4] = 0xE0; if(off != NULL) off[4] = 0xE0;
} }
void applyLegacyFirmPatches(u8 *pos, u32 firmType, u32 console) void applyLegacyFirmPatches(u8 *pos, FirmwareType firmType, u32 isN3DS)
{ {
const patchData twlPatches[] = { const patchData twlPatches[] = {
{{0x1650C0, 0x165D64}, {{ 6, 0x00, 0x20, 0x4E, 0xB0, 0x70, 0xBD }}, 0}, {{0x1650C0, 0x165D64}, {{ 6, 0x00, 0x20, 0x4E, 0xB0, 0x70, 0xBD }}, 0},
@ -141,9 +141,9 @@ void applyLegacyFirmPatches(u8 *pos, u32 firmType, u32 console)
/* Calculate the amount of patches to apply. Only count the boot screen patch for AGB_FIRM /* Calculate the amount of patches to apply. Only count the boot screen patch for AGB_FIRM
if the matching option was enabled (keep it as last) */ if the matching option was enabled (keep it as last) */
u32 numPatches = firmType == 1 ? (sizeof(twlPatches) / sizeof(patchData)) : u32 numPatches = firmType == TWL_FIRM ? (sizeof(twlPatches) / sizeof(patchData)) :
(sizeof(agbPatches) / sizeof(patchData) - !CONFIG(6)); (sizeof(agbPatches) / sizeof(patchData) - !CONFIG(6));
const patchData *patches = firmType == 1 ? twlPatches : agbPatches; const patchData *patches = firmType == TWL_FIRM ? twlPatches : agbPatches;
//Patch //Patch
for(u32 i = 0; i < numPatches; i++) for(u32 i = 0; i < numPatches; i++)
@ -151,12 +151,12 @@ void applyLegacyFirmPatches(u8 *pos, u32 firmType, u32 console)
switch(patches[i].type) switch(patches[i].type)
{ {
case 0: case 0:
memcpy(pos + patches[i].offset[console], patches[i].patch.type0 + 1, patches[i].patch.type0[0]); memcpy(pos + patches[i].offset[isN3DS], patches[i].patch.type0 + 1, patches[i].patch.type0[0]);
break; break;
case 2: case 2:
*(u16 *)(pos + patches[i].offset[console] + 2) = 0; *(u16 *)(pos + patches[i].offset[isN3DS] + 2) = 0;
case 1: case 1:
*(u16 *)(pos + patches[i].offset[console]) = patches[i].patch.type1; *(u16 *)(pos + patches[i].offset[isN3DS]) = patches[i].patch.type1;
break; break;
} }
} }

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@ -22,5 +22,5 @@ void patchFirmlaunches(u8 *pos, u32 size, u32 process9MemAddr);
void patchFirmWrites(u8 *pos, u32 size); void patchFirmWrites(u8 *pos, u32 size);
void patchFirmWriteSafe(u8 *pos, u32 size); void patchFirmWriteSafe(u8 *pos, u32 size);
void reimplementSvcBackdoor(u8 *pos, u32 size); void reimplementSvcBackdoor(u8 *pos, u32 size);
void applyLegacyFirmPatches(u8 *pos, u32 firmType, u32 console); void applyLegacyFirmPatches(u8 *pos, FirmwareType firmType, u32 isN3DS);
u32 getLoader(u8 *pos, u32 *loaderSize); u32 getLoader(u8 *pos, u32 *loaderSize);

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@ -16,3 +16,19 @@ typedef volatile u8 vu8;
typedef volatile u16 vu16; typedef volatile u16 vu16;
typedef volatile u32 vu32; typedef volatile u32 vu32;
typedef volatile u64 vu64; typedef volatile u64 vu64;
//Used by multiple files:
typedef enum FirmwareSource
{
FIRMWARE_SYSNAND = 0,
FIRMWARE_EMUNAND = 1,
FIRMWARE_EMUNAND2 = 2
} FirmwareSource;
typedef enum FirmwareType
{
NATIVE_FIRM = 0,
TWL_FIRM = 1,
AGB_FIRM = 2,
SAFE_FIRM = 3
} FirmwareType;