/* * This file is part of Luma3DS * Copyright (C) 2016-2017 Aurora Wright, TuxSH * * 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 3 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. * * You should have received a copy of the GNU General Public License * along with this program. If not, see . * * Additional Terms 7.b and 7.c of GPLv3 apply to this file: * * Requiring preservation of specified reasonable legal notices or * author attributions in that material or in the Appropriate Legal * Notices displayed by works containing it. * * Prohibiting misrepresentation of the origin of that material, * or requiring that modified versions of such material be marked in * reasonable ways as different from the original version. */ /* * Crypto libs from http://github.com/b1l1s/ctr * kernel9Loader code originally adapted from https://github.com/Reisyukaku/ReiNand/blob/228c378255ba693133dec6f3368e14d386f2cde7/source/crypto.c#L233 * decryptNusFirm code adapted from https://github.com/mid-kid/CakesForeveryWan/blob/master/source/firm.c * ctrNandWrite logic adapted from https://github.com/d0k3/GodMode9/blob/master/source/nand/nand.c */ #include "crypto.h" #include "memory.h" #include "emunand.h" #include "strings.h" #include "utils.h" #include "fatfs/sdmmc/sdmmc.h" /**************************************************************** * Crypto libs ****************************************************************/ /* original version by megazig */ #ifndef __thumb__ #define BSWAP32(x) {\ __asm__\ (\ "eor r1, %1, %1, ror #16\n\t"\ "bic r1, r1, #0xFF0000\n\t"\ "mov %0, %1, ror #8\n\t"\ "eor %0, %0, r1, lsr #8\n\t"\ :"=r"(x)\ :"0"(x)\ :"r1"\ );\ }; #define ADD_u128_u32(u128_0, u128_1, u128_2, u128_3, u32_0) {\ __asm__\ (\ "adds %0, %4\n\t"\ "addcss %1, %1, #1\n\t"\ "addcss %2, %2, #1\n\t"\ "addcs %3, %3, #1\n\t"\ : "+r"(u128_0), "+r"(u128_1), "+r"(u128_2), "+r"(u128_3)\ : "r"(u32_0)\ : "cc"\ );\ } #else #define BSWAP32(x) {x = __builtin_bswap32(x);} #define ADD_u128_u32(u128_0, u128_1, u128_2, u128_3, u32_0) {\ __asm__\ (\ "mov r4, #0\n\t"\ "add %0, %0, %4\n\t"\ "adc %1, %1, r4\n\t"\ "adc %2, %2, r4\n\t"\ "adc %3, %3, r4\n\t"\ : "+r"(u128_0), "+r"(u128_1), "+r"(u128_2), "+r"(u128_3)\ : "r"(u32_0)\ : "cc", "r4"\ );\ } #endif /*__thumb__*/ static void aes_setkey(u8 keyslot, const void *key, u32 keyType, u32 mode) { u32 *key32 = (u32 *)key; *REG_AESCNT = (*REG_AESCNT & ~(AES_CNT_INPUT_ENDIAN | AES_CNT_INPUT_ORDER)) | mode; if(keyslot <= 3) { if((mode & AES_CNT_INPUT_ORDER) == AES_INPUT_TWLREVERSED) { REGs_AESTWLKEYS[keyslot][keyType][0] = key32[3]; REGs_AESTWLKEYS[keyslot][keyType][1] = key32[2]; REGs_AESTWLKEYS[keyslot][keyType][2] = key32[1]; REGs_AESTWLKEYS[keyslot][keyType][3] = key32[0]; } else { REGs_AESTWLKEYS[keyslot][keyType][0] = key32[0]; REGs_AESTWLKEYS[keyslot][keyType][1] = key32[1]; REGs_AESTWLKEYS[keyslot][keyType][2] = key32[2]; REGs_AESTWLKEYS[keyslot][keyType][3] = key32[3]; } } else if(keyslot < 0x40) { *REG_AESKEYCNT = (*REG_AESKEYCNT >> 6 << 6) | keyslot | AES_KEYCNT_WRITE; REG_AESKEYFIFO[keyType] = key32[0]; REG_AESKEYFIFO[keyType] = key32[1]; REG_AESKEYFIFO[keyType] = key32[2]; REG_AESKEYFIFO[keyType] = key32[3]; } } static void aes_use_keyslot(u8 keyslot) { if(keyslot > 0x3F) return; *REG_AESKEYSEL = keyslot; *REG_AESCNT = *REG_AESCNT | 0x04000000; /* mystery bit */ } static void aes_setiv(const void *iv, u32 mode) { const u32 *iv32 = (const u32 *)iv; *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 if(mode & AES_INPUT_NORMAL) { REG_AESCTR[0] = iv32[3]; REG_AESCTR[1] = iv32[2]; REG_AESCTR[2] = iv32[1]; REG_AESCTR[3] = iv32[0]; } else { REG_AESCTR[0] = iv32[0]; REG_AESCTR[1] = iv32[1]; REG_AESCTR[2] = iv32[2]; REG_AESCTR[3] = iv32[3]; } } static void aes_advctr(void *ctr, u32 val, u32 mode) { u32 *ctr32 = (u32 *)ctr; int i; if(mode & AES_INPUT_BE) { for(i = 0; i < 4; ++i) //Endian swap BSWAP32(ctr32[i]); } if(mode & AES_INPUT_NORMAL) { ADD_u128_u32(ctr32[3], ctr32[2], ctr32[1], ctr32[0], val); } else { ADD_u128_u32(ctr32[0], ctr32[1], ctr32[2], ctr32[3], val); } if(mode & AES_INPUT_BE) { for(i = 0; i < 4; ++i) //Endian swap BSWAP32(ctr32[i]); } } static void aes_change_ctrmode(void *ctr, u32 fromMode, u32 toMode) { u32 *ctr32 = (u32 *)ctr; int i; if((fromMode ^ toMode) & AES_CNT_INPUT_ENDIAN) { for(i = 0; i < 4; ++i) BSWAP32(ctr32[i]); } if((fromMode ^ toMode) & AES_CNT_INPUT_ORDER) { u32 temp = ctr32[0]; ctr32[0] = ctr32[3]; ctr32[3] = temp; temp = ctr32[1]; ctr32[1] = ctr32[2]; ctr32[2] = temp; } } static void aes_batch(void *dst, const void *src, u32 blockCount) { *REG_AESBLKCNT = blockCount << 16; *REG_AESCNT |= AES_CNT_START; const u32 *src32 = (const u32 *)src; u32 *dst32 = (u32 *)dst; u32 wbc = blockCount; u32 rbc = blockCount; while(rbc) { 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++; wbc--; } 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; rbc--; } } } static void aes(void *dst, const void *src, u32 blockCount, void *iv, u32 mode, u32 ivMode) { *REG_AESCNT = mode | AES_CNT_INPUT_ORDER | AES_CNT_OUTPUT_ORDER | AES_CNT_INPUT_ENDIAN | AES_CNT_OUTPUT_ENDIAN | AES_CNT_FLUSH_READ | AES_CNT_FLUSH_WRITE; u32 blocks; while(blockCount != 0) { if((mode & AES_ALL_MODES) != AES_ECB_ENCRYPT_MODE && (mode & AES_ALL_MODES) != AES_ECB_DECRYPT_MODE) aes_setiv(iv, ivMode); blocks = (blockCount >= 0xFFFF) ? 0xFFFF : blockCount; //Save the last block for the next decryption CBC batch's iv if((mode & AES_ALL_MODES) == AES_CBC_DECRYPT_MODE) { memcpy(iv, src + (blocks - 1) * AES_BLOCK_SIZE, AES_BLOCK_SIZE); aes_change_ctrmode(iv, AES_INPUT_BE | AES_INPUT_NORMAL, ivMode); } //Process the current batch aes_batch(dst, src, blocks); //Save the last block for the next encryption CBC batch's iv if((mode & AES_ALL_MODES) == AES_CBC_ENCRYPT_MODE) { memcpy(iv, dst + (blocks - 1) * AES_BLOCK_SIZE, AES_BLOCK_SIZE); aes_change_ctrmode(iv, AES_INPUT_BE | AES_INPUT_NORMAL, ivMode); } //Advance counter for CTR mode else if((mode & AES_ALL_MODES) == AES_CTR_MODE) aes_advctr(iv, blocks, ivMode); src += blocks * AES_BLOCK_SIZE; dst += blocks * AES_BLOCK_SIZE; blockCount -= blocks; } } static void sha_wait_idle() { while(*REG_SHA_CNT & 1); } void sha(void *res, const void *src, u32 size, u32 mode) { sha_wait_idle(); *REG_SHA_CNT = mode | SHA_CNT_OUTPUT_ENDIAN | SHA_NORMAL_ROUND; const u32 *src32 = (const u32 *)src; int i; while(size >= 0x40) { sha_wait_idle(); for(i = 0; i < 4; ++i) { *REG_SHA_INFIFO = *src32++; *REG_SHA_INFIFO = *src32++; *REG_SHA_INFIFO = *src32++; *REG_SHA_INFIFO = *src32++; } size -= 0x40; } sha_wait_idle(); memcpy((void *)REG_SHA_INFIFO, src32, size); *REG_SHA_CNT = (*REG_SHA_CNT & ~SHA_NORMAL_ROUND) | SHA_FINAL_ROUND; while(*REG_SHA_CNT & SHA_FINAL_ROUND); sha_wait_idle(); u32 hashSize = SHA_256_HASH_SIZE; if(mode == SHA_224_MODE) hashSize = SHA_224_HASH_SIZE; else if(mode == SHA_1_MODE) hashSize = SHA_1_HASH_SIZE; memcpy(res, (void *)REG_SHA_HASH, hashSize); } /*****************************************************************/ __attribute__((aligned(4))) static u8 nandCtr[AES_BLOCK_SIZE]; static u8 nandSlot; static u32 fatStart = 0; FirmwareSource firmSource = FIRMWARE_SYSNAND; __attribute__((aligned(4))) static const u8 key1s[2][AES_BLOCK_SIZE] = { {0x07, 0x29, 0x44, 0x38, 0xF8, 0xC9, 0x75, 0x93, 0xAA, 0x0E, 0x4A, 0xB4, 0xAE, 0x84, 0xC1, 0xD8}, {0xA2, 0xF4, 0x00, 0x3C, 0x7A, 0x95, 0x10, 0x25, 0xDF, 0x4E, 0x9E, 0x74, 0xE3, 0x0C, 0x92, 0x99} }, key2s[2][AES_BLOCK_SIZE] = { {0x42, 0x3F, 0x81, 0x7A, 0x23, 0x52, 0x58, 0x31, 0x6E, 0x75, 0x8E, 0x3A, 0x39, 0x43, 0x2E, 0xD0}, {0xFF, 0x77, 0xA0, 0x9A, 0x99, 0x81, 0xE9, 0x48, 0xEC, 0x51, 0xC9, 0x32, 0x5D, 0x14, 0xEC, 0x25} }; int ctrNandInit(void) { __attribute__((aligned(4))) u8 cid[AES_BLOCK_SIZE], shaSum[SHA_256_HASH_SIZE]; sdmmc_get_cid(1, (u32 *)cid); sha(shaSum, cid, sizeof(cid), SHA_256_MODE); memcpy(nandCtr, shaSum, sizeof(nandCtr)); nandSlot = ISN3DS ? 0x05 : 0x04; int result; u8 __attribute__((aligned(4))) temp[0x200]; //Read NCSD header result = firmSource == FIRMWARE_SYSNAND ? sdmmc_nand_readsectors(0, 1, temp) : sdmmc_sdcard_readsectors(emuHeader, 1, temp); if(!result) { u32 partitionNum = 1; //TWL partitions need to be first for(u8 *partitionId = temp + 0x111; *partitionId != 1; partitionId++, partitionNum++); u32 ctrMbrOffset = *((u32 *)(temp + 0x120) + (2 * partitionNum)); //Read CTR MBR result = ctrNandRead(ctrMbrOffset, 1, temp); //Calculate final CTRNAND FAT offset if(!result) fatStart = ctrMbrOffset + *(u32 *)(temp + 0x1C6); } return result; } int ctrNandRead(u32 sector, u32 sectorCount, u8 *outbuf) { __attribute__((aligned(4))) u8 tmpCtr[sizeof(nandCtr)]; memcpy(tmpCtr, nandCtr, sizeof(nandCtr)); aes_advctr(tmpCtr, ((sector + fatStart) * 0x200) / AES_BLOCK_SIZE, AES_INPUT_BE | AES_INPUT_NORMAL); //Read int result; if(firmSource == FIRMWARE_SYSNAND) result = sdmmc_nand_readsectors(sector + fatStart, sectorCount, outbuf); else { sector += emuOffset; result = sdmmc_sdcard_readsectors(sector + fatStart, sectorCount, outbuf); } //Decrypt aes_use_keyslot(nandSlot); aes(outbuf, outbuf, sectorCount * 0x200 / AES_BLOCK_SIZE, tmpCtr, AES_CTR_MODE, AES_INPUT_BE | AES_INPUT_NORMAL); return result; } int ctrNandWrite(u32 sector, u32 sectorCount, const u8 *inbuf) { u8 *buffer = (u8 *)0xFFF00000; u32 bufferSize = 0x4000; __attribute__((aligned(4))) u8 tmpCtr[sizeof(nandCtr)]; memcpy(tmpCtr, nandCtr, sizeof(nandCtr)); aes_advctr(tmpCtr, ((sector + fatStart) * 0x200) / AES_BLOCK_SIZE, AES_INPUT_BE | AES_INPUT_NORMAL); aes_use_keyslot(nandSlot); int result = 0; for(u32 tempSector = 0; tempSector < sectorCount && !result; tempSector += bufferSize / 0x200) { u32 tempCount = (bufferSize / 0x200) < (sectorCount - tempSector) ? (bufferSize / 0x200) : (sectorCount - tempSector); memcpy(buffer, inbuf + (tempSector * 0x200), tempCount * 0x200); //Encrypt aes(buffer, buffer, tempCount * 0x200 / AES_BLOCK_SIZE, tmpCtr, AES_CTR_MODE, AES_INPUT_BE | AES_INPUT_NORMAL); //Write result = sdmmc_nand_writesectors(tempSector + sector + fatStart, tempCount, buffer); } return result; } u32 decryptExeFs(Cxi *cxi) { if(memcmp(cxi->ncch.magic, "NCCH", 4) != 0) return 0; if(cxi->ncch.exeFsOffset != 5) return 0; u8 *exeFsOffset = (u8 *)cxi + 6 * 0x200; u32 exeFsSize = (cxi->ncch.exeFsSize - 1) * 0x200; if(exeFsSize > 0x400000) return 0; __attribute__((aligned(4))) u8 ncchCtr[AES_BLOCK_SIZE] = {0}; for(u32 i = 0; i < 8; i++) ncchCtr[7 - i] = cxi->ncch.partitionId[i]; ncchCtr[8] = 2; aes_setkey(0x2C, cxi, AES_KEYY, AES_INPUT_BE | AES_INPUT_NORMAL); aes_advctr(ncchCtr, 0x200 / AES_BLOCK_SIZE, AES_INPUT_BE | AES_INPUT_NORMAL); aes_use_keyslot(0x2C); aes(cxi, exeFsOffset, exeFsSize / AES_BLOCK_SIZE, ncchCtr, AES_CTR_MODE, AES_INPUT_BE | AES_INPUT_NORMAL); return memcmp(cxi, "FIRM", 4) == 0 ? exeFsSize : 0; } u32 decryptNusFirm(const Ticket *ticket, Cxi *cxi, u32 ncchSize) { if(memcmp(ticket->sigIssuer, "Root", 4) != 0) return 0; __attribute__((aligned(4))) static const u8 keyY0x3D[AES_BLOCK_SIZE] = {0x0C, 0x76, 0x72, 0x30, 0xF0, 0x99, 0x8F, 0x1C, 0x46, 0x82, 0x82, 0x02, 0xFA, 0xAC, 0xBE, 0x4C}; __attribute__((aligned(4))) u8 titleKey[AES_BLOCK_SIZE], cetkIv[AES_BLOCK_SIZE] = {0}; memcpy(titleKey, ticket->titleKey, sizeof(titleKey)); memcpy(cetkIv, ticket->titleId, sizeof(ticket->titleId)); aes_setkey(0x3D, keyY0x3D, AES_KEYY, AES_INPUT_BE | AES_INPUT_NORMAL); aes_use_keyslot(0x3D); aes(titleKey, titleKey, 1, cetkIv, AES_CBC_DECRYPT_MODE, AES_INPUT_BE | AES_INPUT_NORMAL); __attribute__((aligned(4))) u8 ncchIv[AES_BLOCK_SIZE] = {0}; aes_setkey(0x16, titleKey, AES_KEYNORMAL, AES_INPUT_BE | AES_INPUT_NORMAL); aes_use_keyslot(0x16); aes(cxi, cxi, ncchSize / AES_BLOCK_SIZE, ncchIv, AES_CBC_DECRYPT_MODE, AES_INPUT_BE | AES_INPUT_NORMAL); return decryptExeFs(cxi); } static inline void twlConsoleInfoInit(void) { u64 twlConsoleId = ISDEVUNIT ? OTP_DEVCONSOLEID : (0x80000000ULL | (*(vu64 *)0x01FFB808 ^ 0x8C267B7B358A6AFULL)); CFG_TWLUNITINFO = CFG_UNITINFO; OTP_TWLCONSOLEID = twlConsoleId; *REG_AESCNT = 0; vu32 *k3X = REGs_AESTWLKEYS[3][1], *k1X = REGs_AESTWLKEYS[1][1]; k3X[0] = (u32)twlConsoleId; k3X[3] = (u32)(twlConsoleId >> 32); k1X[2] = (u32)(twlConsoleId >> 32); k1X[3] = (u32)twlConsoleId; aes_setkey(2, (u8 *)0x01FFD398, AES_KEYX, AES_INPUT_TWLNORMAL); if(CFG_TWLUNITINFO != 0) { __attribute__((aligned(4))) static const u8 key2YDev[AES_BLOCK_SIZE] = {0x3B, 0x06, 0x86, 0x57, 0x33, 0x04, 0x88, 0x11, 0x49, 0x04, 0x6B, 0x33, 0x12, 0x02, 0xAC, 0xF3}, key3YDev[AES_BLOCK_SIZE] = {0xAA, 0xBF, 0x76, 0xF1, 0x7A, 0xB8, 0xE8, 0x66, 0x97, 0x64, 0x6A, 0x26, 0x05, 0x00, 0xA0, 0xE1}; k3X[1] = 0xEE7A4B1E; k3X[2] = 0xAF42C08B; aes_setkey(2, key2YDev, AES_KEYY, AES_INPUT_TWLNORMAL); aes_setkey(3, key3YDev, AES_KEYY, AES_INPUT_TWLNORMAL); } else { u32 last3YWord = 0xE1A00005; __attribute__((aligned(4))) u8 key3YRetail[AES_BLOCK_SIZE]; memcpy(key3YRetail, (u8 *)0x01FFD3C8, 12); memcpy(key3YRetail + 12, &last3YWord, 4); k3X[1] = *(vu32 *)0x01FFD3A8; //"NINT" k3X[2] = *(vu32 *)0x01FFD3AC; //"ENDO" aes_setkey(2, (u8 *)0x01FFD220, AES_KEYY, AES_INPUT_TWLNORMAL); aes_setkey(3, key3YRetail, AES_KEYY, AES_INPUT_TWLNORMAL); } } void setupKeyslots(void) { //Setup 0x24 KeyY __attribute__((aligned(4))) static const u8 keyY0x24[AES_BLOCK_SIZE] = {0x74, 0xCA, 0x07, 0x48, 0x84, 0xF4, 0x22, 0x8D, 0xEB, 0x2A, 0x1C, 0xA7, 0x2D, 0x28, 0x77, 0x62}; aes_setkey(0x24, keyY0x24, AES_KEYY, AES_INPUT_BE | AES_INPUT_NORMAL); //Setup 0x25 KeyX and 0x2F KeyY __attribute__((aligned(4))) static const u8 keyX0x25s[2][AES_BLOCK_SIZE] = { {0xCE, 0xE7, 0xD8, 0xAB, 0x30, 0xC0, 0x0D, 0xAE, 0x85, 0x0E, 0xF5, 0xE3, 0x82, 0xAC, 0x5A, 0xF3}, {0x81, 0x90, 0x7A, 0x4B, 0x6F, 0x1B, 0x47, 0x32, 0x3A, 0x67, 0x79, 0x74, 0xCE, 0x4A, 0xD7, 0x1B} }, keyY0x2Fs[2][AES_BLOCK_SIZE] = { {0xC3, 0x69, 0xBA, 0xA2, 0x1E, 0x18, 0x8A, 0x88, 0xA9, 0xAA, 0x94, 0xE5, 0x50, 0x6A, 0x9F, 0x16}, {0x73, 0x25, 0xC4, 0xEB, 0x14, 0x3A, 0x0D, 0x5F, 0x5D, 0xB6, 0xE5, 0xC5, 0x7A, 0x21, 0x95, 0xAC} }; aes_setkey(0x25, keyX0x25s[ISDEVUNIT ? 1 : 0], AES_KEYX, AES_INPUT_BE | AES_INPUT_NORMAL); aes_setkey(0x2F, keyY0x2Fs[ISDEVUNIT ? 1 : 0], AES_KEYY, AES_INPUT_BE | AES_INPUT_NORMAL); if(ISN3DS) { //Setup 0x05 KeyY __attribute__((aligned(4))) static const u8 keyY0x5[AES_BLOCK_SIZE] = {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); } //Setup TWL keys twlConsoleInfoInit(); __attribute__((aligned(4))) u8 keyBlocks[2][AES_BLOCK_SIZE] = { {0xA4, 0x8D, 0xE4, 0xF1, 0x0B, 0x36, 0x44, 0xAA, 0x90, 0x31, 0x28, 0xFF, 0x4D, 0xCA, 0x76, 0xDF}, {0xDD, 0xDA, 0xA4, 0xC6, 0x2C, 0xC4, 0x50, 0xE9, 0xDA, 0xB6, 0x9B, 0x0D, 0x9D, 0x2A, 0x21, 0x98} }, decKey[AES_BLOCK_SIZE]; //Initialize Key 0x18 aes_setkey(0x11, key1s[ISDEVUNIT ? 1 : 0], AES_KEYNORMAL, AES_INPUT_BE | AES_INPUT_NORMAL); aes_use_keyslot(0x11); aes(decKey, keyBlocks[0], 1, NULL, AES_ECB_DECRYPT_MODE, 0); aes_setkey(0x18, decKey, AES_KEYX, AES_INPUT_BE | AES_INPUT_NORMAL); //Initialize Key 0x19-0x1F aes_setkey(0x11, key2s[ISDEVUNIT ? 1 : 0], AES_KEYNORMAL, AES_INPUT_BE | AES_INPUT_NORMAL); aes_use_keyslot(0x11); for(u8 slot = 0x19; slot < 0x20; slot++, keyBlocks[1][0xF]++) { aes(decKey, keyBlocks[1], 1, NULL, AES_ECB_DECRYPT_MODE, 0); aes_setkey(slot, decKey, AES_KEYX, AES_INPUT_BE | AES_INPUT_NORMAL); } } void kernel9Loader(Arm9Bin *arm9Section) { //Determine the kernel9loader version u32 k9lVersion; switch(arm9Section->magic[3]) { case 0xFF: k9lVersion = 0; break; case '1': k9lVersion = 1; break; default: k9lVersion = 2; } u32 *startOfArm9Bin = (u32 *)((u8 *)arm9Section + 0x800); if(*startOfArm9Bin == 0x47704770 || *startOfArm9Bin == 0xB0862000) return; //Already decrypted aes_setkey(0x11, k9lVersion == 2 ? key2s[ISDEVUNIT ? 1 : 0] : key1s[ISDEVUNIT ? 1 : 0], AES_KEYNORMAL, AES_INPUT_BE | AES_INPUT_NORMAL); u8 arm9BinSlot = k9lVersion == 0 ? 0x15 : 0x16; //Set keyX __attribute__((aligned(4))) u8 keyX[AES_BLOCK_SIZE]; aes_use_keyslot(0x11); aes(keyX, k9lVersion == 0 ? arm9Section->keyX : arm9Section->slot0x16keyX, 1, NULL, AES_ECB_DECRYPT_MODE, 0); aes_setkey(arm9BinSlot, keyX, AES_KEYX, AES_INPUT_BE | AES_INPUT_NORMAL); //Set keyY __attribute__((aligned(4))) u8 keyY[AES_BLOCK_SIZE]; memcpy(keyY, arm9Section->keyY, sizeof(keyY)); aes_setkey(arm9BinSlot, keyY, AES_KEYY, AES_INPUT_BE | AES_INPUT_NORMAL); //Set CTR __attribute__((aligned(4))) u8 arm9BinCtr[AES_BLOCK_SIZE]; memcpy(arm9BinCtr, arm9Section->ctr, sizeof(arm9BinCtr)); //Decrypt ARM9 binary aes_use_keyslot(arm9BinSlot); aes(startOfArm9Bin, startOfArm9Bin, decAtoi(arm9Section->size, sizeof(arm9Section->size)) / AES_BLOCK_SIZE, arm9BinCtr, AES_CTR_MODE, AES_INPUT_BE | AES_INPUT_NORMAL); if(*startOfArm9Bin != 0x47704770 && *startOfArm9Bin != 0xB0862000) error("Failed to decrypt the ARM9 binary."); } void computePinHash(u8 *outbuf, const u8 *inbuf) { __attribute__((aligned(4))) u8 cid[AES_BLOCK_SIZE], cipherText[AES_BLOCK_SIZE]; sdmmc_get_cid(1, (u32 *)cid); aes_use_keyslot(0x04); //Console-unique keyslot whose keys are set by the ARM9 bootROM aes(cipherText, inbuf, 1, cid, AES_CBC_ENCRYPT_MODE, AES_INPUT_BE | AES_INPUT_NORMAL); sha(outbuf, cipherText, sizeof(cipherText), SHA_256_MODE); }