/*
Copyright 2016-2019 Arisotura
This file is part of melonDS.
melonDS 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.
melonDS 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 melonDS. If not, see http://www.gnu.org/licenses/.
*/
#include <stdio.h>
#include <string.h>
#include "DSi.h"
#include "DSi_AES.h"
#include "FIFO.h"
#include "tiny-AES-c/aes.hpp"
#include "Platform.h"
namespace DSi_AES
{
u32 Cnt;
u32 BlkCnt;
u32 RemBlocks;
bool OutputFlush;
u32 InputDMASize, OutputDMASize;
u32 AESMode;
FIFO<u32>* InputFIFO;
FIFO<u32>* OutputFIFO;
u8 IV[16];
u8 MAC[16];
u8 KeyNormal[4][16];
u8 KeyX[4][16];
u8 KeyY[4][16];
u8 CurKey[16];
u8 CurMAC[16];
AES_ctx Ctx;
void Swap16(u8* dst, u8* src)
{
for (int i = 0; i < 16; i++)
dst[i] = src[15-i];
}
void ROL16(u8* val, u32 n)
{
u32 n_coarse = n >> 3;
u32 n_fine = n & 7;
u8 tmp[16];
for (u32 i = 0; i < 16; i++)
{
tmp[i] = val[(i - n_coarse) & 0xF];
}
for (u32 i = 0; i < 16; i++)
{
val[i] = (tmp[i] << n_fine) | (tmp[(i - 1) & 0xF] >> (8-n_fine));
}
}
#define _printhex(str, size) { for (int z = 0; z < (size); z++) printf("%02X", (str)[z]); printf("\n"); }
#define _printhex2(str, size) { for (int z = 0; z < (size); z++) printf("%02X", (str)[z]); }
#define _printhexR(str, size) { for (int z = 0; z < (size); z++) printf("%02X", (str)[((size)-1)-z]); printf("\n"); }
#define _printhex2R(str, size) { for (int z = 0; z < (size); z++) printf("%02X", (str)[((size)-1)-z]); }
bool Init()
{
InputFIFO = new FIFO<u32>(16);
OutputFIFO = new FIFO<u32>(16);
const u8 zero[16] = {0};
AES_init_ctx_iv(&Ctx, zero, zero);
return true;
}
void DeInit()
{
delete InputFIFO;
delete OutputFIFO;
}
void Reset()
{
Cnt = 0;
BlkCnt = 0;
RemBlocks = 0;
OutputFlush = false;
InputDMASize = 0;
OutputDMASize = 0;
AESMode = 0;
InputFIFO->Clear();
OutputFIFO->Clear();
memset(IV, 0, sizeof(IV));
memset(MAC, 0, sizeof(MAC));
memset(KeyNormal, 0, sizeof(KeyNormal));
memset(KeyX, 0, sizeof(KeyX));
memset(KeyY, 0, sizeof(KeyY));
memset(CurKey, 0, sizeof(CurKey));
memset(CurMAC, 0, sizeof(CurMAC));
// initialize keys
FILE* f = Platform::OpenLocalFile("aeskeys.bin", "rb");
if (f)
{
fread(KeyNormal[0], 16, 1, f);
fread(KeyX[0], 16, 1, f);
fread(KeyY[0], 16, 1, f);
fread(KeyNormal[1], 16, 1, f);
fread(KeyX[1], 16, 1, f);
fread(KeyY[1], 16, 1, f);
fread(KeyNormal[2], 16, 1, f);
fread(KeyX[2], 16, 1, f);
fread(KeyY[2], 16, 1, f);
fread(KeyNormal[3], 16, 1, f);
fread(KeyX[3], 16, 1, f);
fread(KeyY[3], 16, 1, f);
fclose(f);
}
else
printf("AES: aeskeys.bin not found\n");
}
void ProcessBlock_CCM_Decrypt()
{
u8 data[16];
u8 data_rev[16];
*(u32*)&data[0] = InputFIFO->Read();
*(u32*)&data[4] = InputFIFO->Read();
*(u32*)&data[8] = InputFIFO->Read();
*(u32*)&data[12] = InputFIFO->Read();
//printf("AES-CCM: "); _printhex2(data, 16);
Swap16(data_rev, data);
AES_CTR_xcrypt_buffer(&Ctx, data_rev, 16);
for (int i = 0; i < 16; i++) CurMAC[i] ^= data_rev[i];
AES_ECB_encrypt(&Ctx, CurMAC);
Swap16(data, data_rev);
//printf(" -> "); _printhex2(data, 16);
OutputFIFO->Write(*(u32*)&data[0]);
OutputFIFO->Write(*(u32*)&data[4]);
OutputFIFO->Write(*(u32*)&data[8]);
OutputFIFO->Write(*(u32*)&data[12]);
}
void ProcessBlock_CTR()
{
u8 data[16];
u8 data_rev[16];
*(u32*)&data[0] = InputFIFO->Read();
*(u32*)&data[4] = InputFIFO->Read();
*(u32*)&data[8] = InputFIFO->Read();
*(u32*)&data[12] = InputFIFO->Read();
//printf("AES-CTR: "); _printhex2(data, 16);
Swap16(data_rev, data);
AES_CTR_xcrypt_buffer(&Ctx, data_rev, 16);
Swap16(data, data_rev);
//printf(" -> "); _printhex(data, 16);
OutputFIFO->Write(*(u32*)&data[0]);
OutputFIFO->Write(*(u32*)&data[4]);
OutputFIFO->Write(*(u32*)&data[8]);
OutputFIFO->Write(*(u32*)&data[12]);
}
u32 ReadCnt()
{
u32 ret = Cnt;
ret |= InputFIFO->Level();
ret |= (OutputFIFO->Level() << 5);
//printf("READ AES CNT: %08X, LEVELS: IN=%d OUT=%d\n", ret, InputFIFO->Level(), OutputFIFO->Level());
return ret;
}
void WriteCnt(u32 val)
{printf("AES CNT = %08X\n", val);
u32 oldcnt = Cnt;
Cnt = val & 0xFC1FF000;
/*if (val & (3<<10))
{
if (val & (1<<11)) OutputFlush = true;
Update();
}*/
u32 dmasize_in[4] = {0, 4, 8, 12};
u32 dmasize_out[4] = {4, 8, 12, 16};
InputDMASize = dmasize_in[(val >> 12) & 0x3];
OutputDMASize = dmasize_out[(val >> 14) & 0x3];
AESMode = (val >> 28) & 0x3;
if (AESMode == 1) printf("AES-CCM TODO\n");
if (val & (1<<24))
{
u32 slot = (val >> 26) & 0x3;
memcpy(CurKey, KeyNormal[slot], 16);
}
if (!(oldcnt & (1<<31)) && (val & (1<<31)))
{
// transfer start (checkme)
RemBlocks = BlkCnt >> 16;
if (RemBlocks > 0)
{
u8 key[16];
u8 iv[16];
Swap16(key, CurKey);
Swap16(iv, IV);
if (AESMode < 2)
{
if (BlkCnt & 0xFFFF) printf("AES: CCM EXTRA LEN TODO\n");
u32 maclen = (val >> 16) & 0x7;
if (maclen < 1) maclen = 1;
iv[0] = 0x02;
for (int i = 0; i < 12; i++) iv[1+i] = iv[4+i];
iv[13] = 0x00;
iv[14] = 0x00;
iv[15] = 0x01;
AES_init_ctx_iv(&Ctx, key, iv);
iv[0] |= (maclen << 3) | ((BlkCnt & 0xFFFF) ? (1<<6) : 0);
iv[13] = RemBlocks >> 12;
iv[14] = RemBlocks >> 4;
iv[15] = RemBlocks << 4;
memcpy(CurMAC, iv, 16);
AES_ECB_encrypt(&Ctx, CurMAC);
}
else
{
AES_init_ctx_iv(&Ctx, key, iv);
}
DSi::CheckNDMAs(1, 0x2A);
}
else
{
// no blocks to process? oh well. mark it finished
// CHECKME: does this trigger any IRQ or shit?
Cnt &= ~(1<<31);
}
}
printf("AES CNT: %08X / mode=%d key=%d inDMA=%d outDMA=%d blocks=%d\n",
val, AESMode, (val >> 26) & 0x3, InputDMASize, OutputDMASize, RemBlocks);
}
void WriteBlkCnt(u32 val)
{printf("AES BLOCK CNT %08X / %d\n", val, val>>16);
BlkCnt = val;
}
u32 ReadOutputFIFO()
{
if (OutputFIFO->IsEmpty()) printf("!!! AES OUTPUT FIFO EMPTY\n");
u32 ret = OutputFIFO->Read();
if (Cnt & (1<<31))
{
CheckInputDMA();
CheckOutputDMA();
}
else
{
if (OutputFIFO->Level() > 0)
DSi::CheckNDMAs(1, 0x2B);
else
DSi::StopNDMAs(1, 0x2B);
}
return ret;
}
void WriteInputFIFO(u32 val)
{
// TODO: add some delay to processing
if (InputFIFO->IsFull()) printf("!!! AES INPUT FIFO FULL\n");
InputFIFO->Write(val);
if (!(Cnt & (1<<31))) return;
Update();
}
void CheckInputDMA()
{
if (RemBlocks == 0) return;
if (InputFIFO->Level() <= InputDMASize)
{
// trigger input DMA
DSi::CheckNDMAs(1, 0x2A);
}
Update();
}
void CheckOutputDMA()
{
if (OutputFIFO->Level() >= OutputDMASize)
{
// trigger output DMA
DSi::CheckNDMAs(1, 0x2B);
}
}
void Update()
{
while (InputFIFO->Level() >= 4 && OutputFIFO->Level() <= 12 && RemBlocks > 0)
{
switch (AESMode)
{
case 0: ProcessBlock_CCM_Decrypt(); break;
case 2:
case 3: ProcessBlock_CTR(); break;
default:
// dorp
OutputFIFO->Write(InputFIFO->Read());
OutputFIFO->Write(InputFIFO->Read());
OutputFIFO->Write(InputFIFO->Read());
OutputFIFO->Write(InputFIFO->Read());
}
RemBlocks--;
}
CheckOutputDMA();
if (RemBlocks == 0)
{
if (AESMode == 0)
{
Ctx.Iv[13] = 0x00;
Ctx.Iv[14] = 0x00;
Ctx.Iv[15] = 0x00;
AES_CTR_xcrypt_buffer(&Ctx, CurMAC, 16);
//printf("FINAL MAC: "); _printhexR(CurMAC, 16);
//printf("INPUT MAC: "); _printhex(MAC, 16);
Cnt |= (1<<21);
for (int i = 0; i < 16; i++)
{
if (CurMAC[15-i] != MAC[i]) Cnt &= ~(1<<21);
}
}
else
{
// CHECKME
Cnt &= ~(1<<21);
}
printf("AES: FINISHED\n");
Cnt &= ~(1<<31);
if (Cnt & (1<<30)) NDS::SetIRQ2(NDS::IRQ2_DSi_AES);
DSi::StopNDMAs(1, 0x2A);
if (OutputFIFO->Level() > 0)
DSi::CheckNDMAs(1, 0x2B);
else
DSi::StopNDMAs(1, 0x2B);
OutputFlush = false;
}
}
void WriteIV(u32 offset, u32 val, u32 mask)
{
u32 old = *(u32*)&IV[offset];
*(u32*)&IV[offset] = (old & ~mask) | (val & mask);
//printf("AES: IV: "); _printhex(IV, 16);
}
void WriteMAC(u32 offset, u32 val, u32 mask)
{
u32 old = *(u32*)&MAC[offset];
*(u32*)&MAC[offset] = (old & ~mask) | (val & mask);
//printf("AES: MAC: "); _printhex(MAC, 16);
}
void DeriveNormalKey(u32 slot)
{
const u8 key_const[16] = {0xFF, 0xFE, 0xFB, 0x4E, 0x29, 0x59, 0x02, 0x58, 0x2A, 0x68, 0x0F, 0x5F, 0x1A, 0x4F, 0x3E, 0x79};
u8 tmp[16];
//printf("slot%d keyX: ", slot); _printhex(KeyX[slot], 16);
//printf("slot%d keyY: ", slot); _printhex(KeyY[slot], 16);
for (int i = 0; i < 16; i++)
tmp[i] = KeyX[slot][i] ^ KeyY[slot][i];
u32 carry = 0;
for (int i = 0; i < 16; i++)
{
u32 res = tmp[i] + key_const[15-i] + carry;
tmp[i] = res & 0xFF;
carry = res >> 8;
}
ROL16(tmp, 42);
//printf("derive normalkey %d\n", slot); _printhex(tmp, 16);
memcpy(KeyNormal[slot], tmp, 16);
}
void WriteKeyNormal(u32 slot, u32 offset, u32 val, u32 mask)
{
u32 old = *(u32*)&KeyNormal[slot][offset];
*(u32*)&KeyNormal[slot][offset] = (old & ~mask) | (val & mask);
//printf("KeyNormal(%d): ", slot); _printhex(KeyNormal[slot], 16);
}
void WriteKeyX(u32 slot, u32 offset, u32 val, u32 mask)
{
u32 old = *(u32*)&KeyX[slot][offset];
*(u32*)&KeyX[slot][offset] = (old & ~mask) | (val & mask);
//printf("KeyX(%d): ", slot); _printhex(KeyX[slot], 16);
}
void WriteKeyY(u32 slot, u32 offset, u32 val, u32 mask)
{
u32 old = *(u32*)&KeyY[slot][offset];
*(u32*)&KeyY[slot][offset] = (old & ~mask) | (val & mask);
//printf("[%08X] KeyY(%d): ", NDS::GetPC(1), slot); _printhex(KeyY[slot], 16);
if (offset >= 0xC)
{
DeriveNormalKey(slot);
}
}
// utility
void GetModcryptKey(u8* romheader, u8* key)
{
if ((romheader[0x01C] & 0x04) || (romheader[0x1BF] & 0x80))
{
// dev key
memcpy(key, &romheader[0x000], 16);
return;
}
u8 oldkeys[16*3];
memcpy(&oldkeys[16*0], KeyX[0], 16);
memcpy(&oldkeys[16*1], KeyY[0], 16);
memcpy(&oldkeys[16*2], KeyNormal[0], 16);
KeyX[0][8] = romheader[0x00C];
KeyX[0][9] = romheader[0x00D];
KeyX[0][10] = romheader[0x00E];
KeyX[0][11] = romheader[0x00F];
KeyX[0][12] = romheader[0x00F];
KeyX[0][13] = romheader[0x00E];
KeyX[0][14] = romheader[0x00D];
KeyX[0][15] = romheader[0x00C];
memcpy(KeyY[0], &romheader[0x350], 16);
DeriveNormalKey(0);
memcpy(key, KeyNormal[0], 16);
memcpy(KeyX[0], &oldkeys[16*0], 16);
memcpy(KeyY[0], &oldkeys[16*1], 16);
memcpy(KeyNormal[0], &oldkeys[16*2], 16);
}
void ApplyModcrypt(u8* data, u32 len, u8* key, u8* iv)
{
u8 key_rev[16], iv_rev[16];
u8 data_rev[16];
u8 oldkeys[16*2];
memcpy(&oldkeys[16*0], Ctx.RoundKey, 16);
memcpy(&oldkeys[16*1], Ctx.Iv, 16);
Swap16(key_rev, key);
Swap16(iv_rev, iv);
AES_init_ctx_iv(&Ctx, key_rev, iv_rev);
for (u32 i = 0; i < len; i += 16)
{
Swap16(data_rev, &data[i]);
AES_CTR_xcrypt_buffer(&Ctx, data_rev, 16);
Swap16(&data[i], data_rev);
}
memcpy(Ctx.RoundKey, &oldkeys[16*0], 16);
memcpy(Ctx.Iv, &oldkeys[16*1], 16);
}
}