/* Copyright 2016-2023 melonDS team 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 #include #include "NDS.h" #include "DSi.h" #include "AREngine.h" #include "Platform.h" using Platform::Log; using Platform::LogLevel; namespace AREngine { // AR code file - frontend is responsible for managing this ARCodeFile* CodeFile; u8 (*BusRead8)(u32 addr); u16 (*BusRead16)(u32 addr); u32 (*BusRead32)(u32 addr); void (*BusWrite8)(u32 addr, u8 val); void (*BusWrite16)(u32 addr, u16 val); void (*BusWrite32)(u32 addr, u32 val); bool Init() { CodeFile = nullptr; return true; } void DeInit() { } void Reset() { if (NDS::ConsoleType == 1) { BusRead8 = DSi::ARM7Read8; BusRead16 = DSi::ARM7Read16; BusRead32 = DSi::ARM7Read32; BusWrite8 = DSi::ARM7Write8; BusWrite16 = DSi::ARM7Write16; BusWrite32 = DSi::ARM7Write32; } else { BusRead8 = NDS::ARM7Read8; BusRead16 = NDS::ARM7Read16; BusRead32 = NDS::ARM7Read32; BusWrite8 = NDS::ARM7Write8; BusWrite16 = NDS::ARM7Write16; BusWrite32 = NDS::ARM7Write32; } } ARCodeFile* GetCodeFile() { return CodeFile; } void SetCodeFile(ARCodeFile* file) { CodeFile = file; } #define case16(x) \ case ((x)+0x00): case ((x)+0x01): case ((x)+0x02): case ((x)+0x03): \ case ((x)+0x04): case ((x)+0x05): case ((x)+0x06): case ((x)+0x07): \ case ((x)+0x08): case ((x)+0x09): case ((x)+0x0A): case ((x)+0x0B): \ case ((x)+0x0C): case ((x)+0x0D): case ((x)+0x0E): case ((x)+0x0F) void RunCheat(ARCode& arcode) { u32* code = &arcode.Code[0]; u32 offset = 0; u32 datareg = 0; u32 cond = 1; u32 condstack = 0; u32* loopstart = code; u32 loopcount = 0; u32 loopcond = 1; u32 loopcondstack = 0; // TODO: does anything reset this?? u32 c5count = 0; for (;;) { if (code >= &arcode.Code[arcode.Code.size()]) break; u32 a = *code++; u32 b = *code++; u8 op = a >> 24; if ((op < 0xD0 && op != 0xC5) || op > 0xD2) { if (!cond) { if ((op & 0xF0) == 0xE0) { for (u32 i = 0; i < b; i += 8) code += 2; } continue; } } switch (op) { case16(0x00): // 32-bit write BusWrite32((a & 0x0FFFFFFF) + offset, b); break; case16(0x10): // 16-bit write BusWrite16((a & 0x0FFFFFFF) + offset, b & 0xFFFF); break; case16(0x20): // 8-bit write BusWrite8((a & 0x0FFFFFFF) + offset, b & 0xFF); break; case16(0x30): // IF b > u32[a] { condstack <<= 1; condstack |= cond; u32 addr = a & 0x0FFFFFFF; if (!addr) addr = offset; u32 chk = BusRead32(addr); cond = (b > chk) ? 1:0; } break; case16(0x40): // IF b < u32[a] { condstack <<= 1; condstack |= cond; u32 addr = a & 0x0FFFFFFF; if (!addr) addr = offset; u32 chk = BusRead32(addr); cond = (b < chk) ? 1:0; } break; case16(0x50): // IF b == u32[a] { condstack <<= 1; condstack |= cond; u32 addr = a & 0x0FFFFFFF; if (!addr) addr = offset; u32 chk = BusRead32(addr); cond = (b == chk) ? 1:0; } break; case16(0x60): // IF b != u32[a] { condstack <<= 1; condstack |= cond; u32 addr = a & 0x0FFFFFFF; if (!addr) addr = offset; u32 chk = BusRead32(addr); cond = (b != chk) ? 1:0; } break; case16(0x70): // IF b.l > ((~b.h) & u16[a]) { condstack <<= 1; condstack |= cond; u32 addr = a & 0x0FFFFFFF; if (!addr) addr = offset; u16 val = BusRead16(addr); u16 chk = ~(b >> 16); chk &= val; cond = ((b & 0xFFFF) > chk) ? 1:0; } break; case16(0x80): // IF b.l < ((~b.h) & u16[a]) { condstack <<= 1; condstack |= cond; u32 addr = a & 0x0FFFFFFF; if (!addr) addr = offset; u16 val = BusRead16(addr); u16 chk = ~(b >> 16); chk &= val; cond = ((b & 0xFFFF) < chk) ? 1:0; } break; case16(0x90): // IF b.l == ((~b.h) & u16[a]) { condstack <<= 1; condstack |= cond; u32 addr = a & 0x0FFFFFFF; if (!addr) addr = offset; u16 val = BusRead16(addr); u16 chk = ~(b >> 16); chk &= val; cond = ((b & 0xFFFF) == chk) ? 1:0; } break; case16(0xA0): // IF b.l != ((~b.h) & u16[a]) { condstack <<= 1; condstack |= cond; u32 addr = a & 0x0FFFFFFF; if (!addr) addr = offset; u16 val = BusRead16(addr); u16 chk = ~(b >> 16); chk &= val; cond = ((b & 0xFFFF) != chk) ? 1:0; } break; case16(0xB0): // offset = u32[a + offset] offset = BusRead32((a & 0x0FFFFFFF) + offset); break; case 0xC0: // FOR 0..b loopstart = code; // points to the first opcode after the FOR loopcount = b; loopcond = cond; // checkme loopcondstack = condstack; // (GBAtek is not very clear there) break; case 0xC4: // offset = pointer to C4000000 opcode // theoretically used for safe storage, by accessing [offset+4] // in practice could be used for a self-modifying AR code // could be implemented with some hackery, but, does anything even // use it?? Log(LogLevel::Error, "AR: !! THE FUCKING C4000000 OPCODE. TELL ARISOTURA.\n"); return; case 0xC5: // count++ / IF (count & b.l) == b.h { // with weird condition checking, apparently // oh well c5count++; if (!cond) break; condstack <<= 1; condstack |= cond; u16 mask = b & 0xFFFF; u16 chk = b >> 16; cond = ((c5count & mask) == chk) ? 1:0; } break; case 0xC6: // u32[b] = offset BusWrite32(b, offset); break; case 0xD0: // ENDIF cond = condstack & 0x1; condstack >>= 1; break; case 0xD1: // NEXT if (loopcount > 0) { loopcount--; code = loopstart; } else { cond = loopcond; condstack = loopcondstack; } break; case 0xD2: // NEXT+FLUSH if (loopcount > 0) { loopcount--; code = loopstart; } else { offset = 0; datareg = 0; condstack = 0; cond = 1; } break; case 0xD3: // offset = b offset = b; break; case 0xD4: // datareg += b datareg += b; break; case 0xD5: // datareg = b datareg = b; break; case 0xD6: // u32[b+offset] = datareg / offset += 4 BusWrite32(b + offset, datareg); offset += 4; break; case 0xD7: // u16[b+offset] = datareg / offset += 2 BusWrite16(b + offset, datareg & 0xFFFF); offset += 2; break; case 0xD8: // u8[b+offset] = datareg / offset += 1 BusWrite8(b + offset, datareg & 0xFF); offset += 1; break; case 0xD9: // datareg = u32[b+offset] datareg = BusRead32(b + offset); break; case 0xDA: // datareg = u16[b+offset] datareg = BusRead16(b + offset); break; case 0xDB: // datareg = u8[b+offset] datareg = BusRead8(b + offset); break; case 0xDC: // offset += b offset += b; break; case16(0xE0): // copy b param bytes to address a+offset { // TODO: check for bad alignment of dstaddr u32 dstaddr = (a & 0x0FFFFFFF) + offset; u32 bytesleft = b; while (bytesleft >= 8) { BusWrite32(dstaddr, *code++); dstaddr += 4; BusWrite32(dstaddr, *code++); dstaddr += 4; bytesleft -= 8; } if (bytesleft > 0) { u8* leftover = (u8*)code; code += 2; if (bytesleft >= 4) { BusWrite32(dstaddr, *(u32*)leftover); dstaddr += 4; leftover += 4; bytesleft -= 4; } while (bytesleft > 0) { BusWrite8(dstaddr, *leftover++); dstaddr++; bytesleft--; } } } break; case16(0xF0): // copy b bytes from address offset to address a { // TODO: check for bad alignment of srcaddr/dstaddr u32 srcaddr = offset; u32 dstaddr = (a & 0x0FFFFFFF); u32 bytesleft = b; while (bytesleft >= 4) { BusWrite32(dstaddr, BusRead32(srcaddr)); srcaddr += 4; dstaddr += 4; bytesleft -= 4; } while (bytesleft > 0) { BusWrite8(dstaddr, BusRead8(srcaddr)); srcaddr++; dstaddr++; bytesleft--; } } break; default: Log(LogLevel::Warn, "!! bad AR opcode %08X %08X\n", a, b); return; } } } void RunCheats() { if (!CodeFile) return; for (ARCodeCatList::iterator i = CodeFile->Categories.begin(); i != CodeFile->Categories.end(); i++) { ARCodeCat& cat = *i; for (ARCodeList::iterator j = cat.Codes.begin(); j != cat.Codes.end(); j++) { ARCode& code = *j; if (code.Enabled) RunCheat(code); } } } }