/********************************************************************************** Snes9x - Portable Super Nintendo Entertainment System (TM) emulator. (c) Copyright 1996 - 2002 Gary Henderson (gary.henderson@ntlworld.com), Jerremy Koot (jkoot@snes9x.com) (c) Copyright 2002 - 2004 Matthew Kendora (c) Copyright 2002 - 2005 Peter Bortas (peter@bortas.org) (c) Copyright 2004 - 2005 Joel Yliluoma (http://iki.fi/bisqwit/) (c) Copyright 2001 - 2006 John Weidman (jweidman@slip.net) (c) Copyright 2002 - 2006 funkyass (funkyass@spam.shaw.ca), Kris Bleakley (codeviolation@hotmail.com) (c) Copyright 2002 - 2007 Brad Jorsch (anomie@users.sourceforge.net), Nach (n-a-c-h@users.sourceforge.net), zones (kasumitokoduck@yahoo.com) (c) Copyright 2006 - 2007 nitsuja BS-X C emulator code (c) Copyright 2005 - 2006 Dreamer Nom, zones C4 x86 assembler and some C emulation code (c) Copyright 2000 - 2003 _Demo_ (_demo_@zsnes.com), Nach, zsKnight (zsknight@zsnes.com) C4 C++ code (c) Copyright 2003 - 2006 Brad Jorsch, Nach DSP-1 emulator code (c) Copyright 1998 - 2006 _Demo_, Andreas Naive (andreasnaive@gmail.com) Gary Henderson, Ivar (ivar@snes9x.com), John Weidman, Kris Bleakley, Matthew Kendora, Nach, neviksti (neviksti@hotmail.com) DSP-2 emulator code (c) Copyright 2003 John Weidman, Kris Bleakley, Lord Nightmare (lord_nightmare@users.sourceforge.net), Matthew Kendora, neviksti DSP-3 emulator code (c) Copyright 2003 - 2006 John Weidman, Kris Bleakley, Lancer, z80 gaiden DSP-4 emulator code (c) Copyright 2004 - 2006 Dreamer Nom, John Weidman, Kris Bleakley, Nach, z80 gaiden OBC1 emulator code (c) Copyright 2001 - 2004 zsKnight, pagefault (pagefault@zsnes.com), Kris Bleakley, Ported from x86 assembler to C by sanmaiwashi SPC7110 and RTC C++ emulator code (c) Copyright 2002 Matthew Kendora with research by zsKnight, John Weidman, Dark Force S-DD1 C emulator code (c) Copyright 2003 Brad Jorsch with research by Andreas Naive, John Weidman S-RTC C emulator code (c) Copyright 2001-2006 byuu, John Weidman ST010 C++ emulator code (c) Copyright 2003 Feather, John Weidman, Kris Bleakley, Matthew Kendora Super FX x86 assembler emulator code (c) Copyright 1998 - 2003 _Demo_, pagefault, zsKnight, Super FX C emulator code (c) Copyright 1997 - 1999 Ivar, Gary Henderson, John Weidman Sound DSP emulator code is derived from SNEeSe and OpenSPC: (c) Copyright 1998 - 2003 Brad Martin (c) Copyright 1998 - 2006 Charles Bilyue' SH assembler code partly based on x86 assembler code (c) Copyright 2002 - 2004 Marcus Comstedt (marcus@mc.pp.se) 2xSaI filter (c) Copyright 1999 - 2001 Derek Liauw Kie Fa HQ2x, HQ3x, HQ4x filters (c) Copyright 2003 Maxim Stepin (maxim@hiend3d.com) Win32 GUI code (c) Copyright 2003 - 2006 blip, funkyass, Matthew Kendora, Nach, nitsuja Mac OS GUI code (c) Copyright 1998 - 2001 John Stiles (c) Copyright 2001 - 2007 zones Specific ports contains the works of other authors. See headers in individual files. Snes9x homepage: http://www.snes9x.com Permission to use, copy, modify and/or distribute Snes9x in both binary and source form, for non-commercial purposes, is hereby granted without fee, providing that this license information and copyright notice appear with all copies and any derived work. This software is provided 'as-is', without any express or implied warranty. In no event shall the authors be held liable for any damages arising from the use of this software or it's derivatives. Snes9x is freeware for PERSONAL USE only. Commercial users should seek permission of the copyright holders first. Commercial use includes, but is not limited to, charging money for Snes9x or software derived from Snes9x, including Snes9x or derivatives in commercial game bundles, and/or using Snes9x as a promotion for your commercial product. The copyright holders request that bug fixes and improvements to the code should be forwarded to them so everyone can benefit from the modifications in future versions. Super NES and Super Nintendo Entertainment System are trademarks of Nintendo Co., Limited and its subsidiary companies. **********************************************************************************/ #include #ifdef HAVE_STRINGS_H #include #endif #include "snes9x.h" #include "memmap.h" #include "cpuops.h" #ifndef NGC #include "cheats.h" #endif #include "ppu.h" #include "cpuexec.h" #include "s9xdebug.h" #include "missing.h" #include "display.h" #include "apu.h" #include "sa1.h" #include "spc7110.h" #ifdef DEBUGGER static void WhatsMissing (); static void WhatsUsed (); EXTERN_C SDMA DMA[8]; extern struct SCheatData Cheat; FILE *trace = NULL; FILE *trace2 = NULL; struct SBreakPoint S9xBreakpoint[6]; struct SDebug { struct { uint8 Bank; uint16 Address; } Dump; struct { uint8 Bank; uint16 Address; } Unassemble; } Debug = { { 0, 0 }, { 0, 0 } }; char *HelpMessage[] = { "Command Help:", "? - Shows this Command Help", "r - Shows the Registers", "i - Shows the interrupt vectors", "t - Trace current instruction [Step-into]", "T - Toggle CPU instruction tracing to trace.log", "D - Toggle DMA tracing to stdout", "H - Toggle H-DMA tracing to stdout", "P - Toggle DSP tracing to stdout", "U - Toggle unknown register read/write tracing", "V - Toggle non-DMA V-RAM read/write tracing", "R - Reset ROM.", "p - Proceed to next instruction [Step-over]", "s - Skip to next instruction [Skip]", "S - dump sprite (OBJ) status", "g [Address] - Go or Go to [Address]", "u [Address] - Disassemble from PC or [Address]", "d [Address] - Dump from PC or [Address]", "bv [Number] - View Breakpoints or View Breakpoint [Number]", "bs [Number] [Address] - Enable/Disable Breakpoint", " [Enable example: BS #2 $02:8002]", " [Disable example: BS #2]", "c - Dump SNES colour palette", "W - Show what SNES hardware features a ROM is using", " which might not be implemented yet.", "w - Show some SNES hardware features used so far in this frame", "q - Quit emulator", "", "[Address] - $Bank:Address or $Address", " [For example: $01:8123]", "[Number] - #Number", " [For example: #1]", "a - Show Sound CPU status", "A - Toggle sound CPU instruction tracing to aputrace.log", "B - Toggle sound DSP register tracing", "C - Dump sound sample addresses", "ad [Address] - Dump sound CPU RAM from PC or [Address]", "", NULL}; char *S9xMnemonics[256] = { "BRK", "ORA", "COP", "ORA", "TSB", "ORA", "ASL", "ORA", "PHP", "ORA", "ASL", "PHD", "TSB", "ORA", "ASL", "ORA", "BPL", "ORA", "ORA", "ORA", "TRB", "ORA", "ASL", "ORA", "CLC", "ORA", "INC", "TCS", "TRB", "ORA", "ASL", "ORA", "JSR", "AND", "JSL", "AND", "BIT", "AND", "ROL", "AND", "PLP", "AND", "ROL", "PLD", "BIT", "AND", "ROL", "AND", "BMI", "AND", "AND", "AND", "BIT", "AND", "ROL", "AND", "SEC", "AND", "DEC", "TSC", "BIT", "AND", "ROL", "AND", "RTI", "EOR", "WDM", "EOR", "MVP", "EOR", "LSR", "EOR", "PHA", "EOR", "LSR", "PHK", "JMP", "EOR", "LSR", "EOR", "BVC", "EOR", "EOR", "EOR", "MVN", "EOR", "LSR", "EOR", "CLI", "EOR", "PHY", "TCD", "JMP", "EOR", "LSR", "EOR", "RTS", "ADC", "PER", "ADC", "STZ", "ADC", "ROR", "ADC", "PLA", "ADC", "ROR", "RTL", "JMP", "ADC", "ROR", "ADC", "BVS", "ADC", "ADC", "ADC", "STZ", "ADC", "ROR", "ADC", "SEI", "ADC", "PLY", "TDC", "JMP", "ADC", "ROR", "ADC", "BRA", "STA", "BRL", "STA", "STY", "STA", "STX", "STA", "DEY", "BIT", "TXA", "PHB", "STY", "STA", "STX", "STA", "BCC", "STA", "STA", "STA", "STY", "STA", "STX", "STA", "TYA", "STA", "TXS", "TXY", "STZ", "STA", "STZ", "STA", "LDY", "LDA", "LDX", "LDA", "LDY", "LDA", "LDX", "LDA", "TAY", "LDA", "TAX", "PLB", "LDY", "LDA", "LDX", "LDA", "BCS", "LDA", "LDA", "LDA", "LDY", "LDA", "LDX", "LDA", "CLV", "LDA", "TSX", "TYX", "LDY", "LDA", "LDX", "LDA", "CPY", "CMP", "REP", "CMP", "CPY", "CMP", "DEC", "CMP", "INY", "CMP", "DEX", "WAI", "CPY", "CMP", "DEC", "CMP", "BNE", "CMP", "CMP", "CMP", "PEI", "CMP", "DEC", "CMP", "CLD", "CMP", "PHX", "STP", "JML", "CMP", "DEC", "CMP", "CPX", "SBC", "SEP", "SBC", "CPX", "SBC", "INC", "SBC", "INX", "SBC", "NOP", "XBA", "CPX", "SBC", "INC", "SBC", "BEQ", "SBC", "SBC", "SBC", "PEA", "SBC", "INC", "SBC", "SED", "SBC", "PLX", "XCE", "JSR", "SBC", "INC", "SBC" }; int AddrModes[256] = { //0 1 2 3 4 5 6 7 8 9 A B C D E F 3, 10, 3, 19, 6, 6, 6, 12, 0, 1,24, 0, 14, 14, 14, 17, //0 4, 11, 9, 20, 6, 7, 7, 13, 0, 16,24, 0, 14, 15, 15, 18, //1 14, 10,17, 19, 6, 6, 6, 12, 0, 1,24, 0, 14, 14, 14, 17, //2 4, 11, 9, 20, 7, 7, 7, 13, 0, 16,24, 0, 15, 15, 15, 18, //3 0, 10, 3, 19, 25,6, 6, 12, 0, 1,24, 0, 14, 14, 14, 17, //4 4, 11, 9, 20, 25,7, 7, 13, 0, 16, 0, 0, 17, 15, 15, 18, //5 0, 10, 5, 19, 6, 6, 6, 12, 0, 1,24, 0, 21, 14, 14, 17, //6 4, 11, 9, 20, 7, 7, 7, 13, 0, 16, 0, 0, 23, 15, 15, 18, //7 4, 10, 5, 19, 6, 6, 6, 12, 0, 1, 0, 0, 14, 14, 14, 17, //8 4, 11, 9, 20, 7, 7, 8, 13, 0, 16, 0, 0, 14, 15, 15, 18, //9 2, 10, 2, 19, 6, 6, 6, 12, 0, 1, 0, 0, 14, 14, 14, 17, //A 4, 11, 9, 20, 7, 7, 8, 13, 0, 16, 0, 0, 15, 15, 16, 18, //B 2, 10, 3, 19, 6, 6, 6, 12, 0, 1, 0, 0, 14, 14, 14, 17, //C 4, 11, 9, 9,27, 7, 7, 13, 0, 16, 0, 0, 22, 15, 15, 18, //D 2, 10, 3, 19, 6, 6, 6, 12, 0, 1, 0, 0, 14, 14, 14, 17, //E 4, 11, 9, 20,26, 7, 7, 13, 0, 16, 0, 0, 23, 15, 15, 18 //F }; uint8 S9xOPrint (char *Line, uint8 Bank, uint16 Address) { uint8 S9xOpcode; uint8 Operant[3]; uint16 Word; uint8 Byte; uint8 Size = 0; char SByte; short SWord; #if 0 sprintf (Line, "%04X%04X%04X%04X%02X%04X%c%c%c%c%c%c%c%c%c%03d%03d", Registers.A.W, Registers.X.W, Registers.Y.W, Registers.D.W, Registers.DB, Registers.S.W, CheckEmulation () ? 'E' : 'e', CheckNegative () ? 'N' : 'n', CheckOverflow () ? 'V' : 'v', CheckMemory () ? 'M' : 'm', CheckIndex () ? 'X' : 'x', CheckDecimal () ? 'D' : 'd', CheckIRQ () ? 'I' : 'i', CheckZero () ? 'Z' : 'z', CheckCarry () ? 'C' : 'c', CPU.Cycles, CPU.V_Counter); return (0); #else int32 Cycles = CPU.Cycles; uint32 WaitAddress = CPU.WaitAddress; S9xOpcode = S9xGetByte ((Bank << 16) + Address); sprintf (Line, "$%02X:%04X %02X ", Bank, Address, S9xOpcode); Operant[0] = S9xGetByte ((Bank << 16) + Address + 1); Operant[1] = S9xGetByte ((Bank << 16) + Address + 2); Operant[2] = S9xGetByte ((Bank << 16) + Address + 3); switch (AddrModes[S9xOpcode]) { case 0: //Implied sprintf (Line, "%s %s", Line, S9xMnemonics[S9xOpcode]); Size = 1; break; case 1: //Immediate[MemoryFlag] if (!CheckFlag (MemoryFlag)) { //Accumulator 16 - Bit sprintf (Line, "%s%02X %02X %s #$%02X%02X", Line, Operant[0], Operant[1], S9xMnemonics[S9xOpcode], Operant[1], Operant[0]); Size = 3; } else { //Accumulator 8 - Bit sprintf (Line, "%s%02X %s #$%02X", Line, Operant[0], S9xMnemonics[S9xOpcode], Operant[0]); Size = 2; } break; case 2: //Immediate[IndexFlag] if (!CheckFlag (IndexFlag)) { //X / Y 16 - Bit sprintf (Line, "%s%02X %02X %s #$%02X%02X", Line, Operant[0], Operant[1], S9xMnemonics[S9xOpcode], Operant[1], Operant[0]); Size = 3; } else { //X / Y 8 - Bit sprintf (Line, "%s%02X %s #$%02X", Line, Operant[0], S9xMnemonics[S9xOpcode], Operant[0]); Size = 2; } break; case 3: //Immediate[Always 8 - Bit] if (1) { //Always 8 - Bit sprintf (Line, "%s%02X %s #$%02X", Line, Operant[0], S9xMnemonics[S9xOpcode], Operant[0]); Size = 2; } break; case 4: //Relative sprintf (Line, "%s%02X %s $%02X", Line, Operant[0], S9xMnemonics[S9xOpcode], Operant[0]); SByte = Operant[0]; Word = Address; Word += SByte; Word += 2; sprintf (Line, "%-32s[$%04X]", Line, Word); Size = 2; break; case 5: //Relative Long sprintf (Line, "%s%02X %02X %s $%02X%02X", Line, Operant[0], Operant[1], S9xMnemonics[S9xOpcode], Operant[1], Operant[0]); SWord = (Operant[1] << 8) | Operant[0]; Word = Address; Word += SWord; Word += 3; sprintf (Line, "%-32s[$%04X]", Line, Word); Size = 3; break; case 6: //Direct sprintf (Line, "%s%02X %s $%02X", Line, Operant[0], S9xMnemonics[S9xOpcode], Operant[0]); Word = Operant[0]; Word += Registers.D.W; sprintf (Line, "%-32s[$00:%04X]", Line, Word); Size = 2; break; case 7: //Direct indexed (with x) sprintf (Line, "%s%02X %s $%02X,x", Line, Operant[0], S9xMnemonics[S9xOpcode], Operant[0]); Word = Operant[0]; Word += Registers.D.W; Word += Registers.X.W; sprintf (Line, "%-32s[$00:%04X]", Line, Word); Size = 2; break; case 8: //Direct indexed (with y) sprintf (Line, "%s%02X %s $%02X,y", Line, Operant[0], S9xMnemonics[S9xOpcode], Operant[0]); Word = Operant[0]; Word += Registers.D.W; Word += Registers.Y.W; sprintf (Line, "%-32s[$00:%04X]", Line, Word); Size = 2; break; case 9: //Direct Indirect sprintf (Line, "%s%02X %s ($%02X)", Line, Operant[0], S9xMnemonics[S9xOpcode], Operant[0]); Word = Operant[0]; Word += Registers.D.W; Word = S9xGetWord (Word); sprintf (Line, "%-32s[$%02X:%04X]", Line, Registers.DB, Word); Size = 2; break; case 10: //Direct Indexed Indirect sprintf (Line, "%s%02X %s ($%02X,x)", Line, Operant[0], S9xMnemonics[S9xOpcode], Operant[0]); Word = Operant[0]; Word += Registers.D.W; Word += Registers.X.W; Word = S9xGetWord (Word); sprintf (Line, "%-32s[$%02X:%04X]", Line, Registers.DB, Word); Size = 2; break; case 11: //Direct Indirect Indexed sprintf (Line, "%s%02X %s ($%02X),y", Line, Operant[0], S9xMnemonics[S9xOpcode], Operant[0]); Word = Operant[0]; Word += Registers.D.W; Word = S9xGetWord (Word); Word += Registers.Y.W; sprintf (Line, "%-32s[$%02X:%04X]", Line, Registers.DB, Word); Size = 2; break; case 12: //Direct Indirect Long sprintf (Line, "%s%02X %s [$%02X]", Line, Operant[0], S9xMnemonics[S9xOpcode], Operant[0]); Word = Operant[0]; Word += Registers.D.W; Byte = S9xGetByte (Word + 2); Word = S9xGetWord (Word); sprintf (Line, "%-32s[$%02X:%04X]", Line, Byte, Word); Size = 2; break; case 13: //Direct Indirect Indexed Long sprintf (Line, "%s%02X %s [$%02X],y", Line, Operant[0], S9xMnemonics[S9xOpcode], Operant[0]); Word = Operant[0]; Word += Registers.D.W; Byte = S9xGetByte (Word + 2); Word = S9xGetWord (Word); Word += Registers.Y.W; sprintf (Line, "%-32s[$%02X:%04X]", Line, Byte, Word); Size = 2; break; case 14: //Absolute sprintf (Line, "%s%02X %02X %s $%02X%02X", Line, Operant[0], Operant[1], S9xMnemonics[S9xOpcode], Operant[1], Operant[0]); Word = (Operant[1] << 8) | Operant[0]; sprintf (Line, "%-32s[$%02X:%04X]", Line, Registers.DB, Word); Size = 3; break; case 15: //Absolute Indexed (With X) sprintf (Line, "%s%02X %02X %s $%02X%02X,x", Line, Operant[0], Operant[1], S9xMnemonics[S9xOpcode], Operant[1], Operant[0]); Word = (Operant[1] << 8) | Operant[0]; Word += Registers.X.W; sprintf (Line, "%-32s[$%02X:%04X]", Line, Registers.DB, Word); Size = 3; break; case 16: //Absolute Indexed (With Y) sprintf (Line, "%s%02X %02X %s $%02X%02X,y", Line, Operant[0], Operant[1], S9xMnemonics[S9xOpcode], Operant[1], Operant[0]); Word = (Operant[1] << 8) | Operant[0]; Word += Registers.Y.W; sprintf (Line, "%-32s[$%02X:%04X]", Line, Registers.DB, Word); Size = 3; break; case 17: //Absolute long sprintf (Line, "%s%02X %02X %02X %s $%02X%02X%02X", Line, Operant[0], Operant[1], Operant[2], S9xMnemonics[S9xOpcode], Operant[2], Operant[1], Operant[0]); Word = (Operant[1] << 8) | Operant[0]; sprintf (Line, "%-32s[$%02X:%04X]", Line, Operant[2], Word); Size = 4; break; case 18: //Absolute Indexed long sprintf (Line, "%s%02X %02X %02X %s $%02X%02X%02X,x", Line, Operant[0], Operant[1], Operant[2], S9xMnemonics[S9xOpcode], Operant[2], Operant[1], Operant[0]); Word = (Operant[1] << 8) | Operant[0]; Word += Registers.X.W; sprintf (Line, "%-32s[$%02X:%04X]", Line, Operant[2], Word); Size = 4; break; case 19: //StackRelative sprintf (Line, "%s%02X %s $%02X,s", Line, Operant[0], S9xMnemonics[S9xOpcode], Operant[0]); Word = Registers.S.W; Word += Operant[0]; sprintf (Line, "%-32s[$00:%04X]", Line, Word); Size = 2; break; case 20: //Stack Relative Indirect Indexed sprintf (Line, "%s%02X %s ($%02X,s),y", Line, Operant[0], S9xMnemonics[S9xOpcode], Operant[0]); Word = Registers.S.W; Word += Operant[0]; Word = S9xGetWord (Word); Word += Registers.Y.W; sprintf (Line, "%-32s[$%02X:%04X]", Line, Registers.DB, Word); Size = 2; break; case 21: //Absolute Indirect sprintf (Line, "%s%02X %02X %s ($%02X%02X)", Line, Operant[0], Operant[1], S9xMnemonics[S9xOpcode], Operant[1], Operant[0]); Word = (Operant[1] << 8) | Operant[0]; Word = S9xGetWord (Word); sprintf (Line, "%-32s[$%02X:%04X]", Line, Registers.PB, Word); Size = 3; break; case 22: //Absolute Indirect Long sprintf (Line, "%s%02X %02X %s [$%02X%02X]", Line, Operant[0], Operant[1], S9xMnemonics[S9xOpcode], Operant[1], Operant[0]); Word = (Operant[1] << 8) | Operant[0]; Byte = S9xGetByte (Word + 2); Word = S9xGetWord (Word); sprintf (Line, "%-32s[$%02X:%04X]", Line, Byte, Word); Size = 3; break; case 23: //Absolute Indexed Indirect sprintf (Line, "%s%02X %02X %s ($%02X%02X,x)", Line, Operant[0], Operant[1], S9xMnemonics[S9xOpcode], Operant[1], Operant[0]); Word = (Operant[1] << 8) | Operant[0]; Word += Registers.X.W; Word = S9xGetWord (ICPU.ShiftedPB + Word); sprintf (Line, "%-32s[$%02X:%04X]", Line, Registers.PB, Word); Size = 3; break; case 24: //Implied accumulator sprintf (Line, "%s %s A", Line, S9xMnemonics[S9xOpcode]); Size = 1; break; case 25: // MVN/MVP SRC DST sprintf (Line, "%s%02X %02X %s %02X %02X", Line, Operant[0], Operant[1], S9xMnemonics[S9xOpcode], Operant[1], Operant[0]); Size = 3; break; case 26: // PEA sprintf (Line, "%s%02X %02X %s $%02X%02X", Line, Operant[0], Operant[1], S9xMnemonics[S9xOpcode], Operant[1], Operant[0]); Size = 3; break; case 27: // PEI Direct Indirect sprintf (Line, "%s%02X %s ($%02X)", Line, Operant[0], S9xMnemonics[S9xOpcode], Operant[0]); Word = Operant[0]; Word += Registers.D.W; Word = S9xGetWord (Word); sprintf (Line, "%-32s[$%04X]", Line, Word); Size = 2; break; } // XXX: sprintf (Line, "%-44s A:%04X X:%04X Y:%04X D:%04X DB:%02X S:%04X P:%c%c%c%c%c%c%c%c%c HC:%04d VC:%03d FC:%02d %02x", Line, Registers.A.W, Registers.X.W, Registers.Y.W, Registers.D.W, Registers.DB, Registers.S.W, CheckEmulation () ? 'E' : 'e', CheckNegative () ? 'N' : 'n', CheckOverflow () ? 'V' : 'v', CheckMemory () ? 'M' : 'm', CheckIndex () ? 'X' : 'x', CheckDecimal () ? 'D' : 'd', CheckIRQ () ? 'I' : 'i', CheckZero () ? 'Z' : 'z', CheckCarry () ? 'C' : 'c', Cycles, CPU.V_Counter, IPPU.FrameCount, CPU.IRQActive); CPU.Cycles = Cycles; CPU.WaitAddress = WaitAddress; return Size; #endif } uint8 S9xSA1OPrint (char *Line, uint8 Bank, uint16 Address) { uint8 S9xOpcode; uint8 Operant[3]; uint16 Word; uint8 Byte; uint8 Size = 0; char SByte; short SWord; #if 0 sprintf (Line, "%04X%04X%04X%04X%02X%04X%c%c%c%c%c%c%c%c%c%03d%03d", SA1Registers.A.W, SA1Registers.X.W, SA1Registers.Y.W, SA1Registers.D.W, SA1Registers.DB, SA1Registers.S.W, SA1CheckEmulation () ? 'E' : 'e', SA1CheckNegative () ? 'N' : 'n', SA1CheckOverflow () ? 'V' : 'v', SA1CheckMemory () ? 'M' : 'm', SA1CheckIndex () ? 'X' : 'x', SA1CheckDecimal () ? 'D' : 'd', SA1CheckIRQ () ? 'I' : 'i', SA1CheckZero () ? 'Z' : 'z', SA1CheckCarry () ? 'C' : 'c', CPU.Cycles, CPU.V_Counter); return (0); #else S9xOpcode = S9xSA1GetByte ((Bank << 16) + Address); sprintf (Line, "$%02X:%04X %02X ", Bank, Address, S9xOpcode); Operant[0] = S9xSA1GetByte ((Bank << 16) + Address + 1); Operant[1] = S9xSA1GetByte ((Bank << 16) + Address + 2); Operant[2] = S9xSA1GetByte ((Bank << 16) + Address + 3); switch (AddrModes[S9xOpcode]) { case 0: //Implied sprintf (Line, "%s %s", Line, S9xMnemonics[S9xOpcode]); Size = 1; break; case 1: //Immediate[MemoryFlag] if (!SA1CheckFlag (MemoryFlag)) { //Accumulator 16 - Bit sprintf (Line, "%s%02X %02X %s #$%02X%02X", Line, Operant[0], Operant[1], S9xMnemonics[S9xOpcode], Operant[1], Operant[0]); Size = 3; } else { //Accumulator 8 - Bit sprintf (Line, "%s%02X %s #$%02X", Line, Operant[0], S9xMnemonics[S9xOpcode], Operant[0]); Size = 2; } break; case 2: //Immediate[IndexFlag] if (!SA1CheckFlag (IndexFlag)) { //X / Y 16 - Bit sprintf (Line, "%s%02X %02X %s #$%02X%02X", Line, Operant[0], Operant[1], S9xMnemonics[S9xOpcode], Operant[1], Operant[0]); Size = 3; } else { //X / Y 8 - Bit sprintf (Line, "%s%02X %s #$%02X", Line, Operant[0], S9xMnemonics[S9xOpcode], Operant[0]); Size = 2; } break; case 3: //Immediate[Always 8 - Bit] if (1) { //Always 8 - Bit sprintf (Line, "%s%02X %s #$%02X", Line, Operant[0], S9xMnemonics[S9xOpcode], Operant[0]); Size = 2; } break; case 4: //Relative sprintf (Line, "%s%02X %s $%02X", Line, Operant[0], S9xMnemonics[S9xOpcode], Operant[0]); SByte = Operant[0]; Word = Address; Word += SByte; Word += 2; sprintf (Line, "%-32s[$%04X]", Line, Word); Size = 2; break; case 5: //Relative Long sprintf (Line, "%s%02X %02X %s $%02X%02X", Line, Operant[0], Operant[1], S9xMnemonics[S9xOpcode], Operant[1], Operant[0]); SWord = (Operant[1] << 8) | Operant[0]; Word = Address; Word += SWord; Word += 3; sprintf (Line, "%-32s[$%04X]", Line, Word); Size = 3; break; case 6: //Direct sprintf (Line, "%s%02X %s $%02X", Line, Operant[0], S9xMnemonics[S9xOpcode], Operant[0]); Word = Operant[0]; Word += SA1Registers.D.W; sprintf (Line, "%-32s[$00:%04X]", Line, Word); Size = 2; break; case 7: //Direct indexed (with x) sprintf (Line, "%s%02X %s $%02X,x", Line, Operant[0], S9xMnemonics[S9xOpcode], Operant[0]); Word = Operant[0]; Word += SA1Registers.D.W; Word += SA1Registers.X.W; sprintf (Line, "%-32s[$00:%04X]", Line, Word); Size = 2; break; case 8: //Direct indexed (with y) sprintf (Line, "%s%02X %s $%02X,y", Line, Operant[0], S9xMnemonics[S9xOpcode], Operant[0]); Word = Operant[0]; Word += SA1Registers.D.W; Word += SA1Registers.Y.W; sprintf (Line, "%-32s[$00:%04X]", Line, Word); Size = 2; break; case 9: //Direct Indirect sprintf (Line, "%s%02X %s ($%02X)", Line, Operant[0], S9xMnemonics[S9xOpcode], Operant[0]); Word = Operant[0]; Word += SA1Registers.D.W; Word = S9xSA1GetWord (Word); sprintf (Line, "%-32s[$%02X:%04X]", Line, SA1Registers.DB, Word); Size = 2; break; case 10: //Direct Indexed Indirect sprintf (Line, "%s%02X %s ($%02X,x)", Line, Operant[0], S9xMnemonics[S9xOpcode], Operant[0]); Word = Operant[0]; Word += SA1Registers.D.W; Word += SA1Registers.X.W; Word = S9xSA1GetWord (Word); sprintf (Line, "%-32s[$%02X:%04X]", Line, SA1Registers.DB, Word); Size = 2; break; case 11: //Direct Indirect Indexed sprintf (Line, "%s%02X %s ($%02X),y", Line, Operant[0], S9xMnemonics[S9xOpcode], Operant[0]); Word = Operant[0]; Word += SA1Registers.D.W; Word = S9xSA1GetWord (Word); Word += SA1Registers.Y.W; sprintf (Line, "%-32s[$%02X:%04X]", Line, SA1Registers.DB, Word); Size = 2; break; case 12: //Direct Indirect Long sprintf (Line, "%s%02X %s [$%02X]", Line, Operant[0], S9xMnemonics[S9xOpcode], Operant[0]); Word = Operant[0]; Word += SA1Registers.D.W; Byte = S9xSA1GetByte (Word + 2); Word = S9xSA1GetWord (Word); sprintf (Line, "%-32s[$%02X:%04X]", Line, Byte, Word); Size = 2; break; case 13: //Direct Indirect Indexed Long sprintf (Line, "%s%02X %s [$%02X],y", Line, Operant[0], S9xMnemonics[S9xOpcode], Operant[0]); Word = Operant[0]; Word += SA1Registers.D.W; Byte = S9xSA1GetByte (Word + 2); Word = S9xSA1GetWord (Word); Word += SA1Registers.Y.W; sprintf (Line, "%-32s[$%02X:%04X]", Line, Byte, Word); Size = 2; break; case 14: //Absolute sprintf (Line, "%s%02X %02X %s $%02X%02X", Line, Operant[0], Operant[1], S9xMnemonics[S9xOpcode], Operant[1], Operant[0]); Word = (Operant[1] << 8) | Operant[0]; sprintf (Line, "%-32s[$%02X:%04X]", Line, SA1Registers.DB, Word); Size = 3; break; case 15: //Absolute Indexed (With X) sprintf (Line, "%s%02X %02X %s $%02X%02X,x", Line, Operant[0], Operant[1], S9xMnemonics[S9xOpcode], Operant[1], Operant[0]); Word = (Operant[1] << 8) | Operant[0]; Word += SA1Registers.X.W; sprintf (Line, "%-32s[$%02X:%04X]", Line, SA1Registers.DB, Word); Size = 3; break; case 16: //Absolute Indexed (With Y) sprintf (Line, "%s%02X %02X %s $%02X%02X,y", Line, Operant[0], Operant[1], S9xMnemonics[S9xOpcode], Operant[1], Operant[0]); Word = (Operant[1] << 8) | Operant[0]; Word += SA1Registers.Y.W; sprintf (Line, "%-32s[$%02X:%04X]", Line, SA1Registers.DB, Word); Size = 3; break; case 17: //Absolute long sprintf (Line, "%s%02X %02X %02X %s $%02X%02X%02X", Line, Operant[0], Operant[1], Operant[2], S9xMnemonics[S9xOpcode], Operant[2], Operant[1], Operant[0]); Word = (Operant[1] << 8) | Operant[0]; sprintf (Line, "%-32s[$%02X:%04X]", Line, Operant[2], Word); Size = 4; break; case 18: //Absolute Indexed long sprintf (Line, "%s%02X %02X %02X %s $%02X%02X%02X,x", Line, Operant[0], Operant[1], Operant[2], S9xMnemonics[S9xOpcode], Operant[2], Operant[1], Operant[0]); Word = (Operant[1] << 8) | Operant[0]; Word += SA1Registers.X.W; sprintf (Line, "%-32s[$%02X:%04X]", Line, Operant[2], Word); Size = 4; break; case 19: //StackRelative sprintf (Line, "%s%02X %s $%02X,s", Line, Operant[0], S9xMnemonics[S9xOpcode], Operant[0]); Word = SA1Registers.S.W; Word += Operant[0]; sprintf (Line, "%-32s[$00:%04X]", Line, Word); Size = 2; break; case 20: //Stack Relative Indirect Indexed sprintf (Line, "%s%02X %s ($%02X,s),y", Line, Operant[0], S9xMnemonics[S9xOpcode], Operant[0]); Word = SA1Registers.S.W; Word += Operant[0]; Word = S9xSA1GetWord (Word); Word += SA1Registers.Y.W; sprintf (Line, "%-32s[$%02X:%04X]", Line, SA1Registers.DB, Word); Size = 2; break; case 21: //Absolute Indirect sprintf (Line, "%s%02X %02X %s ($%02X%02X)", Line, Operant[0], Operant[1], S9xMnemonics[S9xOpcode], Operant[1], Operant[0]); Word = (Operant[1] << 8) | Operant[0]; Word = S9xSA1GetWord (Word); sprintf (Line, "%-32s[$%02X:%04X]", Line, SA1Registers.PB, Word); Size = 3; break; case 22: //Absolute Indirect Long sprintf (Line, "%s%02X %02X %s [$%02X%02X]", Line, Operant[0], Operant[1], S9xMnemonics[S9xOpcode], Operant[1], Operant[0]); Word = (Operant[1] << 8) | Operant[0]; Byte = S9xSA1GetByte (Word + 2); Word = S9xSA1GetWord (Word); sprintf (Line, "%-32s[$%02X:%04X]", Line, Byte, Word); Size = 3; break; case 23: //Absolute Indexed Indirect sprintf (Line, "%s%02X %02X %s ($%02X%02X,x)", Line, Operant[0], Operant[1], S9xMnemonics[S9xOpcode], Operant[1], Operant[0]); Word = (Operant[1] << 8) | Operant[0]; Word += SA1Registers.X.W; Word = S9xSA1GetWord (SA1.ShiftedPB + Word); sprintf (Line, "%-32s[$%02X:%04X]", Line, SA1Registers.PB, Word); Size = 3; break; case 24: //Implied accumulator sprintf (Line, "%s %s A", Line, S9xMnemonics[S9xOpcode]); Size = 1; break; case 25: // MVN/MVP SRC DST sprintf (Line, "%s %s %02X %02X", Line, S9xMnemonics[S9xOpcode], Operant[0], Operant[1]); Size = 3; break; } sprintf (Line, "%-44s A:%04X X:%04X Y:%04X D:%04X DB:%02X S:%04X P:%c%c%c%c%c%c%c%c%c HC:%03ld VC:%03ld", Line, SA1Registers.A.W, SA1Registers.X.W, SA1Registers.Y.W, SA1Registers.D.W, SA1Registers.DB, SA1Registers.S.W, SA1CheckEmulation () ? 'E' : 'e', SA1CheckNegative () ? 'N' : 'n', SA1CheckOverflow () ? 'V' : 'v', SA1CheckMemory () ? 'M' : 'm', SA1CheckIndex () ? 'X' : 'x', SA1CheckDecimal () ? 'D' : 'd', SA1CheckIRQ () ? 'I' : 'i', SA1CheckZero () ? 'Z' : 'z', SA1CheckCarry () ? 'C' : 'c', CPU.Cycles, CPU.V_Counter); return Size; #endif } /**********************************************************************************************/ /* DPrint() */ /* This function prints a line in the debug listbox and deletes upperlines if needed */ /**********************************************************************************************/ void DPrint (char *Line) { printf ("%s\n", Line); } /**********************************************************************************************/ /* GetNumber() */ /* This function gets a number from a debug command */ /**********************************************************************************************/ int GetNumber (char *Line, uint16 * Number) { int i; if (sscanf (Line, " #%d", &i) == 1) { *Number = i; return (1); } return (-1); } /**********************************************************************************************/ /* GetStartAddress() */ /* This function gets a starting address from a debug command */ /**********************************************************************************************/ short GetStartAddress (char *Line, uint8 *Bank, uint32 *Address) { uint32 a, b; if (sscanf (Line + 1, " $%x:%x", &b, &a) != 2) return (-1); *Bank = b; *Address = a; return (1); } /**********************************************************************************************/ /* ProcessDebugCommand() */ /* This function processes a debug command */ /**********************************************************************************************/ static void ProcessDebugCommand (char *Line) { uint8 Bank = Registers.PB; uint32 Address = Registers.PCw; uint16 Hold; uint16 Number; char String [512]; short ErrorCode; if (strcasecmp (Line, "cheat") == 0) { S9xStartCheatSearch (&Cheat); printf ("Cheat Search Started\n"); return; } if (strcasecmp (Line, "less") == 0) { S9xSearchForChange (&Cheat, S9X_LESS_THAN, S9X_8_BITS, FALSE, TRUE); printf ("Recorded all values that have decreased\n"); return; } if (strcasecmp (Line, "print") == 0) { printf ("Cheat search results:\n"); S9xOutputCheatSearchResults (&Cheat); return; } if (strncasecmp (Line, "constant", 8) == 0) { uint32 Byte; if (sscanf (&Line [8], "%x %x", &Address, &Byte) == 2) S9xAddCheat (TRUE, TRUE, Address, Byte); return; } if (strncasecmp (Line, "dump", 4) == 0) { int Count; if (sscanf (&Line [4], "%x %d", &Address, &Count) == 2) { sprintf (String, "%06x%05d.sd2", Address, Count); FILE *fs = fopen (String, "wb"); if (fs) { int i; for (i = 0; i < Count; i++) putc (S9xGetByte (Address + i), fs); fclose (fs); } else printf ("Can't open %s for writing\n", String); } else printf ("Usage: dump start_address_in_hex count_in_decimal\n"); return; } if (Line[0] == 'i') { printf ("Vectors:\n"); sprintf (String, " 8 Bit 16 Bit "); DPrint (String); sprintf (String, "ABT $00:%04X|$00:%04X", S9xGetWord (0xFFF8), S9xGetWord (0xFFE8)); DPrint (String); sprintf (String, "BRK $00:%04X|$00:%04X", S9xGetWord (0xFFFE), S9xGetWord (0xFFE6)); DPrint (String); sprintf (String, "COP $00:%04X|$00:%04X", S9xGetWord (0xFFF4), S9xGetWord (0xFFE4)); DPrint (String); sprintf (String, "IRQ $00:%04X|$00:%04X", S9xGetWord (0xFFFE), S9xGetWord (0xFFEE)); DPrint (String); sprintf (String, "NMI $00:%04X|$00:%04X", S9xGetWord (0xFFFA), S9xGetWord (0xFFEA)); DPrint (String); sprintf (String, "RES $00:%04X", S9xGetWord (0xFFFC)); DPrint (String); } if (strncmp (Line, "ai", 2) == 0) { printf ("APU vectors:"); for (int i = 0; i < 0x40; i += 2) { if (i % 16 == 0) printf ("\n%04x ", 0xffc0 + i); printf ("%04x ", APU.ExtraRAM [i]); } printf ("\n"); } if (Line[0] == 's') { Registers.PCw += S9xOPrint (String, Bank, Address); Bank = Registers.PB; Address = Registers.PCw; Line[0] = 'r'; } if (Line[0] == 'z') { uint16 *p = (uint16 *) &Memory.VRAM [PPU.BG[2].SCBase << 1]; for (int l = 0; l < 32; l++) { for (int c = 0; c < 32; c++, p++) { printf ("%04x,", *p++); } printf ("\n"); } } if (*Line == 'c') { printf ("Colours:\n"); for (int i = 0; i < 256; i++) { printf ("%02x%02x%02x ", PPU.CGDATA[i] & 0x1f, (PPU.CGDATA[i] >> 5) & 0x1f, (PPU.CGDATA[i] >> 10) & 0x1f); } printf ("\n"); } if (*Line == 'S') { int SmallWidth, LargeWidth; int SmallHeight, LargeHeight; switch ((Memory.FillRAM[0x2101] >> 5) & 7) { case 0: SmallWidth = SmallHeight = 8; LargeWidth = LargeHeight = 16; break; case 1: SmallWidth = SmallHeight = 8; LargeWidth = LargeHeight = 32; break; case 2: SmallWidth = SmallHeight = 8; LargeWidth = LargeHeight = 64; break; case 3: SmallWidth = SmallHeight = 16; LargeWidth = LargeHeight = 32; break; case 4: SmallWidth = SmallHeight = 16; LargeWidth = LargeHeight = 64; break; default: case 5: SmallWidth = SmallHeight = 32; LargeWidth = LargeHeight = 64; break; case 6: SmallWidth = 16; SmallHeight = 32; LargeWidth = 32; LargeHeight = 64; break; case 7: SmallWidth = 16; SmallHeight = 32; LargeWidth = LargeHeight = 32; break; } printf ("Sprites: Small: %dx%d, Large: %dx%d, OAMAddr: 0x%04x, OBJNameBase: 0x%04x, OBJNameSelect: 0x%04x, First: %d\n", SmallWidth,SmallHeight, LargeWidth,LargeHeight, PPU.OAMAddr, PPU.OBJNameBase, PPU.OBJNameSelect, PPU.FirstSprite); // for (int p = 0; p < 4; p++) // { // int c = 0; // int i; // for (i = 0; GFX.OBJList [i] >= 0; i++) // { // if (PPU.OBJ[GFX.OBJList [i]].Priority == p) // c++; // } // printf ("Priority %d: %03d, ", p, c); // } // printf ("\n"); for (int i = 0; i < 128; i++) { printf ("X:%3d Y:%3d %c%c%d%c ", PPU.OBJ[i].HPos, PPU.OBJ[i].VPos, PPU.OBJ[i].VFlip ? 'V' : 'v', PPU.OBJ[i].HFlip ? 'H' : 'h', PPU.OBJ[i].Priority, PPU.OBJ[i].Size ? 'S' : 's'); if (i % 4 == 3) printf ("\n"); } } if (*Line == 'T') { if (Line [1] == 'S') { SA1.Flags ^= TRACE_FLAG; if (SA1.Flags & TRACE_FLAG) { printf ("SA1 CPU instruction tracing enabled.\n"); if (trace2 == NULL) trace2 = fopen ("trace_sa1.log", "wb"); } else { printf ("SA1 CPU instruction tracing disabled.\n"); fclose (trace2); trace2 = NULL; } } else { CPU.Flags ^= TRACE_FLAG; if (CPU.Flags & TRACE_FLAG) { printf ("CPU instruction tracing enabled.\n"); if (trace == NULL) trace = fopen ("trace.log", "wb"); } else { printf ("CPU instruction tracing disabled.\n"); fclose (trace); trace = NULL; } } } if (*Line == 'A') { APU.Flags ^= TRACE_FLAG; extern FILE *apu_trace; if (APU.Flags & TRACE_FLAG) { if (apu_trace == NULL) apu_trace = fopen ("aputrace.log", "wb"); } else { if (apu_trace) { fclose (apu_trace); apu_trace = NULL; } } printf ("APU tracing %s\n", APU.Flags & TRACE_FLAG ? "enabled" : "disabled"); } if (*Line == 'B') { Settings.TraceSoundDSP ^= 1; printf ("Sound DSP register tracing %s\n", Settings.TraceSoundDSP ? "enabled" : "disabled"); S9xOpenCloseSoundTracingFile (Settings.TraceSoundDSP); } if (*Line == 'b') S9xPrintAPUState (); if (*Line == 'C') { printf ("SPC700 sample addresses at 0x%04x:\n", APU.DSP [APU_DIR] << 8); for (int i = 0; i < 256; i++) { uint8 *dir = IAPU.RAM + (((APU.DSP [APU_DIR] << 8) + i * 4) & 0xffff); int addr = *dir + (*(dir + 1) << 8); int addr2 = *(dir + 2) + (*(dir + 3) << 8); printf ("%04X %04X;", addr, addr2); if (i % 8 == 7) printf ("\n"); } } if (*Line == 'R') { S9xReset (); printf ("SNES reset.\n"); CPU.Flags |= DEBUG_MODE_FLAG; } if (strncmp (Line, "ad", 2) == 0) { uint32 Count = 16; Address = 0; if (sscanf (Line+2, "%x,%x", &Address, &Count) != 2) { if (sscanf (Line + 2, "%x", &Address) == 1) Count = 16; } printf ("APU RAM dump:\n"); for (uint32 l = 0; l < Count; l += 16) { printf ("%04X ", Address); for (int i = 0; i < 16; i++) printf ("%02X ", IAPU.RAM [Address++]); printf ("\n"); } *Line = 0; } if (*Line == 'a') { printf ("APU in-ports: %02X %02X %02X %02X\n", IAPU.RAM [0xF4], IAPU.RAM [0xF5], IAPU.RAM [0xF6], IAPU.RAM [0xF7]); printf ("APU out-ports: %02X %02X %02X %02X\n", APU.OutPorts [0], APU.OutPorts [1], APU.OutPorts [2], APU.OutPorts [3]); printf ("ROM/RAM switch: %s\n", (IAPU.RAM [0xf1] & 0x80) ? "ROM" : "RAM"); for (int i = 0; i < 3; i++) if (APU.TimerEnabled [i]) printf ("Timer%d enabled, Value: 0x%03X, 4-bit: 0x%02X, Target: 0x%03X\n", i, APU.Timer [i], IAPU.RAM [0xfd + i], APU.TimerTarget [i]); } if (*Line == 'P') { Settings.TraceDSP = !Settings.TraceDSP; printf ("DSP tracing %s\n", Settings.TraceDSP ? "enabled" : "disabled"); } if (Line[0] == 'p') { S9xBreakpoint[5].Enabled = FALSE; Address += S9xOPrint (String, Bank, Address); if (strncmp (&String[18], "JMP", 3) != 0 && strncmp (&String[18], "JML", 3) != 0 && strncmp (&String[18], "RT", 2) != 0 && strncmp (&String[18], "BRA", 3)) { S9xBreakpoint[5].Enabled = TRUE; S9xBreakpoint[5].Bank = Bank; S9xBreakpoint[5].Address = Address; } else { CPU.Flags |= SINGLE_STEP_FLAG; CPU.Flags &= ~DEBUG_MODE_FLAG; } } if (Line[0] == 'b') { if (Line[1] == 's') { GetNumber (Line + 2, &Hold); if (Hold > 4) Hold = 0; if (Hold < 5) if (GetStartAddress (Line + 5, &Bank, &Address) == -1) { //Clear S9xBreakpoint S9xBreakpoint[Hold].Enabled = FALSE; } else { //Set S9xBreakpoint S9xBreakpoint[Hold].Enabled = TRUE; S9xBreakpoint[Hold].Bank = Bank; S9xBreakpoint[Hold].Address = Address; CPU.Flags |= BREAK_FLAG; } Line = "bv"; } if (Line[1] == 'v') { Number = 0; if (GetNumber (Line + 2, &Number) == -1 && Number < 5) { //Show All Breakpoints DPrint ("Breakpoints:"); for (Number = 0; Number != 5; Number++) { if (S9xBreakpoint[Number].Enabled) sprintf (String, "%i @ $%02X:%04X", Number, S9xBreakpoint[Number].Bank, S9xBreakpoint[Number].Address); else sprintf (String, "%i @ Disabled", Number); DPrint (String); } } else { //Show selected S9xBreakpoint DPrint ("Breakpoint:"); if (S9xBreakpoint[Number].Enabled) sprintf (String, "%i @ $%02X:%04X", Number, S9xBreakpoint[Number].Bank, S9xBreakpoint[Number].Address); else sprintf (String, "%i @ Disabled", Number); DPrint (String); } } } if (Line[0] == '?' || strcasecmp (Line, "help") == 0) { for (short Counter = 0; HelpMessage[Counter] != NULL; Counter++) DPrint (HelpMessage[Counter]); } if (Line[0] == 't') { CPU.Flags |= SINGLE_STEP_FLAG; CPU.Flags &= ~DEBUG_MODE_FLAG; } if (Line[0] == 'f') { CPU.Flags |= FRAME_ADVANCE_FLAG; CPU.Flags &= ~DEBUG_MODE_FLAG; // Render this frame IPPU.RenderThisFrame = TRUE; IPPU.FrameSkip = 0; if (sscanf (&Line [1], "%u", &ICPU.FrameAdvanceCount) != 1) ICPU.Frame = 0; } if (Line[0] == 'g') { S9xBreakpoint[5].Enabled = FALSE; int i; bool8 found = FALSE; for (i = 0; i < 5; i++) { if (S9xBreakpoint[i].Enabled) { found = TRUE; if (S9xBreakpoint[i].Bank == Registers.PB && S9xBreakpoint[i].Address == Registers.PCw) { S9xBreakpoint[i].Enabled = 2; break; } } } if (!found) CPU.Flags &= ~BREAK_FLAG; ErrorCode = GetStartAddress (Line, &Bank, &Address); if (ErrorCode == 1) { S9xBreakpoint[5].Enabled = TRUE; S9xBreakpoint[5].Bank = Bank; S9xBreakpoint[5].Address = Address; CPU.Flags |= BREAK_FLAG; } CPU.Flags &= ~DEBUG_MODE_FLAG; } if (*Line == 'D') { Settings.TraceDMA = !Settings.TraceDMA; printf ("DMA tracing %s\n", Settings.TraceDMA ? "enabled" : "disabled"); } if (*Line == 'V') { Settings.TraceVRAM = !Settings.TraceVRAM; printf ("Non-DMA VRAM write tracing %s\n", Settings.TraceVRAM ? "enabled" : "disabled"); } if (*Line == 'H') { Settings.TraceHDMA = !Settings.TraceHDMA; printf ("H-DMA tracing %s\n", Settings.TraceHDMA ? "enabled" : "disabled"); } if (*Line == 'U') { Settings.TraceUnknownRegisters = !Settings.TraceUnknownRegisters; printf ("Unknown registers read/write tracing %s\n", Settings.TraceUnknownRegisters ? "enabled" : "disabled"); } if (Line[0] == 'd') { int CLine; int CByte; int32 Cycles = CPU.Cycles; uint8 MemoryByte; if (Debug.Dump.Bank != 0 || Debug.Dump.Address != 0) { Bank = Debug.Dump.Bank; Address = Debug.Dump.Address; } ErrorCode = GetStartAddress (Line, &Bank, &Address); for (CLine = 0; CLine != 10; CLine++) { sprintf (String, "$%02X:%04X", Bank, Address); for (CByte = 0; CByte != 16; CByte++) { if (Address + CByte == 0x2140 || Address + CByte == 0x2141 || Address + CByte == 0x2142 || Address + CByte == 0x2143 || Address + CByte == 0x4210) { MemoryByte = 0; } else { MemoryByte = S9xGetByte ((Bank << 16) + Address + CByte); } sprintf (String, "%s %02X", String, MemoryByte); } sprintf (String, "%s-", String); for (CByte = 0; CByte != 16; CByte++) { if (Address + CByte == 0x2140 || Address + CByte == 0x2141 || Address + CByte == 0x2142 || Address + CByte == 0x2143 || Address + CByte == 0x4210) { MemoryByte = 0; } else { MemoryByte = S9xGetByte ((Bank << 16) + Address + CByte); } if (MemoryByte < 32 || MemoryByte >= 127) MemoryByte = '?'; sprintf (String, "%s%c", String, MemoryByte); } Address += 16; DPrint (String); } Debug.Dump.Bank = Bank; Debug.Dump.Address = Address; CPU.Cycles = Cycles; } if (*Line == 'q') S9xExit (); if (*Line == 'W') WhatsMissing (); if (*Line == 'w') WhatsUsed (); if (Line[0] == 'r') { #if 0 sprintf (String, "A[%04X] X[%04X] Y[%04X] S[%04X] D[%04X] DB[%02X] P[%02X] F[%s %s %s %s %s %s %s %s / %s]", Registers.A.W, Registers.X.W, Registers.Y.W, Registers.S.W, Registers.D.W, Registers.DB, Registers.PL, (Registers.P.W & 128) != 0 ? "N" : "n", (Registers.P.W & 64) != 0 ? "V" : "v", (Registers.P.W & 32) != 0 ? "M" : "m", (Registers.P.W & 16) != 0 ? "X" : "x", (Registers.P.W & 8) != 0 ? "D" : "d", (Registers.P.W & 4) != 0 ? "I" : "i", (Registers.P.W & 2) != 0 ? "Z" : "z", (Registers.P.W & 1) != 0 ? "C" : "c", (Registers.P.W & 256) != 0 ? "E" : "e"); DPrint (String); #endif S9xOPrint (String, Bank, Address); DPrint (String); } if (Line[0] == 'u') { if (Debug.Unassemble.Bank != 0 || Debug.Unassemble.Address != 0) { Bank = Debug.Unassemble.Bank; Address = Debug.Unassemble.Address; } ErrorCode = GetStartAddress (Line, &Bank, &Address); for (short Counter = 0; Counter != 10; Counter++) { Address += S9xOPrint (String, Bank, Address); DPrint (String); } Debug.Unassemble.Bank = Bank; Debug.Unassemble.Address = Address; } DPrint (""); return; } static void PrintWindow (uint8 * a) { for (int i = 0; i < 6; i++) if (a[i]) switch (i) { case 0: printf ("Background 0, "); break; case 1: printf ("Background 1, "); break; case 2: printf ("Background 2, "); break; case 3: printf ("Background 3, "); break; case 4: printf ("Objects, "); break; case 5: printf ("Colour window, "); break; } } static char *ClipFn (int logic) { switch (logic) { case CLIP_OR: return ("OR"); case CLIP_AND: return ("AND"); case CLIP_XOR: return ("XOR"); case CLIP_XNOR: return ("XNOR"); default: return ("???"); } } static void WhatsUsed () { printf ("V-line: %ld, H-Pos: %ld\n", CPU.V_Counter, CPU.Cycles); printf ("Screen mode: %d, ", PPU.BGMode); if (PPU.BGMode <= 1 && (Memory.FillRAM [0x2105] & 8)) printf ("(BG#2 Priority)"); printf ("Brightness: %d", PPU.Brightness); if (Memory.FillRAM[0x2100] & 0x80) printf (" (screen blanked)"); printf ("\n"); if (Memory.FillRAM[0x2133] & 1) printf ("Interlace, "); if (Memory.FillRAM[0x2133] & 4) printf ("240 line visible, "); if (Memory.FillRAM[0x2133] & 8) printf ("Pseudo 512 pixels horizontal resolution, "); if (Memory.FillRAM[0x2133] & 0x40) printf ("Mode 7 priority per pixel, "); printf ("\n"); if (PPU.BGMode == 7 && (Memory.FillRAM[0x211a] & 3)) printf ("Mode 7 flipping, "); if (PPU.BGMode == 7) printf ("Mode 7 screen repeat: %d,", (Memory.FillRAM[0x211a] & 0xc0) >> 6); if (Memory.FillRAM[0x2130] & 1) printf ("32K colour mode, "); if (PPU.BGMode == 7) { // Sign extend 13 bit values to 16 bit values... if (PPU.CentreX & (1 << 12)) PPU.CentreX |= 0xe000; if (PPU.CentreY & (1 << 12)) PPU.CentreY |= 0xe000; printf ("\nMatrix A: %.3f, B: %.3f, C: %.3f, D: %.3f, Centre X: %d Y:%d\n", (double) PPU.MatrixA / 256, (double) PPU.MatrixB / 256, (double) PPU.MatrixC / 256, (double) PPU.MatrixD / 256, PPU.CentreX, PPU.CentreY); } if ((Memory.FillRAM[0x2106] & 0xf0) && (Memory.FillRAM[0x2106] & 0x0f)) { printf ("\nMosaic effect(%d) on ", PPU.Mosaic); for (int i = 0; i < 4; i++) if (Memory.FillRAM[0x2106] & (1 << i)) printf ("BG%d,", i); printf (","); } if (PPU.HVBeamCounterLatched) printf ("V and H beam pos latched, "); if (Memory.FillRAM[0x4200] & 0x20) printf ("V-IRQ enabled at %d\n", PPU.IRQVBeamPos); if (Memory.FillRAM[0x4200] & 0x10) printf ("H-IRQ enabled at %d\n", PPU.IRQHBeamPos); if (Memory.FillRAM[0x4200] & 0x80) printf ("V-blank NMI enabled\n"); int i; for (i = 0; i < 8; i++) { if (missing.hdma_this_frame & (1 << i)) { printf ("H-DMA %d [%d] 0x%02X%04X->0x21%02X %s %s 0x%02X%04X %s addressing\n", i, DMA[i].TransferMode, DMA[i].ABank, DMA[i].AAddress, DMA[i].BAddress, DMA[i].AAddressDecrement ? "dec" : "inc", DMA[i].Repeat ? "repeat" : "continue", DMA[i].IndirectBank, DMA[i].IndirectAddress, DMA[i].HDMAIndirectAddressing ? "indirect" : "absolute"); } } for (i = 0; i < 8; i++) { if (missing.dma_this_frame & (1 << i)) { printf ("DMA %d %d 0x%02X%04X->0x21%02X Num: %d %s\n", i, DMA[i].TransferMode, DMA[i].ABank, DMA[i].AAddress, DMA[i].BAddress, DMA[i].TransferBytes, DMA[i].AAddressFixed ? "fixed" : (DMA[i].AAddressDecrement ? "dec" : "inc")); } } printf ("VRAM write address: 0x%04x(%s), Full Graphic: %d, Address inc: %d\n", PPU.VMA.Address, PPU.VMA.High ? "Byte" : "Word", PPU.VMA.FullGraphicCount, PPU.VMA.Increment); for (i = 0; i < 4; i++) { printf ("BG%d: VOffset:%d, HOffset:%d, W:%d, H:%d, TS:%d, BA:0x%04x, TA:0x%04X\n", i, PPU.BG[i].VOffset, PPU.BG[i].HOffset, (PPU.BG[i].SCSize & 1) * 32 + 32, (PPU.BG[i].SCSize & 2) * 16 + 32, PPU.BG[i].BGSize * 8 + 8, PPU.BG[i].SCBase, PPU.BG[i].NameBase); } char *s = ""; switch ((Memory.FillRAM [0x2130] & 0xc0) >> 6) { case 0: s = "always on"; break; case 1: s = "inside"; break; case 2: s = "outside"; break; case 3: s = "always off"; break; } printf ("Main screen (%s): ", s); for (i = 0; i < 5; i++) if (Memory.FillRAM[0x212c] & (1 << i)) switch (i) { case 0: printf ("BG0,"); break; case 1: printf ("BG1,"); break; case 2: printf ("BG2,"); break; case 3: printf ("BG3,"); break; case 4: printf ("OBJ,"); break; } switch ((Memory.FillRAM [0x2130] & 0x30) >> 4) { case 0: s = "always on"; break; case 1: s = "inside"; break; case 2: s = "outside"; break; case 3: s = "always off"; break; } printf ("\nSub-screen (%s): ", s); for (i = 0; i < 5; i++) if (Memory.FillRAM[0x212d] & (1 << i)) switch (i) { case 0: printf ("BG0,"); break; case 1: printf ("BG1,"); break; case 2: printf ("BG2,"); break; case 3: printf ("BG3,"); break; case 4: printf ("OBJ,"); break; } printf ("\n"); if ((Memory.FillRAM[0x2131] & 0x3f)) { if (Memory.FillRAM[0x2131] & 0x80) { if (Memory.FillRAM[0x2130] & 0x02) printf ("Subscreen subtract"); else printf ("Fixed colour subtract"); } else { if (Memory.FillRAM[0x2130] & 0x02) printf ("Subscreen addition"); else printf ("Fixed colour addition"); } if (Memory.FillRAM [0x2131] & 0x40) printf ("(half):"); else printf (":"); for (i = 0; i < 6; i++) if (Memory.FillRAM[0x2131] & (1 << i)) { switch (i) { case 0: printf ("BG0,"); break; case 1: printf ("BG1,"); break; case 2: printf ("BG2,"); break; case 3: printf ("BG3,"); break; case 4: printf ("OBJ,"); break; case 5: printf ("BACK,"); break; } } printf ("\n"); } printf ("\nWindow 1 (%d, %d, %02x, %02x): ", PPU.Window1Left, PPU.Window1Right, Memory.FillRAM [0x212e], Memory.FillRAM [0x212f]); for (i = 0; i < 6; i++) if (PPU.ClipWindow1Enable [i]) switch (i) { case 0: printf ("BG0(%s-%s),", PPU.ClipWindow1Inside [i] ? "I" : "O", ClipFn (PPU.ClipWindowOverlapLogic[0])); break; case 1: printf ("BG1(%s-%s),", PPU.ClipWindow1Inside [i] ? "I" : "O", ClipFn (PPU.ClipWindowOverlapLogic[1])); break; case 2: printf ("BG2(%s-%s),", PPU.ClipWindow1Inside [i] ? "I" : "O", ClipFn (PPU.ClipWindowOverlapLogic[2])); break; case 3: printf ("BG3(%s-%s),", PPU.ClipWindow1Inside [i] ? "I" : "O", ClipFn (PPU.ClipWindowOverlapLogic[3])); break; case 4: printf ("OBJ(%s-%s),", PPU.ClipWindow1Inside [i] ? "I" : "O", ClipFn (PPU.ClipWindowOverlapLogic[4])); break; case 5: printf ("COL(%s-%s)", PPU.ClipWindow1Inside [i] ? "I" : "O", ClipFn (PPU.ClipWindowOverlapLogic[5])); break; } printf ("\nWindow 2 (%d, %d): ", PPU.Window2Left, PPU.Window2Right); for (i = 0; i < 6; i++) if (PPU.ClipWindow2Enable [i]) switch (i) { case 0: printf ("BG0(%s),", PPU.ClipWindow2Inside [i] ? "I" : "O"); break; case 1: printf ("BG1(%s),", PPU.ClipWindow2Inside [i] ? "I" : "O"); break; case 2: printf ("BG2(%s),", PPU.ClipWindow2Inside [i] ? "I" : "O"); break; case 3: printf ("BG3(%s),", PPU.ClipWindow2Inside [i] ? "I" : "O"); break; case 4: printf ("OBJ(%s),", PPU.ClipWindow2Inside [i] ? "I" : "O"); break; case 5: printf ("COL(%s)", PPU.ClipWindow2Inside [i] ? "I" : "O"); break; } printf ("\nFixed colour: %02x%02x%02x\n", PPU.FixedColourRed, PPU.FixedColourGreen, PPU.FixedColourBlue); } static void WhatsMissing () { printf ("Processor: "); if (missing.emulate6502) printf ("emulation mode, "); if (missing.decimal_mode) printf ("decimal mode,"); if (missing.mv_8bit_index) printf ("MVP/MVN with 8bit index registers and XH or YH > 0,"); if (missing.mv_8bit_acc) printf ("MVP/MVN with 8bit accumulator > 255"); printf ("\nScreen modes used:"); int i; for (i = 0; i < 8; i++) if (missing.modes[i]) printf (" %d,", i); printf ("\n"); if (missing.interlace) printf ("Interlace, "); if (missing.pseudo_512) printf ("Pseudo 512 pixels horizontal resolution, "); if (missing.lines_239) printf ("240 lines visible,"); if (missing.sprite_double_height) printf ("double-hight sprites,"); printf ("\n"); if (missing.mode7_fx) printf ("Mode 7 rotation/scaling, "); if (missing.matrix_read) printf ("Mode 7 read matrix registers, "); if (missing.mode7_flip) printf ("Mode 7 flipping, "); if (missing.mode7_bgmode) printf ("Mode 7 priority per pixel, "); if (missing.direct) printf ("Direct 32000 colour mode"); printf ("\n"); if (missing.mosaic) printf ("Mosaic effect, "); if (missing.subscreen) printf ("Subscreen enabled, "); if (missing.subscreen_add) printf ("Subscreen colour add, "); if (missing.subscreen_sub) printf ("Subscreen colour subtract, "); if (missing.fixed_colour_add) printf ("Fixed colour add, "); if (missing.fixed_colour_sub) printf ("Fixed colour subtract"); printf ("\n"); printf ("Window 1 enabled on:"); PrintWindow (missing.window1); printf ("\nWindow 2 enabled on:"); PrintWindow (missing.window2); printf ("\n"); if (missing.bg_offset_read) printf ("BG offset read, "); if (missing.oam_address_read) printf ("OAM address read,"); if (missing.sprite_priority_rotation) printf ("Sprite priority rotation, "); if (missing.fast_rom) printf ("Fast 3.58MHz ROM access enabled, "); if (missing.matrix_multiply) printf ("Matrix multiply 16bit by 8bit used"); printf ("\n"); if (missing.virq) printf ("V-position IRQ used at line %d, ", missing.virq_pos); if (missing.hirq) printf ("H-position IRQ used at position %d, ", missing.hirq_pos); printf ("\n"); if (missing.h_v_latch) printf ("H and V-Pos latched, "); if (missing.h_counter_read) printf ("H-Pos read, "); if (missing.v_counter_read) printf ("V-Pos read"); printf ("\n"); if (missing.oam_read) printf ("OAM read, "); if (missing.vram_read) printf ("VRAM read, "); if (missing.cgram_read) printf ("CG-RAM read, "); if (missing.wram_read) printf ("WRAM read, "); if (missing.dma_read) printf ("DMA read,"); if (missing.vram_inc) printf ("VRAM inc: %d,", missing.vram_inc); if (missing.vram_full_graphic_inc) printf ("VRAM full graphic inc: %d,", missing.vram_full_graphic_inc); printf ("\n"); for (i = 0; i < 8; i++) { if (missing.hdma[i].used) { printf ("HDMA %d, 0x%02X%04X->0x21%02X %s ", i, missing.hdma[i].abus_bank, missing.hdma[i].abus_address, missing.hdma[i].bbus_address, missing.hdma[i].indirect_address ? "indirect" : "absolute"); if (missing.hdma[i].force_table_address_write) printf ("Forced address write, "); if (missing.hdma[i].force_table_address_read) printf ("Current address read, "); if (missing.hdma[i].line_count_write) printf ("Line count write, "); if (missing.hdma[i].line_count_read) printf ("Line count read"); printf ("\n"); } } for (i = 0; i < 8; i++) { if (missing.dma_channels & (1 << i)) { printf ("DMA %d %d 0x%02X%04X->0x21%02X Num: %d %s\n", i, DMA[i].TransferMode, DMA[i].ABank, DMA[i].AAddress, DMA[i].BAddress, DMA[i].TransferBytes, DMA[i].AAddressFixed ? "fixed" : (DMA[i].AAddressDecrement ? "dec" : "inc")); } } if (missing.unknownppu_read) printf ("Read from unknown PPU register: $%04X\n", missing.unknownppu_read); if (missing.unknownppu_write) printf ("Write to unknown PPU register: $%04X\n", missing.unknownppu_write); if (missing.unknowncpu_read) printf ("Read from unknown CPU register: $%04X\n", missing.unknowncpu_read); if (missing.unknowncpu_write) printf ("Write to unknown CPU register: $%04X\n", missing.unknowncpu_write); if (missing.unknowndsp_read) printf ("Read from unknown DSP register: $%04X\n", missing.unknowndsp_read); if (missing.unknowndsp_write) printf ("Write to unknown DSP register: $%04X\n", missing.unknowndsp_write); } void S9xDoDebug () { char Line[513]; Debug.Dump.Bank = 0; Debug.Dump.Address = 0; Debug.Unassemble.Bank = 0; Debug.Unassemble.Address = 0; S9xTextMode (); ProcessDebugCommand ("r"); while (CPU.Flags & DEBUG_MODE_FLAG) { printf ("> "); fflush (stdout); fgets (Line, sizeof (Line) - 1, stdin); Line [strlen (Line) - 1] = 0; int32 Cycles = CPU.Cycles; ProcessDebugCommand (Line); CPU.Cycles = Cycles; } if (!(CPU.Flags & SINGLE_STEP_FLAG)) S9xGraphicsMode (); } void S9xTrace () { if(!trace) trace=fopen("trace.log", "a"); char String [512]; S9xOPrint (String, Registers.PB, Registers.PCw); fprintf (trace, "%s\n", String); } void S9xSA1Trace () { char String [512]; S9xSA1OPrint (String, SA1Registers.PB, SA1Registers.PCw); fprintf (trace2, "%s\n", String); fflush (trace2); } void S9xTraceMessage (const char *s) { if(s) { if (trace) fprintf (trace, "%s\n", s); else if (trace2) fprintf (trace2, "%s\n", s); } } extern "C" void TraceSA1 () { SA1.Flags ^= TRACE_FLAG; if (SA1.Flags & TRACE_FLAG) { printf ("SA1 CPU instruction tracing enabled.\n"); if (trace2 == NULL) trace2 = fopen ("trace_sa1.log", "wb"); } else { printf ("SA1 CPU instruction tracing disabled.\n"); fclose (trace2); trace2 = NULL; } } extern "C" void Trace () { CPU.Flags ^= TRACE_FLAG; if (CPU.Flags & TRACE_FLAG) { if (trace == NULL) trace = fopen ("trace.log", "wb"); printf ("CPU instruction tracing enabled.\n"); } else { printf ("CPU instruction tracing disabled.\n"); fclose (trace); trace = NULL; } } #endif