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CATSFC/source/spc700.cpp

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/*******************************************************************************
Snes9x - Portable Super Nintendo Entertainment System (TM) emulator.
(c) Copyright 1996 - 2002 Gary Henderson (gary.henderson@ntlworld.com) and
Jerremy Koot (jkoot@snes9x.com)
(c) Copyright 2001 - 2004 John Weidman (jweidman@slip.net)
(c) Copyright 2002 - 2004 Brad Jorsch (anomie@users.sourceforge.net),
funkyass (funkyass@spam.shaw.ca),
Joel Yliluoma (http://iki.fi/bisqwit/)
Kris Bleakley (codeviolation@hotmail.com),
Matthew Kendora,
Nach (n-a-c-h@users.sourceforge.net),
Peter Bortas (peter@bortas.org) and
zones (kasumitokoduck@yahoo.com)
C4 x86 assembler and some C emulation code
(c) Copyright 2000 - 2003 zsKnight (zsknight@zsnes.com),
_Demo_ (_demo_@zsnes.com), and Nach
C4 C++ code
(c) Copyright 2003 Brad Jorsch
DSP-1 emulator code
(c) Copyright 1998 - 2004 Ivar (ivar@snes9x.com), _Demo_, Gary Henderson,
John Weidman, neviksti (neviksti@hotmail.com),
Kris Bleakley, Andreas Naive
DSP-2 emulator code
(c) Copyright 2003 Kris Bleakley, John Weidman, neviksti, Matthew Kendora, and
Lord Nightmare (lord_nightmare@users.sourceforge.net
OBC1 emulator code
(c) Copyright 2001 - 2004 zsKnight, pagefault (pagefault@zsnes.com) and
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, and Dark Force
S-DD1 C emulator code
(c) Copyright 2003 Brad Jorsch with research by
Andreas Naive and John Weidman
S-RTC C emulator code
(c) Copyright 2001 John Weidman
ST010 C++ emulator code
(c) Copyright 2003 Feather, Kris Bleakley, John Weidman and Matthew Kendora
Super FX x86 assembler emulator code
(c) Copyright 1998 - 2003 zsKnight, _Demo_, and pagefault
Super FX C emulator code
(c) Copyright 1997 - 1999 Ivar, Gary Henderson and John Weidman
SH assembler code partly based on x86 assembler code
(c) Copyright 2002 - 2004 Marcus Comstedt (marcus@mc.pp.se)
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 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.
Snes9x is freeware for PERSONAL USE only. Commercial users should
seek permission of the copyright holders first. Commercial use includes
charging money for Snes9x or software derived from Snes9x.
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 "snes9x.h"
#include "spc700.h"
#include "memmap.h"
#include "display.h"
#include "cpuexec.h"
#include "apu.h"
// SPC700/Sound DSP chips have a 24.57MHz crystal on their PCB.
#ifdef NO_INLINE_SET_GET
uint8 S9xAPUGetByteZ (uint8 address);
uint8 S9xAPUGetByte (uint32 address);
void S9xAPUSetByteZ (uint8, uint8 address);
void S9xAPUSetByte (uint8, uint32 address);
#else
#undef INLINE
#define INLINE inline
#include "apumem.h"
#endif
#define OP1 (*(IAPU.PC + 1))
#define OP2 (*(IAPU.PC + 2))
#ifdef SPC700_SHUTDOWN
#define APUShutdown() \
if (Settings.Shutdown && (IAPU.PC == IAPU.WaitAddress1 || IAPU.PC == IAPU.WaitAddress2)) \
{ \
if (IAPU.WaitCounter == 0) \
{ \
if (!ICPU.CPUExecuting) \
APU.Cycles = CPU.Cycles = CPU.NextEvent; \
else \
IAPU.APUExecuting = FALSE; \
} \
else \
if (IAPU.WaitCounter >= 2) \
IAPU.WaitCounter = 1; \
else \
IAPU.WaitCounter--; \
}
#else
#define APUShutdown()
#endif
#define APUSetZN8(b)\
IAPU._Zero = (b);
#define APUSetZN16(w)\
IAPU._Zero = ((w) != 0) | ((w) >> 8);
void STOP (char *s)
{
char buffer[100];
#ifdef DEBUGGER
S9xAPUOPrint (buffer, IAPU.PC - IAPU.RAM);
#endif
sprintf (String, "Sound CPU in unknown state executing %s at %04X\n%s\n", s, IAPU.PC - IAPU.RAM, buffer);
S9xMessage (S9X_ERROR, S9X_APU_STOPPED, String);
APU.TimerEnabled[0] = APU.TimerEnabled[1] = APU.TimerEnabled[2] = FALSE;
IAPU.APUExecuting = FALSE;
#ifdef DEBUGGER
CPU.Flags |= DEBUG_MODE_FLAG;
#else
S9xExit ();
#endif
}
#define TCALL(n)\
{\
PushW (IAPU.PC - IAPU.RAM + 1); \
IAPU.PC = IAPU.RAM + (APU.ExtraRAM [((15 - n) << 1)] + \
(APU.ExtraRAM [((15 - n) << 1) + 1] << 8)); \
}
// XXX: HalfCarry - BJ fixed?
#define SBC(a,b)\
int16 Int16 = (short) (a) - (short) (b) + (short) (APUCheckCarry ()) - 1;\
IAPU._Carry = Int16 >= 0;\
if ((((a) ^ (b)) & 0x80) && (((a) ^ (uint8) Int16) & 0x80))\
APUSetOverflow ();\
else \
APUClearOverflow (); \
APUSetHalfCarry ();\
if(((a) ^ (b) ^ (uint8) Int16) & 0x10)\
APUClearHalfCarry ();\
(a) = (uint8) Int16;\
APUSetZN8 ((uint8) Int16);
// XXX: HalfCarry - BJ fixed?
// XXX: HalfCarry used Int16 before; trying to fix it with Work16 [Neb]
#define ADC(a,b)\
uint16 Work16 = (a) + (b) + APUCheckCarry();\
IAPU._Carry = Work16 >= 0x100; \
if (~((a) ^ (b)) & ((b) ^ (uint8) Work16) & 0x80)\
APUSetOverflow ();\
else \
APUClearOverflow (); \
APUClearHalfCarry ();\
if(((a) ^ (b) ^ (uint8) Work16) & 0x10)\
APUSetHalfCarry ();\
(a) = (uint8) Work16;\
APUSetZN8 ((uint8) Work16);
#define CMP(a,b)\
int16 Int16 = (short) (a) - (short) (b);\
IAPU._Carry = Int16 >= 0;\
APUSetZN8 ((uint8) Int16);
#define ASL(b)\
IAPU._Carry = ((b) & 0x80) != 0; \
(b) <<= 1;\
APUSetZN8 (b);
#define LSR(b)\
IAPU._Carry = (b) & 1;\
(b) >>= 1;\
APUSetZN8 (b);
#define ROL(b)\
uint16 Work16 = ((b) << 1) | APUCheckCarry (); \
IAPU._Carry = Work16 >= 0x100; \
(b) = (uint8) Work16; \
APUSetZN8 (b);
#define ROR(b)\
uint16 Work16 = (b) | ((uint16) APUCheckCarry () << 8); \
IAPU._Carry = (uint8) Work16 & 1; \
Work16 >>= 1; \
(b) = (uint8) Work16; \
APUSetZN8 (b);
#define Push(b)\
*(IAPU.RAM + 0x100 + IAPU.Registers.S) = b;\
IAPU.Registers.S--;
#define Pop(b)\
IAPU.Registers.S++;\
(b) = *(IAPU.RAM + 0x100 + IAPU.Registers.S);
#ifdef FAST_LSB_WORD_ACCESS
#define PushW(w)\
*(uint16 *) (IAPU.RAM + 0xff + IAPU.Registers.S) = w;\
IAPU.Registers.S -= 2;
#define PopW(w)\
IAPU.Registers.S += 2;\
w = *(uint16 *) (IAPU.RAM + 0xff + IAPU.Registers.S);
#else
#define PushW(w)\
*(IAPU.RAM + 0xff + IAPU.Registers.S) = w;\
*(IAPU.RAM + 0x100 + IAPU.Registers.S) = (w >> 8);\
IAPU.Registers.S -= 2;
#define PopW(w)\
IAPU.Registers.S += 2; \
(w) = *(IAPU.RAM + 0xff + IAPU.Registers.S) + (*(IAPU.RAM + 0x100 + IAPU.Registers.S) << 8);
#endif
#define Relative()\
int8 Int8 = OP1;\
int16 Int16 = (int) (IAPU.PC + 2 - IAPU.RAM) + Int8;
#define Relative2()\
int8 Int8 = OP2;\
int16 Int16 = (int) (IAPU.PC + 3 - IAPU.RAM) + Int8;
#ifdef FAST_LSB_WORD_ACCESS
#define IndexedXIndirect()\
IAPU.Address = *(uint16 *) (IAPU.DirectPage + ((OP1 + IAPU.Registers.X) & 0xff));
#define Absolute()\
IAPU.Address = *(uint16 *) (IAPU.PC + 1);
#define AbsoluteX()\
IAPU.Address = *(uint16 *) (IAPU.PC + 1) + IAPU.Registers.X;
#define AbsoluteY()\
IAPU.Address = *(uint16 *) (IAPU.PC + 1) + IAPU.Registers.YA.B.Y;
#define MemBit()\
IAPU.Address = *(uint16 *) (IAPU.PC + 1);\
IAPU.Bit = (uint8)(IAPU.Address >> 13);\
IAPU.Address &= 0x1fff;
#define IndirectIndexedY()\
IAPU.Address = *(uint16 *) (IAPU.DirectPage + OP1) + IAPU.Registers.YA.B.Y;
#else
#define IndexedXIndirect()\
IAPU.Address = *(IAPU.DirectPage + ((OP1 + IAPU.Registers.X) & 0xff)) + \
(*(IAPU.DirectPage + ((OP1 + IAPU.Registers.X + 1) & 0xff)) << 8);
#define Absolute()\
IAPU.Address = OP1 + (OP2 << 8);
#define AbsoluteX()\
IAPU.Address = OP1 + (OP2 << 8) + IAPU.Registers.X;
#define AbsoluteY()\
IAPU.Address = OP1 + (OP2 << 8) + IAPU.Registers.YA.B.Y;
#define MemBit()\
IAPU.Address = OP1 + (OP2 << 8);\
IAPU.Bit = (int8) (IAPU.Address >> 13);\
IAPU.Address &= 0x1fff;
#define IndirectIndexedY()\
IAPU.Address = *(IAPU.DirectPage + OP1) + \
(*(IAPU.DirectPage + OP1 + 1) << 8) + \
IAPU.Registers.YA.B.Y;
#endif
void Apu00 ()
{
// NOP
IAPU.PC++;
}
void Apu01 () { TCALL (0) }
void Apu11 () { TCALL (1) }
void Apu21 () { TCALL (2) }
void Apu31 () { TCALL (3) }
void Apu41 () { TCALL (4) }
void Apu51 () { TCALL (5) }
void Apu61 () { TCALL (6) }
void Apu71 () { TCALL (7) }
void Apu81 () { TCALL (8) }
void Apu91 () { TCALL (9) }
void ApuA1 () { TCALL (10) }
void ApuB1 () { TCALL (11) }
void ApuC1 () { TCALL (12) }
void ApuD1 () { TCALL (13) }
void ApuE1 () { TCALL (14) }
void ApuF1 () { TCALL (15) }
void Apu3F () // CALL absolute
{
Absolute ();
// 0xB6f for Star Fox 2
PushW (IAPU.PC + 3 - IAPU.RAM);
IAPU.PC = IAPU.RAM + IAPU.Address;
}
void Apu4F () // PCALL $XX
{
uint8 Work8 = OP1;
PushW (IAPU.PC + 2 - IAPU.RAM);
IAPU.PC = IAPU.RAM + 0xff00 + Work8;
}
#define SET(b) \
S9xAPUSetByteZ ((uint8) (S9xAPUGetByteZ (OP1 ) | (1 << (b))), OP1); \
IAPU.PC += 2
void Apu02 ()
{
SET (0);
}
void Apu22 ()
{
SET (1);
}
void Apu42 ()
{
SET (2);
}
void Apu62 ()
{
SET (3);
}
void Apu82 ()
{
SET (4);
}
void ApuA2 ()
{
SET (5);
}
void ApuC2 ()
{
SET (6);
}
void ApuE2 ()
{
SET (7);
}
#define CLR(b) \
S9xAPUSetByteZ ((uint8) (S9xAPUGetByteZ (OP1) & ~(1 << (b))), OP1); \
IAPU.PC += 2;
void Apu12 ()
{
CLR (0);
}
void Apu32 ()
{
CLR (1);
}
void Apu52 ()
{
CLR (2);
}
void Apu72 ()
{
CLR (3);
}
void Apu92 ()
{
CLR (4);
}
void ApuB2 ()
{
CLR (5);
}
void ApuD2 ()
{
CLR (6);
}
void ApuF2 ()
{
CLR (7);
}
#define BBS(b) \
uint8 Work8 = OP1; \
Relative2 (); \
if (S9xAPUGetByteZ (Work8) & (1 << (b))) \
{ \
IAPU.PC = IAPU.RAM + (uint16) Int16; \
APU.Cycles += IAPU.TwoCycles; \
} \
else \
IAPU.PC += 3
void Apu03 ()
{
BBS (0);
}
void Apu23 ()
{
BBS (1);
}
void Apu43 ()
{
BBS (2);
}
void Apu63 ()
{
BBS (3);
}
void Apu83 ()
{
BBS (4);
}
void ApuA3 ()
{
BBS (5);
}
void ApuC3 ()
{
BBS (6);
}
void ApuE3 ()
{
BBS (7);
}
#define BBC(b) \
uint8 Work8 = OP1; \
Relative2 (); \
if (!(S9xAPUGetByteZ (Work8) & (1 << (b)))) \
{ \
IAPU.PC = IAPU.RAM + (uint16) Int16; \
APU.Cycles += IAPU.TwoCycles; \
} \
else \
IAPU.PC += 3
void Apu13 ()
{
BBC (0);
}
void Apu33 ()
{
BBC (1);
}
void Apu53 ()
{
BBC (2);
}
void Apu73 ()
{
BBC (3);
}
void Apu93 ()
{
BBC (4);
}
void ApuB3 ()
{
BBC (5);
}
void ApuD3 ()
{
BBC (6);
}
void ApuF3 ()
{
BBC (7);
}
void Apu04 ()
{
// OR A,dp
IAPU.Registers.YA.B.A |= S9xAPUGetByteZ (OP1);
APUSetZN8 (IAPU.Registers.YA.B.A);
IAPU.PC += 2;
}
void Apu05 ()
{
// OR A,abs
Absolute ();
IAPU.Registers.YA.B.A |= S9xAPUGetByte (IAPU.Address);
APUSetZN8 (IAPU.Registers.YA.B.A);
IAPU.PC += 3;
}
void Apu06 ()
{
// OR A,(X)
IAPU.Registers.YA.B.A |= S9xAPUGetByteZ (IAPU.Registers.X);
APUSetZN8 (IAPU.Registers.YA.B.A);
IAPU.PC++;
}
void Apu07 ()
{
// OR A,(dp+X)
IndexedXIndirect ();
IAPU.Registers.YA.B.A |= S9xAPUGetByte (IAPU.Address);
APUSetZN8 (IAPU.Registers.YA.B.A);
IAPU.PC += 2;
}
void Apu08 ()
{
// OR A,#00
IAPU.Registers.YA.B.A |= OP1;
APUSetZN8 (IAPU.Registers.YA.B.A);
IAPU.PC += 2;
}
void Apu09 ()
{
// OR dp(dest),dp(src)
uint8 Work8 = S9xAPUGetByteZ (OP1);
Work8 |= S9xAPUGetByteZ (OP2);
S9xAPUSetByteZ (Work8, OP2);
APUSetZN8 (Work8);
IAPU.PC += 3;
}
void Apu14 ()
{
// OR A,dp+X
IAPU.Registers.YA.B.A |= S9xAPUGetByteZ (OP1 + IAPU.Registers.X);
APUSetZN8 (IAPU.Registers.YA.B.A);
IAPU.PC += 2;
}
void Apu15 ()
{
// OR A,abs+X
AbsoluteX ();
IAPU.Registers.YA.B.A |= S9xAPUGetByte (IAPU.Address);
APUSetZN8 (IAPU.Registers.YA.B.A);
IAPU.PC += 3;
}
void Apu16 ()
{
// OR A,abs+Y
AbsoluteY ();
IAPU.Registers.YA.B.A |= S9xAPUGetByte (IAPU.Address);
APUSetZN8 (IAPU.Registers.YA.B.A);
IAPU.PC += 3;
}
void Apu17 ()
{
// OR A,(dp)+Y
IndirectIndexedY ();
IAPU.Registers.YA.B.A |= S9xAPUGetByte (IAPU.Address);
APUSetZN8 (IAPU.Registers.YA.B.A);
IAPU.PC += 2;
}
void Apu18 ()
{
// OR dp,#00
uint8 Work8 = OP1;
Work8 |= S9xAPUGetByteZ (OP2);
S9xAPUSetByteZ (Work8, OP2);
APUSetZN8 (Work8);
IAPU.PC += 3;
}
void Apu19 ()
{
// OR (X),(Y)
uint8 Work8 = S9xAPUGetByteZ (IAPU.Registers.X) | S9xAPUGetByteZ (IAPU.Registers.YA.B.Y);
APUSetZN8 (Work8);
S9xAPUSetByteZ (Work8, IAPU.Registers.X);
IAPU.PC++;
}
void Apu0A ()
{
// OR1 C,membit
MemBit ();
if (!APUCheckCarry ())
{
if (S9xAPUGetByte (IAPU.Address) & (1 << IAPU.Bit))
APUSetCarry ();
}
IAPU.PC += 3;
}
void Apu2A ()
{
// OR1 C,not membit
MemBit ();
if (!APUCheckCarry ())
{
if (!(S9xAPUGetByte (IAPU.Address) & (1 << IAPU.Bit)))
APUSetCarry ();
}
IAPU.PC += 3;
}
void Apu4A ()
{
// AND1 C,membit
MemBit ();
if (APUCheckCarry ())
{
if (!(S9xAPUGetByte (IAPU.Address) & (1 << IAPU.Bit)))
APUClearCarry ();
}
IAPU.PC += 3;
}
void Apu6A ()
{
// AND1 C, not membit
MemBit ();
if (APUCheckCarry ())
{
if ((S9xAPUGetByte (IAPU.Address) & (1 << IAPU.Bit)))
APUClearCarry ();
}
IAPU.PC += 3;
}
void Apu8A ()
{
// EOR1 C, membit
MemBit ();
if (APUCheckCarry ())
{
if (S9xAPUGetByte (IAPU.Address) & (1 << IAPU.Bit))
APUClearCarry ();
}
else
{
if (S9xAPUGetByte (IAPU.Address) & (1 << IAPU.Bit))
APUSetCarry ();
}
IAPU.PC += 3;
}
void ApuAA ()
{
// MOV1 C,membit
MemBit ();
if (S9xAPUGetByte (IAPU.Address) & (1 << IAPU.Bit))
APUSetCarry ();
else
APUClearCarry ();
IAPU.PC += 3;
}
void ApuCA ()
{
// MOV1 membit,C
MemBit ();
if (APUCheckCarry ())
{
S9xAPUSetByte (S9xAPUGetByte (IAPU.Address) | (1 << IAPU.Bit), IAPU.Address);
}
else
{
S9xAPUSetByte (S9xAPUGetByte (IAPU.Address) & ~(1 << IAPU.Bit), IAPU.Address);
}
IAPU.PC += 3;
}
void ApuEA ()
{
// NOT1 membit
MemBit ();
S9xAPUSetByte (S9xAPUGetByte (IAPU.Address) ^ (1 << IAPU.Bit), IAPU.Address);
IAPU.PC += 3;
}
void Apu0B ()
{
// ASL dp
uint8 Work8 = S9xAPUGetByteZ (OP1);
ASL (Work8);
S9xAPUSetByteZ (Work8, OP1);
IAPU.PC += 2;
}
void Apu0C ()
{
// ASL abs
Absolute ();
uint8 Work8 = S9xAPUGetByte (IAPU.Address);
ASL (Work8);
S9xAPUSetByte (Work8, IAPU.Address);
IAPU.PC += 3;
}
void Apu1B ()
{
// ASL dp+X
uint8 Work8 = S9xAPUGetByteZ (OP1 + IAPU.Registers.X);
ASL (Work8);
S9xAPUSetByteZ (Work8, OP1 + IAPU.Registers.X);
IAPU.PC += 2;
}
void Apu1C ()
{
// ASL A
ASL (IAPU.Registers.YA.B.A);
IAPU.PC++;
}
void Apu0D ()
{
// PUSH PSW
S9xAPUPackStatus ();
Push (IAPU.Registers.P);
IAPU.PC++;
}
void Apu2D ()
{
// PUSH A
Push (IAPU.Registers.YA.B.A);
IAPU.PC++;
}
void Apu4D ()
{
// PUSH X
Push (IAPU.Registers.X);
IAPU.PC++;
}
void Apu6D ()
{
// PUSH Y
Push (IAPU.Registers.YA.B.Y);
IAPU.PC++;
}
void Apu8E ()
{
// POP PSW
Pop (IAPU.Registers.P);
S9xAPUUnpackStatus ();
if (APUCheckDirectPage ())
IAPU.DirectPage = IAPU.RAM + 0x100;
else
IAPU.DirectPage = IAPU.RAM;
IAPU.PC++;
}
void ApuAE ()
{
// POP A
Pop (IAPU.Registers.YA.B.A);
IAPU.PC++;
}
void ApuCE ()
{
// POP X
Pop (IAPU.Registers.X);
IAPU.PC++;
}
void ApuEE ()
{
// POP Y
Pop (IAPU.Registers.YA.B.Y);
IAPU.PC++;
}
void Apu0E ()
{
// TSET1 abs
Absolute ();
uint8 Work8 = S9xAPUGetByte (IAPU.Address);
S9xAPUSetByte (Work8 | IAPU.Registers.YA.B.A, IAPU.Address);
Work8 &= IAPU.Registers.YA.B.A;
APUSetZN8 (Work8);
IAPU.PC += 3;
}
void Apu4E ()
{
// TCLR1 abs
Absolute ();
uint8 Work8 = S9xAPUGetByte (IAPU.Address);
S9xAPUSetByte (Work8 & ~IAPU.Registers.YA.B.A, IAPU.Address);
Work8 &= IAPU.Registers.YA.B.A;
APUSetZN8 (Work8);
IAPU.PC += 3;
}
void Apu0F ()
{
// BRK
#if 0
STOP ("BRK");
#else
PushW (IAPU.PC + 1 - IAPU.RAM);
S9xAPUPackStatus ();
Push (IAPU.Registers.P);
APUSetBreak ();
APUClearInterrupt ();
// XXX:Where is the BRK vector ???
IAPU.PC = IAPU.RAM + APU.ExtraRAM[0x20] + (APU.ExtraRAM[0x21] << 8);
#endif
}
void ApuEF ()
{
// SLEEP
// XXX: sleep
// STOP ("SLEEP");
IAPU.APUExecuting = FALSE;
IAPU.PC++;
}
void ApuFF ()
{
// STOP
// STOP ("STOP");
IAPU.APUExecuting = FALSE;
IAPU.PC++;
}
void Apu10 ()
{
// BPL
Relative ();
if (!APUCheckNegative ())
{
IAPU.PC = IAPU.RAM + (uint16) Int16;
APU.Cycles += IAPU.TwoCycles;
APUShutdown ();
}
else
IAPU.PC += 2;
}
void Apu30 ()
{
// BMI
Relative ();
if (APUCheckNegative ())
{
IAPU.PC = IAPU.RAM + (uint16) Int16;
APU.Cycles += IAPU.TwoCycles;
APUShutdown ();
}
else
IAPU.PC += 2;
}
void Apu90 ()
{
// BCC
Relative ();
if (!APUCheckCarry ())
{
IAPU.PC = IAPU.RAM + (uint16) Int16;
APU.Cycles += IAPU.TwoCycles;
APUShutdown ();
}
else
IAPU.PC += 2;
}
void ApuB0 ()
{
// BCS
Relative ();
if (APUCheckCarry ())
{
IAPU.PC = IAPU.RAM + (uint16) Int16;
APU.Cycles += IAPU.TwoCycles;
APUShutdown ();
}
else
IAPU.PC += 2;
}
void ApuD0 ()
{
// BNE
Relative ();
if (!APUCheckZero ())
{
IAPU.PC = IAPU.RAM + (uint16) Int16;
APU.Cycles += IAPU.TwoCycles;
APUShutdown ();
}
else
IAPU.PC += 2;
}
void ApuF0 ()
{
// BEQ
Relative ();
if (APUCheckZero ())
{
IAPU.PC = IAPU.RAM + (uint16) Int16;
APU.Cycles += IAPU.TwoCycles;
APUShutdown ();
}
else
IAPU.PC += 2;
}
void Apu50 ()
{
// BVC
Relative ();
if (!APUCheckOverflow ())
{
IAPU.PC = IAPU.RAM + (uint16) Int16;
APU.Cycles += IAPU.TwoCycles;
}
else
IAPU.PC += 2;
}
void Apu70 ()
{
// BVS
Relative ();
if (APUCheckOverflow ())
{
IAPU.PC = IAPU.RAM + (uint16) Int16;
APU.Cycles += IAPU.TwoCycles;
}
else
IAPU.PC += 2;
}
void Apu2F ()
{
// BRA
Relative ();
IAPU.PC = IAPU.RAM + (uint16) Int16;
}
void Apu80 ()
{
// SETC
APUSetCarry ();
IAPU.PC++;
}
void ApuED ()
{
// NOTC
IAPU._Carry ^= 1;
IAPU.PC++;
}
void Apu40 ()
{
// SETP
APUSetDirectPage ();
IAPU.DirectPage = IAPU.RAM + 0x100;
IAPU.PC++;
}
void Apu1A ()
{
// DECW dp
uint16 Work16 = S9xAPUGetByteZ (OP1) + (S9xAPUGetByteZ (OP1 + 1) << 8);
Work16--;
S9xAPUSetByteZ ((uint8) Work16, OP1);
S9xAPUSetByteZ (Work16 >> 8, OP1 + 1);
APUSetZN16 (Work16);
IAPU.PC += 2;
}
void Apu5A ()
{
// CMPW YA,dp
uint16 Work16 = S9xAPUGetByteZ (OP1) + (S9xAPUGetByteZ (OP1 + 1) << 8);
int32 Int32 = (long) IAPU.Registers.YA.W - (long) Work16;
IAPU._Carry = Int32 >= 0;
APUSetZN16 ((uint16) Int32);
IAPU.PC += 2;
}
void Apu3A ()
{
// INCW dp
uint16 Work16 = S9xAPUGetByteZ (OP1) + (S9xAPUGetByteZ (OP1 + 1) << 8);
Work16++;
S9xAPUSetByteZ ((uint8) Work16, OP1);
S9xAPUSetByteZ (Work16 >> 8, OP1 + 1);
APUSetZN16 (Work16);
IAPU.PC += 2;
}
// XXX: HalfCarry - BJ Fixed? Or is it between bits 7 and 8 for ADDW/SUBW?
void Apu7A ()
{
// ADDW YA,dp
uint16 Work16 = S9xAPUGetByteZ (OP1) + (S9xAPUGetByteZ (OP1 + 1) << 8);
uint32 Work32 = (uint32) IAPU.Registers.YA.W + Work16;
IAPU._Carry = Work32 >= 0x10000;
if (~(IAPU.Registers.YA.W ^ Work16) & (Work16 ^ (uint16) Work32) & 0x8000)
APUSetOverflow ();
else
APUClearOverflow ();
APUClearHalfCarry ();
if((IAPU.Registers.YA.W ^ Work16 ^ (uint16) Work32) & 0x10)
APUSetHalfCarry ();
IAPU.Registers.YA.W = (uint16) Work32;
APUSetZN16 (IAPU.Registers.YA.W);
IAPU.PC += 2;
}
// XXX: BJ: i think the old HalfCarry behavior was wrong...
// XXX: Or is it between bits 7 and 8 for ADDW/SUBW?
// XXX: Used Work32 instead of Int32 before. Fixed? [Neb]
void Apu9A ()
{
// SUBW YA,dp
uint16 Work16 = S9xAPUGetByteZ (OP1) + (S9xAPUGetByteZ (OP1 + 1) << 8);
int32 Int32 = (long) IAPU.Registers.YA.W - (long) Work16;
APUClearHalfCarry ();
IAPU._Carry = Int32 >= 0;
if (((IAPU.Registers.YA.W ^ Work16) & 0x8000) &&
((IAPU.Registers.YA.W ^ (uint16) Int32) & 0x8000))
APUSetOverflow ();
else
APUClearOverflow ();
if (((IAPU.Registers.YA.W ^ Work16) & 0x0080) &&
((IAPU.Registers.YA.W ^ (uint16) Int32) & 0x0080))
APUSetHalfCarry ();
APUSetHalfCarry ();
if((IAPU.Registers.YA.W ^ Work16 ^ (uint16) Int32) & 0x10)
APUClearHalfCarry ();
IAPU.Registers.YA.W = (uint16) Int32;
APUSetZN16 (IAPU.Registers.YA.W);
IAPU.PC += 2;
}
void ApuBA ()
{
// MOVW YA,dp
IAPU.Registers.YA.B.A = S9xAPUGetByteZ (OP1);
IAPU.Registers.YA.B.Y = S9xAPUGetByteZ (OP1 + 1);
APUSetZN16 (IAPU.Registers.YA.W);
IAPU.PC += 2;
}
void ApuDA ()
{
// MOVW dp,YA
S9xAPUSetByteZ (IAPU.Registers.YA.B.A, OP1);
S9xAPUSetByteZ (IAPU.Registers.YA.B.Y, OP1 + 1);
IAPU.PC += 2;
}
void Apu64 ()
{
// CMP A,dp
uint8 Work8 = S9xAPUGetByteZ (OP1);
CMP (IAPU.Registers.YA.B.A, Work8);
IAPU.PC += 2;
}
void Apu65 ()
{
// CMP A,abs
Absolute ();
uint8 Work8 = S9xAPUGetByte (IAPU.Address);
CMP (IAPU.Registers.YA.B.A, Work8);
IAPU.PC += 3;
}
void Apu66 ()
{
// CMP A,(X)
uint8 Work8 = S9xAPUGetByteZ (IAPU.Registers.X);
CMP (IAPU.Registers.YA.B.A, Work8);
IAPU.PC++;
}
void Apu67 ()
{
// CMP A,(dp+X)
IndexedXIndirect ();
uint8 Work8 = S9xAPUGetByte (IAPU.Address);
CMP (IAPU.Registers.YA.B.A, Work8);
IAPU.PC += 2;
}
void Apu68 ()
{
// CMP A,#00
uint8 Work8 = OP1;
CMP (IAPU.Registers.YA.B.A, Work8);
IAPU.PC += 2;
}
void Apu69 ()
{
// CMP dp(dest), dp(src)
uint8 W1 = S9xAPUGetByteZ (OP1);
uint8 Work8 = S9xAPUGetByteZ (OP2);
CMP (Work8, W1);
IAPU.PC += 3;
}
void Apu74 ()
{
// CMP A, dp+X
uint8 Work8 = S9xAPUGetByteZ (OP1 + IAPU.Registers.X);
CMP (IAPU.Registers.YA.B.A, Work8);
IAPU.PC += 2;
}
void Apu75 ()
{
// CMP A,abs+X
AbsoluteX ();
uint8 Work8 = S9xAPUGetByte (IAPU.Address);
CMP (IAPU.Registers.YA.B.A, Work8);
IAPU.PC += 3;
}
void Apu76 ()
{
// CMP A, abs+Y
AbsoluteY ();
uint8 Work8 = S9xAPUGetByte (IAPU.Address);
CMP (IAPU.Registers.YA.B.A, Work8);
IAPU.PC += 3;
}
void Apu77 ()
{
// CMP A,(dp)+Y
IndirectIndexedY ();
uint8 Work8 = S9xAPUGetByte (IAPU.Address);
CMP (IAPU.Registers.YA.B.A, Work8);
IAPU.PC += 2;
}
void Apu78 ()
{
// CMP dp,#00
uint8 Work8 = OP1;
uint8 W1 = S9xAPUGetByteZ (OP2);
CMP (W1, Work8);
IAPU.PC += 3;
}
void Apu79 ()
{
// CMP (X),(Y)
uint8 W1 = S9xAPUGetByteZ (IAPU.Registers.X);
uint8 Work8 = S9xAPUGetByteZ (IAPU.Registers.YA.B.Y);
CMP (W1, Work8);
IAPU.PC++;
}
void Apu1E ()
{
// CMP X,abs
Absolute ();
uint8 Work8 = S9xAPUGetByte (IAPU.Address);
CMP (IAPU.Registers.X, Work8);
IAPU.PC += 3;
}
void Apu3E ()
{
// CMP X,dp
uint8 Work8 = S9xAPUGetByteZ (OP1);
CMP (IAPU.Registers.X, Work8);
IAPU.PC += 2;
}
void ApuC8 ()
{
// CMP X,#00
CMP (IAPU.Registers.X, OP1);
IAPU.PC += 2;
}
void Apu5E ()
{
// CMP Y,abs
Absolute ();
uint8 Work8 = S9xAPUGetByte (IAPU.Address);
CMP (IAPU.Registers.YA.B.Y, Work8);
IAPU.PC += 3;
}
void Apu7E ()
{
// CMP Y,dp
uint8 Work8 = S9xAPUGetByteZ (OP1);
CMP (IAPU.Registers.YA.B.Y, Work8);
IAPU.PC += 2;
}
void ApuAD ()
{
// CMP Y,#00
uint8 Work8 = OP1;
CMP (IAPU.Registers.YA.B.Y, Work8);
IAPU.PC += 2;
}
void Apu1F ()
{
// JMP (abs+X)
Absolute ();
IAPU.PC = IAPU.RAM + S9xAPUGetByte (IAPU.Address + IAPU.Registers.X) +
(S9xAPUGetByte (IAPU.Address + IAPU.Registers.X + 1) << 8);
// XXX: HERE:
// APU.Flags |= TRACE_FLAG;
}
void Apu5F ()
{
// JMP abs
Absolute ();
IAPU.PC = IAPU.RAM + IAPU.Address;
}
void Apu20 ()
{
// CLRP
APUClearDirectPage ();
IAPU.DirectPage = IAPU.RAM;
IAPU.PC++;
}
void Apu60 ()
{
// CLRC
APUClearCarry ();
IAPU.PC++;
}
void ApuE0 ()
{
// CLRV
APUClearHalfCarry ();
APUClearOverflow ();
IAPU.PC++;
}
void Apu24 ()
{
// AND A,dp
IAPU.Registers.YA.B.A &= S9xAPUGetByteZ (OP1);
APUSetZN8 (IAPU.Registers.YA.B.A);
IAPU.PC += 2;
}
void Apu25 ()
{
// AND A,abs
Absolute ();
IAPU.Registers.YA.B.A &= S9xAPUGetByte (IAPU.Address);
APUSetZN8 (IAPU.Registers.YA.B.A);
IAPU.PC += 3;
}
void Apu26 ()
{
// AND A,(X)
IAPU.Registers.YA.B.A &= S9xAPUGetByteZ (IAPU.Registers.X);
APUSetZN8 (IAPU.Registers.YA.B.A);
IAPU.PC++;
}
void Apu27 ()
{
// AND A,(dp+X)
IndexedXIndirect ();
IAPU.Registers.YA.B.A &= S9xAPUGetByte (IAPU.Address);
APUSetZN8 (IAPU.Registers.YA.B.A);
IAPU.PC += 2;
}
void Apu28 ()
{
// AND A,#00
IAPU.Registers.YA.B.A &= OP1;
APUSetZN8 (IAPU.Registers.YA.B.A);
IAPU.PC += 2;
}
void Apu29 ()
{
// AND dp(dest),dp(src)
uint8 Work8 = S9xAPUGetByteZ (OP1);
Work8 &= S9xAPUGetByteZ (OP2);
S9xAPUSetByteZ (Work8, OP2);
APUSetZN8 (Work8);
IAPU.PC += 3;
}
void Apu34 ()
{
// AND A,dp+X
IAPU.Registers.YA.B.A &= S9xAPUGetByteZ (OP1 + IAPU.Registers.X);
APUSetZN8 (IAPU.Registers.YA.B.A);
IAPU.PC += 2;
}
void Apu35 ()
{
// AND A,abs+X
AbsoluteX ();
IAPU.Registers.YA.B.A &= S9xAPUGetByte (IAPU.Address);
APUSetZN8 (IAPU.Registers.YA.B.A);
IAPU.PC += 3;
}
void Apu36 ()
{
// AND A,abs+Y
AbsoluteY ();
IAPU.Registers.YA.B.A &= S9xAPUGetByte (IAPU.Address);
APUSetZN8 (IAPU.Registers.YA.B.A);
IAPU.PC += 3;
}
void Apu37 ()
{
// AND A,(dp)+Y
IndirectIndexedY ();
IAPU.Registers.YA.B.A &= S9xAPUGetByte (IAPU.Address);
APUSetZN8 (IAPU.Registers.YA.B.A);
IAPU.PC += 2;
}
void Apu38 ()
{
// AND dp,#00
uint8 Work8 = OP1;
Work8 &= S9xAPUGetByteZ (OP2);
S9xAPUSetByteZ (Work8, OP2);
APUSetZN8 (Work8);
IAPU.PC += 3;
}
void Apu39 ()
{
// AND (X),(Y)
uint8 Work8 = S9xAPUGetByteZ (IAPU.Registers.X) & S9xAPUGetByteZ (IAPU.Registers.YA.B.Y);
APUSetZN8 (Work8);
S9xAPUSetByteZ (Work8, IAPU.Registers.X);
IAPU.PC++;
}
void Apu2B ()
{
// ROL dp
uint8 Work8 = S9xAPUGetByteZ (OP1);
ROL (Work8);
S9xAPUSetByteZ (Work8, OP1);
IAPU.PC += 2;
}
void Apu2C ()
{
// ROL abs
Absolute ();
uint8 Work8 = S9xAPUGetByte (IAPU.Address);
ROL (Work8);
S9xAPUSetByte (Work8, IAPU.Address);
IAPU.PC += 3;
}
void Apu3B ()
{
// ROL dp+X
uint8 Work8 = S9xAPUGetByteZ (OP1 + IAPU.Registers.X);
ROL (Work8);
S9xAPUSetByteZ (Work8, OP1 + IAPU.Registers.X);
IAPU.PC += 2;
}
void Apu3C ()
{
// ROL A
ROL (IAPU.Registers.YA.B.A);
IAPU.PC++;
}
void Apu2E ()
{
// CBNE dp,rel
uint8 Work8 = OP1;
Relative2 ();
if (S9xAPUGetByteZ (Work8) != IAPU.Registers.YA.B.A)
{
IAPU.PC = IAPU.RAM + (uint16) Int16;
APU.Cycles += IAPU.TwoCycles;
APUShutdown ();
}
else
IAPU.PC += 3;
}
void ApuDE ()
{
// CBNE dp+X,rel
uint8 Work8 = OP1 + IAPU.Registers.X;
Relative2 ();
if (S9xAPUGetByteZ (Work8) != IAPU.Registers.YA.B.A)
{
IAPU.PC = IAPU.RAM + (uint16) Int16;
APU.Cycles += IAPU.TwoCycles;
APUShutdown ();
}
else
IAPU.PC += 3;
}
void Apu3D ()
{
// INC X
IAPU.Registers.X++;
APUSetZN8 (IAPU.Registers.X);
#ifdef SPC700_SHUTDOWN
IAPU.WaitCounter++;
#endif
IAPU.PC++;
}
void ApuFC ()
{
// INC Y
IAPU.Registers.YA.B.Y++;
APUSetZN8 (IAPU.Registers.YA.B.Y);
#ifdef SPC700_SHUTDOWN
IAPU.WaitCounter++;
#endif
IAPU.PC++;
}
void Apu1D ()
{
// DEC X
IAPU.Registers.X--;
APUSetZN8 (IAPU.Registers.X);
#ifdef SPC700_SHUTDOWN
IAPU.WaitCounter++;
#endif
IAPU.PC++;
}
void ApuDC ()
{
// DEC Y
IAPU.Registers.YA.B.Y--;
APUSetZN8 (IAPU.Registers.YA.B.Y);
#ifdef SPC700_SHUTDOWN
IAPU.WaitCounter++;
#endif
IAPU.PC++;
}
void ApuAB ()
{
// INC dp
uint8 Work8 = S9xAPUGetByteZ (OP1) + 1;
S9xAPUSetByteZ (Work8, OP1);
APUSetZN8 (Work8);
#ifdef SPC700_SHUTDOWN
IAPU.WaitCounter++;
#endif
IAPU.PC += 2;
}
void ApuAC ()
{
// INC abs
Absolute ();
uint8 Work8 = S9xAPUGetByte (IAPU.Address) + 1;
S9xAPUSetByte (Work8, IAPU.Address);
APUSetZN8 (Work8);
#ifdef SPC700_SHUTDOWN
IAPU.WaitCounter++;
#endif
IAPU.PC += 3;
}
void ApuBB ()
{
// INC dp+X
uint8 Work8 = S9xAPUGetByteZ (OP1 + IAPU.Registers.X) + 1;
S9xAPUSetByteZ (Work8, OP1 + IAPU.Registers.X);
APUSetZN8 (Work8);
#ifdef SPC700_SHUTDOWN
IAPU.WaitCounter++;
#endif
IAPU.PC += 2;
}
void ApuBC ()
{
// INC A
IAPU.Registers.YA.B.A++;
APUSetZN8 (IAPU.Registers.YA.B.A);
#ifdef SPC700_SHUTDOWN
IAPU.WaitCounter++;
#endif
IAPU.PC++;
}
void Apu8B ()
{
// DEC dp
uint8 Work8 = S9xAPUGetByteZ (OP1) - 1;
S9xAPUSetByteZ (Work8, OP1);
APUSetZN8 (Work8);
#ifdef SPC700_SHUTDOWN
IAPU.WaitCounter++;
#endif
IAPU.PC += 2;
}
void Apu8C ()
{
// DEC abs
Absolute ();
uint8 Work8 = S9xAPUGetByte (IAPU.Address) - 1;
S9xAPUSetByte (Work8, IAPU.Address);
APUSetZN8 (Work8);
#ifdef SPC700_SHUTDOWN
IAPU.WaitCounter++;
#endif
IAPU.PC += 3;
}
void Apu9B ()
{
// DEC dp+X
uint8 Work8 = S9xAPUGetByteZ (OP1 + IAPU.Registers.X) - 1;
S9xAPUSetByteZ (Work8, OP1 + IAPU.Registers.X);
APUSetZN8 (Work8);
#ifdef SPC700_SHUTDOWN
IAPU.WaitCounter++;
#endif
IAPU.PC += 2;
}
void Apu9C ()
{
// DEC A
IAPU.Registers.YA.B.A--;
APUSetZN8 (IAPU.Registers.YA.B.A);
#ifdef SPC700_SHUTDOWN
IAPU.WaitCounter++;
#endif
IAPU.PC++;
}
void Apu44 ()
{
// EOR A,dp
IAPU.Registers.YA.B.A ^= S9xAPUGetByteZ (OP1);
APUSetZN8 (IAPU.Registers.YA.B.A);
IAPU.PC += 2;
}
void Apu45 ()
{
// EOR A,abs
Absolute ();
IAPU.Registers.YA.B.A ^= S9xAPUGetByte (IAPU.Address);
APUSetZN8 (IAPU.Registers.YA.B.A);
IAPU.PC += 3;
}
void Apu46 ()
{
// EOR A,(X)
IAPU.Registers.YA.B.A ^= S9xAPUGetByteZ (IAPU.Registers.X);
APUSetZN8 (IAPU.Registers.YA.B.A);
IAPU.PC++;
}
void Apu47 ()
{
// EOR A,(dp+X)
IndexedXIndirect ();
IAPU.Registers.YA.B.A ^= S9xAPUGetByte (IAPU.Address);
APUSetZN8 (IAPU.Registers.YA.B.A);
IAPU.PC += 2;
}
void Apu48 ()
{
// EOR A,#00
IAPU.Registers.YA.B.A ^= OP1;
APUSetZN8 (IAPU.Registers.YA.B.A);
IAPU.PC += 2;
}
void Apu49 ()
{
// EOR dp(dest),dp(src)
uint8 Work8 = S9xAPUGetByteZ (OP1);
Work8 ^= S9xAPUGetByteZ (OP2);
S9xAPUSetByteZ (Work8, OP2);
APUSetZN8 (Work8);
IAPU.PC += 3;
}
void Apu54 ()
{
// EOR A,dp+X
IAPU.Registers.YA.B.A ^= S9xAPUGetByteZ (OP1 + IAPU.Registers.X);
APUSetZN8 (IAPU.Registers.YA.B.A);
IAPU.PC += 2;
}
void Apu55 ()
{
// EOR A,abs+X
AbsoluteX ();
IAPU.Registers.YA.B.A ^= S9xAPUGetByte (IAPU.Address);
APUSetZN8 (IAPU.Registers.YA.B.A);
IAPU.PC += 3;
}
void Apu56 ()
{
// EOR A,abs+Y
AbsoluteY ();
IAPU.Registers.YA.B.A ^= S9xAPUGetByte (IAPU.Address);
APUSetZN8 (IAPU.Registers.YA.B.A);
IAPU.PC += 3;
}
void Apu57 ()
{
// EOR A,(dp)+Y
IndirectIndexedY ();
IAPU.Registers.YA.B.A ^= S9xAPUGetByte (IAPU.Address);
APUSetZN8 (IAPU.Registers.YA.B.A);
IAPU.PC += 2;
}
void Apu58 ()
{
// EOR dp,#00
uint8 Work8 = OP1;
Work8 ^= S9xAPUGetByteZ (OP2);
S9xAPUSetByteZ (Work8, OP2);
APUSetZN8 (Work8);
IAPU.PC += 3;
}
void Apu59 ()
{
// EOR (X),(Y)
uint8 Work8 = S9xAPUGetByteZ (IAPU.Registers.X) ^ S9xAPUGetByteZ (IAPU.Registers.YA.B.Y);
APUSetZN8 (Work8);
S9xAPUSetByteZ (Work8, IAPU.Registers.X);
IAPU.PC++;
}
void Apu4B ()
{
// LSR dp
uint8 Work8 = S9xAPUGetByteZ (OP1);
LSR (Work8);
S9xAPUSetByteZ (Work8, OP1);
IAPU.PC += 2;
}
void Apu4C ()
{
// LSR abs
Absolute ();
uint8 Work8 = S9xAPUGetByte (IAPU.Address);
LSR (Work8);
S9xAPUSetByte (Work8, IAPU.Address);
IAPU.PC += 3;
}
void Apu5B ()
{
// LSR dp+X
uint8 Work8 = S9xAPUGetByteZ (OP1 + IAPU.Registers.X);
LSR (Work8);
S9xAPUSetByteZ (Work8, OP1 + IAPU.Registers.X);
IAPU.PC += 2;
}
void Apu5C ()
{
// LSR A
LSR (IAPU.Registers.YA.B.A);
IAPU.PC++;
}
void Apu7D ()
{
// MOV A,X
IAPU.Registers.YA.B.A = IAPU.Registers.X;
APUSetZN8 (IAPU.Registers.YA.B.A);
IAPU.PC++;
}
void ApuDD ()
{
// MOV A,Y
IAPU.Registers.YA.B.A = IAPU.Registers.YA.B.Y;
APUSetZN8 (IAPU.Registers.YA.B.A);
IAPU.PC++;
}
void Apu5D ()
{
// MOV X,A
IAPU.Registers.X = IAPU.Registers.YA.B.A;
APUSetZN8 (IAPU.Registers.X);
IAPU.PC++;
}
void ApuFD ()
{
// MOV Y,A
IAPU.Registers.YA.B.Y = IAPU.Registers.YA.B.A;
APUSetZN8 (IAPU.Registers.YA.B.Y);
IAPU.PC++;
}
void Apu9D ()
{
//MOV X,SP
IAPU.Registers.X = IAPU.Registers.S;
APUSetZN8 (IAPU.Registers.X);
IAPU.PC++;
}
void ApuBD ()
{
// MOV SP,X
IAPU.Registers.S = IAPU.Registers.X;
IAPU.PC++;
}
void Apu6B ()
{
// ROR dp
uint8 Work8 = S9xAPUGetByteZ (OP1);
ROR (Work8);
S9xAPUSetByteZ (Work8, OP1);
IAPU.PC += 2;
}
void Apu6C ()
{
// ROR abs
Absolute ();
uint8 Work8 = S9xAPUGetByte (IAPU.Address);
ROR (Work8);
S9xAPUSetByte (Work8, IAPU.Address);
IAPU.PC += 3;
}
void Apu7B ()
{
// ROR dp+X
uint8 Work8 = S9xAPUGetByteZ (OP1 + IAPU.Registers.X);
ROR (Work8);
S9xAPUSetByteZ (Work8, OP1 + IAPU.Registers.X);
IAPU.PC += 2;
}
void Apu7C ()
{
// ROR A
ROR (IAPU.Registers.YA.B.A);
IAPU.PC++;
}
void Apu6E ()
{
// DBNZ dp,rel
uint8 Work8 = OP1;
Relative2 ();
uint8 W1 = S9xAPUGetByteZ (Work8) - 1;
S9xAPUSetByteZ (W1, Work8);
if (W1 != 0)
{
IAPU.PC = IAPU.RAM + (uint16) Int16;
APU.Cycles += IAPU.TwoCycles;
}
else
IAPU.PC += 3;
}
void ApuFE ()
{
// DBNZ Y,rel
Relative ();
IAPU.Registers.YA.B.Y--;
if (IAPU.Registers.YA.B.Y != 0)
{
IAPU.PC = IAPU.RAM + (uint16) Int16;
APU.Cycles += IAPU.TwoCycles;
}
else
IAPU.PC += 2;
}
void Apu6F ()
{
// RET
PopW (IAPU.Registers.PC);
IAPU.PC = IAPU.RAM + IAPU.Registers.PC;
}
void Apu7F ()
{
// RETI
// STOP ("RETI");
Pop (IAPU.Registers.P);
S9xAPUUnpackStatus ();
PopW (IAPU.Registers.PC);
IAPU.PC = IAPU.RAM + IAPU.Registers.PC;
}
void Apu84 ()
{
// ADC A,dp
uint8 Work8 = S9xAPUGetByteZ (OP1);
ADC (IAPU.Registers.YA.B.A, Work8);
IAPU.PC += 2;
}
void Apu85 ()
{
// ADC A, abs
Absolute ();
uint8 Work8 = S9xAPUGetByte (IAPU.Address);
ADC (IAPU.Registers.YA.B.A, Work8);
IAPU.PC += 3;
}
void Apu86 ()
{
// ADC A,(X)
uint8 Work8 = S9xAPUGetByteZ (IAPU.Registers.X);
ADC (IAPU.Registers.YA.B.A, Work8);
IAPU.PC++;
}
void Apu87 ()
{
// ADC A,(dp+X)
IndexedXIndirect ();
uint8 Work8 = S9xAPUGetByte (IAPU.Address);
ADC (IAPU.Registers.YA.B.A, Work8);
IAPU.PC += 2;
}
void Apu88 ()
{
// ADC A,#00
uint8 Work8 = OP1;
ADC (IAPU.Registers.YA.B.A, Work8);
IAPU.PC += 2;
}
void Apu89 ()
{
// ADC dp(dest),dp(src)
uint8 Work8 = S9xAPUGetByteZ (OP1);
uint8 W1 = S9xAPUGetByteZ (OP2);
ADC (W1, Work8);
S9xAPUSetByteZ (W1, OP2);
IAPU.PC += 3;
}
void Apu94 ()
{
// ADC A,dp+X
uint8 Work8 = S9xAPUGetByteZ (OP1 + IAPU.Registers.X);
ADC (IAPU.Registers.YA.B.A, Work8);
IAPU.PC += 2;
}
void Apu95 ()
{
// ADC A, abs+X
AbsoluteX ();
uint8 Work8 = S9xAPUGetByte (IAPU.Address);
ADC (IAPU.Registers.YA.B.A, Work8);
IAPU.PC += 3;
}
void Apu96 ()
{
// ADC A, abs+Y
AbsoluteY ();
uint8 Work8 = S9xAPUGetByte (IAPU.Address);
ADC (IAPU.Registers.YA.B.A, Work8);
IAPU.PC += 3;
}
void Apu97 ()
{
// ADC A, (dp)+Y
IndirectIndexedY ();
uint8 Work8 = S9xAPUGetByte (IAPU.Address);
ADC (IAPU.Registers.YA.B.A, Work8);
IAPU.PC += 2;
}
void Apu98 ()
{
// ADC dp,#00
uint8 Work8 = OP1;
uint8 W1 = S9xAPUGetByteZ (OP2);
ADC (W1, Work8);
S9xAPUSetByteZ (W1, OP2);
IAPU.PC += 3;
}
void Apu99 ()
{
// ADC (X),(Y)
uint8 W1 = S9xAPUGetByteZ (IAPU.Registers.X);
uint8 Work8 = S9xAPUGetByteZ (IAPU.Registers.YA.B.Y);
ADC (W1, Work8);
S9xAPUSetByteZ (W1, IAPU.Registers.X);
IAPU.PC++;
}
void Apu8D ()
{
// MOV Y,#00
IAPU.Registers.YA.B.Y = OP1;
APUSetZN8 (IAPU.Registers.YA.B.Y);
IAPU.PC += 2;
}
void Apu8F ()
{
// MOV dp,#00
uint8 Work8 = OP1;
S9xAPUSetByteZ (Work8, OP2);
IAPU.PC += 3;
}
void Apu9E ()
{
// DIV YA,X
if (IAPU.Registers.X == 0)
{
APUSetOverflow ();
IAPU.Registers.YA.B.Y = 0xff;
IAPU.Registers.YA.B.A = 0xff;
}
else
{
APUClearOverflow ();
uint8 Work8 = IAPU.Registers.YA.W / IAPU.Registers.X;
IAPU.Registers.YA.B.Y = IAPU.Registers.YA.W % IAPU.Registers.X;
IAPU.Registers.YA.B.A = Work8;
}
// XXX How should Overflow, Half Carry, Zero and Negative flags be set??
// APUSetZN16 (IAPU.Registers.YA.W);
APUSetZN8 (IAPU.Registers.YA.B.A);
IAPU.PC++;
}
void Apu9F ()
{
// XCN A
IAPU.Registers.YA.B.A = (IAPU.Registers.YA.B.A >> 4) | (IAPU.Registers.YA.B.A << 4);
APUSetZN8 (IAPU.Registers.YA.B.A);
IAPU.PC++;
}
void ApuA4 ()
{
// SBC A, dp
uint8 Work8 = S9xAPUGetByteZ (OP1);
SBC (IAPU.Registers.YA.B.A, Work8);
IAPU.PC += 2;
}
void ApuA5 ()
{
// SBC A, abs
Absolute ();
uint8 Work8 = S9xAPUGetByte (IAPU.Address);
SBC (IAPU.Registers.YA.B.A, Work8);
IAPU.PC += 3;
}
void ApuA6 ()
{
// SBC A, (X)
uint8 Work8 = S9xAPUGetByteZ (IAPU.Registers.X);
SBC (IAPU.Registers.YA.B.A, Work8);
IAPU.PC++;
}
void ApuA7 ()
{
// SBC A,(dp+X)
IndexedXIndirect ();
uint8 Work8 = S9xAPUGetByte (IAPU.Address);
SBC (IAPU.Registers.YA.B.A, Work8);
IAPU.PC += 2;
}
void ApuA8 ()
{
// SBC A,#00
uint8 Work8 = OP1;
SBC (IAPU.Registers.YA.B.A, Work8);
IAPU.PC += 2;
}
void ApuA9 ()
{
// SBC dp(dest), dp(src)
uint8 Work8 = S9xAPUGetByteZ (OP1);
uint8 W1 = S9xAPUGetByteZ (OP2);
SBC (W1, Work8);
S9xAPUSetByteZ (W1, OP2);
IAPU.PC += 3;
}
void ApuB4 ()
{
// SBC A, dp+X
uint8 Work8 = S9xAPUGetByteZ (OP1 + IAPU.Registers.X);
SBC (IAPU.Registers.YA.B.A, Work8);
IAPU.PC += 2;
}
void ApuB5 ()
{
// SBC A,abs+X
AbsoluteX ();
uint8 Work8 = S9xAPUGetByte (IAPU.Address);
SBC (IAPU.Registers.YA.B.A, Work8);
IAPU.PC += 3;
}
void ApuB6 ()
{
// SBC A,abs+Y
AbsoluteY ();
uint8 Work8 = S9xAPUGetByte (IAPU.Address);
SBC (IAPU.Registers.YA.B.A, Work8);
IAPU.PC += 3;
}
void ApuB7 ()
{
// SBC A,(dp)+Y
IndirectIndexedY ();
uint8 Work8 = S9xAPUGetByte (IAPU.Address);
SBC (IAPU.Registers.YA.B.A, Work8);
IAPU.PC += 2;
}
void ApuB8 ()
{
// SBC dp,#00
uint8 Work8 = OP1;
uint8 W1 = S9xAPUGetByteZ (OP2);
SBC (W1, Work8);
S9xAPUSetByteZ (W1, OP2);
IAPU.PC += 3;
}
void ApuB9 ()
{
// SBC (X),(Y)
uint8 W1 = S9xAPUGetByteZ (IAPU.Registers.X);
uint8 Work8 = S9xAPUGetByteZ (IAPU.Registers.YA.B.Y);
SBC (W1, Work8);
S9xAPUSetByteZ (W1, IAPU.Registers.X);
IAPU.PC++;
}
void ApuAF ()
{
// MOV (X)+, A
S9xAPUSetByteZ (IAPU.Registers.YA.B.A, IAPU.Registers.X++);
IAPU.PC++;
}
void ApuBE ()
{
// DAS
if ((IAPU.Registers.YA.B.A & 0x0f) > 9 || !APUCheckHalfCarry())
{
IAPU.Registers.YA.B.A -= 6;
}
if (IAPU.Registers.YA.B.A > 0x9f || !IAPU._Carry)
{
IAPU.Registers.YA.B.A -= 0x60;
APUClearCarry ();
}
else { APUSetCarry (); }
APUSetZN8 (IAPU.Registers.YA.B.A);
IAPU.PC++;
}
void ApuBF ()
{
// MOV A,(X)+
IAPU.Registers.YA.B.A = S9xAPUGetByteZ (IAPU.Registers.X++);
APUSetZN8 (IAPU.Registers.YA.B.A);
IAPU.PC++;
}
void ApuC0 ()
{
// DI
APUClearInterrupt ();
IAPU.PC++;
}
void ApuA0 ()
{
// EI
APUSetInterrupt ();
IAPU.PC++;
}
void ApuC4 ()
{
// MOV dp,A
S9xAPUSetByteZ (IAPU.Registers.YA.B.A, OP1);
IAPU.PC += 2;
}
void ApuC5 ()
{
// MOV abs,A
Absolute ();
S9xAPUSetByte (IAPU.Registers.YA.B.A, IAPU.Address);
IAPU.PC += 3;
}
void ApuC6 ()
{
// MOV (X), A
S9xAPUSetByteZ (IAPU.Registers.YA.B.A, IAPU.Registers.X);
IAPU.PC++;
}
void ApuC7 ()
{
// MOV (dp+X),A
IndexedXIndirect ();
S9xAPUSetByte (IAPU.Registers.YA.B.A, IAPU.Address);
IAPU.PC += 2;
}
void ApuC9 ()
{
// MOV abs,X
Absolute ();
S9xAPUSetByte (IAPU.Registers.X, IAPU.Address);
IAPU.PC += 3;
}
void ApuCB ()
{
// MOV dp,Y
S9xAPUSetByteZ (IAPU.Registers.YA.B.Y, OP1);
IAPU.PC += 2;
}
void ApuCC ()
{
// MOV abs,Y
Absolute ();
S9xAPUSetByte (IAPU.Registers.YA.B.Y, IAPU.Address);
IAPU.PC += 3;
}
void ApuCD ()
{
// MOV X,#00
IAPU.Registers.X = OP1;
APUSetZN8 (IAPU.Registers.X);
IAPU.PC += 2;
}
void ApuCF ()
{
// MUL YA
IAPU.Registers.YA.W = (uint16) IAPU.Registers.YA.B.A * IAPU.Registers.YA.B.Y;
APUSetZN16 (IAPU.Registers.YA.W);
IAPU.PC++;
}
void ApuD4 ()
{
// MOV dp+X, A
S9xAPUSetByteZ (IAPU.Registers.YA.B.A, OP1 + IAPU.Registers.X);
IAPU.PC += 2;
}
void ApuD5 ()
{
// MOV abs+X,A
AbsoluteX ();
S9xAPUSetByte (IAPU.Registers.YA.B.A, IAPU.Address);
IAPU.PC += 3;
}
void ApuD6 ()
{
// MOV abs+Y,A
AbsoluteY ();
S9xAPUSetByte (IAPU.Registers.YA.B.A, IAPU.Address);
IAPU.PC += 3;
}
void ApuD7 ()
{
// MOV (dp)+Y,A
IndirectIndexedY ();
S9xAPUSetByte (IAPU.Registers.YA.B.A, IAPU.Address);
IAPU.PC += 2;
}
void ApuD8 ()
{
// MOV dp,X
S9xAPUSetByteZ (IAPU.Registers.X, OP1);
IAPU.PC += 2;
}
void ApuD9 ()
{
// MOV dp+Y,X
S9xAPUSetByteZ (IAPU.Registers.X, OP1 + IAPU.Registers.YA.B.Y);
IAPU.PC += 2;
}
void ApuDB ()
{
// MOV dp+X,Y
S9xAPUSetByteZ (IAPU.Registers.YA.B.Y, OP1 + IAPU.Registers.X);
IAPU.PC += 2;
}
void ApuDF ()
{
// DAA
if ((IAPU.Registers.YA.B.A & 0x0f) > 9 || APUCheckHalfCarry())
{
if(IAPU.Registers.YA.B.A > 0xf0) APUSetCarry ();
IAPU.Registers.YA.B.A += 6;
//APUSetHalfCarry (); Intel procs do this, but this is a Sony proc...
}
//else { APUClearHalfCarry (); } ditto as above
if (IAPU.Registers.YA.B.A > 0x9f || IAPU._Carry)
{
IAPU.Registers.YA.B.A += 0x60;
APUSetCarry ();
}
else { APUClearCarry (); }
APUSetZN8 (IAPU.Registers.YA.B.A);
IAPU.PC++;
}
void ApuE4 ()
{
// MOV A, dp
IAPU.Registers.YA.B.A = S9xAPUGetByteZ (OP1);
APUSetZN8 (IAPU.Registers.YA.B.A);
IAPU.PC += 2;
}
void ApuE5 ()
{
// MOV A,abs
Absolute ();
IAPU.Registers.YA.B.A = S9xAPUGetByte (IAPU.Address);
APUSetZN8 (IAPU.Registers.YA.B.A);
IAPU.PC += 3;
}
void ApuE6 ()
{
// MOV A,(X)
IAPU.Registers.YA.B.A = S9xAPUGetByteZ (IAPU.Registers.X);
APUSetZN8 (IAPU.Registers.YA.B.A);
IAPU.PC++;
}
void ApuE7 ()
{
// MOV A,(dp+X)
IndexedXIndirect ();
IAPU.Registers.YA.B.A = S9xAPUGetByte (IAPU.Address);
APUSetZN8 (IAPU.Registers.YA.B.A);
IAPU.PC += 2;
}
void ApuE8 ()
{
// MOV A,#00
IAPU.Registers.YA.B.A = OP1;
APUSetZN8 (IAPU.Registers.YA.B.A);
IAPU.PC += 2;
}
void ApuE9 ()
{
// MOV X, abs
Absolute ();
IAPU.Registers.X = S9xAPUGetByte (IAPU.Address);
APUSetZN8 (IAPU.Registers.X);
IAPU.PC += 3;
}
void ApuEB ()
{
// MOV Y,dp
IAPU.Registers.YA.B.Y = S9xAPUGetByteZ (OP1);
APUSetZN8 (IAPU.Registers.YA.B.Y);
IAPU.PC += 2;
}
void ApuEC ()
{
// MOV Y,abs
Absolute ();
IAPU.Registers.YA.B.Y = S9xAPUGetByte (IAPU.Address);
APUSetZN8 (IAPU.Registers.YA.B.Y);
IAPU.PC += 3;
}
void ApuF4 ()
{
// MOV A, dp+X
IAPU.Registers.YA.B.A = S9xAPUGetByteZ (OP1 + IAPU.Registers.X);
APUSetZN8 (IAPU.Registers.YA.B.A);
IAPU.PC += 2;
}
void ApuF5 ()
{
// MOV A, abs+X
AbsoluteX ();
IAPU.Registers.YA.B.A = S9xAPUGetByte (IAPU.Address);
APUSetZN8 (IAPU.Registers.YA.B.A);
IAPU.PC += 3;
}
void ApuF6 ()
{
// MOV A, abs+Y
AbsoluteY ();
IAPU.Registers.YA.B.A = S9xAPUGetByte (IAPU.Address);
APUSetZN8 (IAPU.Registers.YA.B.A);
IAPU.PC += 3;
}
void ApuF7 ()
{
// MOV A, (dp)+Y
IndirectIndexedY ();
IAPU.Registers.YA.B.A = S9xAPUGetByte (IAPU.Address);
APUSetZN8 (IAPU.Registers.YA.B.A);
IAPU.PC += 2;
}
void ApuF8 ()
{
// MOV X,dp
IAPU.Registers.X = S9xAPUGetByteZ (OP1);
APUSetZN8 (IAPU.Registers.X);
IAPU.PC += 2;
}
void ApuF9 ()
{
// MOV X,dp+Y
IAPU.Registers.X = S9xAPUGetByteZ (OP1 + IAPU.Registers.YA.B.Y);
APUSetZN8 (IAPU.Registers.X);
IAPU.PC += 2;
}
void ApuFA ()
{
// MOV dp(dest),dp(src)
S9xAPUSetByteZ (S9xAPUGetByteZ (OP1), OP2);
IAPU.PC += 3;
}
void ApuFB ()
{
// MOV Y,dp+X
IAPU.Registers.YA.B.Y = S9xAPUGetByteZ (OP1 + IAPU.Registers.X);
APUSetZN8 (IAPU.Registers.YA.B.Y);
IAPU.PC += 2;
}
#ifdef NO_INLINE_SET_GET
#undef INLINE
#define INLINE
#include "apumem.h"
#endif
void (*S9xApuOpcodes[256]) (void) =
{
Apu00, Apu01, Apu02, Apu03, Apu04, Apu05, Apu06, Apu07,
Apu08, Apu09, Apu0A, Apu0B, Apu0C, Apu0D, Apu0E, Apu0F,
Apu10, Apu11, Apu12, Apu13, Apu14, Apu15, Apu16, Apu17,
Apu18, Apu19, Apu1A, Apu1B, Apu1C, Apu1D, Apu1E, Apu1F,
Apu20, Apu21, Apu22, Apu23, Apu24, Apu25, Apu26, Apu27,
Apu28, Apu29, Apu2A, Apu2B, Apu2C, Apu2D, Apu2E, Apu2F,
Apu30, Apu31, Apu32, Apu33, Apu34, Apu35, Apu36, Apu37,
Apu38, Apu39, Apu3A, Apu3B, Apu3C, Apu3D, Apu3E, Apu3F,
Apu40, Apu41, Apu42, Apu43, Apu44, Apu45, Apu46, Apu47,
Apu48, Apu49, Apu4A, Apu4B, Apu4C, Apu4D, Apu4E, Apu4F,
Apu50, Apu51, Apu52, Apu53, Apu54, Apu55, Apu56, Apu57,
Apu58, Apu59, Apu5A, Apu5B, Apu5C, Apu5D, Apu5E, Apu5F,
Apu60, Apu61, Apu62, Apu63, Apu64, Apu65, Apu66, Apu67,
Apu68, Apu69, Apu6A, Apu6B, Apu6C, Apu6D, Apu6E, Apu6F,
Apu70, Apu71, Apu72, Apu73, Apu74, Apu75, Apu76, Apu77,
Apu78, Apu79, Apu7A, Apu7B, Apu7C, Apu7D, Apu7E, Apu7F,
Apu80, Apu81, Apu82, Apu83, Apu84, Apu85, Apu86, Apu87,
Apu88, Apu89, Apu8A, Apu8B, Apu8C, Apu8D, Apu8E, Apu8F,
Apu90, Apu91, Apu92, Apu93, Apu94, Apu95, Apu96, Apu97,
Apu98, Apu99, Apu9A, Apu9B, Apu9C, Apu9D, Apu9E, Apu9F,
ApuA0, ApuA1, ApuA2, ApuA3, ApuA4, ApuA5, ApuA6, ApuA7,
ApuA8, ApuA9, ApuAA, ApuAB, ApuAC, ApuAD, ApuAE, ApuAF,
ApuB0, ApuB1, ApuB2, ApuB3, ApuB4, ApuB5, ApuB6, ApuB7,
ApuB8, ApuB9, ApuBA, ApuBB, ApuBC, ApuBD, ApuBE, ApuBF,
ApuC0, ApuC1, ApuC2, ApuC3, ApuC4, ApuC5, ApuC6, ApuC7,
ApuC8, ApuC9, ApuCA, ApuCB, ApuCC, ApuCD, ApuCE, ApuCF,
ApuD0, ApuD1, ApuD2, ApuD3, ApuD4, ApuD5, ApuD6, ApuD7,
ApuD8, ApuD9, ApuDA, ApuDB, ApuDC, ApuDD, ApuDE, ApuDF,
ApuE0, ApuE1, ApuE2, ApuE3, ApuE4, ApuE5, ApuE6, ApuE7,
ApuE8, ApuE9, ApuEA, ApuEB, ApuEC, ApuED, ApuEE, ApuEF,
ApuF0, ApuF1, ApuF2, ApuF3, ApuF4, ApuF5, ApuF6, ApuF7,
ApuF8, ApuF9, ApuFA, ApuFB, ApuFC, ApuFD, ApuFE, ApuFF
};
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