mc6809.c

/*
Copyright 2015 by Joseph Forgione
This file is part of VCC (Virtual Color Computer).

    VCC (Virtual Color Computer) is free software: you can redistribute it and/or modify
    it under the terms of the GNU General Public License as published by
    the Free Software Foundation, either version 3 of the License, or
    (at your option) any later version.

    VCC (Virtual Color Computer) is distributed in the hope that it will be useful,
    but WITHOUT ANY WARRANTY; without even the implied warranty of
    MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
    GNU General Public License for more details.

    You should have received a copy of the GNU General Public License
    along with VCC (Virtual Color Computer).  If not, see <http://www.gnu.org/licenses/>.
*/

#include <windows.h>
#include <stdio.h>
#include "defines.h"
#include "mc6809.h"
#include "mc6809defs.h"
#include "tcc1014mmu.h"
#include "OpDecoder.h"
#include "Disassembler.h"

//Global variables for CPU Emulation-----------------------

#define NTEST8(r) r>0x7F; 
#define NTEST16(r) r>0x7FFF;
#define OTEST8(c,a,b,r) c ^ (((a^b^r)>>7) &1);
#define OTEST16(c,a,b,r) c ^ (((a^b^r)>>15)&1);
#define ZTEST(r) !r;

typedef union
{
	unsigned short Reg;
	struct
	{
		unsigned char lsb,msb;
	} B;
} cpuregister;

#define D_REG	d.Reg
#define PC_REG	pc.Reg
#define X_REG	x.Reg
#define Y_REG	y.Reg
#define U_REG	u.Reg
#define S_REG	s.Reg
#define A_REG	d.B.msb
#define B_REG	d.B.lsb
#define DP_REG	dp.B.msb

static cpuregister pc,x,y,u,s,dp,d;
static unsigned int cc[8];
static unsigned char *ureg8[8]; 
static unsigned char ccbits;
static unsigned short *xfreg16[8];
static int CycleCounter=0;
static unsigned int SyncWaiting=0;
static unsigned int temp32;
static unsigned short temp16;
static unsigned char temp8; 
static unsigned char PendingInterupts=0;
static unsigned char IRQWaiter=0;
static unsigned char Source=0,Dest=0;
static unsigned char postbyte=0;
static short unsigned postword=0;
static signed char *spostbyte=(signed char *)&postbyte;
static signed short *spostword=(signed short *)&postword;
static char InInterupt=0;
static std::vector<unsigned short> CPUBreakpoints;
static std::vector<unsigned short> CPUTraceTriggers;

//END Global variables for CPU Emulation-------------------

//Fuction Prototypes---------------------------------------
_inline unsigned short CalculateEA(unsigned char);
static void setcc (unsigned char);
static unsigned char getcc(void);
static void cpu_firq(void);
static void cpu_irq(void);
static void cpu_nmi(void);
//END Fuction Prototypes-----------------------------------

void MC6809Reset(void)
{
	char index;
	for(index=0;index<=5;index++)		//Set all register to 0 except V
		*xfreg16[index] = 0;
	for(index=0;index<=7;index++)
		*ureg8[index]=0;
	for(index=0;index<=7;index++)
		cc[index]=0;
	dp.Reg=0;
	cc[I]=1;
	cc[F]=1;
	SyncWaiting=0;
	pc.Reg=MemRead16(VRESET);	//PC gets its reset vector
	SetMapType(0);
	return;
}

void MC6809Init(void)
{	//Call this first or RESET will core!
	// reg pointers for TFR and EXG and LEA ops
	xfreg16[0]=&D_REG;
	xfreg16[1]=&X_REG;
	xfreg16[2]=&Y_REG;
	xfreg16[3]=&U_REG;
	xfreg16[4]=&S_REG;
	xfreg16[5]=&PC_REG;

	ureg8[0]=(unsigned char*)&A_REG;		
	ureg8[1]=(unsigned char*)&B_REG;		
	ureg8[2]=(unsigned char*)&ccbits;
	ureg8[3]=(unsigned char*)&dp.B.msb;
	ureg8[4]=(unsigned char*)&dp.B.msb;
	ureg8[5]=(unsigned char*)&dp.B.msb;
	ureg8[6]=(unsigned char*)&dp.B.msb;
	ureg8[7]=(unsigned char*)&dp.B.msb;

	cc[I]=1;
	cc[F]=1;
	return;
}


VCC::CPUState MC6809GetState()
{
	VCC::CPUState regs = { 0 };

	regs.CC = getcc();
	regs.DP = DP_REG;
	regs.A = A_REG;
	regs.B = B_REG;
	regs.X = X_REG;
	regs.Y = Y_REG;
	regs.U = U_REG;
	regs.S = S_REG;
	regs.PC = PC_REG;

	regs.IsNative6309 = false;

	return regs;
}


void MC6809SetBreakpoints(const std::vector<unsigned short>& breakpoints)
{
	CPUBreakpoints = breakpoints;
}

void MC6809SetTraceTriggers(const std::vector<unsigned short>& triggers)
{
	CPUTraceTriggers = triggers;
}

int MC6809Exec( int CycleFor)
{
static unsigned char opcode=0;
static unsigned char msn,lsn;
extern int JS_Ramp_Clock;
int PrevCycleCount = 0;

CycleCounter=0;
while (CycleCounter<CycleFor) {

	if (PendingInterupts)
	{
		if (PendingInterupts & 4)
			cpu_nmi();

		if (PendingInterupts & 2)
			cpu_firq();

		if (PendingInterupts & 1)
		{
			if (IRQWaiter==0)	// This is needed to fix a subtle timming problem
				cpu_irq();		// It allows the CPU to see $FF03 bit 7 high before
			else				// The IRQ is asserted.
				IRQWaiter-=1;
		}
	}

	if (SyncWaiting==1)
		return(0);

	// CPU is halted.
	if (EmuState.Debugger.IsHalted())
	{
		return(CycleFor - CycleCounter);
	}

	// Any CPU Breakpoints set?
	if (!EmuState.Debugger.IsStepping() && !CPUBreakpoints.empty())
	{
		if (find(CPUBreakpoints.begin(), CPUBreakpoints.end(), pc.Reg) != CPUBreakpoints.end())
		{
			EmuState.Debugger.Halt();
			return(CycleFor - CycleCounter);
		}
	}

	// Is the execution trace enabled - but currently not running?
	if (EmuState.Debugger.IsTracingEnabled() && !EmuState.Debugger.IsTracing())
	{
		// Only Start Tracing when we hit a start trigger.
		if (!CPUTraceTriggers.empty())
		{
			if (find(CPUTraceTriggers.begin(), CPUTraceTriggers.end(), pc.Reg) != CPUTraceTriggers.end())
			{
				EmuState.Debugger.TraceStart();
			}
		}
		else
		{
			// Otherwise start right away.
			EmuState.Debugger.TraceStart();
		}
	}

	// Trace is running.
	if (EmuState.Debugger.IsTracing())
	{
		EmuState.Debugger.TraceCaptureBefore(CycleCounter, MC6809GetState());
	}


switch (MemRead8(pc.Reg++)){

case NEG_D: //0
	temp16=(dp.Reg |MemRead8(pc.Reg++));
	postbyte=MemRead8(temp16);
	temp8=0-postbyte;
	cc[C]=temp8>0;
	cc[V]= (postbyte==0x80);
	cc[N]= NTEST8(temp8);
	cc[Z]= ZTEST(temp8);
	MemWrite8(temp8,temp16);
	CycleCounter+=6;
	break;

case COM_D:
	temp16=(dp.Reg |MemRead8(pc.Reg++));
	temp8=MemRead8(temp16);
	temp8=0xFF-temp8;
	cc[Z]= ZTEST(temp8);
	cc[N]= NTEST8(temp8); 
	cc[C]=1;
	cc[V] = 0;
	MemWrite8(temp8,temp16);
	CycleCounter+=6;
	break;

case LSR_D: //S2
	temp16=(dp.Reg |MemRead8(pc.Reg++));
	temp8=MemRead8(temp16);
	cc[C]= temp8 & 1;
	temp8= temp8 >>1;
	cc[Z]= ZTEST(temp8);
	cc[N]=0;
	MemWrite8(temp8,temp16);
	CycleCounter+=6;
	break;

case ROR_D: //S2
	temp16=(dp.Reg |MemRead8(pc.Reg++));
	temp8=MemRead8(temp16);
	postbyte= cc[C]<<7;
	cc[C]= temp8 & 1;
	temp8= (temp8 >> 1)| postbyte;
	cc[Z]= ZTEST(temp8);
	cc[N]= NTEST8(temp8);
	MemWrite8(temp8,temp16);
	CycleCounter+=6;
	break;

case ASR_D: //7
	temp16=(dp.Reg |MemRead8(pc.Reg++));
	temp8=MemRead8(temp16);
	cc[C]= temp8 & 1;
	temp8 = (temp8 & 0x80) | (temp8 >>1);
	cc[Z]= ZTEST(temp8);
	cc[N]= NTEST8(temp8);
	MemWrite8(temp8,temp16);
	CycleCounter+=6;
	break;

case ASL_D: //8
	temp16=(dp.Reg |MemRead8(pc.Reg++));
	temp8=MemRead8(temp16);
	cc[C]= (temp8 & 0x80) >>7;
	cc[V]= cc[C] ^ ((temp8 & 0x40) >> 6);
	temp8= temp8 <<1;
	cc[N]= NTEST8(temp8);
	cc[Z]= ZTEST(temp8);
	MemWrite8(temp8,temp16);
	CycleCounter+=6;
	break;

case ROL_D:	//9
	temp16=(dp.Reg |MemRead8(pc.Reg++));
	temp8=MemRead8(temp16);
	postbyte=cc[C];
	cc[C]=(temp8 & 0x80)>>7;
	cc[V]= cc[C] ^ ((temp8 & 0x40) >>6);
	temp8 = (temp8<<1) | postbyte;
	cc[Z]= ZTEST(temp8);
	cc[N]= NTEST8(temp8);
	MemWrite8(temp8,temp16);
	CycleCounter+=6;
	break;

case DEC_D: //A
	temp16=(dp.Reg |MemRead8(pc.Reg++));
	temp8=MemRead8(temp16)-1;
	cc[Z]= ZTEST(temp8);
	cc[N]= NTEST8(temp8);
	cc[V]= temp8==0x7F;
	MemWrite8(temp8,temp16);
	CycleCounter+=6;
	break;

case INC_D: //C
	temp16=(dp.Reg |MemRead8(pc.Reg++));
	temp8=MemRead8(temp16)+1;
	cc[Z]= ZTEST(temp8);
	cc[V]= temp8==0x80;
	cc[N]= NTEST8(temp8);
	MemWrite8(temp8,temp16);
	CycleCounter+=6;
	break;

case TST_D: //D
	temp8=MemRead8((dp.Reg |MemRead8(pc.Reg++)));
	cc[Z]= ZTEST(temp8);
	cc[N]= NTEST8(temp8);
	cc[V] = 0;
	CycleCounter+=6;
	break;

case JMP_D:	//E
	pc.Reg= ((dp.Reg |MemRead8(pc.Reg)));
	CycleCounter+=3;
	break;

case CLR_D:	//F
	MemWrite8(0,(dp.Reg |MemRead8(pc.Reg++)));
	cc[Z]=1;
	cc[N]=0;
	cc[V] = 0;
	cc[C]=0;
	CycleCounter+=6;
	break;

case Page2:
		switch (MemRead8(pc.Reg++)) 
		{

		case LBEQ_R: //1027
			if (cc[Z])
			{
				*spostword=MemRead16(pc.Reg);
				pc.Reg+=*spostword;
				CycleCounter+=1;
			}
			pc.Reg+=2;
			CycleCounter+=5;
			break;

		case LBRN_R: //1021
			pc.Reg+=2;
			CycleCounter+=5;
			break;

		case LBHI_R: //1022
			if  (!(cc[C] | cc[Z]))
			{
				*spostword=MemRead16(pc.Reg);
				pc.Reg+=*spostword;
				CycleCounter+=1;
			}
			pc.Reg+=2;
			CycleCounter+=5;
			break;

		case LBLS_R: //1023
			if (cc[C] | cc[Z])
			{
				*spostword=MemRead16(pc.Reg);
				pc.Reg+=*spostword;
				CycleCounter+=1;
			}
			pc.Reg+=2;
			CycleCounter+=5;
			break;

		case LBHS_R: //1024
			if (!cc[C])
			{
				*spostword=MemRead16(pc.Reg);
				pc.Reg+=*spostword;
				CycleCounter+=1;
			}
			pc.Reg+=2;
			CycleCounter+=6;
			break;

		case LBCS_R: //1025
			if (cc[C])
			{
				*spostword=MemRead16(pc.Reg);
				pc.Reg+=*spostword;
				CycleCounter+=1;
			}
			pc.Reg+=2;
			CycleCounter+=5;
			break;

		case LBNE_R: //1026
			if (!cc[Z])
			{
				*spostword=MemRead16(pc.Reg);
				pc.Reg+=*spostword;
				CycleCounter+=1;
			}
			pc.Reg+=2;
			CycleCounter+=5;
			break;

		case LBVC_R: //1028
			if ( !cc[V])
			{
				*spostword=MemRead16(pc.Reg);
				pc.Reg+=*spostword;
				CycleCounter+=1;
			}
			pc.Reg+=2;
			CycleCounter+=5;
			break;

		case LBVS_R: //1029
			if ( cc[V])
			{
				*spostword=MemRead16(pc.Reg);
				pc.Reg+=*spostword;
				CycleCounter+=1;
			}
			pc.Reg+=2;
			CycleCounter+=5;
			break;

		case LBPL_R: //102A
		if (!cc[N])
			{
				*spostword=MemRead16(pc.Reg);
				pc.Reg+=*spostword;
				CycleCounter+=1;
			}
			pc.Reg+=2;
			CycleCounter+=5;
			break;

		case LBMI_R: //102B
		if ( cc[N])
			{
				*spostword=MemRead16(pc.Reg);
				pc.Reg+=*spostword;
				CycleCounter+=1;
			}
			pc.Reg+=2;
			CycleCounter+=5;
			break;

		case LBGE_R: //102C
			if (! (cc[N] ^ cc[V]))
			{
				*spostword=MemRead16(pc.Reg);
				pc.Reg+=*spostword;
				CycleCounter+=1;
			}
			pc.Reg+=2;
			CycleCounter+=5;
			break;

		case LBLT_R: //102D
			if ( cc[V] ^ cc[N])
			{
				*spostword=MemRead16(pc.Reg);
				pc.Reg+=*spostword;
				CycleCounter+=1;
			}
			pc.Reg+=2;
			CycleCounter+=5;
			break;

		case LBGT_R: //102E
			if ( !( cc[Z] | (cc[N]^cc[V] ) ))
			{
				*spostword=MemRead16(pc.Reg);
				pc.Reg+=*spostword;
				CycleCounter+=1;
			}
			pc.Reg+=2;
			CycleCounter+=5;
			break;

		case LBLE_R:	//102F
			if ( cc[Z] | (cc[N]^cc[V]) )
			{
				*spostword=MemRead16(pc.Reg);
				pc.Reg+=*spostword;
				CycleCounter+=1;
			}
			pc.Reg+=2;
			CycleCounter+=5;
			break;

		case SWI2_I: //103F
			cc[E]=1;
			MemWrite8( pc.B.lsb,--s.Reg);
			MemWrite8( pc.B.msb,--s.Reg);
			MemWrite8( u.B.lsb,--s.Reg);
			MemWrite8( u.B.msb,--s.Reg);
			MemWrite8( y.B.lsb,--s.Reg);
			MemWrite8( y.B.msb,--s.Reg);
			MemWrite8( x.B.lsb,--s.Reg);
			MemWrite8( x.B.msb,--s.Reg);
			MemWrite8( dp.B.msb,--s.Reg);
			MemWrite8(B_REG,--s.Reg);
			MemWrite8(A_REG,--s.Reg);
			MemWrite8(getcc(),--s.Reg);
			pc.Reg=MemRead16(VSWI2);
			CycleCounter+=20;
			break;

		case CMPD_M: //1083
			postword=MemRead16(pc.Reg);
			temp16 = D_REG-postword;
			cc[C]= temp16 > D_REG;
			cc[V]= OTEST16(cc[C],postword,temp16,D_REG);//cc[C]^((postword^temp16^D_REG)>>15);
			cc[N]= NTEST16(temp16);
			cc[Z]= ZTEST(temp16);
			pc.Reg+=2;
			CycleCounter+=5;
			break;

		case CMPY_M: //108C
			postword=MemRead16(pc.Reg);
			temp16 = y.Reg-postword;
			cc[C]= temp16 > y.Reg;
			cc[V]= OTEST16(cc[C],postword,temp16,y.Reg);//cc[C]^((postword^temp16^y.Reg)>>15);
			cc[N]= NTEST16(temp16);
			cc[Z]= ZTEST(temp16);
			pc.Reg+=2;
			CycleCounter+=5;
			break;
	
		case LDY_M: //108E
			y.Reg= MemRead16(pc.Reg);
			cc[Z]= ZTEST(y.Reg);
			cc[N]= NTEST16(y.Reg);
			cc[V]= 0;
			pc.Reg+=2;
			CycleCounter+=5;
			break;

		case CMPD_D: //1093
			postword=MemRead16((dp.Reg |MemRead8(pc.Reg++)));
			temp16= D_REG - postword ;
			cc[C]= temp16 > D_REG;
			cc[V]= OTEST16(cc[C],postword,temp16,D_REG); //cc[C]^((postword^temp16^D_REG)>>15);
			cc[N]= NTEST16(temp16);
			cc[Z]= ZTEST(temp16);
			CycleCounter+=7;
			break;

		case CMPY_D:	//109C
			postword=MemRead16((dp.Reg |MemRead8(pc.Reg++)));
			temp16= y.Reg - postword ;
			cc[C]= temp16 > y.Reg;
			cc[V]= OTEST16(cc[C],postword,temp16,y.Reg);//cc[C]^((postword^temp16^y.Reg)>>15);
			cc[N]= NTEST16(temp16);
			cc[Z]= ZTEST(temp16);
			CycleCounter+=7;
			break;

		case LDY_D: //109E
			y.Reg=MemRead16((dp.Reg |MemRead8(pc.Reg++)));
			cc[Z]= ZTEST(y.Reg);	
			cc[N]= NTEST16(y.Reg);
			cc[V]= 0;
			CycleCounter+=6;
			break;
	
		case STY_D: //109F
			MemWrite16(y.Reg,(dp.Reg |MemRead8(pc.Reg++)));
			cc[Z]= ZTEST(y.Reg);
			cc[N]= NTEST16(y.Reg);
			cc[V]= 0;
			CycleCounter+=6;
			break;

		case CMPD_X: //10A3
			postword=MemRead16(CalculateEA(MemRead8(pc.Reg++)));
			temp16= D_REG - postword ;
			cc[C]= temp16 > D_REG;
			cc[V]= OTEST16(cc[C],postword,temp16,D_REG);//cc[C]^((postword^temp16^D_REG)>>15);
			cc[N]= NTEST16(temp16);
			cc[Z]= ZTEST(temp16);
			CycleCounter+=7;
			break;

		case CMPY_X: //10AC
			postword=MemRead16(CalculateEA(MemRead8(pc.Reg++)));
			temp16= y.Reg - postword ;
			cc[C]= temp16 > y.Reg;
			cc[V]= OTEST16(cc[C],postword,temp16,Y_REG);
			cc[N]= NTEST16(temp16);
			cc[Z]= ZTEST(temp16);
			CycleCounter+=7;
			break;

		case LDY_X: //10AE
			y.Reg=MemRead16(CalculateEA(MemRead8(pc.Reg++)));
			cc[Z]= ZTEST(y.Reg);
			cc[N]= NTEST16(y.Reg);
			cc[V]= 0;
			CycleCounter+=6;
			break;

		case STY_X: //10AF
			MemWrite16(y.Reg,CalculateEA(MemRead8(pc.Reg++)));
			cc[Z]= ZTEST(y.Reg);
			cc[N]= NTEST16(y.Reg);
			cc[V]= 0;
			CycleCounter+=6;
			break;

		case CMPD_E: //10B3
			postword=MemRead16(MemRead16(pc.Reg));
			temp16 = D_REG-postword;
			cc[C]= temp16 > D_REG;
			cc[V]= OTEST16(cc[C],postword,temp16,D_REG);
			cc[N]= NTEST16(temp16);
			cc[Z]= ZTEST(temp16);
			pc.Reg+=2;
			CycleCounter+=8;
			break;


		case CMPY_E: //10BC
			postword=MemRead16(MemRead16(pc.Reg));
			temp16 = y.Reg-postword;
			cc[C]= temp16 > y.Reg;
			cc[V]= OTEST16(cc[C],postword,temp16,Y_REG);
			cc[N]= NTEST16(temp16);
			cc[Z]= ZTEST(temp16);
			pc.Reg+=2;
			CycleCounter+=8;
			break;

		case LDY_E: //10BE
			y.Reg=MemRead16(MemRead16(pc.Reg));
			cc[Z]= ZTEST(y.Reg);
			cc[N]= NTEST16(y.Reg);
			cc[V]= 0;
			pc.Reg+=2;
			CycleCounter+=7;
			break;

		case STY_E: //10BF
			MemWrite16(y.Reg,MemRead16(pc.Reg));
			cc[Z]= ZTEST(y.Reg);
			cc[N]= NTEST16(y.Reg);
			cc[V]= 0;
			pc.Reg+=2;
			CycleCounter+=7;
			break;

		case LDS_I:  //10CE
			s.Reg=MemRead16(pc.Reg);
			cc[Z]= ZTEST(s.Reg);
			cc[N]= NTEST16(s.Reg);
			cc[V] = 0;
			pc.Reg+=2;
			CycleCounter+=4;
			break;

		case LDS_D: //10DE
			s.Reg=MemRead16((dp.Reg |MemRead8(pc.Reg++)));
			cc[Z]= ZTEST(s.Reg);
			cc[N]= NTEST16(s.Reg);
			cc[V] = 0;
			CycleCounter+=6;
			break;

		case STS_D: //10DF
			MemWrite16(s.Reg,(dp.Reg |MemRead8(pc.Reg++)));
			cc[Z]= ZTEST(s.Reg);
			cc[N]= NTEST16(s.Reg);
			cc[V]= 0;
			CycleCounter+=6;
			break;

		case LDS_X: //10EE
			s.Reg=MemRead16(CalculateEA(MemRead8(pc.Reg++)));
			cc[Z]= ZTEST(s.Reg);
			cc[N]= NTEST16(s.Reg);
			cc[V]= 0;
			CycleCounter+=6;
			break;

		case STS_X: //10EF
			MemWrite16(s.Reg,CalculateEA(MemRead8(pc.Reg++)));
			cc[Z]= ZTEST(s.Reg);
			cc[N]= NTEST16(s.Reg);
			cc[V]= 0;
			CycleCounter+=6;
			break;

		case LDS_E: //10FE
			s.Reg=MemRead16(MemRead16(pc.Reg));
			cc[Z]= ZTEST(s.Reg);
			cc[N]= NTEST16(s.Reg);
			cc[V]= 0;
			pc.Reg+=2;
			CycleCounter+=7;
			break;

		case STS_E: //10FF
			MemWrite16(s.Reg,MemRead16(pc.Reg));
			cc[Z] = ZTEST(s.Reg);
			cc[N]= NTEST16(s.Reg);
			cc[V] = 0;
			pc.Reg+=2;
			CycleCounter+=7;
			break;

		default:
//			MessageBox(0,"Unhandled Op","Ok",0);
			break;
	} //Page 2 switch END
	break;

	case Page3:
		switch (MemRead8(pc.Reg++)) {

		case BREAK: //113E
			if (EmuState.Debugger.Break_Enabled()) {
				PendingInterupts = 0;
				EmuState.Debugger.Halt();
			} else {
				CycleCounter+=4;
			}
			break;

		case SWI3_I: //113F
			cc[E]=1;
			MemWrite8( pc.B.lsb,--s.Reg);
			MemWrite8( pc.B.msb,--s.Reg);
			MemWrite8( u.B.lsb,--s.Reg);
			MemWrite8( u.B.msb,--s.Reg);
			MemWrite8( y.B.lsb,--s.Reg);
			MemWrite8( y.B.msb,--s.Reg);
			MemWrite8( x.B.lsb,--s.Reg);
			MemWrite8( x.B.msb,--s.Reg);
			MemWrite8( dp.B.msb,--s.Reg);
			MemWrite8(B_REG,--s.Reg);
			MemWrite8(A_REG,--s.Reg);
			MemWrite8(getcc(),--s.Reg);
			pc.Reg=MemRead16(VSWI3);
			CycleCounter+=20;
			break;

		case CMPU_M: //1183
			postword=MemRead16(pc.Reg);
			temp16 = u.Reg-postword;
			cc[C]= temp16 > u.Reg;
			cc[V]= OTEST16(cc[C],postword,temp16,U_REG);
			cc[N]= NTEST16(temp16);
			cc[Z]= ZTEST(temp16);
			pc.Reg+=2;	
			CycleCounter+=5;
			break;

		case CMPS_M: //118C
			postword=MemRead16(pc.Reg);
			temp16 = s.Reg-postword;
			cc[C]= temp16 > s.Reg;
			cc[V]= OTEST16(cc[C],postword,temp16,S_REG);
			cc[N]= NTEST16(temp16);
			cc[Z]= ZTEST(temp16);
			pc.Reg+=2;
			CycleCounter+=5;
			break;

		case CMPU_D: //1193
			postword=MemRead16((dp.Reg |MemRead8(pc.Reg++)));
			temp16= u.Reg - postword ;
			cc[C]= temp16 > u.Reg;
			cc[V]= OTEST16(cc[C],postword,temp16,U_REG);
			cc[N]= NTEST16(temp16);
			cc[Z]= ZTEST(temp16);
			CycleCounter+=7;
			break;

		case CMPS_D: //119C
			postword=MemRead16((dp.Reg |MemRead8(pc.Reg++)));
			temp16= s.Reg - postword ;
			cc[C]= temp16 > s.Reg;
			cc[V]= OTEST16(cc[C],postword,temp16,S_REG);
			cc[N]= NTEST16(temp16);
			cc[Z]= ZTEST(temp16);
			CycleCounter+=7;
			break;

		case CMPU_X: //11A3
			postword=MemRead16(CalculateEA(MemRead8(pc.Reg++)));
			temp16= u.Reg - postword ;
			cc[C]= temp16 > u.Reg;
			cc[V]= OTEST16(cc[C],postword,temp16,U_REG);
			cc[N]= NTEST16(temp16);
			cc[Z]= ZTEST(temp16);
			CycleCounter+=7;
			break;

		case CMPS_X:  //11AC
			postword=MemRead16(CalculateEA(MemRead8(pc.Reg++)));
			temp16= s.Reg - postword ;
			cc[C]= temp16 > s.Reg;
			cc[V]= OTEST16(cc[C],postword,temp16,S_REG);
			cc[N]= NTEST16(temp16);
			cc[Z]= ZTEST(temp16);
			CycleCounter+=7;
			break;

		case CMPU_E: //11B3
			postword=MemRead16(MemRead16(pc.Reg));
			temp16 = u.Reg-postword;
			cc[C]= temp16 > u.Reg;
			cc[V]= OTEST16(cc[C],postword,temp16,U_REG);
			cc[N]= NTEST16(temp16);
			cc[Z]= ZTEST(temp16);
			pc.Reg+=2;
			CycleCounter+=8;
			break;

		case CMPS_E: //11BC
			postword=MemRead16(MemRead16(pc.Reg));
			temp16 = s.Reg-postword;
			cc[C]= temp16 > s.Reg;
			cc[V]= OTEST16(cc[C],postword,temp16,S_REG);
			cc[N]= NTEST16(temp16);
			cc[Z]= ZTEST(temp16);
			pc.Reg+=2;
			CycleCounter+=8;
			break;

		default:
//			MessageBox(0,"Unhandled Op","Ok",0);
		break;

	} //Page 3 switch END
	break;

case NOP_I:	//12
	CycleCounter+=2;
	break;

case SYNC_I: //13
	CycleCounter=CycleFor;
	SyncWaiting=1;
	break;

case HALT: //15
	if (EmuState.Debugger.Halt_Enabled()) {
		PendingInterupts = 0;
		VCC::ApplyHaltpoints(0);
		EmuState.Debugger.Halt();
		PC_REG -= 1;
	} else {
		CycleCounter+=2;
	}
	break;

case LBRA_R: //16
	*spostword=MemRead16(pc.Reg);
	pc.Reg+=2;
	pc.Reg+=*spostword;
	CycleCounter+=5;
	break;

case LBSR_R: //17
	*spostword=MemRead16(pc.Reg);
	pc.Reg+=2;
	s.Reg--;
	MemWrite8(pc.B.lsb,s.Reg--);
	MemWrite8(pc.B.msb,s.Reg);
	pc.Reg+=*spostword;
	CycleCounter+=9;
	break;

case DAA_I: //19
//	MessageBox(0,"DAA","Ok",0);
	msn=(A_REG & 0xF0) ;
	lsn=(A_REG & 0xF);
	temp8=0;
	if ( cc[H] ||  (lsn >9) )
		temp8 |= 0x06;

	if ( (msn>0x80) && (lsn>9)) 
		temp8|=0x60;
	
	if ( (msn>0x90) || cc[C] )
		temp8|=0x60;

	temp16= A_REG+temp8;
	cc[C]|=((temp16 & 0x100)>>8);
	A_REG= temp16 & 0xFF;
	cc[N]= NTEST8(A_REG);
	cc[Z]= ZTEST(A_REG);
	CycleCounter+=2;
	break;

case ORCC_M: //1A
	postbyte=MemRead8(pc.Reg++);
	temp8=getcc();
	temp8 = (temp8 | postbyte);
	setcc(temp8);
	CycleCounter+=3;
	break;

case ANDCC_M: //1C
	postbyte=MemRead8(pc.Reg++);
	temp8=getcc();
	temp8 = (temp8 & postbyte);
	setcc(temp8);
	CycleCounter+=3;
	break;

case SEX_I: //1D
//	A_REG = ((signed char)B_REG < 0) ? 0xff : 0x00;
	A_REG= 0-(B_REG>>7);
	cc[Z]= ZTEST(D_REG);
	cc[N]= NTEST16(D_REG);
	CycleCounter+=2;
	break;

case EXG_M: //1E
	postbyte=MemRead8(pc.Reg++);
	ccbits=getcc();
	if ( ((postbyte & 0x80)>>4)==(postbyte & 0x08)) //Verify like size registers
	{
		if (postbyte & 0x08) //8 bit EXG
		{
			temp8= (*ureg8[((postbyte & 0x70) >> 4)]); 
			(*ureg8[((postbyte & 0x70) >> 4)]) = (*ureg8[postbyte & 0x07]);
			(*ureg8[postbyte & 0x07])=temp8;
		}
		else // 16 bit EXG
		{
			temp16=(*xfreg16[((postbyte & 0x70) >> 4)]);
			(*xfreg16[((postbyte & 0x70) >> 4)])=(*xfreg16[postbyte & 0x07]);
			(*xfreg16[postbyte & 0x07])=temp16;
		}
	}
	setcc(ccbits);
	CycleCounter+=8;
	break;

case TFR_M: //1F
	postbyte=MemRead8(pc.Reg++);
	Source= postbyte>>4;
	Dest=postbyte & 15;
	switch (Dest)
	{
		case 0:
		case 1:
		case 2:
		case 3:
		case 4:
		case 5:
		case 6:
		case 7:
			*xfreg16[Dest]=0xFFFF;
			if ((Source == 12) | (Source == 13))
			{
				*xfreg16[Dest] = 0;
			}
			else if (Source <= 7)
			{
				//make sure the source is valud
				if (xfreg16[Source])
				{
					*xfreg16[Dest] = *xfreg16[Source];
				}	
			}
		break;

		case 8:
		case 9:
		case 10:
		case 11:
		case 14:
		case 15:
			ccbits=getcc();
			*ureg8[Dest&7]=0xFF;
			if ( (Source==12) | (Source==13) )
				*ureg8[Dest&7]=0;
			else
				if (Source>7)
					*ureg8[Dest&7]=*ureg8[Source&7];
			setcc(ccbits);
		break;
	}
	CycleCounter+=6;
	break;

case BRA_R: //20
	*spostbyte=MemRead8(pc.Reg++);
	pc.Reg+=*spostbyte;
	CycleCounter+=3;
	break;

case BRN_R: //21
	CycleCounter+=3;
	pc.Reg++;
	break;

case BHI_R: //22
	if  (!(cc[C] | cc[Z]))
		pc.Reg+=(signed char)MemRead8(pc.Reg);
	pc.Reg++;
	CycleCounter+=3;
	break;

case BLS_R: //23
	if (cc[C] | cc[Z])
		pc.Reg+=(signed char)MemRead8(pc.Reg);
	pc.Reg++;
	CycleCounter+=3;
	break;

case BHS_R: //24
	if (!cc[C])
		pc.Reg+=(signed char)MemRead8(pc.Reg);
	pc.Reg++;
	CycleCounter+=3;
	break;

case BLO_R: //25
	if (cc[C])
		pc.Reg+=(signed char)MemRead8(pc.Reg);
	pc.Reg++;
	CycleCounter+=3;
	break;

case BNE_R: //26
	if (!cc[Z])
		pc.Reg+=(signed char)MemRead8(pc.Reg);
	pc.Reg++;
	CycleCounter+=3;
	break;

case BEQ_R: //27
	if (cc[Z])
		pc.Reg+=(signed char)MemRead8(pc.Reg);
	pc.Reg++;
	CycleCounter+=3;
	break;

case BVC_R: //28
	if (!cc[V])
		pc.Reg+=(signed char)MemRead8(pc.Reg);
	pc.Reg++;
	CycleCounter+=3;
	break;

case BVS_R: //29
	if ( cc[V])
		pc.Reg+=(signed char)MemRead8(pc.Reg);
	pc.Reg++;
	CycleCounter+=3;
	break;

case BPL_R: //2A
	if (!cc[N])
		pc.Reg+=(signed char)MemRead8(pc.Reg);
	pc.Reg++;
	CycleCounter+=3;
	break;

case BMI_R: //2B
	if ( cc[N])
		pc.Reg+=(signed char)MemRead8(pc.Reg);
	pc.Reg++;
	CycleCounter+=3;
	break;

case BGE_R: //2C
	if (! (cc[N] ^ cc[V]))
		pc.Reg+=(signed char)MemRead8(pc.Reg);
	pc.Reg++;
	CycleCounter+=3;
	break;

case BLT_R: //2D
	if ( cc[V] ^ cc[N])
		pc.Reg+=(signed char)MemRead8(pc.Reg);
	pc.Reg++;
	CycleCounter+=3;
	break;

case BGT_R: //2E
	if ( !( cc[Z] | (cc[N]^cc[V] ) ))
		pc.Reg+=(signed char)MemRead8(pc.Reg);
	pc.Reg++;
	CycleCounter+=3;
	break;

case BLE_R: //2F
	if ( cc[Z] | (cc[N]^cc[V]) )
		pc.Reg+=(signed char)MemRead8(pc.Reg);
	pc.Reg++;
	CycleCounter+=3;
	break;

case LEAX_X: //30
	x.Reg=CalculateEA(MemRead8(pc.Reg++));
	cc[Z]= ZTEST(x.Reg);
	CycleCounter+=4;
	break;

case LEAY_X: //31
	y.Reg=CalculateEA(MemRead8(pc.Reg++));
	cc[Z]= ZTEST(y.Reg);
	CycleCounter+=4;
	break;

case LEAS_X: //32
	s.Reg=CalculateEA(MemRead8(pc.Reg++));
	CycleCounter+=4;
	break;

case LEAU_X: //33
	u.Reg=CalculateEA(MemRead8(pc.Reg++));
	CycleCounter+=4;
	break;

case PSHS_M: //34
	postbyte=MemRead8(pc.Reg++);
	if (postbyte & 0x80)
	{
		MemWrite8( pc.B.lsb,--s.Reg);
		MemWrite8( pc.B.msb,--s.Reg);
		CycleCounter+=2;
	}
	if (postbyte & 0x40)
	{
		MemWrite8( u.B.lsb,--s.Reg);
		MemWrite8( u.B.msb,--s.Reg);
		CycleCounter+=2;
	}
	if (postbyte & 0x20)
	{
		MemWrite8( y.B.lsb,--s.Reg);
		MemWrite8( y.B.msb,--s.Reg);
		CycleCounter+=2;
	}
	if (postbyte & 0x10)
	{
		MemWrite8( x.B.lsb,--s.Reg);
		MemWrite8( x.B.msb,--s.Reg);
		CycleCounter+=2;
	}
	if (postbyte & 0x08)
	{
		MemWrite8( dp.B.msb,--s.Reg);
		CycleCounter+=1;
	}
	if (postbyte & 0x04)
	{
		MemWrite8(B_REG,--s.Reg);
		CycleCounter+=1;
	}
	if (postbyte & 0x02)
	{
		MemWrite8(A_REG,--s.Reg);
		CycleCounter+=1;
	}
	if (postbyte & 0x01)
	{
		MemWrite8(getcc(),--s.Reg);
		CycleCounter+=1;
	}

	CycleCounter+=5;
	break;

case PULS_M: //35
	postbyte=MemRead8(pc.Reg++);
	if (postbyte & 0x01)
	{
		setcc(MemRead8(s.Reg++));
		CycleCounter+=1;
	}
	if (postbyte & 0x02)
	{
		A_REG=MemRead8(s.Reg++);
		CycleCounter+=1;
	}
	if (postbyte & 0x04)
	{
		B_REG=MemRead8(s.Reg++);
		CycleCounter+=1;
	}
	if (postbyte & 0x08)
	{
		dp.B.msb=MemRead8(s.Reg++);
		CycleCounter+=1;
	}
	if (postbyte & 0x10)
	{
		x.B.msb=MemRead8( s.Reg++);
		x.B.lsb=MemRead8( s.Reg++);
		CycleCounter+=2;
	}
	if (postbyte & 0x20)
	{
		y.B.msb=MemRead8( s.Reg++);
		y.B.lsb=MemRead8( s.Reg++);
		CycleCounter+=2;
	}
	if (postbyte & 0x40)
	{
		u.B.msb=MemRead8( s.Reg++);
		u.B.lsb=MemRead8( s.Reg++);
		CycleCounter+=2;
	}
	if (postbyte & 0x80)
	{
		pc.B.msb=MemRead8( s.Reg++);
		pc.B.lsb=MemRead8( s.Reg++);
		CycleCounter+=2;
	}
	CycleCounter+=5;
	break;

case PSHU_M: //36
	postbyte=MemRead8(pc.Reg++);
	if (postbyte & 0x80)
	{
		MemWrite8( pc.B.lsb,--u.Reg);
		MemWrite8( pc.B.msb,--u.Reg);
		CycleCounter+=2;
	}
	if (postbyte & 0x40)
	{
		MemWrite8( s.B.lsb,--u.Reg);
		MemWrite8( s.B.msb,--u.Reg);
		CycleCounter+=2;
	}
	if (postbyte & 0x20)
	{
		MemWrite8( y.B.lsb,--u.Reg);
		MemWrite8( y.B.msb,--u.Reg);
		CycleCounter+=2;
	}
	if (postbyte & 0x10)
	{
		MemWrite8( x.B.lsb,--u.Reg);
		MemWrite8( x.B.msb,--u.Reg);
		CycleCounter+=2;
	}
	if (postbyte & 0x08)
	{
		MemWrite8( dp.B.msb,--u.Reg);
		CycleCounter+=1;
	}
	if (postbyte & 0x04)
	{
		MemWrite8(B_REG,--u.Reg);
		CycleCounter+=1;
	}
	if (postbyte & 0x02)
	{
		MemWrite8(A_REG,--u.Reg);
		CycleCounter+=1;
	}
	if (postbyte & 0x01)
	{
		MemWrite8(getcc(),--u.Reg);
		CycleCounter+=1;
	}
	CycleCounter+=5;
	break;

case PULU_M: //37
	postbyte=MemRead8(pc.Reg++);
	if (postbyte & 0x01)
	{
		setcc(MemRead8(u.Reg++));
		CycleCounter+=1;
	}
	if (postbyte & 0x02)
	{
		A_REG=MemRead8(u.Reg++);
		CycleCounter+=1;
	}
	if (postbyte & 0x04)
	{
		B_REG=MemRead8(u.Reg++);
		CycleCounter+=1;
	}
	if (postbyte & 0x08)
	{
		dp.B.msb=MemRead8(u.Reg++);
		CycleCounter+=1;
	}
	if (postbyte & 0x10)
	{
		x.B.msb=MemRead8( u.Reg++);
		x.B.lsb=MemRead8( u.Reg++);
		CycleCounter+=2;
	}
	if (postbyte & 0x20)
	{
		y.B.msb=MemRead8( u.Reg++);
		y.B.lsb=MemRead8( u.Reg++);
		CycleCounter+=2;
	}
	if (postbyte & 0x40)
	{
		s.B.msb=MemRead8( u.Reg++);
		s.B.lsb=MemRead8( u.Reg++);
		CycleCounter+=2;
	}
	if (postbyte & 0x80)
	{
		pc.B.msb=MemRead8( u.Reg++);
		pc.B.lsb=MemRead8( u.Reg++);
		CycleCounter+=2;
	}
	CycleCounter+=5;
	break;

case RTS_I: //39
	pc.B.msb=MemRead8(s.Reg++);
	pc.B.lsb=MemRead8(s.Reg++);
	CycleCounter+=5;
	break;

case ABX_I: //3A
	x.Reg=x.Reg+B_REG;
	CycleCounter+=3;
	break;

case RTI_I: //3B
	setcc(MemRead8(s.Reg++));
	CycleCounter+=6;
	InInterupt=0;
	if (cc[E])
	{
		A_REG=MemRead8(s.Reg++);
		B_REG=MemRead8(s.Reg++);
		dp.B.msb=MemRead8(s.Reg++);
		x.B.msb=MemRead8(s.Reg++);
		x.B.lsb=MemRead8(s.Reg++);
		y.B.msb=MemRead8(s.Reg++);
		y.B.lsb=MemRead8(s.Reg++);
		u.B.msb=MemRead8(s.Reg++);
		u.B.lsb=MemRead8(s.Reg++);
		CycleCounter+=9;
	}
	pc.B.msb=MemRead8(s.Reg++);
	pc.B.lsb=MemRead8(s.Reg++);
	break;

case CWAI_I: //3C
	postbyte=MemRead8(pc.Reg++);
	ccbits=getcc();
	ccbits = ccbits & postbyte;
	setcc(ccbits);
	CycleCounter=CycleFor;
	SyncWaiting=1;
	break;

case MUL_I: //3D
	D_REG = A_REG * B_REG;
	cc[C]= B_REG >0x7F;
	cc[Z]= ZTEST(D_REG);
	CycleCounter+=11;
	break;

case RESET:	//Undocumented
	MC6809Reset();
	break;

case SWI1_I: //3F
	cc[E]=1;
	MemWrite8( pc.B.lsb,--s.Reg);
	MemWrite8( pc.B.msb,--s.Reg);
	MemWrite8( u.B.lsb,--s.Reg);
	MemWrite8( u.B.msb,--s.Reg);
	MemWrite8( y.B.lsb,--s.Reg);
	MemWrite8( y.B.msb,--s.Reg);
	MemWrite8( x.B.lsb,--s.Reg);
	MemWrite8( x.B.msb,--s.Reg);
	MemWrite8( dp.B.msb,--s.Reg);
	MemWrite8(B_REG,--s.Reg);
	MemWrite8(A_REG,--s.Reg);
	MemWrite8(getcc(),--s.Reg);
	pc.Reg=MemRead16(VSWI);
	CycleCounter+=19;
	cc[I]=1;
	cc[F]=1;
	break;

case NEGA_I: //40
	temp8= 0-A_REG;
	cc[C]= temp8>0;
	cc[V]= A_REG==0x80; //cc[C] ^ ((A_REG^temp8)>>7);
	cc[N]= NTEST8(temp8);
	cc[Z]= ZTEST(temp8);
	A_REG= temp8;
	CycleCounter+=2;
	break;

case COMA_I: //43
	A_REG= 0xFF- A_REG;
	cc[Z]= ZTEST(A_REG);
	cc[N]= NTEST8(A_REG);
	cc[C]= 1;
	cc[V]= 0;
	CycleCounter+=2;
	break;

case LSRA_I: //44
	cc[C]= A_REG & 1;
	A_REG= A_REG>>1;
	cc[Z]= ZTEST(A_REG);
	cc[N]= 0;
	CycleCounter+=2;
	break;

case RORA_I: //46
	postbyte=cc[C]<<7;
	cc[C]= A_REG & 1;
	A_REG= (A_REG>>1) | postbyte;
	cc[Z]= ZTEST(A_REG);
	cc[N]= NTEST8(A_REG);
	CycleCounter+=2;
	break;

case ASRA_I: //47
	cc[C]= A_REG & 1;
	A_REG= (A_REG & 0x80) | (A_REG >> 1);
	cc[Z]= ZTEST(A_REG);
	cc[N]= NTEST8(A_REG);
	CycleCounter+=2;
	break;

case ASLA_I: //48 JF
	cc[C]= A_REG > 0x7F;
	cc[V]=  cc[C] ^((A_REG & 0x40)>>6);
	A_REG= A_REG<<1;
	cc[N]= NTEST8(A_REG);
	cc[Z]= ZTEST(A_REG);
	CycleCounter+=2;
	break;

case ROLA_I: //49
	postbyte=cc[C];
	cc[C]= A_REG > 0x7F;
	cc[V]= cc[C] ^ ((A_REG & 0x40)>>6);
	A_REG= (A_REG<<1) | postbyte;
	cc[Z]= ZTEST(A_REG);
	cc[N]= NTEST8(A_REG);
	CycleCounter+=2;
	break;

case DECA_I: //4A
	A_REG--;
	cc[Z]= ZTEST(A_REG);
	cc[V]= A_REG==0x7F;
	cc[N]= NTEST8(A_REG);
	CycleCounter+=2;
	break;

case INCA_I: //4C
	A_REG++;
	cc[Z]= ZTEST(A_REG);
	cc[V]= A_REG==0x80;
	cc[N]= NTEST8(A_REG);
	CycleCounter+=2;
	break;

case TSTA_I: //4D
	cc[Z]= ZTEST(A_REG);
	cc[N]= NTEST8(A_REG);
	cc[V]= 0;
	CycleCounter+=2;
	break;

case CLRA_I: //4F
	A_REG= 0;
	cc[C]=0;
	cc[V] = 0;
	cc[N]=0;
	cc[Z]=1;
	CycleCounter+=2;
	break;

case NEGB_I: //50
	temp8= 0-B_REG;
	cc[C]= temp8>0;
	cc[V]= B_REG == 0x80;	
	cc[N]= NTEST8(temp8);
	cc[Z]= ZTEST(temp8);
	B_REG= temp8;
	CycleCounter+=2;
	break;

case COMB_I: //53
	B_REG= 0xFF- B_REG;
	cc[Z]= ZTEST(B_REG);
	cc[N]= NTEST8(B_REG);
	cc[C]= 1;
	cc[V]= 0;
	CycleCounter+=2;
	break;

case LSRB_I: //54
	cc[C]= B_REG & 1;
	B_REG= B_REG>>1;
	cc[Z]= ZTEST(B_REG);
	cc[N]= 0;
	CycleCounter+=2;
	break;

case RORB_I: //56
	postbyte=cc[C]<<7;
	cc[C]= B_REG & 1;
	B_REG= (B_REG>>1) | postbyte;
	cc[Z]= ZTEST(B_REG);
	cc[N]= NTEST8(B_REG);
	CycleCounter+=2;
	break;

case ASRB_I: //57
	cc[C]= B_REG & 1;
	B_REG= (B_REG & 0x80) | (B_REG >> 1);
	cc[Z]= ZTEST(B_REG);
	cc[N]= NTEST8(B_REG);
	CycleCounter+=2;
	break;

case ASLB_I: //58
	cc[C]= B_REG > 0x7F;
	cc[V]=  cc[C] ^((B_REG & 0x40)>>6);
	B_REG= B_REG<<1;
	cc[N]= NTEST8(B_REG);
	cc[Z]= ZTEST(B_REG);
	CycleCounter+=2;
	break;

case ROLB_I: //59
	postbyte=cc[C];
	cc[C]= B_REG > 0x7F;
	cc[V]= cc[C] ^ ((B_REG & 0x40)>>6);
	B_REG= (B_REG<<1) | postbyte;
	cc[Z]= ZTEST(B_REG);
	cc[N]= NTEST8(B_REG);
	CycleCounter+=2;
	break;

case DECB_I: //5A
	B_REG--;
	cc[Z]= ZTEST(B_REG);
	cc[V]= B_REG==0x7F;
	cc[N]= NTEST8(B_REG);
	CycleCounter+=2;
	break;

case INCB_I: //5C
	B_REG++;
	cc[Z]= ZTEST(B_REG);
	cc[V]= B_REG==0x80; 
	cc[N]= NTEST8(B_REG);
	CycleCounter+=2;
	break;

case TSTB_I: //5D
	cc[Z]= ZTEST(B_REG);
	cc[N]= NTEST8(B_REG);
	cc[V]= 0;
	CycleCounter+=2;
	break;

case CLRB_I: //5F
	B_REG=0;
	cc[C]=0;
	cc[N]=0;
	cc[V] = 0;
	cc[Z]=1;
	CycleCounter+=2;
	break;

case NEG_X: //60
	temp16=CalculateEA(MemRead8(pc.Reg++));	
	postbyte=MemRead8(temp16);
	temp8= 0-postbyte;
	cc[C]= temp8>0;
	cc[V]= postbyte == 0x80;
	cc[N]= NTEST8(temp8);
	cc[Z]= ZTEST(temp8);
	MemWrite8(temp8,temp16);
	CycleCounter+=6;
	break;

case COM_X: //63
	temp16=CalculateEA(MemRead8(pc.Reg++));
	temp8=MemRead8(temp16);
	temp8= 0xFF-temp8;
	cc[Z]= ZTEST(temp8);
	cc[N]= NTEST8(temp8);
	cc[V]= 0;
	cc[C]= 1;
	MemWrite8(temp8,temp16);
	CycleCounter+=6;
	break;

case LSR_X: //64
	temp16=CalculateEA(MemRead8(pc.Reg++));
	temp8=MemRead8(temp16);
	cc[C]= temp8 & 1;
	temp8= temp8 >>1;
	cc[Z]= ZTEST(temp8);
	cc[N]= 0;
	MemWrite8(temp8,temp16);
	CycleCounter+=6;
	break;

case ROR_X: //66
	temp16=CalculateEA(MemRead8(pc.Reg++));
	temp8=MemRead8(temp16);
	postbyte=cc[C]<<7;
	cc[C]= (temp8 & 1);
	temp8= (temp8>>1) | postbyte;
	cc[Z]= ZTEST(temp8);
	cc[N]= NTEST8(temp8);
	MemWrite8(temp8,temp16);
	CycleCounter+=6;
	break;

case ASR_X: //67
	temp16=CalculateEA(MemRead8(pc.Reg++));
	temp8=MemRead8(temp16);
	cc[C]= temp8 & 1;
	temp8= (temp8 & 0x80) | (temp8 >>1);
	cc[Z]= ZTEST(temp8);
	cc[N]= NTEST8(temp8);
	MemWrite8(temp8,temp16);
	CycleCounter+=6;
	break;

case ASL_X: //68
	temp16=CalculateEA(MemRead8(pc.Reg++));
	temp8= MemRead8(temp16);
	cc[C]= temp8 > 0x7F;
	cc[V]= cc[C] ^ ((temp8 & 0x40)>>6);
	temp8= temp8<<1;
	cc[N]= NTEST8(temp8);
	cc[Z]= ZTEST(temp8);	
	MemWrite8(temp8,temp16);
	CycleCounter+=6;
	break;

case ROL_X: //69
	temp16=CalculateEA(MemRead8(pc.Reg++));
	temp8=MemRead8(temp16);
	postbyte=cc[C];
	cc[C]= temp8 > 0x7F;
	cc[V]= ( cc[C] ^ ((temp8 & 0x40)>>6));
	temp8= ((temp8<<1) | postbyte);
	cc[Z]= ZTEST(temp8);
	cc[N]= NTEST8(temp8);
	MemWrite8(temp8,temp16);
	CycleCounter+=6;
	break;

case DEC_X: //6A
	temp16=CalculateEA(MemRead8(pc.Reg++));
	temp8=MemRead8(temp16);
	temp8--;
	cc[Z]= ZTEST(temp8);
	cc[N]= NTEST8(temp8);
	cc[V]= (temp8==0x7F);
	MemWrite8(temp8,temp16);
	CycleCounter+=6;
	break;

case INC_X: //6C
	temp16=CalculateEA(MemRead8(pc.Reg++));
	temp8=MemRead8(temp16);
	temp8++;
	cc[V]= (temp8 == 0x80);
	cc[N]= NTEST8(temp8);
	cc[Z]= ZTEST(temp8);
	MemWrite8(temp8,temp16);
	CycleCounter+=6;
	break;

case TST_X: //6D
	temp8=MemRead8(CalculateEA(MemRead8(pc.Reg++)));
	cc[Z]= ZTEST(temp8);
	cc[N]= NTEST8(temp8);
	cc[V]= 0;
	CycleCounter+=6;
	break;

case JMP_X: //6E
	pc.Reg=CalculateEA(MemRead8(pc.Reg++));
	CycleCounter+=3;
	break;

case CLR_X: //6F
	MemWrite8(0,CalculateEA(MemRead8(pc.Reg++)));
	cc[C]= 0;
	cc[N]= 0;
	cc[V]= 0;
	cc[Z]= 1; 
	CycleCounter+=6;
	break;

case NEG_E: //70
	temp16=MemRead16(pc.Reg);
	postbyte=MemRead8(temp16);
	temp8=0-postbyte;
	cc[C]= temp8>0;
	cc[V]= postbyte == 0x80;
	cc[N]= NTEST8(temp8);
	cc[Z]= ZTEST(temp8);
	MemWrite8(temp8,temp16);
	pc.Reg+=2;
	CycleCounter+=7;
	break;

case COM_E: //73
	temp16=MemRead16(pc.Reg);
	temp8=MemRead8(temp16);
	temp8=0xFF-temp8;
	cc[Z]= ZTEST(temp8);
	cc[N]= NTEST8(temp8);
	cc[C]= 1;
	cc[V]= 0;
	MemWrite8(temp8,temp16);
	pc.Reg+=2;
	CycleCounter+=7;
	break;

case LSR_E:  //74
	temp16=MemRead16(pc.Reg);
	temp8=MemRead8(temp16);
	cc[C]= temp8 & 1;
	temp8= temp8>>1;
	cc[Z]= ZTEST(temp8);
	cc[N]= 0;
	MemWrite8(temp8,temp16);
	pc.Reg+=2;
	CycleCounter+=7;
	break;

case ROR_E: //76
	temp16=MemRead16(pc.Reg);
	temp8=MemRead8(temp16);
	postbyte=cc[C]<<7;
	cc[C]= temp8 & 1;
	temp8= (temp8>>1) | postbyte;
	cc[Z]= ZTEST(temp8);
	cc[N]= NTEST8(temp8);
	MemWrite8(temp8,temp16);
	pc.Reg+=2;
	CycleCounter+=7;
	break;

case ASR_E: //77
	temp16=MemRead16(pc.Reg);
	temp8=MemRead8(temp16);
	cc[C]= temp8 & 1;
	temp8= (temp8 & 0x80) | (temp8 >>1);
	cc[Z]= ZTEST(temp8);
	cc[N]= NTEST8(temp8);
	MemWrite8(temp8,temp16);
	pc.Reg+=2;
	CycleCounter+=7;
	break;

case ASL_E: //78
	temp16=MemRead16(pc.Reg);
	temp8= MemRead8(temp16);
	cc[C]= temp8 > 0x7F;
	cc[V]= cc[C] ^ ((temp8 & 0x40)>>6);
	temp8= temp8<<1;
	cc[N]= NTEST8(temp8);
	cc[Z]= ZTEST(temp8);
	MemWrite8(temp8,temp16);	
	pc.Reg+=2;
	CycleCounter+=7;
	break;

case ROL_E: //79
	temp16=MemRead16(pc.Reg);
	temp8=MemRead8(temp16);
	postbyte=cc[C];
	cc[C]= temp8 > 0x7F;
	cc[V]= cc[C] ^  ((temp8 & 0x40)>>6);
	temp8= ((temp8<<1) | postbyte);
	cc[Z]= ZTEST(temp8);
	cc[N]= NTEST8(temp8);
	MemWrite8(temp8,temp16);
	pc.Reg+=2;
	CycleCounter+=7;
	break;

case DEC_E: //7A
	temp16=MemRead16(pc.Reg);
	temp8=MemRead8(temp16);
	temp8--;
	cc[Z]= ZTEST(temp8);
	cc[N]= NTEST8(temp8);
	cc[V]= temp8==0x7F;
	MemWrite8(temp8,temp16);
	pc.Reg+=2;
	CycleCounter+=7;
	break;

case INC_E: //7C
	temp16=MemRead16(pc.Reg);
	temp8=MemRead8(temp16);
	temp8++;
	cc[Z]= ZTEST(temp8);
	cc[V]= temp8==0x80;
	cc[N]= NTEST8(temp8);
	MemWrite8(temp8,temp16);
	pc.Reg+=2;
	CycleCounter+=7;
	break;

case TST_E: //7D
	temp8=MemRead8(MemRead16(pc.Reg));
	cc[Z]= ZTEST(temp8);
	cc[N]= NTEST8(temp8);
	cc[V]= 0;
	pc.Reg+=2;
	CycleCounter+=7;
	break;

case JMP_E: //7E
	pc.Reg=MemRead16(pc.Reg);
	CycleCounter+=4;
	break;

case CLR_E: //7F
	MemWrite8(0,MemRead16(pc.Reg));
	cc[C]= 0;
	cc[N]= 0;
	cc[V]= 0;
	cc[Z]= 1;
	pc.Reg+=2;
	CycleCounter+=7;
	break;

case SUBA_M: //80
	postbyte=MemRead8(pc.Reg++);
	temp16 = A_REG - postbyte;
	cc[C]=(temp16 & 0x100)>>8; 
	cc[V]= OTEST8(cc[C],postbyte,temp16,A_REG);
	A_REG=(temp16 & 0xFF);
	cc[Z]= ZTEST(A_REG);
	cc[N]= NTEST8(A_REG);
	CycleCounter+=2;
	break;

case CMPA_M: //81
	postbyte=MemRead8(pc.Reg++);
	temp8= A_REG-postbyte;
	cc[C]= temp8 > A_REG;
	cc[V]= OTEST8(cc[C],postbyte,temp8,A_REG);
	cc[N]= NTEST8(temp8);
	cc[Z]= ZTEST(temp8);
	CycleCounter+=2;
	break;

case SBCA_M:  //82
	postbyte=MemRead8(pc.Reg++);
	temp16=A_REG-postbyte-cc[C];
	cc[C]= (temp16 & 0x100)>>8;
	cc[V]= OTEST8(cc[C],postbyte,temp16,A_REG);
	A_REG = (temp16 & 0xFF);
	cc[N]= NTEST8(A_REG);
	cc[Z]= ZTEST(A_REG);
	CycleCounter+=2;
	break;

case SUBD_M: //83
	temp16=MemRead16(pc.Reg);
	temp32=D_REG-temp16;
	cc[C]=(temp32 & 0x10000)>>16;
	cc[V]=OTEST16(cc[C],temp32,temp16,D_REG);
	D_REG=(temp32 & 0xFFFF);
	cc[Z]= ZTEST(D_REG);
	cc[N]= NTEST16(D_REG);
	pc.Reg+=2;
	CycleCounter+=4;
	break;

case ANDA_M: //84
	A_REG = A_REG & MemRead8(pc.Reg++);
	cc[N]= NTEST8(A_REG);
	cc[Z]= ZTEST(A_REG);
	cc[V]= 0;
	CycleCounter+=2;
	break;

case BITA_M: //85
	temp8= A_REG & MemRead8(pc.Reg++);
	cc[N]= NTEST8(temp8);
	cc[Z]= ZTEST(temp8);
	cc[V]= 0;
	CycleCounter+=2;
	break;

case LDA_M: //86
	A_REG= MemRead8(pc.Reg++);
	cc[Z]= ZTEST(A_REG);
	cc[N]= NTEST8(A_REG);
	cc[V]= 0;
	CycleCounter+=2;
	break;

case EORA_M: //88
	A_REG= A_REG ^ MemRead8(pc.Reg++);
	cc[N]= NTEST8(A_REG);
	cc[Z]= ZTEST(A_REG);
	cc[V]= 0;
	CycleCounter+=2;
	break;

case ADCA_M: //89
	postbyte=MemRead8(pc.Reg++);
	temp16= A_REG + postbyte + cc[C];
	cc[C]= (temp16 & 0x100)>>8;
	cc[V]= OTEST8(cc[C],postbyte,temp16,A_REG);
	cc[H]= ((A_REG ^ temp16 ^ postbyte) & 0x10)>>4;
	A_REG= (temp16 & 0xFF);
	cc[N]= NTEST8(A_REG);
	cc[Z]= ZTEST(A_REG);
	CycleCounter+=2;
	break;	

case ORA_M: //8A
	A_REG = A_REG | MemRead8(pc.Reg++);
	cc[N]= NTEST8(A_REG);
	cc[Z]= ZTEST(A_REG);
	cc[V]= 0;
	CycleCounter+=2;
	break;

case ADDA_M: //8B
	postbyte=MemRead8(pc.Reg++);
	temp16=A_REG+postbyte;
	cc[C]=(temp16 & 0x100)>>8;
	cc[H]= ((A_REG ^ postbyte ^ temp16) & 0x10)>>4;
	cc[V]=OTEST8(cc[C],postbyte,temp16,A_REG);
	A_REG=(temp16 & 0xFF);
	cc[N]= NTEST8(A_REG);
	cc[Z]= ZTEST(A_REG);
	CycleCounter+=2;
	break;

case CMPX_M: //8C
	postword=MemRead16(pc.Reg);
	temp16 = x.Reg-postword;
	cc[C]= temp16 > x.Reg;
	cc[V]= OTEST16(cc[C],postword,temp16,X_REG);
	cc[N]= NTEST16(temp16);
	cc[Z] = ZTEST(temp16);
	pc.Reg+=2;
	CycleCounter+=4;
	break;

case BSR_R: //8D
	*spostbyte=MemRead8(pc.Reg++);
	s.Reg--;
	MemWrite8(pc.B.lsb,s.Reg--);
	MemWrite8(pc.B.msb,s.Reg);
	pc.Reg+=*spostbyte;
	CycleCounter+=7;
	break;

case LDX_M: //8E
	x.Reg= MemRead16(pc.Reg);
	cc[Z]= ZTEST(x.Reg);
	cc[N]= NTEST16(x.Reg);
	cc[V]= 0;
	pc.Reg+=2;
	CycleCounter+=3;
	break;

case SUBA_D: //90
	postbyte=MemRead8( (dp.Reg |MemRead8(pc.Reg++)));
	temp16 = A_REG - postbyte;
	cc[C]=(temp16 & 0x100)>>8; 
	cc[V]= OTEST8(cc[C],postbyte,temp16,A_REG);
	A_REG=(temp16 & 0xFF);
	cc[Z]= ZTEST(A_REG);
	cc[N]= NTEST8(A_REG);
	CycleCounter+=4;
	break;	

case CMPA_D: //91
	postbyte=MemRead8((dp.Reg |MemRead8(pc.Reg++)));
	temp8= A_REG-postbyte;
	cc[C]= temp8 > A_REG;
	cc[V]= OTEST8(cc[C],postbyte,temp8,A_REG);
	cc[N]= NTEST8(temp8);
	cc[Z]= ZTEST(temp8);
	CycleCounter+=4;
	break;

case SBCA_D: //92
	postbyte=MemRead8((dp.Reg |MemRead8(pc.Reg++)));
	temp16=A_REG-postbyte-cc[C];
	cc[C]= (temp16 & 0x100)>>8;
	cc[V]= OTEST8(cc[C],postbyte,temp16,A_REG);
	A_REG = (temp16 & 0xFF);
	cc[N]= NTEST8(A_REG);
	cc[Z]= ZTEST(A_REG);
	CycleCounter+=4;
	break;

case SUBD_D: //93
	temp16=MemRead16((dp.Reg |MemRead8(pc.Reg++)));
	temp32=D_REG-temp16;
	cc[C]=(temp32 & 0x10000)>>16;
	cc[V]= OTEST16(cc[C],temp32,temp16,D_REG);
	D_REG=(temp32 & 0xFFFF);
	cc[Z]= ZTEST(D_REG);
	cc[N]= NTEST16(D_REG);
	CycleCounter+=6;
	break;

case ANDA_D: //94
	A_REG = A_REG & MemRead8((dp.Reg |MemRead8(pc.Reg++)));
	cc[N]= NTEST8(A_REG);
	cc[Z]= ZTEST(A_REG);
	cc[V]= 0;
	CycleCounter+=4;
	break;

case BITA_D: //95
	temp8 = A_REG & MemRead8((dp.Reg |MemRead8(pc.Reg++)));
	cc[N]= NTEST8(temp8);
	cc[Z]= ZTEST(temp8);
	cc[V]= 0;
	CycleCounter+=4;
	break;

case LDA_D: //96
	A_REG= MemRead8((dp.Reg |MemRead8(pc.Reg++)));
	cc[Z]= ZTEST(A_REG);
	cc[N]= NTEST8(A_REG);
	cc[V]= 0;
	CycleCounter+=4;
	break;

case STA_D: //97
	MemWrite8( A_REG,(dp.Reg |MemRead8(pc.Reg++)));
	cc[Z]= ZTEST(A_REG);
	cc[N]= NTEST8(A_REG);
	cc[V]= 0;
	CycleCounter+=4;
	break;

case EORA_D: //98
	A_REG= A_REG ^ MemRead8((dp.Reg |MemRead8(pc.Reg++)));
	cc[N]= NTEST8(A_REG);
	cc[Z]= ZTEST(A_REG);
	cc[V]= 0;
	CycleCounter+=4;
	break;

case ADCA_D: //99
	postbyte=MemRead8((dp.Reg |MemRead8(pc.Reg++)));
	temp16= A_REG + postbyte + cc[C];
	cc[C]= (temp16 & 0x100)>>8;
	cc[V]= OTEST8(cc[C],postbyte,temp16,A_REG);
	cc[H]= ((A_REG ^ temp16 ^ postbyte) & 0x10)>>4;
	A_REG= (temp16 & 0xFF);
	cc[N]= NTEST8(A_REG);
	cc[Z]= ZTEST(A_REG);
	CycleCounter+=4;
	break;

case ORA_D: //9A
	A_REG = A_REG | MemRead8((dp.Reg |MemRead8(pc.Reg++)));
	cc[N]= NTEST8(A_REG);
	cc[Z]= ZTEST(A_REG);
	cc[V]= 0;
	CycleCounter+=4;
	break;

case ADDA_D: //9B
	postbyte=MemRead8((dp.Reg |MemRead8(pc.Reg++)));
	temp16=A_REG+postbyte;
	cc[C]=(temp16 & 0x100)>>8;
	cc[H]= ((A_REG ^ postbyte ^ temp16) & 0x10)>>4;
	cc[V]=OTEST8(cc[C],postbyte,temp16,A_REG);
	A_REG=(temp16 & 0xFF);
	cc[N]= NTEST8(A_REG);
	cc[Z] = ZTEST(A_REG);
	CycleCounter+=4;
	break;

case CMPX_D: //9C
	postword=MemRead16((dp.Reg |MemRead8(pc.Reg++)));
	temp16= x.Reg - postword ;
	cc[C]= temp16 > x.Reg;
	cc[V]= OTEST16(cc[C],postword,temp16,X_REG);
	cc[N]= NTEST16(temp16);
	cc[Z] = ZTEST(temp16);
	CycleCounter+=6;
	break;

case BSR_D: //9D
	temp16=(dp.Reg |MemRead8(pc.Reg++));
	s.Reg--;
	MemWrite8(pc.B.lsb,s.Reg--);
	MemWrite8(pc.B.msb,s.Reg);
	pc.Reg=temp16;
	CycleCounter+=7;
	break;

case LDX_D: //9E
	x.Reg=MemRead16((dp.Reg |MemRead8(pc.Reg++)));
	cc[Z]= ZTEST(x.Reg);	
	cc[N]= NTEST16(x.Reg);
	cc[V]= 0;
	CycleCounter+=5;
	break;

case STX_D: //9F
	MemWrite16(x.Reg,(dp.Reg |MemRead8(pc.Reg++)));
	cc[Z]= ZTEST(x.Reg);
	cc[N]= NTEST16(x.Reg);
	cc[V]= 0;
	CycleCounter+=5;
	break;

case SUBA_X: //A0
	postbyte=MemRead8(CalculateEA(MemRead8(pc.Reg++)));
	temp16 = A_REG - postbyte;
	cc[C]=(temp16 & 0x100)>>8; 
	cc[V]= OTEST8(cc[C],postbyte,temp16,A_REG);
	A_REG=(temp16 & 0xFF);
	cc[Z] = ZTEST(A_REG);
	cc[N]=NTEST8(A_REG);
	CycleCounter+=4;
	break;	


case CMPA_X: //A1
	postbyte=MemRead8(CalculateEA(MemRead8(pc.Reg++)));
	temp8= A_REG-postbyte;
	cc[C]= temp8 > A_REG;
	cc[V]= OTEST8(cc[C],postbyte,temp8,A_REG);
	cc[N]= NTEST8(temp8);
	cc[Z]= ZTEST(temp8);
	CycleCounter+=4;
	break;

case SBCA_X: //A2
	postbyte=MemRead8(CalculateEA(MemRead8(pc.Reg++)));
	temp16=A_REG-postbyte-cc[C];
	cc[C]= (temp16 & 0x100)>>8;
	cc[V]= OTEST8(cc[C],postbyte,temp16,A_REG);
	A_REG = (temp16 & 0xFF);
	cc[N]= NTEST8(A_REG);
	cc[Z]= ZTEST(A_REG);
	CycleCounter+=4;
	break;

case SUBD_X: //A3
	temp16=MemRead16(CalculateEA(MemRead8(pc.Reg++)));
	temp32=D_REG-temp16;
	cc[C]= (temp32 & 0x10000)>>16;
	cc[V]= OTEST16(cc[C],temp32,temp16,D_REG);
	D_REG= (temp32 & 0xFFFF);
	cc[Z]= ZTEST(D_REG);
	cc[N]= NTEST16(D_REG);
	CycleCounter+=6;
	break;

case ANDA_X: //A4
	A_REG= A_REG & MemRead8(CalculateEA(MemRead8(pc.Reg++)));
	cc[N]= NTEST8(A_REG);
	cc[Z]= ZTEST(A_REG);
	cc[V]= 0;
	CycleCounter+=4;
	break;

case BITA_X:  //A5
	temp8 =A_REG & MemRead8(CalculateEA(MemRead8(pc.Reg++)));
	cc[N]= NTEST8(temp8);
	cc[Z]= ZTEST(temp8);
	cc[V]= 0;
	CycleCounter+=4;
	break;

case LDA_X: //A6
	A_REG= MemRead8(CalculateEA(MemRead8(pc.Reg++)));
	cc[Z]= ZTEST(A_REG);
	cc[N]= NTEST8(A_REG);
	cc[V]= 0;
	CycleCounter+=4;
	break;

case STA_X: //A7
	MemWrite8(A_REG,CalculateEA(MemRead8(pc.Reg++)));
	cc[Z]= ZTEST(A_REG);
	cc[N]= NTEST8(A_REG);
	cc[V]= 0;
	CycleCounter+=4;
	break;

case EORA_X: //A8
	A_REG= A_REG ^ MemRead8(CalculateEA(MemRead8(pc.Reg++)));
	cc[N]= NTEST8(A_REG);
	cc[Z]= ZTEST(A_REG);
	cc[V]= 0;
	CycleCounter+=4;
	break;

case ADCA_X: //A9
	postbyte=MemRead8(CalculateEA(MemRead8(pc.Reg++)));
	temp16= A_REG + postbyte + cc[C];
	cc[C]= (temp16 & 0x100)>>8;
	cc[V]= OTEST8(cc[C],postbyte,temp16,A_REG);
	cc[H]= ((A_REG ^ temp16 ^ postbyte) & 0x10)>>4;
	A_REG= (temp16 & 0xFF);
	cc[N]= NTEST8(A_REG);
	cc[Z]= ZTEST(A_REG);
	CycleCounter+=4;
	break;

case ORA_X: //AA
	A_REG= A_REG | MemRead8(CalculateEA(MemRead8(pc.Reg++)));
	cc[N]= NTEST8(A_REG);
	cc[Z]= ZTEST(A_REG);
	cc[V]= 0;
	CycleCounter+=4;
	break;

case ADDA_X: //AB
	postbyte=MemRead8(CalculateEA(MemRead8(pc.Reg++)));
	temp16=A_REG+postbyte;
	cc[C]=(temp16 & 0x100)>>8;
	cc[H]= ((A_REG ^ postbyte ^ temp16) & 0x10)>>4;
	cc[V]=OTEST8(cc[C],postbyte,temp16,A_REG);
	A_REG=(temp16 & 0xFF);
	cc[N]= NTEST8(A_REG);
	cc[Z] = ZTEST(A_REG);
	CycleCounter+=4;
	break;

case CMPX_X: //AC
	postword=MemRead16(CalculateEA(MemRead8(pc.Reg++)));
	temp16= x.Reg - postword ;
	cc[C]= temp16 > x.Reg;
	cc[V]= OTEST16(cc[C],postword,temp16,X_REG);
	cc[N]= NTEST16(temp16);
	cc[Z] = ZTEST(temp16);
	CycleCounter+=6;
	break;

case BSR_X: //AD
	temp16=CalculateEA(MemRead8(pc.Reg++));

	s.Reg--;
	MemWrite8(pc.B.lsb,s.Reg--);
	MemWrite8(pc.B.msb,s.Reg);
	pc.Reg=temp16;
	CycleCounter+=7;
	break;

case LDX_X: //AE
	x.Reg=MemRead16(CalculateEA(MemRead8(pc.Reg++)));
	cc[Z]= ZTEST(x.Reg);
	cc[N]= NTEST16(x.Reg);
	cc[V]= 0;
	CycleCounter+=5;
	break;

case STX_X: //AF
	MemWrite16(x.Reg,CalculateEA(MemRead8(pc.Reg++)));
	cc[Z]= ZTEST(x.Reg);
	cc[N]= NTEST16(x.Reg);
	cc[V] = 0;
	CycleCounter+=5;
	break;

case SUBA_E: //B0
	postbyte=MemRead8(MemRead16(pc.Reg));
	temp16 = A_REG - postbyte;
	cc[C]=(temp16 & 0x100)>>8; 
	cc[V]= OTEST8(cc[C],postbyte,temp16,A_REG);
	A_REG=(temp16 & 0xFF);
	cc[Z] = ZTEST(A_REG);
	cc[N]=NTEST8(A_REG);
	pc.Reg+=2;
	CycleCounter+=5;
	break;

case	CMPA_E: //B1
	postbyte=MemRead8(MemRead16(pc.Reg));
	temp8= A_REG-postbyte;
	cc[C]= temp8 > A_REG;
	cc[V]= OTEST8(cc[C],postbyte,temp8,A_REG);
	cc[N]= NTEST8(temp8);
	cc[Z]= ZTEST(temp8);
	pc.Reg+=2;
	CycleCounter+=5;
	break;

case SBCA_E: //B2
	postbyte=MemRead8(MemRead16(pc.Reg));
	temp16=A_REG-postbyte-cc[C];
	cc[C]= (temp16 & 0x100)>>8;
	cc[V]= OTEST8(cc[C],postbyte,temp16,A_REG);
	A_REG = (temp16 & 0xFF);
	cc[N]= NTEST8(A_REG);
	cc[Z]= ZTEST(A_REG);
	pc.Reg+=2;
	CycleCounter+=5;
	break;

case SUBD_E: //B3
	temp16=MemRead16(MemRead16(pc.Reg));
	temp32=D_REG-temp16;
	cc[C]= (temp32 & 0x10000)>>16;
	cc[V]= OTEST16(cc[C],temp32,temp16,D_REG);
	D_REG= (temp32 & 0xFFFF);
	cc[Z]= ZTEST(D_REG);
	cc[N]= NTEST16(D_REG);
	pc.Reg+=2;
	CycleCounter+=7;
	break;

case ANDA_E: //B4
	postbyte=MemRead8(MemRead16(pc.Reg));
	A_REG = A_REG & postbyte;
	cc[N]= NTEST8(A_REG);
	cc[Z]= ZTEST(A_REG);
	cc[V]= 0;
	pc.Reg+=2;
	CycleCounter+=5;
	break;

case BITA_E: //B5
	temp8 = A_REG & MemRead8(MemRead16(pc.Reg));
	cc[N]= NTEST8(temp8);
	cc[Z]= ZTEST(temp8);
	cc[V]= 0;
	pc.Reg+=2;
	CycleCounter+=5;
	break;

case LDA_E: //B6
	A_REG= MemRead8(MemRead16(pc.Reg));
	cc[Z]= ZTEST(A_REG);
	cc[N]= NTEST8(A_REG);
	cc[V]= 0;
	pc.Reg+=2;
	CycleCounter+=5;
	break;

case STA_E: //B7
	MemWrite8(A_REG,MemRead16(pc.Reg));
	cc[Z]= ZTEST(A_REG);
	cc[N]= NTEST8(A_REG);
	cc[V]= 0;
	pc.Reg+=2;
	CycleCounter+=5;
	break;

case EORA_E:  //B8
	A_REG = A_REG ^ MemRead8(MemRead16(pc.Reg));
	cc[N]= NTEST8(A_REG);
	cc[Z]= ZTEST(A_REG);
	cc[V]= 0;
	pc.Reg+=2;
	CycleCounter+=5;
	break;

case ADCA_E: //B9
	postbyte=MemRead8(MemRead16(pc.Reg));
	temp16= A_REG + postbyte + cc[C];
	cc[C]= (temp16 & 0x100)>>8;
	cc[V]= OTEST8(cc[C],postbyte,temp16,A_REG);
	cc[H]= ((A_REG ^ temp16 ^ postbyte) & 0x10)>>4;
	A_REG= (temp16 & 0xFF);
	cc[N]= NTEST8(A_REG);
	cc[Z]= ZTEST(A_REG);
	pc.Reg+=2;
	CycleCounter+=5;
	break;

case ORA_E: //BA
	A_REG = A_REG | MemRead8(MemRead16(pc.Reg));
	cc[N]= NTEST8(A_REG);
	cc[Z]= ZTEST(A_REG);
	cc[V]= 0;
	pc.Reg+=2;
	CycleCounter+=5;
	break;

case ADDA_E: //BB
	postbyte=MemRead8(MemRead16(pc.Reg));
	temp16=A_REG+postbyte;
	cc[C]= (temp16 & 0x100)>>8;
	cc[H]= ((A_REG ^ postbyte ^ temp16) & 0x10)>>4;
	cc[V]= OTEST8(cc[C],postbyte,temp16,A_REG);
	A_REG= (temp16 & 0xFF);
	cc[N]= NTEST8(A_REG);
	cc[Z]= ZTEST(A_REG);
	pc.Reg+=2;
	CycleCounter+=5;
	break;

case CMPX_E: //BC
	postword=MemRead16(MemRead16(pc.Reg));
	temp16 = x.Reg-postword;
	cc[C]= temp16 > x.Reg;
	cc[V]= OTEST16(cc[C],postword,temp16,X_REG);
	cc[N]= NTEST16(temp16);
	cc[Z]= ZTEST(temp16);
	pc.Reg+=2;
	CycleCounter+=7;
	break;

case BSR_E: //BD
	postword=MemRead16(pc.Reg);
	pc.Reg+=2;
	s.Reg--;
	MemWrite8(pc.B.lsb,s.Reg--);
	MemWrite8(pc.B.msb,s.Reg);
	pc.Reg=postword;
	CycleCounter+=8;
	break;

case LDX_E: //BE
	x.Reg=MemRead16(MemRead16(pc.Reg));
	cc[Z]= ZTEST(x.Reg);
	cc[N]= NTEST16(x.Reg);
	cc[V]= 0;
	pc.Reg+=2;
	CycleCounter+=6;
	break;

case STX_E: //BF
	MemWrite16(x.Reg,MemRead16(pc.Reg));
	cc[Z]= ZTEST(x.Reg);
	cc[N]= NTEST16(x.Reg);
	cc[V]= 0;
	pc.Reg+=2;
	CycleCounter+=6;
	break;

case SUBB_M: //C0
	postbyte=MemRead8(pc.Reg++);
	temp16 = B_REG - postbyte;
	cc[C]=(temp16 & 0x100)>>8; 
	cc[V]= OTEST8(cc[C],postbyte,temp16,B_REG);
	B_REG=(temp16 & 0xFF);
	cc[Z] = ZTEST(B_REG);
	cc[N]=NTEST8(B_REG);
	CycleCounter+=2;
	break;

case CMPB_M: //C1
	postbyte=MemRead8(pc.Reg++);
	temp8= B_REG-postbyte;
	cc[C]= temp8 > B_REG;
	cc[V]= OTEST8(cc[C],postbyte,temp8,B_REG);
	cc[N]= NTEST8(temp8);
	cc[Z]= ZTEST(temp8);
	CycleCounter+=2;
	break;

case SBCB_M: //C3
	postbyte=MemRead8(pc.Reg++);
	temp16=B_REG-postbyte-cc[C];
	cc[C]= (temp16 & 0x100)>>8;
	cc[V]= OTEST8(cc[C],postbyte,temp16,B_REG);
	B_REG = (temp16 & 0xFF);
	cc[N]= NTEST8(B_REG);
	cc[Z]= ZTEST(B_REG);
	CycleCounter+=2;
	break;

case ADDD_M: //C3
	temp16=MemRead16(pc.Reg);
	temp32= D_REG+ temp16;
	cc[C]= (temp32 & 0x10000)>>16;
	cc[V]= OTEST16(cc[C],temp32,temp16,D_REG);
	D_REG= (temp32 & 0xFFFF);
	cc[Z]= ZTEST(D_REG);
	cc[N]= NTEST16(D_REG);
	pc.Reg+=2;
	CycleCounter+=4;
	break;

case ANDB_M: //C4
//	postbyte=MemRead8(pc.Reg++);
	B_REG = B_REG & MemRead8(pc.Reg++);
	cc[N]= NTEST8(B_REG);
	cc[Z]= ZTEST(B_REG);
	cc[V] = 0;
	CycleCounter+=2;
	break;

case BITB_M: //C5
	temp8 = B_REG & MemRead8(pc.Reg++);
	cc[N]= NTEST8(temp8);
	cc[Z]= ZTEST(temp8);
	cc[V]= 0;
	CycleCounter+=2;
	break;

case LDB_M: //C6
	B_REG=MemRead8(pc.Reg++);
	cc[Z]= ZTEST(B_REG);
	cc[N]= NTEST8(B_REG);
	cc[V]= 0;
	CycleCounter+=2;
	break;

case EORB_M: //C8
//	postbyte=MemRead8(pc.Reg++);
	B_REG = B_REG ^ MemRead8(pc.Reg++);
	cc[N]=NTEST8(B_REG);
	cc[Z] = ZTEST(B_REG);
	cc[V] = 0;
	CycleCounter+=2;
	break;

case ADCB_M: //C9
	postbyte=MemRead8(pc.Reg++);
	temp16= B_REG + postbyte + cc[C];
	cc[C]= (temp16 & 0x100)>>8;
	cc[V]= OTEST8(cc[C],postbyte,temp16,B_REG);
	cc[H]= ((B_REG ^ temp16 ^ postbyte) & 0x10)>>4;
	B_REG= (temp16 & 0xFF);
	cc[N]= NTEST8(B_REG);
	cc[Z]= ZTEST(B_REG);
	CycleCounter+=2;
	break;

case ORB_M: //CA
//	postbyte=MemRead8(pc.Reg++);
	B_REG = B_REG | MemRead8(pc.Reg++);
	cc[N]= NTEST8(B_REG);
	cc[Z] = ZTEST(B_REG);
	cc[V] = 0;
	CycleCounter+=2;
	break;

case ADDB_M: //CB
	postbyte=MemRead8(pc.Reg++);
	temp16=B_REG+postbyte;
	cc[C]=(temp16 & 0x100)>>8;
	cc[H]= ((B_REG ^ postbyte ^ temp16) & 0x10)>>4;
	cc[V]=OTEST8(cc[C],postbyte,temp16,B_REG);
	B_REG=(temp16 & 0xFF);
	cc[N]= NTEST8(B_REG);
	cc[Z] = ZTEST(B_REG);
	CycleCounter+=2;
	break;

case LDD_M: //CC
	D_REG=MemRead16(pc.Reg);
	cc[Z]= ZTEST(D_REG);
	cc[N]= NTEST16(D_REG);
	cc[V]= 0;
	pc.Reg+=2;
	CycleCounter+=3;
	break;

case LDU_M: //CE
	u.Reg=MemRead16(pc.Reg);
	cc[Z]= ZTEST(u.Reg);
	cc[N]= NTEST16(u.Reg);
	cc[V]= 0;
	pc.Reg+=2;
	CycleCounter+=3;
	break;

case SUBB_D: //D0
	postbyte=MemRead8( (dp.Reg |MemRead8(pc.Reg++)));
	temp16 = B_REG - postbyte;
	cc[C]=(temp16 & 0x100)>>8; 
	cc[V]= OTEST8(cc[C],postbyte,temp16,B_REG);
	B_REG=(temp16 & 0xFF);
	cc[Z] = ZTEST(B_REG);
	cc[N]= NTEST8(B_REG);
	CycleCounter+=4;
	break;

case CMPB_D: //D1
	postbyte=MemRead8((dp.Reg |MemRead8(pc.Reg++)));
	temp8= B_REG-postbyte;
	cc[C]= temp8 > B_REG;
	cc[V]= OTEST8(cc[C],postbyte,temp8,B_REG);
	cc[N]= NTEST8(temp8);
	cc[Z]= ZTEST(temp8);
	CycleCounter+=4;
	break;

case SBCB_D: //D2
	postbyte=MemRead8((dp.Reg |MemRead8(pc.Reg++)));
	temp16=B_REG-postbyte-cc[C];
	cc[C]= (temp16 & 0x100)>>8;
	cc[V]= OTEST8(cc[C],postbyte,temp16,B_REG);
	B_REG = (temp16 & 0xFF);
	cc[N]= NTEST8(B_REG);
	cc[Z]= ZTEST(B_REG);
	CycleCounter+=4;
	break;

case ADDD_D: //D3
	temp16=MemRead16( (dp.Reg |MemRead8(pc.Reg++)));
	temp32= D_REG+ temp16;
	cc[C]=(temp32 & 0x10000)>>16;
	cc[V]= OTEST16(cc[C],temp32,temp16,D_REG);
	D_REG= (temp32 & 0xFFFF);
	cc[Z]= ZTEST(D_REG);
	cc[N]= NTEST16(D_REG);
	CycleCounter+=6;
	break;

case ANDB_D: //D4 
//	postbyte=MemRead8((dp.Reg |MemRead8(pc.Reg++)));
	B_REG = B_REG & MemRead8((dp.Reg |MemRead8(pc.Reg++)));
	cc[N]=NTEST8(B_REG);
	cc[Z] = ZTEST(B_REG);
	cc[V] = 0;
	CycleCounter+=4;
	break;

case BITB_D: //D5
	temp8 = B_REG & MemRead8((dp.Reg |MemRead8(pc.Reg++)));
	cc[N]= NTEST8(temp8);
	cc[Z] = ZTEST(temp8);
	cc[V] = 0;
	CycleCounter+=4;
	break;

case LDB_D: //D6
	B_REG=MemRead8( (dp.Reg |MemRead8(pc.Reg++)));
	cc[Z] = ZTEST(B_REG);
	cc[N]= NTEST8(B_REG);
	cc[V] = 0;
	CycleCounter+=4;
	break;

case	STB_D: //D7
	MemWrite8( B_REG,(dp.Reg |MemRead8(pc.Reg++)));
	cc[Z] = ZTEST(B_REG);
	cc[N]= NTEST8(B_REG);
	cc[V] = 0;
	CycleCounter+=4;
	break;

case EORB_D: //D8	
//	postbyte=MemRead8((dp.Reg | MemRead8(pc.Reg++)));
	B_REG = B_REG ^ MemRead8((dp.Reg | MemRead8(pc.Reg++)));
	cc[N]= NTEST8(B_REG);
	cc[Z] = ZTEST(B_REG);
	cc[V] = 0;
	CycleCounter+=4;
	break;

case ADCB_D: //D9
	postbyte=MemRead8((dp.Reg |MemRead8(pc.Reg++)));
	temp16= B_REG + postbyte + cc[C];
	cc[C]= (temp16 & 0x100)>>8;
	cc[V]= OTEST8(cc[C],postbyte,temp16,B_REG);
	cc[H]= ((B_REG ^ temp16 ^ postbyte) & 0x10)>>4;
	B_REG= (temp16 & 0xFF);
	cc[N]= NTEST8(B_REG);
	cc[Z]= ZTEST(B_REG);
	CycleCounter+=4;
	break;

case ORB_D: //DA
//	postbyte=MemRead8((dp.Reg | MemRead8(pc.Reg++)));
	B_REG = B_REG | MemRead8((dp.Reg | MemRead8(pc.Reg++)));
	cc[N]= NTEST8(B_REG);
	cc[Z] = ZTEST(B_REG);
	cc[V] = 0;
	CycleCounter+=4;
	break;

case ADDB_D: //DB
	postbyte=MemRead8((dp.Reg |MemRead8(pc.Reg++)));
	temp16=B_REG+postbyte;
	cc[C]=(temp16 & 0x100)>>8;
	cc[H]= ((B_REG ^ postbyte ^ temp16) & 0x10)>>4;
	cc[V]=OTEST8(cc[C],postbyte,temp16,B_REG);
	B_REG=(temp16 & 0xFF);
	cc[N]= NTEST8(B_REG);
	cc[Z] = ZTEST(B_REG);
	CycleCounter+=4;
	break;

case LDD_D: //DC
	D_REG=MemRead16((dp.Reg | MemRead8(pc.Reg++)));
	cc[Z]= ZTEST(D_REG);
	cc[N]= NTEST16(D_REG);
	cc[V]= 0;
	CycleCounter+=5;
	break;

case STD_D: //DD
	MemWrite16(D_REG,(dp.Reg |MemRead8(pc.Reg++)));
	cc[Z]= ZTEST(D_REG);
	cc[N]= NTEST16(D_REG);
	cc[V]= 0;
	CycleCounter+=5;
	break;

case LDU_D: //DE
	u.Reg=MemRead16((dp.Reg |MemRead8(pc.Reg++)));
	cc[Z]= ZTEST(u.Reg);
	cc[N]= NTEST16(u.Reg);
	cc[V]= 0;
	CycleCounter+=5;
	break;

case STU_D: //DF
	MemWrite16(u.Reg,(dp.Reg |MemRead8(pc.Reg++)));
	cc[Z]= ZTEST(u.Reg);
	cc[N]= NTEST16(u.Reg);
	cc[V]= 0;
	CycleCounter+=5;
	break;

case SUBB_X: //E0
	postbyte=MemRead8(CalculateEA(MemRead8(pc.Reg++)));
	temp16 = B_REG - postbyte;
	cc[C]= (temp16 & 0x100)>>8; 
	cc[V]= OTEST8(cc[C],postbyte,temp16,B_REG);
	B_REG= (temp16 & 0xFF);
	cc[Z]= ZTEST(B_REG);
	cc[N]= NTEST8(B_REG);
	CycleCounter+=4;
	break;

case CMPB_X: //E1
	postbyte=MemRead8(CalculateEA(MemRead8(pc.Reg++)));
	temp8= B_REG-postbyte;
	cc[C]= temp8 > B_REG;
	cc[V]= OTEST8(cc[C],postbyte,temp8,B_REG);
	cc[N]= NTEST8(temp8);
	cc[Z]= ZTEST(temp8);
	CycleCounter+=4;
	break;

case SBCB_X: //E2
	postbyte=MemRead8(CalculateEA(MemRead8(pc.Reg++)));
	temp16=B_REG-postbyte-cc[C];
	cc[C]= (temp16 & 0x100)>>8;
	cc[V]= OTEST8(cc[C],postbyte,temp16,B_REG);
	B_REG = (temp16 & 0xFF);
	cc[N]= NTEST8(B_REG);
	cc[Z]= ZTEST(B_REG);
	CycleCounter+=4;
	break;

case ADDD_X: //E3 
	temp16=MemRead16(CalculateEA(MemRead8(pc.Reg++)));
	temp32= D_REG+ temp16;
	cc[C]=(temp32 & 0x10000)>>16;
	cc[V]= OTEST16(cc[C],temp32,temp16,D_REG);
	D_REG= (temp32 & 0xFFFF);
	cc[Z]= ZTEST(D_REG);
	cc[N]= NTEST16(D_REG);
	CycleCounter+=6;
	break;

case ANDB_X: //E4
//	postbyte=MemRead8(CalculateEA(MemRead8(pc.Reg++)));
	B_REG = B_REG & MemRead8(CalculateEA(MemRead8(pc.Reg++)));
	cc[N]= NTEST8(B_REG);
	cc[Z]= ZTEST(B_REG);
	cc[V]= 0;
	CycleCounter+=4;
	break;

case BITB_X: //E5 
	temp8 = B_REG & MemRead8(CalculateEA(MemRead8(pc.Reg++)));
	cc[N]= NTEST8(temp8);
	cc[Z]= ZTEST(temp8);
	cc[V] = 0;
	CycleCounter+=4;
	break;

case LDB_X: //E6
	B_REG=MemRead8(CalculateEA(MemRead8(pc.Reg++)));
	cc[Z]= ZTEST(B_REG);
	cc[N]= NTEST8(B_REG);
	cc[V]= 0;
	CycleCounter+=4;
	break;

case STB_X: //E7
//	postbyte=MemRead8(pc.Reg++);
	MemWrite8(B_REG,CalculateEA(MemRead8(pc.Reg++)));
	cc[Z]= ZTEST(B_REG);
	cc[N]= NTEST8(B_REG);
	cc[V]= 0;
	CycleCounter+=4;
	break;

case EORB_X: //E8
//	postbyte=MemRead8(pc.Reg++);
//	temp16=CalculateEA(MemRead8(pc.Reg++));
	temp8=MemRead8(CalculateEA(MemRead8(pc.Reg++)));
	B_REG= B_REG ^ temp8;
	cc[N]= NTEST8(B_REG);
	cc[Z] = ZTEST(B_REG);
	cc[V] = 0;
	CycleCounter+=4;
	break;

case ADCB_X: //E9
	postbyte=MemRead8(CalculateEA(MemRead8(pc.Reg++)));
	temp16= B_REG + postbyte + cc[C];
	cc[C]= (temp16 & 0x100)>>8;
	cc[V]= OTEST8(cc[C],postbyte,temp16,B_REG);
	cc[H]= ((B_REG ^ temp16 ^ postbyte) & 0x10)>>4;
	B_REG= (temp16 & 0xFF);
	cc[N]= NTEST8(B_REG);
	cc[Z]= ZTEST(B_REG);
	CycleCounter+=4;
	break;

case ORB_X: //EA 
//	postbyte=MemRead8(CalculateEA(MemRead8(pc.Reg++)));
	B_REG = B_REG | MemRead8(CalculateEA(MemRead8(pc.Reg++)));
	cc[N]= NTEST8(B_REG);
	cc[Z] = ZTEST(B_REG);
	cc[V] = 0;
	CycleCounter+=4;

	break;

case ADDB_X: //EB
	postbyte=MemRead8(CalculateEA(MemRead8(pc.Reg++)));
	temp16=B_REG+postbyte;
	cc[C]=(temp16 & 0x100)>>8;
	cc[H]= ((B_REG ^ postbyte ^ temp16) & 0x10)>>4;
	cc[V]=OTEST8(cc[C],postbyte,temp16,B_REG);
	B_REG=(temp16 & 0xFF);
	cc[N]= NTEST8(B_REG);
	cc[Z] = ZTEST(B_REG);
	CycleCounter+=4;
	break;

case LDD_X: //EC
//	postbyte=MemRead8(pc.Reg++);
	temp16=CalculateEA(MemRead8(pc.Reg++));
	D_REG=MemRead16(temp16);
	cc[Z]= ZTEST(D_REG);
	cc[N]= NTEST16(D_REG);
	cc[V] = 0;
	CycleCounter+=5;
	break;

case STD_X: //ED
//	postbyte=MemRead8(pc.Reg++);
//	temp16=CalculateEA(MemRead8(pc.Reg++));
	MemWrite16(D_REG,CalculateEA(MemRead8(pc.Reg++)));
	cc[Z]= ZTEST(D_REG);
	cc[N]= NTEST16(D_REG);
	cc[V] = 0;
	CycleCounter+=5;
	break;

case LDU_X: //EE
	u.Reg=MemRead16(CalculateEA(MemRead8(pc.Reg++)));
	cc[Z] = ZTEST(u.Reg);
	cc[N]=NTEST16(u.Reg);
	cc[V] = 0;
	CycleCounter+=5;
	break;

case STU_X: //EF
//	postbyte=MemRead8(pc.Reg++);
//	temp16=CalculateEA(MemRead8(pc.Reg++));
	MemWrite16(u.Reg,CalculateEA(MemRead8(pc.Reg++)));
	cc[Z] = ZTEST(u.Reg);
	cc[N]=NTEST16(u.Reg);
	cc[V] = 0;
	CycleCounter+=5;
	break;

case SUBB_E: //F0
	postbyte=MemRead8(MemRead16(pc.Reg));
	temp16 = B_REG - postbyte;
	cc[C]=(temp16 & 0x100)>>8; 
	cc[V]= OTEST8(cc[C],postbyte,temp16,B_REG);
	B_REG=(temp16 & 0xFF);
	cc[Z] = ZTEST(B_REG);
	cc[N]= NTEST8(B_REG);
	pc.Reg+=2;
	CycleCounter+=5;
	break;

case CMPB_E: //F1
	postbyte=MemRead8(MemRead16(pc.Reg));
	temp8= B_REG-postbyte;
	cc[C]= temp8 > B_REG;
	cc[V]= OTEST8(cc[C],postbyte,temp8,B_REG);
	cc[N]= NTEST8(temp8);
	cc[Z]= ZTEST(temp8);
	pc.Reg+=2;
	CycleCounter+=5;
	break;

case SBCB_E: //F2
	postbyte=MemRead8(MemRead16(pc.Reg));
	temp16=B_REG-postbyte-cc[C];
	cc[C]= (temp16 & 0x100)>>8;
	cc[V]= OTEST8(cc[C],postbyte,temp16,B_REG);
	B_REG = (temp16 & 0xFF);
	cc[N]= NTEST8(B_REG);
	cc[Z]= ZTEST(B_REG);
	pc.Reg+=2;
	CycleCounter+=5;
	break;

case ADDD_E: //F3
	temp16=MemRead16(MemRead16(pc.Reg));
	temp32= D_REG+ temp16;
	cc[C]=(temp32 & 0x10000)>>16;
	cc[V]= OTEST16(cc[C],temp32,temp16,D_REG);
	D_REG= (temp32 & 0xFFFF);
	cc[Z]= ZTEST(D_REG);
	cc[N]= NTEST16(D_REG);
	pc.Reg+=2;
	CycleCounter+=7;
	break;

case ANDB_E:  //F4
//	postbyte=MemRead8(MemRead16(pc.Reg));
	B_REG = B_REG & MemRead8(MemRead16(pc.Reg));
	cc[N]= NTEST8(B_REG);
	cc[Z]= ZTEST(B_REG);
	cc[V]= 0;
	pc.Reg+=2;
	CycleCounter+=5;
	break;

case BITB_E: //F5
	temp8 = B_REG & MemRead8(MemRead16(pc.Reg));
	cc[N]= NTEST8(temp8);
	cc[Z]= ZTEST(temp8);
	cc[V]= 0;
	pc.Reg+=2;
	CycleCounter+=5;
	break;

case LDB_E: //F6
	B_REG=MemRead8(MemRead16(pc.Reg));
	cc[Z] = ZTEST(B_REG);
	cc[N]= NTEST8(B_REG);
	cc[V] = 0;
	pc.Reg+=2;
	CycleCounter+=5;
	break;

case STB_E: //F7 
	MemWrite8(B_REG,MemRead16(pc.Reg));
	cc[Z] = ZTEST(B_REG);
	cc[N] = NTEST8(B_REG);
	cc[V] = 0;
	pc.Reg+=2;
	CycleCounter+=5;
	break;

case EORB_E: //F8
//	postbyte=MemRead8(MemRead16(pc.Reg));
	B_REG = B_REG ^ MemRead8(MemRead16(pc.Reg));
	cc[N]= NTEST8(B_REG);
	cc[Z] = ZTEST(B_REG);
	cc[V] = 0;
	pc.Reg+=2;
	CycleCounter+=5;
	break;

case ADCB_E: //F9
	postbyte=MemRead8(MemRead16(pc.Reg));
	temp16= B_REG + postbyte + cc[C];
	cc[C]= (temp16 & 0x100)>>8;
	cc[V]= OTEST8(cc[C],postbyte,temp16,B_REG);
	cc[H]= ((B_REG ^ temp16 ^ postbyte) & 0x10)>>4;
	B_REG= (temp16 & 0xFF);
	cc[N]= NTEST8(B_REG);
	cc[Z]= ZTEST(B_REG);
	pc.Reg+=2;
	CycleCounter+=5;
	break;

case ORB_E: //FA
//	postbyte=MemRead8(MemRead16(pc.Reg));
	B_REG = B_REG | MemRead8(MemRead16(pc.Reg));
	cc[N]= NTEST8(B_REG);
	cc[Z] = ZTEST(B_REG);
	cc[V] = 0;
	pc.Reg+=2;
	CycleCounter+=5;
	break;

case ADDB_E: //FB
	postbyte=MemRead8(MemRead16(pc.Reg));
	temp16=B_REG+postbyte;
	cc[C]=(temp16 & 0x100)>>8;
	cc[H]= ((B_REG ^ postbyte ^ temp16) & 0x10)>>4;
	cc[V]= OTEST8(cc[C],postbyte,temp16,B_REG);
	B_REG=(temp16 & 0xFF);
	cc[N]= NTEST8(B_REG);
	cc[Z] = ZTEST(B_REG);
	pc.Reg+=2;
	CycleCounter+=5;
	break;

case LDD_E: //FC
	D_REG=MemRead16(MemRead16(pc.Reg));
	cc[Z]= ZTEST(D_REG);
	cc[N]= NTEST16(D_REG);
	cc[V]= 0;
	pc.Reg+=2;
	CycleCounter+=6;
	break;

case STD_E: //FD
	MemWrite16(D_REG,MemRead16(pc.Reg));
	cc[Z]= ZTEST(D_REG);
	cc[N]=NTEST16(D_REG);
	cc[V] = 0;
	pc.Reg+=2;
	CycleCounter+=6;
	break;

case LDU_E: //FE
//	postword=MemRead16(pc.Reg);
	u.Reg=MemRead16(MemRead16(pc.Reg));
	cc[Z] = ZTEST(u.Reg);
	cc[N]= NTEST16(u.Reg);
	cc[V] = 0;
	pc.Reg+=2;
	CycleCounter+=6;
	break;

case STU_E: //FF
	MemWrite16(u.Reg,MemRead16(pc.Reg));
	cc[Z] = ZTEST(u.Reg);
	cc[N]= NTEST16(u.Reg);
	cc[V] = 0;
	pc.Reg+=2;
	CycleCounter+=6;
	break;

default:
//	MessageBox(0,"Unhandled Op","Ok",0);
	break;
	}//End Switch

	if (EmuState.Debugger.IsTracing())
	{
		EmuState.Debugger.TraceCaptureAfter(CycleCounter, MC6809GetState());
	}

	// CPU is stepped.
	if (EmuState.Debugger.IsStepping())
	{
		EmuState.Debugger.Halt();
		break;
	}

    if (JS_Ramp_Clock < 0xFFFF) {
        JS_Ramp_Clock += CycleCounter-PrevCycleCount;
    }
    PrevCycleCount = CycleCounter;

}//End While

return(CycleFor-CycleCounter);

}

void cpu_firq(void)
{

	if (!cc[F])
	{
		if (EmuState.Debugger.IsTracing())
		{
			EmuState.Debugger.TraceCaptureInterruptServicing(FIRQ, CycleCounter, MC6809GetState());
		}

		InInterupt=1; //Flag to indicate FIRQ has been asserted
		cc[E]=0; // Turn E flag off
		MemWrite8( pc.B.lsb,--s.Reg);
		MemWrite8( pc.B.msb,--s.Reg);
		MemWrite8(getcc(),--s.Reg);
		cc[I]=1;
		cc[F]=1;
		pc.Reg=MemRead16(VFIRQ);

		CycleCounter += 15;			// 10 Cycles to respond, 5 cycles to stack and load PC.

		if (EmuState.Debugger.IsTracing())
		{
			EmuState.Debugger.TraceCaptureInterruptExecuting(FIRQ, CycleCounter, MC6809GetState());
		}

	}
	else
	{
		if (EmuState.Debugger.IsTracing())
		{
			EmuState.Debugger.TraceCaptureInterruptMasked(FIRQ, CycleCounter, MC6809GetState());
		}
	}
	PendingInterupts=PendingInterupts & 253;
	return;
}

void cpu_irq(void)
{
	if (InInterupt==1) //If FIRQ is running postpone the IRQ
		return;			
	if ((!cc[I]) )
	{
		if (EmuState.Debugger.IsTracing())
		{
			EmuState.Debugger.TraceCaptureInterruptServicing(IRQ, CycleCounter, MC6809GetState());
		}

		cc[E]=1;
		MemWrite8( pc.B.lsb,--s.Reg);
		MemWrite8( pc.B.msb,--s.Reg);
		MemWrite8( u.B.lsb,--s.Reg);
		MemWrite8( u.B.msb,--s.Reg);
		MemWrite8( y.B.lsb,--s.Reg);
		MemWrite8( y.B.msb,--s.Reg);
		MemWrite8( x.B.lsb,--s.Reg);
		MemWrite8( x.B.msb,--s.Reg);
		MemWrite8( dp.B.msb,--s.Reg);
		MemWrite8(B_REG,--s.Reg);
		MemWrite8(A_REG,--s.Reg);
		MemWrite8(getcc(),--s.Reg);

		pc.Reg=MemRead16(VIRQ);
		cc[I]=1; 

		CycleCounter += 24;			// 10 Cycles to respond, 14 cycles to stack and load PC.

		if (EmuState.Debugger.IsTracing())
		{
			EmuState.Debugger.TraceCaptureInterruptExecuting(IRQ, CycleCounter, MC6809GetState());
		}
	}
	else
	{
		if (EmuState.Debugger.IsTracing())
		{
			EmuState.Debugger.TraceCaptureInterruptMasked(IRQ, CycleCounter, MC6809GetState());
		}
	}
	PendingInterupts=PendingInterupts & 254;
	return;
}

void cpu_nmi(void)
{
	if (EmuState.Debugger.IsTracing())
	{
		EmuState.Debugger.TraceCaptureInterruptServicing(NMI, CycleCounter, MC6809GetState());
	}

	cc[E]=1;
	MemWrite8( pc.B.lsb,--s.Reg);
	MemWrite8( pc.B.msb,--s.Reg);
	MemWrite8( u.B.lsb,--s.Reg);
	MemWrite8( u.B.msb,--s.Reg);
	MemWrite8( y.B.lsb,--s.Reg);
	MemWrite8( y.B.msb,--s.Reg);
	MemWrite8( x.B.lsb,--s.Reg);
	MemWrite8( x.B.msb,--s.Reg);
	MemWrite8( dp.B.msb,--s.Reg);
	MemWrite8(B_REG,--s.Reg);
	MemWrite8(A_REG,--s.Reg);
	MemWrite8(getcc(),--s.Reg);
	cc[I]=1;
	cc[F]=1;
	pc.Reg=MemRead16(VNMI);

	CycleCounter += 24;			// 10 Cycles to respond, 14 cycles to stack and load PC.

	if (EmuState.Debugger.IsTracing())
	{
		EmuState.Debugger.TraceCaptureInterruptExecuting(NMI, CycleCounter, MC6809GetState());
	}

	PendingInterupts=PendingInterupts & 251;
	return;
}

/*
_inline unsigned short CalculateEA(unsigned char postbyte)
{
	static unsigned short int ea=0;
	static signed char byte=0;
	static unsigned char Register;
	Register= ((postbyte>>5)&3)+1;
	if (postbyte & 0x80) 
	{
		switch (postbyte & 0x1F)
		{
		case 0:
			ea=(*xfreg16[Register]);
			(*xfreg16[Register])++;
			CycleCounter+=2;
			break;

		case 1:
			ea=(*xfreg16[Register]);
			(*xfreg16[Register])+=2;
			CycleCounter+=3;
			break;

		case 2:
			(*xfreg16[Register])-=1;
			ea=(*xfreg16[Register]);
			CycleCounter+=2;
			break;

		case 3:
			(*xfreg16[Register])-=2;
			ea=(*xfreg16[Register]);
			CycleCounter+=3;
			break;

		case 4:
			ea=(*xfreg16[Register]);
			break;

		case 5:
			ea=(*xfreg16[Register])+((signed char)B_REG);
			CycleCounter+=1;
			break;

		case 6:
			ea=(*xfreg16[Register])+((signed char)A_REG);
			CycleCounter+=1;
			break;

		case 7:

			break;

		case 8:
			ea=(*xfreg16[Register])+(signed char)MemRead8(pc.Reg++);
			CycleCounter+=1;
			break;

		case 9:
			ea=(*xfreg16[Register])+MemRead16(pc.Reg);
			CycleCounter+=4;
			pc.Reg+=2;
			break;

		case 10:

			break;

		case 11:
			ea=(*xfreg16[Register])+D_REG; //Changed to unsigned 03/14/2005 NG Was signed
			CycleCounter+=4;
			break;

		case 12:
			ea=(signed short)pc.Reg+(signed char)MemRead8(pc.Reg)+1; 
			CycleCounter+=1;
			pc.Reg++;
			break;

		case 13: //MM
			ea=pc.Reg+MemRead16(pc.Reg)+2; 
			CycleCounter+=5;
			pc.Reg+=2;
			break;

		case 14:

			break;

		case 15: //01111
			byte=(postbyte>>5)&3;
			switch (byte)
			{
			case 0:

				break;
			case 1:

				break;
			case 2:

				break;
			case 3:

				break;
			}
		break;

		case 16: //10000
			byte=(postbyte>>5)&3;
			switch (byte)
			{
			case 0:

				break;
			case 1:

				break;
			case 2:

				break;
			case 3:

				break;
			}
		break;


		case 17: //10001
			ea=(*xfreg16[Register]);
			(*xfreg16[Register])+=2;
			ea=MemRead16(ea);
			CycleCounter+=6;
			break;

		case 18: //10010 //Illegal
			CycleCounter+=6;
			break;

		case 19: //10011
			(*xfreg16[Register])-=2;
			ea=(*xfreg16[Register]);
			ea=MemRead16(ea);
			CycleCounter+=6;
			break;

		case 20: //10100
			ea=(*xfreg16[Register]);
			ea=MemRead16(ea);
			CycleCounter+=3;
			break;

		case 21: //10101
			ea=(*xfreg16[Register])+((signed char)B_REG);
			ea=MemRead16(ea);
			CycleCounter+=4;
			break;

		case 22: //10110
			ea=(*xfreg16[Register])+((signed char)A_REG);
			ea=MemRead16(ea);
			CycleCounter+=4;
			break;

		case 23: //10111

			break;

		case 24: //11000
			ea=(*xfreg16[Register])+(signed char)MemRead8(pc.Reg++);
			ea=MemRead16(ea);
			CycleCounter+=4;
			break;

		case 25: //11001
			ea=(*xfreg16[Register])+MemRead16(pc.Reg);
			ea=MemRead16(ea);
			CycleCounter+=7;
			pc.Reg+=2;
			break;
		case 26: //11010

			break;

		case 27: //11011
			ea=(*xfreg16[Register])+D_REG;
			ea=MemRead16(ea);
			CycleCounter+=7;
			break;

		case 28: //11100
			ea=(signed short)pc.Reg+(signed char)MemRead8(pc.Reg)+1; 
			ea=MemRead16(ea);
			CycleCounter+=4;
			pc.Reg++;
			break;

		case 29: //11101
			ea=pc.Reg+MemRead16(pc.Reg)+2; 
			ea=MemRead16(ea);
			CycleCounter+=8;
			pc.Reg+=2;
			break;

		case 30: //11110

			break;

		case 31: //11111
			ea=MemRead16(pc.Reg);
			ea=MemRead16(ea);
			CycleCounter+=8;
			pc.Reg+=2;
			break;

		} //END Switch
	}
	else 
	{
		byte= (postbyte & 31);
		byte= (byte << 3);
		byte= byte /8;
		ea= *xfreg16[Register]+byte; //Was signed
		CycleCounter+=1;
	}
return(ea);
}
*/


void setcc (unsigned char bincc)
{
	unsigned char bit;
	for (bit=0;bit<=7;bit++)
		cc[bit]=!!(bincc & (1<<bit));
	return;
}

unsigned char getcc(void)
{
	unsigned char bincc=0,bit=0;
	for (bit=0;bit<=7;bit++)
		if (cc[bit])
			bincc=bincc | (1<<bit);
		return(bincc);
}

void MC6809AssertInterupt(unsigned char Interupt,unsigned char waiter)// 4 nmi 2 firq 1 irq
{
	SyncWaiting=0;
	PendingInterupts=PendingInterupts | (1<<(Interupt-1));
	IRQWaiter=waiter;
	if (EmuState.Debugger.IsTracing())
	{
		EmuState.Debugger.TraceCaptureInterruptRequest(Interupt, CycleCounter, MC6809GetState());
	}
	return;
}

void MC6809DeAssertInterupt(unsigned char Interupt)// 4 nmi 2 firq 1 irq
{
	PendingInterupts=PendingInterupts & ~(1<<(Interupt-1));
	InInterupt=0;
	return;
}

void MC6809ForcePC(unsigned short NewPC)
{
	pc.Reg=NewPC;
	PendingInterupts=0;
	SyncWaiting=0;
	return;
}

static unsigned short CalculateEA(unsigned char postbyte)
{
	static unsigned short int ea=0;
	static signed char byte=0;
	static unsigned char Register;

	Register= ((postbyte>>5)&3)+1;

	if (postbyte & 0x80) 
	{
		switch (postbyte & 0x1F)
		{
		case 0:
			ea=(*xfreg16[Register]);
			(*xfreg16[Register])++;
			CycleCounter+=2;
			break;

		case 1:
			ea=(*xfreg16[Register]);
			(*xfreg16[Register])+=2;
			CycleCounter+=3;
			break;

		case 2:
			(*xfreg16[Register])-=1;
			ea=(*xfreg16[Register]);
			CycleCounter+=2;
			break;

		case 3:
			(*xfreg16[Register])-=2;
			ea=(*xfreg16[Register]);
			CycleCounter+=3;
			break;

		case 4:
			ea=(*xfreg16[Register]);
			break;

		case 5:
			ea=(*xfreg16[Register])+((signed char)B_REG);
			CycleCounter+=1;
			break;

		case 6:
			ea=(*xfreg16[Register])+((signed char)A_REG);
			CycleCounter+=1;
			break;

		case 7:
//			ea=(*xfreg16[Register])+((signed char)E_REG);
			CycleCounter+=1;
			break;

		case 8:
			ea=(*xfreg16[Register])+(signed char)MemRead8(pc.Reg++);
			CycleCounter+=1;
			break;

		case 9:
			ea=(*xfreg16[Register])+MemRead16(pc.Reg);
			CycleCounter+=4;
			pc.Reg+=2;
			break;

		case 10:
//			ea=(*xfreg16[Register])+((signed char)F_REG);
			CycleCounter+=1;
			break;

		case 11:
			ea=(*xfreg16[Register])+D_REG; //Changed to unsigned 03/14/2005 NG Was signed
			CycleCounter+=4;
			break;

		case 12:
			ea=(signed short)pc.Reg+(signed char)MemRead8(pc.Reg)+1; 
			CycleCounter+=1;
			pc.Reg++;
			break;

		case 13: //MM
			ea=pc.Reg+MemRead16(pc.Reg)+2; 
			CycleCounter+=5;
			pc.Reg+=2;
			break;

		case 14:
//			ea=(*xfreg16[Register])+W_REG; 
			CycleCounter+=4;
			break;

		case 15: //01111
			byte=(postbyte>>5)&3;
			switch (byte)
			{
			case 0:
//				ea=W_REG;
				break;
			case 1:
//				ea=W_REG+MemRead16(pc.Reg);
				pc.Reg+=2;
				break;
			case 2:
//				ea=W_REG;
//				W_REG+=2;
				break;
			case 3:
//				W_REG-=2;
//				ea=W_REG;
				break;
			}
		break;

		case 16: //10000
			byte=(postbyte>>5)&3;
			switch (byte)
			{
			case 0:
//				ea=MemRead16(W_REG);
				break;
			case 1:
//				ea=MemRead16(W_REG+MemRead16(pc.Reg));
				pc.Reg+=2;
				break;
			case 2:
//				ea=MemRead16(W_REG);
//				W_REG+=2;
				break;
			case 3:
//				W_REG-=2;
//				ea=MemRead16(W_REG);
				break;
			}
		break;


		case 17: //10001
			ea=(*xfreg16[Register]);
			(*xfreg16[Register])+=2;
			ea=MemRead16(ea);
			CycleCounter+=6;
			break;

		case 18: //10010
//			MessageBox(0,"Hitting undecoded 18","Ok",0);
			CycleCounter+=6;
			break;

		case 19: //10011
			(*xfreg16[Register])-=2;
			ea=(*xfreg16[Register]);
			ea=MemRead16(ea);
			CycleCounter+=6;
			break;

		case 20: //10100
			ea=(*xfreg16[Register]);
			ea=MemRead16(ea);
			CycleCounter+=3;
			break;

		case 21: //10101
			ea=(*xfreg16[Register])+((signed char)B_REG);
			ea=MemRead16(ea);
			CycleCounter+=4;
			break;

		case 22: //10110
			ea=(*xfreg16[Register])+((signed char)A_REG);
			ea=MemRead16(ea);
			CycleCounter+=4;
			break;

		case 23: //10111
//			ea=(*xfreg16[Register])+((signed char)E_REG);
			ea=MemRead16(ea);
			CycleCounter+=4;
			break;

		case 24: //11000
			ea=(*xfreg16[Register])+(signed char)MemRead8(pc.Reg++);
			ea=MemRead16(ea);
			CycleCounter+=4;
			break;

		case 25: //11001
			ea=(*xfreg16[Register])+MemRead16(pc.Reg);
			ea=MemRead16(ea);
			CycleCounter+=7;
			pc.Reg+=2;
			break;
		case 26: //11010
//			ea=(*xfreg16[Register])+((signed char)F_REG);
			ea=MemRead16(ea);
			CycleCounter+=4;
			break;

		case 27: //11011
			ea=(*xfreg16[Register])+D_REG;
			ea=MemRead16(ea);
			CycleCounter+=7;
			break;

		case 28: //11100
			ea=(signed short)pc.Reg+(signed char)MemRead8(pc.Reg)+1; 
			ea=MemRead16(ea);
			CycleCounter+=4;
			pc.Reg++;
			break;

		case 29: //11101
			ea=pc.Reg+MemRead16(pc.Reg)+2; 
			ea=MemRead16(ea);
			CycleCounter+=8;
			pc.Reg+=2;
			break;

		case 30: //11110
//			ea=(*xfreg16[Register])+W_REG; 
			ea=MemRead16(ea);
			CycleCounter+=7;
			break;

		case 31: //11111
			ea=MemRead16(pc.Reg);
			ea=MemRead16(ea);
			CycleCounter+=8;
			pc.Reg+=2;
			break;

		} //END Switch
	}
	else 
	{
		byte= (postbyte & 31);
		byte= (byte << 3);
		byte= byte /8;
		ea= *xfreg16[Register]+byte; //Was signed
		CycleCounter+=1;
	}
return(ea);
}