dosbox-wii/src/cpu/flags.cpp

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2010-11-05 05:55:33 +01:00
/*
* Copyright (C) 2002-2010 The DOSBox Team
*
* This program 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 2 of the License, or
* (at your option) any later version.
*
* This program 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 this program; if not, write to the Free Software
* Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA.
*/
/*
Lazy flag system was designed after the same kind of system used in Bochs.
Probably still some bugs left in here.
*/
#include "dosbox.h"
#include "cpu.h"
#include "lazyflags.h"
#include "pic.h"
LazyFlags lflags;
/* CF Carry Flag -- Set on high-order bit carry or borrow; cleared
otherwise.
*/
Bit32u get_CF(void) {
switch (lflags.type) {
case t_UNKNOWN:
case t_INCb:
case t_INCw:
case t_INCd:
case t_DECb:
case t_DECw:
case t_DECd:
case t_MUL:
return GETFLAG(CF);
case t_ADDb:
return (lf_resb<lf_var1b);
case t_ADDw:
return (lf_resw<lf_var1w);
case t_ADDd:
return (lf_resd<lf_var1d);
case t_ADCb:
return (lf_resb < lf_var1b) || (lflags.oldcf && (lf_resb == lf_var1b));
case t_ADCw:
return (lf_resw < lf_var1w) || (lflags.oldcf && (lf_resw == lf_var1w));
case t_ADCd:
return (lf_resd < lf_var1d) || (lflags.oldcf && (lf_resd == lf_var1d));
case t_SBBb:
return (lf_var1b < lf_resb) || (lflags.oldcf && (lf_var2b==0xff));
case t_SBBw:
return (lf_var1w < lf_resw) || (lflags.oldcf && (lf_var2w==0xffff));
case t_SBBd:
return (lf_var1d < lf_resd) || (lflags.oldcf && (lf_var2d==0xffffffff));
case t_SUBb:
case t_CMPb:
return (lf_var1b<lf_var2b);
case t_SUBw:
case t_CMPw:
return (lf_var1w<lf_var2w);
case t_SUBd:
case t_CMPd:
return (lf_var1d<lf_var2d);
case t_SHLb:
if (lf_var2b>8) return false;
else return (lf_var1b >> (8-lf_var2b)) & 1;
case t_SHLw:
if (lf_var2b>16) return false;
else return (lf_var1w >> (16-lf_var2b)) & 1;
case t_SHLd:
case t_DSHLw: /* Hmm this is not correct for shift higher than 16 */
case t_DSHLd:
return (lf_var1d >> (32 - lf_var2b)) & 1;
case t_RCRb:
case t_SHRb:
return (lf_var1b >> (lf_var2b - 1)) & 1;
case t_RCRw:
case t_SHRw:
return (lf_var1w >> (lf_var2b - 1)) & 1;
case t_RCRd:
case t_SHRd:
case t_DSHRw: /* Hmm this is not correct for shift higher than 16 */
case t_DSHRd:
return (lf_var1d >> (lf_var2b - 1)) & 1;
case t_SARb:
return (((Bit8s) lf_var1b) >> (lf_var2b - 1)) & 1;
case t_SARw:
return (((Bit16s) lf_var1w) >> (lf_var2b - 1)) & 1;
case t_SARd:
return (((Bit32s) lf_var1d) >> (lf_var2b - 1)) & 1;
case t_NEGb:
return lf_var1b;
case t_NEGw:
return lf_var1w;
case t_NEGd:
return lf_var1d;
case t_ORb:
case t_ORw:
case t_ORd:
case t_ANDb:
case t_ANDw:
case t_ANDd:
case t_XORb:
case t_XORw:
case t_XORd:
case t_TESTb:
case t_TESTw:
case t_TESTd:
return false; /* Set to false */
case t_DIV:
return false; /* Unkown */
default:
LOG(LOG_CPU,LOG_ERROR)("get_CF Unknown %d",lflags.type);
}
return 0;
}
/* AF Adjust flag -- Set on carry from or borrow to the low order
four bits of AL; cleared otherwise. Used for decimal
arithmetic.
*/
Bit32u get_AF(void) {
Bitu type=lflags.type;
switch (type) {
case t_UNKNOWN:
return GETFLAG(AF);
case t_ADDb:
case t_ADCb:
case t_SBBb:
case t_SUBb:
case t_CMPb:
return ((lf_var1b ^ lf_var2b) ^ lf_resb) & 0x10;
case t_ADDw:
case t_ADCw:
case t_SBBw:
case t_SUBw:
case t_CMPw:
return ((lf_var1w ^ lf_var2w) ^ lf_resw) & 0x10;
case t_ADCd:
case t_ADDd:
case t_SBBd:
case t_SUBd:
case t_CMPd:
return ((lf_var1d ^ lf_var2d) ^ lf_resd) & 0x10;
case t_INCb:
return (lf_resb & 0x0f) == 0;
case t_INCw:
return (lf_resw & 0x0f) == 0;
case t_INCd:
return (lf_resd & 0x0f) == 0;
case t_DECb:
return (lf_resb & 0x0f) == 0x0f;
case t_DECw:
return (lf_resw & 0x0f) == 0x0f;
case t_DECd:
return (lf_resd & 0x0f) == 0x0f;
case t_NEGb:
return lf_var1b & 0x0f;
case t_NEGw:
return lf_var1w & 0x0f;
case t_NEGd:
return lf_var1d & 0x0f;
case t_SHLb:
case t_SHRb:
case t_SARb:
return lf_var2b & 0x1f;
case t_SHLw:
case t_SHRw:
case t_SARw:
return lf_var2w & 0x1f;
case t_SHLd:
case t_SHRd:
case t_SARd:
return lf_var2d & 0x1f;
case t_ORb:
case t_ORw:
case t_ORd:
case t_ANDb:
case t_ANDw:
case t_ANDd:
case t_XORb:
case t_XORw:
case t_XORd:
case t_TESTb:
case t_TESTw:
case t_TESTd:
case t_DSHLw:
case t_DSHLd:
case t_DSHRw:
case t_DSHRd:
case t_DIV:
case t_MUL:
return false; /* Unkown */
default:
LOG(LOG_CPU,LOG_ERROR)("get_AF Unknown %d",lflags.type);
}
return 0;
}
/* ZF Zero Flag -- Set if result is zero; cleared otherwise.
*/
Bit32u get_ZF(void) {
Bitu type=lflags.type;
switch (type) {
case t_UNKNOWN:
return GETFLAG(ZF);
case t_ADDb:
case t_ORb:
case t_ADCb:
case t_SBBb:
case t_ANDb:
case t_XORb:
case t_SUBb:
case t_CMPb:
case t_INCb:
case t_DECb:
case t_TESTb:
case t_SHLb:
case t_SHRb:
case t_SARb:
case t_NEGb:
return (lf_resb==0);
case t_ADDw:
case t_ORw:
case t_ADCw:
case t_SBBw:
case t_ANDw:
case t_XORw:
case t_SUBw:
case t_CMPw:
case t_INCw:
case t_DECw:
case t_TESTw:
case t_SHLw:
case t_SHRw:
case t_SARw:
case t_DSHLw:
case t_DSHRw:
case t_NEGw:
return (lf_resw==0);
case t_ADDd:
case t_ORd:
case t_ADCd:
case t_SBBd:
case t_ANDd:
case t_XORd:
case t_SUBd:
case t_CMPd:
case t_INCd:
case t_DECd:
case t_TESTd:
case t_SHLd:
case t_SHRd:
case t_SARd:
case t_DSHLd:
case t_DSHRd:
case t_NEGd:
return (lf_resd==0);
case t_DIV:
case t_MUL:
return false; /* Unkown */
default:
LOG(LOG_CPU,LOG_ERROR)("get_ZF Unknown %d",lflags.type);
}
return false;
}
/* SF Sign Flag -- Set equal to high-order bit of result (0 is
positive, 1 if negative).
*/
Bit32u get_SF(void) {
Bitu type=lflags.type;
switch (type) {
case t_UNKNOWN:
return GETFLAG(SF);
case t_ADDb:
case t_ORb:
case t_ADCb:
case t_SBBb:
case t_ANDb:
case t_XORb:
case t_SUBb:
case t_CMPb:
case t_INCb:
case t_DECb:
case t_TESTb:
case t_SHLb:
case t_SHRb:
case t_SARb:
case t_NEGb:
return (lf_resb&0x80);
case t_ADDw:
case t_ORw:
case t_ADCw:
case t_SBBw:
case t_ANDw:
case t_XORw:
case t_SUBw:
case t_CMPw:
case t_INCw:
case t_DECw:
case t_TESTw:
case t_SHLw:
case t_SHRw:
case t_SARw:
case t_DSHLw:
case t_DSHRw:
case t_NEGw:
return (lf_resw&0x8000);
case t_ADDd:
case t_ORd:
case t_ADCd:
case t_SBBd:
case t_ANDd:
case t_XORd:
case t_SUBd:
case t_CMPd:
case t_INCd:
case t_DECd:
case t_TESTd:
case t_SHLd:
case t_SHRd:
case t_SARd:
case t_DSHLd:
case t_DSHRd:
case t_NEGd:
return (lf_resd&0x80000000);
case t_DIV:
case t_MUL:
return false; /* Unkown */
default:
LOG(LOG_CPU,LOG_ERROR)("get_SF Unkown %d",lflags.type);
}
return false;
}
Bit32u get_OF(void) {
Bitu type=lflags.type;
switch (type) {
case t_UNKNOWN:
case t_MUL:
return GETFLAG(OF);
case t_ADDb:
case t_ADCb:
return ((lf_var1b ^ lf_var2b ^ 0x80) & (lf_resb ^ lf_var2b)) & 0x80;
case t_ADDw:
case t_ADCw:
return ((lf_var1w ^ lf_var2w ^ 0x8000) & (lf_resw ^ lf_var2w)) & 0x8000;
case t_ADDd:
case t_ADCd:
return ((lf_var1d ^ lf_var2d ^ 0x80000000) & (lf_resd ^ lf_var2d)) & 0x80000000;
case t_SBBb:
case t_SUBb:
case t_CMPb:
return ((lf_var1b ^ lf_var2b) & (lf_var1b ^ lf_resb)) & 0x80;
case t_SBBw:
case t_SUBw:
case t_CMPw:
return ((lf_var1w ^ lf_var2w) & (lf_var1w ^ lf_resw)) & 0x8000;
case t_SBBd:
case t_SUBd:
case t_CMPd:
return ((lf_var1d ^ lf_var2d) & (lf_var1d ^ lf_resd)) & 0x80000000;
case t_INCb:
return (lf_resb == 0x80);
case t_INCw:
return (lf_resw == 0x8000);
case t_INCd:
return (lf_resd == 0x80000000);
case t_DECb:
return (lf_resb == 0x7f);
case t_DECw:
return (lf_resw == 0x7fff);
case t_DECd:
return (lf_resd == 0x7fffffff);
case t_NEGb:
return (lf_var1b == 0x80);
case t_NEGw:
return (lf_var1w == 0x8000);
case t_NEGd:
return (lf_var1d == 0x80000000);
case t_SHLb:
return (lf_resb ^ lf_var1b) & 0x80;
case t_SHLw:
case t_DSHRw:
case t_DSHLw:
return (lf_resw ^ lf_var1w) & 0x8000;
case t_SHLd:
case t_DSHRd:
case t_DSHLd:
return (lf_resd ^ lf_var1d) & 0x80000000;
case t_SHRb:
if ((lf_var2b&0x1f)==1) return (lf_var1b > 0x80);
else return false;
case t_SHRw:
if ((lf_var2b&0x1f)==1) return (lf_var1w > 0x8000);
else return false;
case t_SHRd:
if ((lf_var2b&0x1f)==1) return (lf_var1d > 0x80000000);
else return false;
case t_ORb:
case t_ORw:
case t_ORd:
case t_ANDb:
case t_ANDw:
case t_ANDd:
case t_XORb:
case t_XORw:
case t_XORd:
case t_TESTb:
case t_TESTw:
case t_TESTd:
case t_SARb:
case t_SARw:
case t_SARd:
return false; /* Return false */
case t_DIV:
return false; /* Unkown */
default:
LOG(LOG_CPU,LOG_ERROR)("get_OF Unkown %d",lflags.type);
}
return false;
}
Bit16u parity_lookup[256] = {
FLAG_PF, 0, 0, FLAG_PF, 0, FLAG_PF, FLAG_PF, 0, 0, FLAG_PF, FLAG_PF, 0, FLAG_PF, 0, 0, FLAG_PF,
0, FLAG_PF, FLAG_PF, 0, FLAG_PF, 0, 0, FLAG_PF, FLAG_PF, 0, 0, FLAG_PF, 0, FLAG_PF, FLAG_PF, 0,
0, FLAG_PF, FLAG_PF, 0, FLAG_PF, 0, 0, FLAG_PF, FLAG_PF, 0, 0, FLAG_PF, 0, FLAG_PF, FLAG_PF, 0,
FLAG_PF, 0, 0, FLAG_PF, 0, FLAG_PF, FLAG_PF, 0, 0, FLAG_PF, FLAG_PF, 0, FLAG_PF, 0, 0, FLAG_PF,
0, FLAG_PF, FLAG_PF, 0, FLAG_PF, 0, 0, FLAG_PF, FLAG_PF, 0, 0, FLAG_PF, 0, FLAG_PF, FLAG_PF, 0,
FLAG_PF, 0, 0, FLAG_PF, 0, FLAG_PF, FLAG_PF, 0, 0, FLAG_PF, FLAG_PF, 0, FLAG_PF, 0, 0, FLAG_PF,
FLAG_PF, 0, 0, FLAG_PF, 0, FLAG_PF, FLAG_PF, 0, 0, FLAG_PF, FLAG_PF, 0, FLAG_PF, 0, 0, FLAG_PF,
0, FLAG_PF, FLAG_PF, 0, FLAG_PF, 0, 0, FLAG_PF, FLAG_PF, 0, 0, FLAG_PF, 0, FLAG_PF, FLAG_PF, 0,
0, FLAG_PF, FLAG_PF, 0, FLAG_PF, 0, 0, FLAG_PF, FLAG_PF, 0, 0, FLAG_PF, 0, FLAG_PF, FLAG_PF, 0,
FLAG_PF, 0, 0, FLAG_PF, 0, FLAG_PF, FLAG_PF, 0, 0, FLAG_PF, FLAG_PF, 0, FLAG_PF, 0, 0, FLAG_PF,
FLAG_PF, 0, 0, FLAG_PF, 0, FLAG_PF, FLAG_PF, 0, 0, FLAG_PF, FLAG_PF, 0, FLAG_PF, 0, 0, FLAG_PF,
0, FLAG_PF, FLAG_PF, 0, FLAG_PF, 0, 0, FLAG_PF, FLAG_PF, 0, 0, FLAG_PF, 0, FLAG_PF, FLAG_PF, 0,
FLAG_PF, 0, 0, FLAG_PF, 0, FLAG_PF, FLAG_PF, 0, 0, FLAG_PF, FLAG_PF, 0, FLAG_PF, 0, 0, FLAG_PF,
0, FLAG_PF, FLAG_PF, 0, FLAG_PF, 0, 0, FLAG_PF, FLAG_PF, 0, 0, FLAG_PF, 0, FLAG_PF, FLAG_PF, 0,
0, FLAG_PF, FLAG_PF, 0, FLAG_PF, 0, 0, FLAG_PF, FLAG_PF, 0, 0, FLAG_PF, 0, FLAG_PF, FLAG_PF, 0,
FLAG_PF, 0, 0, FLAG_PF, 0, FLAG_PF, FLAG_PF, 0, 0, FLAG_PF, FLAG_PF, 0, FLAG_PF, 0, 0, FLAG_PF
};
Bit32u get_PF(void) {
switch (lflags.type) {
case t_UNKNOWN:
return GETFLAG(PF);
default:
return (parity_lookup[lf_resb]);
};
return 0;
}
#if 0
Bitu FillFlags(void) {
// if (lflags.type==t_UNKNOWN) return reg_flags;
Bitu new_word=(reg_flags & ~FLAG_MASK);
if (get_CF()) new_word|=FLAG_CF;
if (get_PF()) new_word|=FLAG_PF;
if (get_AF()) new_word|=FLAG_AF;
if (get_ZF()) new_word|=FLAG_ZF;
if (get_SF()) new_word|=FLAG_SF;
if (get_OF()) new_word|=FLAG_OF;
reg_flags=new_word;
lflags.type=t_UNKNOWN;
return reg_flags;
}
#else
#define DOFLAG_PF reg_flags=(reg_flags & ~FLAG_PF) | parity_lookup[lf_resb];
#define DOFLAG_AF reg_flags=(reg_flags & ~FLAG_AF) | (((lf_var1b ^ lf_var2b) ^ lf_resb) & 0x10);
#define DOFLAG_ZFb SETFLAGBIT(ZF,lf_resb==0);
#define DOFLAG_ZFw SETFLAGBIT(ZF,lf_resw==0);
#define DOFLAG_ZFd SETFLAGBIT(ZF,lf_resd==0);
#define DOFLAG_SFb reg_flags=(reg_flags & ~FLAG_SF) | ((lf_resb & 0x80) >> 0);
#define DOFLAG_SFw reg_flags=(reg_flags & ~FLAG_SF) | ((lf_resw & 0x8000) >> 8);
#define DOFLAG_SFd reg_flags=(reg_flags & ~FLAG_SF) | ((lf_resd & 0x80000000) >> 24);
#define SETCF(NEWBIT) reg_flags=(reg_flags & ~FLAG_CF)|(NEWBIT);
#define SET_FLAG SETFLAGBIT
Bitu FillFlags(void) {
switch (lflags.type) {
case t_UNKNOWN:
break;
case t_ADDb:
SET_FLAG(CF,(lf_resb<lf_var1b));
DOFLAG_AF;
DOFLAG_ZFb;
DOFLAG_SFb;
SET_FLAG(OF,((lf_var1b ^ lf_var2b ^ 0x80) & (lf_resb ^ lf_var1b)) & 0x80);
DOFLAG_PF;
break;
case t_ADDw:
SET_FLAG(CF,(lf_resw<lf_var1w));
DOFLAG_AF;
DOFLAG_ZFw;
DOFLAG_SFw;
SET_FLAG(OF,((lf_var1w ^ lf_var2w ^ 0x8000) & (lf_resw ^ lf_var1w)) & 0x8000);
DOFLAG_PF;
break;
case t_ADDd:
SET_FLAG(CF,(lf_resd<lf_var1d));
DOFLAG_AF;
DOFLAG_ZFd;
DOFLAG_SFd;
SET_FLAG(OF,((lf_var1d ^ lf_var2d ^ 0x80000000) & (lf_resd ^ lf_var1d)) & 0x80000000);
DOFLAG_PF;
break;
case t_ADCb:
SET_FLAG(CF,(lf_resb < lf_var1b) || (lflags.oldcf && (lf_resb == lf_var1b)));
DOFLAG_AF;
DOFLAG_ZFb;
DOFLAG_SFb;
SET_FLAG(OF,((lf_var1b ^ lf_var2b ^ 0x80) & (lf_resb ^ lf_var1b)) & 0x80);
DOFLAG_PF;
break;
case t_ADCw:
SET_FLAG(CF,(lf_resw < lf_var1w) || (lflags.oldcf && (lf_resw == lf_var1w)));
DOFLAG_AF;
DOFLAG_ZFw;
DOFLAG_SFw;
SET_FLAG(OF,((lf_var1w ^ lf_var2w ^ 0x8000) & (lf_resw ^ lf_var1w)) & 0x8000);
DOFLAG_PF;
break;
case t_ADCd:
SET_FLAG(CF,(lf_resd < lf_var1d) || (lflags.oldcf && (lf_resd == lf_var1d)));
DOFLAG_AF;
DOFLAG_ZFd;
DOFLAG_SFd;
SET_FLAG(OF,((lf_var1d ^ lf_var2d ^ 0x80000000) & (lf_resd ^ lf_var1d)) & 0x80000000);
DOFLAG_PF;
break;
case t_SBBb:
SET_FLAG(CF,(lf_var1b < lf_resb) || (lflags.oldcf && (lf_var2b==0xff)));
DOFLAG_AF;
DOFLAG_ZFb;
DOFLAG_SFb;
SET_FLAG(OF,(lf_var1b ^ lf_var2b) & (lf_var1b ^ lf_resb) & 0x80);
DOFLAG_PF;
break;
case t_SBBw:
SET_FLAG(CF,(lf_var1w < lf_resw) || (lflags.oldcf && (lf_var2w==0xffff)));
DOFLAG_AF;
DOFLAG_ZFw;
DOFLAG_SFw;
SET_FLAG(OF,(lf_var1w ^ lf_var2w) & (lf_var1w ^ lf_resw) & 0x8000);
DOFLAG_PF;
break;
case t_SBBd:
SET_FLAG(CF,(lf_var1d < lf_resd) || (lflags.oldcf && (lf_var2d==0xffffffff)));
DOFLAG_AF;
DOFLAG_ZFd;
DOFLAG_SFd;
SET_FLAG(OF,(lf_var1d ^ lf_var2d) & (lf_var1d ^ lf_resd) & 0x80000000);
DOFLAG_PF;
break;
case t_SUBb:
case t_CMPb:
SET_FLAG(CF,(lf_var1b<lf_var2b));
DOFLAG_AF;
DOFLAG_ZFb;
DOFLAG_SFb;
SET_FLAG(OF,(lf_var1b ^ lf_var2b) & (lf_var1b ^ lf_resb) & 0x80);
DOFLAG_PF;
break;
case t_SUBw:
case t_CMPw:
SET_FLAG(CF,(lf_var1w<lf_var2w));
DOFLAG_AF;
DOFLAG_ZFw;
DOFLAG_SFw;
SET_FLAG(OF,(lf_var1w ^ lf_var2w) & (lf_var1w ^ lf_resw) & 0x8000);
DOFLAG_PF;
break;
case t_SUBd:
case t_CMPd:
SET_FLAG(CF,(lf_var1d<lf_var2d));
DOFLAG_AF;
DOFLAG_ZFd;
DOFLAG_SFd;
SET_FLAG(OF,(lf_var1d ^ lf_var2d) & (lf_var1d ^ lf_resd) & 0x80000000);
DOFLAG_PF;
break;
case t_ORb:
SET_FLAG(CF,false);
SET_FLAG(AF,false);
DOFLAG_ZFb;
DOFLAG_SFb;
SET_FLAG(OF,false);
DOFLAG_PF;
break;
case t_ORw:
SET_FLAG(CF,false);
SET_FLAG(AF,false);
DOFLAG_ZFw;
DOFLAG_SFw;
SET_FLAG(OF,false);
DOFLAG_PF;
break;
case t_ORd:
SET_FLAG(CF,false);
SET_FLAG(AF,false);
DOFLAG_ZFd;
DOFLAG_SFd;
SET_FLAG(OF,false);
DOFLAG_PF;
break;
case t_TESTb:
case t_ANDb:
SET_FLAG(CF,false);
SET_FLAG(AF,false);
DOFLAG_ZFb;
DOFLAG_SFb;
SET_FLAG(OF,false);
DOFLAG_PF;
break;
case t_TESTw:
case t_ANDw:
SET_FLAG(CF,false);
SET_FLAG(AF,false);
DOFLAG_ZFw;
DOFLAG_SFw;
SET_FLAG(OF,false);
DOFLAG_PF;
break;
case t_TESTd:
case t_ANDd:
SET_FLAG(CF,false);
SET_FLAG(AF,false);
DOFLAG_ZFd;
DOFLAG_SFd;
SET_FLAG(OF,false);
DOFLAG_PF;
break;
case t_XORb:
SET_FLAG(CF,false);
SET_FLAG(AF,false);
DOFLAG_ZFb;
DOFLAG_SFb;
SET_FLAG(OF,false);
DOFLAG_PF;
break;
case t_XORw:
SET_FLAG(CF,false);
SET_FLAG(AF,false);
DOFLAG_ZFw;
DOFLAG_SFw;
SET_FLAG(OF,false);
DOFLAG_PF;
break;
case t_XORd:
SET_FLAG(CF,false);
SET_FLAG(AF,false);
DOFLAG_ZFd;
DOFLAG_SFd;
SET_FLAG(OF,false);
DOFLAG_PF;
break;
case t_SHLb:
if (lf_var2b>8) SET_FLAG(CF,false);
else SET_FLAG(CF,(lf_var1b >> (8-lf_var2b)) & 1);
DOFLAG_ZFb;
DOFLAG_SFb;
SET_FLAG(OF,(lf_resb ^ lf_var1b) & 0x80);
DOFLAG_PF;
SET_FLAG(AF,(lf_var2b&0x1f));
break;
case t_SHLw:
if (lf_var2b>16) SET_FLAG(CF,false);
else SET_FLAG(CF,(lf_var1w >> (16-lf_var2b)) & 1);
DOFLAG_ZFw;
DOFLAG_SFw;
SET_FLAG(OF,(lf_resw ^ lf_var1w) & 0x8000);
DOFLAG_PF;
SET_FLAG(AF,(lf_var2w&0x1f));
break;
case t_SHLd:
SET_FLAG(CF,(lf_var1d >> (32 - lf_var2b)) & 1);
DOFLAG_ZFd;
DOFLAG_SFd;
SET_FLAG(OF,(lf_resd ^ lf_var1d) & 0x80000000);
DOFLAG_PF;
SET_FLAG(AF,(lf_var2d&0x1f));
break;
case t_DSHLw:
SET_FLAG(CF,(lf_var1d >> (32 - lf_var2b)) & 1);
DOFLAG_ZFw;
DOFLAG_SFw;
SET_FLAG(OF,(lf_resw ^ lf_var1w) & 0x8000);
DOFLAG_PF;
break;
case t_DSHLd:
SET_FLAG(CF,(lf_var1d >> (32 - lf_var2b)) & 1);
DOFLAG_ZFd;
DOFLAG_SFd;
SET_FLAG(OF,(lf_resd ^ lf_var1d) & 0x80000000);
DOFLAG_PF;
break;
case t_SHRb:
SET_FLAG(CF,(lf_var1b >> (lf_var2b - 1)) & 1);
DOFLAG_ZFb;
DOFLAG_SFb;
if ((lf_var2b&0x1f)==1) SET_FLAG(OF,(lf_var1b >= 0x80));
else SET_FLAG(OF,false);
DOFLAG_PF;
SET_FLAG(AF,(lf_var2b&0x1f));
break;
case t_SHRw:
SET_FLAG(CF,(lf_var1w >> (lf_var2b - 1)) & 1);
DOFLAG_ZFw;
DOFLAG_SFw;
if ((lf_var2w&0x1f)==1) SET_FLAG(OF,(lf_var1w >= 0x8000));
else SET_FLAG(OF,false);
DOFLAG_PF;
SET_FLAG(AF,(lf_var2w&0x1f));
break;
case t_SHRd:
SET_FLAG(CF,(lf_var1d >> (lf_var2b - 1)) & 1);
DOFLAG_ZFd;
DOFLAG_SFd;
if ((lf_var2d&0x1f)==1) SET_FLAG(OF,(lf_var1d >= 0x80000000));
else SET_FLAG(OF,false);
DOFLAG_PF;
SET_FLAG(AF,(lf_var2d&0x1f));
break;
case t_DSHRw: /* Hmm this is not correct for shift higher than 16 */
SET_FLAG(CF,(lf_var1d >> (lf_var2b - 1)) & 1);
DOFLAG_ZFw;
DOFLAG_SFw;
SET_FLAG(OF,(lf_resw ^ lf_var1w) & 0x8000);
DOFLAG_PF;
break;
case t_DSHRd:
SET_FLAG(CF,(lf_var1d >> (lf_var2b - 1)) & 1);
DOFLAG_ZFd;
DOFLAG_SFd;
SET_FLAG(OF,(lf_resd ^ lf_var1d) & 0x80000000);
DOFLAG_PF;
break;
case t_SARb:
SET_FLAG(CF,(((Bit8s) lf_var1b) >> (lf_var2b - 1)) & 1);
DOFLAG_ZFb;
DOFLAG_SFb;
SET_FLAG(OF,false);
DOFLAG_PF;
SET_FLAG(AF,(lf_var2b&0x1f));
break;
case t_SARw:
SET_FLAG(CF,(((Bit16s) lf_var1w) >> (lf_var2b - 1)) & 1);
DOFLAG_ZFw;
DOFLAG_SFw;
SET_FLAG(OF,false);
DOFLAG_PF;
SET_FLAG(AF,(lf_var2w&0x1f));
break;
case t_SARd:
SET_FLAG(CF,(((Bit32s) lf_var1d) >> (lf_var2b - 1)) & 1);
DOFLAG_ZFd;
DOFLAG_SFd;
SET_FLAG(OF,false);
DOFLAG_PF;
SET_FLAG(AF,(lf_var2d&0x1f));
break;
case t_INCb:
SET_FLAG(AF,(lf_resb & 0x0f) == 0);
DOFLAG_ZFb;
DOFLAG_SFb;
SET_FLAG(OF,(lf_resb == 0x80));
DOFLAG_PF;
break;
case t_INCw:
SET_FLAG(AF,(lf_resw & 0x0f) == 0);
DOFLAG_ZFw;
DOFLAG_SFw;
SET_FLAG(OF,(lf_resw == 0x8000));
DOFLAG_PF;
break;
case t_INCd:
SET_FLAG(AF,(lf_resd & 0x0f) == 0);
DOFLAG_ZFd;
DOFLAG_SFd;
SET_FLAG(OF,(lf_resd == 0x80000000));
DOFLAG_PF;
break;
case t_DECb:
SET_FLAG(AF,(lf_resb & 0x0f) == 0x0f);
DOFLAG_ZFb;
DOFLAG_SFb;
SET_FLAG(OF,(lf_resb == 0x7f));
DOFLAG_PF;
break;
case t_DECw:
SET_FLAG(AF,(lf_resw & 0x0f) == 0x0f);
DOFLAG_ZFw;
DOFLAG_SFw;
SET_FLAG(OF,(lf_resw == 0x7fff));
DOFLAG_PF;
break;
case t_DECd:
SET_FLAG(AF,(lf_resd & 0x0f) == 0x0f);
DOFLAG_ZFd;
DOFLAG_SFd;
SET_FLAG(OF,(lf_resd == 0x7fffffff));
DOFLAG_PF;
break;
case t_NEGb:
SET_FLAG(CF,(lf_var1b!=0));
SET_FLAG(AF,(lf_resb & 0x0f) != 0);
DOFLAG_ZFb;
DOFLAG_SFb;
SET_FLAG(OF,(lf_var1b == 0x80));
DOFLAG_PF;
break;
case t_NEGw:
SET_FLAG(CF,(lf_var1w!=0));
SET_FLAG(AF,(lf_resw & 0x0f) != 0);
DOFLAG_ZFw;
DOFLAG_SFw;
SET_FLAG(OF,(lf_var1w == 0x8000));
DOFLAG_PF;
break;
case t_NEGd:
SET_FLAG(CF,(lf_var1d!=0));
SET_FLAG(AF,(lf_resd & 0x0f) != 0);
DOFLAG_ZFd;
DOFLAG_SFd;
SET_FLAG(OF,(lf_var1d == 0x80000000));
DOFLAG_PF;
break;
case t_DIV:
case t_MUL:
break;
default:
LOG(LOG_CPU,LOG_ERROR)("Unhandled flag type %d",lflags.type);
return 0;
}
lflags.type=t_UNKNOWN;
return reg_flags;
}
void FillFlagsNoCFOF(void) {
switch (lflags.type) {
case t_UNKNOWN:
return;
case t_ADDb:
DOFLAG_AF;
DOFLAG_ZFb;
DOFLAG_SFb;
DOFLAG_PF;
break;
case t_ADDw:
DOFLAG_AF;
DOFLAG_ZFw;
DOFLAG_SFw;
DOFLAG_PF;
break;
case t_ADDd:
DOFLAG_AF;
DOFLAG_ZFd;
DOFLAG_SFd;
DOFLAG_PF;
break;
case t_ADCb:
DOFLAG_AF;
DOFLAG_ZFb;
DOFLAG_SFb;
DOFLAG_PF;
break;
case t_ADCw:
DOFLAG_AF;
DOFLAG_ZFw;
DOFLAG_SFw;
DOFLAG_PF;
break;
case t_ADCd:
DOFLAG_AF;
DOFLAG_ZFd;
DOFLAG_SFd;
DOFLAG_PF;
break;
case t_SBBb:
DOFLAG_AF;
DOFLAG_ZFb;
DOFLAG_SFb;
DOFLAG_PF;
break;
case t_SBBw:
DOFLAG_AF;
DOFLAG_ZFw;
DOFLAG_SFw;
DOFLAG_PF;
break;
case t_SBBd:
DOFLAG_AF;
DOFLAG_ZFd;
DOFLAG_SFd;
DOFLAG_PF;
break;
case t_SUBb:
case t_CMPb:
DOFLAG_AF;
DOFLAG_ZFb;
DOFLAG_SFb;
DOFLAG_PF;
break;
case t_SUBw:
case t_CMPw:
DOFLAG_AF;
DOFLAG_ZFw;
DOFLAG_SFw;
DOFLAG_PF;
break;
case t_SUBd:
case t_CMPd:
DOFLAG_AF;
DOFLAG_ZFd;
DOFLAG_SFd;
DOFLAG_PF;
break;
case t_ORb:
SET_FLAG(AF,false);
DOFLAG_ZFb;
DOFLAG_SFb;
DOFLAG_PF;
break;
case t_ORw:
SET_FLAG(AF,false);
DOFLAG_ZFw;
DOFLAG_SFw;
DOFLAG_PF;
break;
case t_ORd:
SET_FLAG(AF,false);
DOFLAG_ZFd;
DOFLAG_SFd;
DOFLAG_PF;
break;
case t_TESTb:
case t_ANDb:
SET_FLAG(AF,false);
DOFLAG_ZFb;
DOFLAG_SFb;
DOFLAG_PF;
break;
case t_TESTw:
case t_ANDw:
SET_FLAG(AF,false);
DOFLAG_ZFw;
DOFLAG_SFw;
DOFLAG_PF;
break;
case t_TESTd:
case t_ANDd:
SET_FLAG(AF,false);
DOFLAG_ZFd;
DOFLAG_SFd;
DOFLAG_PF;
break;
case t_XORb:
SET_FLAG(AF,false);
DOFLAG_ZFb;
DOFLAG_SFb;
DOFLAG_PF;
break;
case t_XORw:
SET_FLAG(AF,false);
DOFLAG_ZFw;
DOFLAG_SFw;
DOFLAG_PF;
break;
case t_XORd:
SET_FLAG(AF,false);
DOFLAG_ZFd;
DOFLAG_SFd;
DOFLAG_PF;
break;
case t_SHLb:
DOFLAG_ZFb;
DOFLAG_SFb;
DOFLAG_PF;
SET_FLAG(AF,(lf_var2b&0x1f));
break;
case t_SHLw:
DOFLAG_ZFw;
DOFLAG_SFw;
DOFLAG_PF;
SET_FLAG(AF,(lf_var2w&0x1f));
break;
case t_SHLd:
DOFLAG_ZFd;
DOFLAG_SFd;
DOFLAG_PF;
SET_FLAG(AF,(lf_var2d&0x1f));
break;
case t_DSHLw:
DOFLAG_ZFw;
DOFLAG_SFw;
DOFLAG_PF;
break;
case t_DSHLd:
DOFLAG_ZFd;
DOFLAG_SFd;
DOFLAG_PF;
break;
case t_SHRb:
DOFLAG_ZFb;
DOFLAG_SFb;
DOFLAG_PF;
SET_FLAG(AF,(lf_var2b&0x1f));
break;
case t_SHRw:
DOFLAG_ZFw;
DOFLAG_SFw;
DOFLAG_PF;
SET_FLAG(AF,(lf_var2w&0x1f));
break;
case t_SHRd:
DOFLAG_ZFd;
DOFLAG_SFd;
DOFLAG_PF;
SET_FLAG(AF,(lf_var2d&0x1f));
break;
case t_DSHRw: /* Hmm this is not correct for shift higher than 16 */
DOFLAG_ZFw;
DOFLAG_SFw;
DOFLAG_PF;
break;
case t_DSHRd:
DOFLAG_ZFd;
DOFLAG_SFd;
DOFLAG_PF;
break;
case t_SARb:
DOFLAG_ZFb;
DOFLAG_SFb;
DOFLAG_PF;
SET_FLAG(AF,(lf_var2b&0x1f));
break;
case t_SARw:
DOFLAG_ZFw;
DOFLAG_SFw;
DOFLAG_PF;
SET_FLAG(AF,(lf_var2w&0x1f));
break;
case t_SARd:
DOFLAG_ZFd;
DOFLAG_SFd;
DOFLAG_PF;
SET_FLAG(AF,(lf_var2d&0x1f));
break;
case t_INCb:
SET_FLAG(AF,(lf_resb & 0x0f) == 0);
DOFLAG_ZFb;
DOFLAG_SFb;
DOFLAG_PF;
break;
case t_INCw:
SET_FLAG(AF,(lf_resw & 0x0f) == 0);
DOFLAG_ZFw;
DOFLAG_SFw;
DOFLAG_PF;
break;
case t_INCd:
SET_FLAG(AF,(lf_resd & 0x0f) == 0);
DOFLAG_ZFd;
DOFLAG_SFd;
DOFLAG_PF;
break;
case t_DECb:
SET_FLAG(AF,(lf_resb & 0x0f) == 0x0f);
DOFLAG_ZFb;
DOFLAG_SFb;
DOFLAG_PF;
break;
case t_DECw:
SET_FLAG(AF,(lf_resw & 0x0f) == 0x0f);
DOFLAG_ZFw;
DOFLAG_SFw;
DOFLAG_PF;
break;
case t_DECd:
SET_FLAG(AF,(lf_resd & 0x0f) == 0x0f);
DOFLAG_ZFd;
DOFLAG_SFd;
DOFLAG_PF;
break;
case t_NEGb:
SET_FLAG(AF,(lf_resb & 0x0f) != 0);
DOFLAG_ZFb;
DOFLAG_SFb;
DOFLAG_PF;
break;
case t_NEGw:
SET_FLAG(AF,(lf_resw & 0x0f) != 0);
DOFLAG_ZFw;
DOFLAG_SFw;
DOFLAG_PF;
break;
case t_NEGd:
SET_FLAG(AF,(lf_resd & 0x0f) != 0);
DOFLAG_ZFd;
DOFLAG_SFd;
DOFLAG_PF;
break;
case t_DIV:
case t_MUL:
break;
default:
LOG(LOG_CPU,LOG_ERROR)("Unhandled flag type %d",lflags.type);
break;
}
lflags.type=t_UNKNOWN;
}
void DestroyConditionFlags(void) {
lflags.type=t_UNKNOWN;
}
#endif