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huc6280.cpp
784 lines (647 loc) · 20.8 KB
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huc6280.cpp
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/* Mednafen - Multi-system Emulator
*
* 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
*/
#include "pce.h"
#include "vdc.h"
namespace PCE_Fast
{
HuC6280 HuCPU;
uint8 *HuCPUFastMap[0x100];
#define HU_PC PC_local //HuCPU.PC
#define HU_PC_base HuCPU.PC_base
#define HU_A HuCPU.A
#define HU_X X_local //HuCPU.X
#define HU_Y Y_local //HuCPU.Y
#define HU_S HuCPU.S
#define HU_P P_local //HuCPU.P
#define HU_PI HuCPU.mooPI
#define HU_IRQlow HuCPU.IRQlow
#define HU_Page1 Page1_local
//HuCPU.Page1
//Page1_local //HuCPU.Page1
#ifdef HUC6280_LAZY_FLAGS
#define HU_ZNFlags HuCPU.ZNFlags
#endif
#ifdef HUC6280_CRAZY_VERSION
#define LOAD_LOCALS_PC() register uint8 *PC_local = HuCPU.PC;
#else
#define LOAD_LOCALS_PC() register uint32 PC_local /*asm ("edi")*/ = HuCPU.PC; // asm ("edi") = HuCPU.PC;
#endif
#define LOAD_LOCALS() \
LOAD_LOCALS_PC(); \
uint8 X_local = HuCPU.X; \
uint8 Y_local = HuCPU.Y; \
uint8 P_local = HuCPU.P; \
uint8 *Page1_local = HuCPU.Page1;
#define SAVE_LOCALS() HuCPU.PC = PC_local; \
HuCPU.X = X_local; \
HuCPU.Y = Y_local; \
HuCPU.P = P_local; \
HuCPU.Page1 = Page1_local;
#ifdef HUC6280_LAZY_FLAGS
#define COMPRESS_FLAGS() HU_P &= ~(N_FLAG | Z_FLAG); HU_P |= ((HU_ZNFlags >> 24) & 0x80) | ((HU_ZNFlags & 0xFF) ? 0 : Z_FLAG);
//((((HU_ZNFlags & 0xFF) - 1) >> 8) & Z_FLAG);
#define EXPAND_FLAGS() HU_ZNFlags = (HU_P << 24) | ((HU_P & Z_FLAG) ^ Z_FLAG);
#else
#define COMPRESS_FLAGS()
#define EXPAND_FLAGS()
#endif
#ifdef HUC6280_CRAZY_VERSION
#define GetRealPC() ((unsigned int)(HU_PC - HU_PC_base))
#define GetRealPC_EXTERNAL() ((unsigned int)(HuCPU.PC - HuCPU.PC_base))
#else
#define GetRealPC() (HU_PC)
#define GetRealPC_EXTERNAL() (HuCPU.PC)
#endif
#ifdef HUC6280_CRAZY_VERSION
#define SetPC(value) { unsigned int tempmoo = value; HU_PC = &HuCPU.FastPageR[tempmoo >> 13][tempmoo]; \
HU_PC_base = HU_PC - tempmoo; }
#define SetPC_EXTERNAL(value) { unsigned int tempmoo = value; \
HuCPU.PC = &HuCPU.FastPageR[tempmoo >> 13][tempmoo]; HuCPU.PC_base = HuCPU.PC - tempmoo; }
#else
#define SetPC(value) { HU_PC = (value); }
#define SetPC_EXTERNAL(value) { HuCPU.PC = (value); }
#endif
// Page change PC, GET IT?!
#ifdef HUC6280_CRAZY_VERSION
#define FixPC_PC() SetPC(GetRealPC());
#else
#define FixPC_PC()
#endif
//#define IncPC() { HU_PC++; if(!(GetRealPC() & 0x1FFF)) printf("Bank crossing: %04x\n", GetRealPC()); }
//#define IncPC() HU_PC++;
#if 0
#define IncPC() { HU_PC++; if(!(GetRealPC() & 0x1FFF) && \
HuCPU.MPR[(GetRealPC() - 1) >> 13] != (HuCPU.MPR[(GetRealPC()) >> 13] - 1)) \
printf("Bank crossing: %04x, %02x, %02x\n", GetRealPC(), HuCPU.MPR[(GetRealPC() - 1) >> 13], \
HuCPU.MPR[GetRealPC() >> 13]); }
#else
#define IncPC() HU_PC++;
#endif
#ifdef HUC6280_CRAZY_VERSION
#define RdAtPC() (*HU_PC)
//#define RdAtAndIncPC_16() (HU_PC += 2, *(uint16 *)(HU_PC - 2))
#else
#define RdAtPC() RdOp(HU_PC)
//#define RdAtAndIncPC_16() (RdOp(HU_PC++) | ((RdOp(HU_PC++) << 8)))
#endif
// If we change this definition, we'll need to also fix HuC6280_StealCycle() in huc6280.h
#define ADDCYC(x) { HuCPU.timestamp += x; }
static uint8 dummy_bank[8192 + 8192]; // + 8192 for PC-as-ptr safety padding
#define SET_MPR(arg_i, arg_v) \
{ \
const unsigned int wmpr = arg_i, wbank = arg_v; \
if(wmpr == 1) \
{ \
if(wbank != 0xF8 || !HuCPUFastMap[wbank]) \
printf("Crazy page 1: %02x\n", wbank); \
HU_Page1 = HuCPUFastMap[wbank] ? HuCPUFastMap[wbank] + wbank * 8192 : dummy_bank; \
} \
HuCPU.MPR[wmpr] = wbank; \
HuCPU.FastPageR[wmpr] = HuCPUFastMap[wbank] ? (HuCPUFastMap[wbank] + wbank * 8192) - wmpr * 8192 : (dummy_bank - wmpr * 8192); \
}
void HuC6280_SetMPR(int i, int v)
{
uint8 *Page1_local = HuCPU.Page1;
SET_MPR(i, v);
HuCPU.Page1 = Page1_local;
}
static void HuC6280_FlushMPRCache(void)
{
for(int x = 0; x < 9; x++)
HuC6280_SetMPR(x, HuCPU.MPR[x & 0x7]);
}
static INLINE uint8 RdMem(unsigned int A)
{
uint8 wmpr = HuCPU.MPR[A >> 13];
return(PCERead[wmpr]((wmpr << 13) | (A & 0x1FFF)));
}
static INLINE uint16 RdMem16(unsigned int A)
{
return(RdMem(A) | (RdMem(A + 1) << 8));
}
static INLINE void WrMem(unsigned int A, uint8 V)
{
uint8 wmpr = HuCPU.MPR[A >> 13];
PCEWrite[wmpr]((wmpr << 13) | (A & 0x1FFF), V);
}
static INLINE uint8 RdOp(unsigned int A)
{
return(HuCPU.FastPageR[A >> 13][A]);
}
#define PUSH(V) \
{ \
HU_Page1[0x100 + HU_S] = V; \
HU_S--; \
}
#define PUSH_PC() \
{ \
unsigned int real_pc = GetRealPC(); \
PUSH(real_pc >> 8); \
PUSH(real_pc); \
}
#define POP() HU_Page1[0x100 + ++HU_S]
#define POP_PC() \
{ \
unsigned int npc; \
npc = POP(); \
npc |= POP() << 8; \
SetPC(npc); \
}
// Hopefully we never RTS to 0x0000. ;)
#define POP_PC_AP() \
{ \
uint32 npc; \
npc = POP(); \
npc |= POP() << 8; \
npc++; \
SetPC(npc); \
}
/* Some of these operations will only make sense if you know what the flag
constants are. */
#ifdef HUC6280_LAZY_FLAGS
#define X_ZN(zort) { HU_ZNFlags = (int32)(int8)(uint8)(zort); }
#define X_ZN_BIT(opres, argie) { HU_ZNFlags = (opres) | ((argie) << 24); }
#else
static uint8 ZNTable[256];
#define X_ZN(zort) HU_P&=~(Z_FLAG|N_FLAG);HU_P|=ZNTable[zort]
#define X_ZN_BIT(opres, argie) { HU_P &= ~(Z_FLAG | N_FLAG); HU_P |= ZNTable[opres] & Z_FLAG; HU_P |= argie & N_FLAG; }
#endif
#define JR(cond) \
{ \
if(cond) \
{ \
int32 disp; \
disp = 1 + (int8)RdAtPC(); \
ADDCYC(2); \
HU_PC+=disp; \
} \
else IncPC(); \
}
#define BRA \
{ \
int32 disp; \
disp = 1 + (int8)RdAtPC(); \
HU_PC+=disp; \
}
#define BBRi(bitto) JR(!(x & (1 << bitto)))
#define BBSi(bitto) JR(x & (1 << bitto))
#define ST0 VDC_Write_ST(0, x)
#define ST1 VDC_Write_ST(2, x)
#define ST2 VDC_Write_ST(3, x)
#define LDA HU_A=x;X_ZN(HU_A)
#define LDX HU_X=x;X_ZN(HU_X)
#define LDY HU_Y=x;X_ZN(HU_Y)
/* All of the freaky arithmetic operations. */
#define AND HU_A&=x;X_ZN(HU_A);
// FIXME:
#define BIT HU_P&=~V_FLAG; X_ZN_BIT(x & HU_A, x); HU_P |= x & V_FLAG;
#define EOR HU_A^=x;X_ZN(HU_A);
#define ORA HU_A|=x;X_ZN(HU_A);
#define ADC { \
if(HU_P & D_FLAG) \
{ \
uint32 low = (HU_A & 0x0F) + (x & 0x0F) + (HU_P & 1); \
uint32 high = (HU_A & 0xF0) + (x & 0xF0); \
HU_P &= ~C_FLAG; \
if(low > 0x09) { high += 0x10; low += 0x06; } \
if(high > 0x90) { high += 0x60; } \
HU_P |= (high >> 8) & C_FLAG; \
HU_A = (low & 0x0F) | (high & 0xF0); \
X_ZN(HU_A); \
} \
else \
{ \
uint32 l=HU_A+x+(HU_P&1); \
HU_P&=~(C_FLAG|V_FLAG); \
HU_P|=((((HU_A^x)&0x80)^0x80) & ((HU_A^l)&0x80))>>1; \
HU_P|=(l>>8)&C_FLAG; \
HU_A=l; \
X_ZN(HU_A); \
} \
}
#define SBC if(HU_P & D_FLAG) \
{ \
uint32 c = (HU_P & 1) ^ 1; \
uint32 l = HU_A - x - c; \
uint32 low = (HU_A & 0x0f) - (x & 0x0f) - c; \
uint32 high = (HU_A & 0xf0) - (x & 0xf0); \
HU_P &= ~(C_FLAG); \
if(low & 0xf0) low -= 0x06; \
if(low & 0x80) high -= 0x10; \
if(high & 0x0f00) high -= 0x60; \
HU_P |= ((l >> 8) & C_FLAG) ^ C_FLAG; \
HU_A = (low & 0x0F) | (high & 0xf0); \
X_ZN(HU_A); \
} else { \
uint32 l=HU_A-x-((HU_P&1)^1); \
HU_P&=~(C_FLAG|V_FLAG); \
HU_P|=((HU_A^l)&(HU_A^x)&0x80)>>1; \
HU_P|=((l>>8)&C_FLAG)^C_FLAG; \
HU_A=l; \
X_ZN(HU_A); \
}
#define CMPL(a1,a2) { \
uint32 t=a1-a2; \
X_ZN(t&0xFF); \
HU_P&=~C_FLAG; \
HU_P|=((t>>8)&C_FLAG)^C_FLAG; \
}
#define TAM for(int i = 0; i < 8; i ++) { \
if(x & (1 << i)) \
{ \
SET_MPR(i, HU_A); \
} \
} SET_MPR(8, HuCPU.MPR[0]);
#define TMA for(int i = 0; i < 8; i ++) { \
if(x & (1 << i)) \
HU_A = HuCPU.MPR[i]; \
}
#define CSL
#define CSH
#define RMB(bitto) x &= ~(1 << (bitto & 7))
#define SMB(bitto) x |= 1 << (bitto & 7)
// FIXME
#define TSB { HU_P &= ~V_FLAG; X_ZN_BIT(x | HU_A, x); HU_P |= x & V_FLAG; x |= HU_A; }
#define TRB { HU_P &= ~V_FLAG; X_ZN_BIT(x & ~HU_A, x); HU_P |= x & V_FLAG; x &= ~HU_A; }
#define TST { HU_P &= ~V_FLAG; X_ZN_BIT(x & zoomhack, x); HU_P |= x & V_FLAG; }
#define CMP CMPL(HU_A,x)
#define CPX CMPL(HU_X,x)
#define CPY CMPL(HU_Y,x)
/* The following operations modify the byte being worked on. */
#define DEC x--;X_ZN(x)
#define INC x++;X_ZN(x)
#define ASL HU_P&=~C_FLAG;HU_P|=x>>7;x<<=1;X_ZN(x)
#define LSR HU_P&=~C_FLAG;HU_P|=x&1;x>>=1;X_ZN(x)
#define ROL { \
uint8 l=x>>7; \
x<<=1; \
x|=HU_P&C_FLAG; \
HU_P&=~C_FLAG; \
HU_P|=l; \
X_ZN(x); \
}
#define ROR { \
uint8 l=x&1; \
x>>=1; \
x|=(HU_P&C_FLAG)<<7; \
HU_P&=~C_FLAG; \
HU_P|=l; \
X_ZN(x); \
}
/* Absolute */
#define GetAB(target) \
{ \
target=RdAtPC(); \
IncPC(); \
target|=RdAtPC()<<8; \
IncPC(); \
}
/* Absolute Indexed(for reads) */
#define GetABI(target, i) \
{ \
unsigned int tmp; \
GetAB(tmp); \
target=tmp; \
target+=i; \
}
/* Zero Page */
#define GetZP(target) \
{ \
target=RdAtPC(); \
IncPC(); \
}
/* Zero Page Indexed */
#define GetZPI(target,i) \
{ \
target=i+RdAtPC(); \
IncPC(); \
}
/* Indirect */
#define GetIND(target) \
{ \
uint8 tmp; \
tmp=RdAtPC(); \
IncPC(); \
target=HU_Page1[tmp]; \
tmp++; \
target|=HU_Page1[tmp]<<8; \
}
/* Indexed Indirect */
#define GetIX(target) \
{ \
uint8 tmp; \
tmp=RdAtPC(); \
IncPC(); \
tmp+=HU_X; \
target=HU_Page1[tmp]; \
tmp++; \
target|=HU_Page1[tmp] <<8; \
}
/* Indirect Indexed(for reads) */
#define GetIY(target) \
{ \
unsigned int rt; \
uint8 tmp; \
tmp=RdAtPC(); \
rt=HU_Page1[tmp]; \
tmp++; \
rt|=HU_Page1[tmp]<<8; \
target = (rt + HU_Y); \
IncPC(); \
}
/* Now come the macros to wrap up all of the above stuff addressing mode functions
and operation macros. Note that operation macros will always operate(redundant
redundant) on the variable "x".
*/
#define RMW_A(op) {uint8 x=HU_A; op; HU_A=x; break; } /* Meh... */
#define RMW_AB(op) {unsigned int EA; uint8 x; GetAB(EA); x=RdMem(EA); op; WrMem(EA,x); break; }
#define RMW_ABI(reg,op) {unsigned int EA; uint8 x; GetABI(EA,reg); x=RdMem(EA); op; WrMem(EA,x); break; }
#define RMW_ABX(op) RMW_ABI(HU_X,op)
#define RMW_ABY(op) RMW_ABI(HU_Y,op)
#define RMW_IND(op) { unsigned int EA; uint8 x; GetIND(EA); x = RdMem(EA); op; WrMem(EA, x); break; }
#define RMW_IX(op) { unsigned int EA; uint8 x; GetIX(EA); x=RdMem(EA); op; WrMem(EA,x); break; }
#define RMW_IY(op) { unsigned int EA; uint8 x; GetIY(EA); x=RdMem(EA); op; WrMem(EA,x); break; }
#define RMW_ZP(op) { uint8 EA; uint8 x; GetZP(EA); x=HU_Page1[EA]; op; HU_Page1[EA] = x; break; }
#define RMW_ZPX(op) { uint8 EA; uint8 x; GetZPI(EA,HU_X); x=HU_Page1[EA]; op; HU_Page1[EA] = x; break;}
#define LD_IM(op) { uint8 x; x=RdAtPC(); IncPC(); op; break; }
#define LD_ZP(op) { uint8 EA; uint8 x; GetZP(EA); x=HU_Page1[EA]; op; break; }
#define LD_ZPX(op) { uint8 EA; uint8 x; GetZPI(EA,HU_X); x=HU_Page1[EA]; op; break; }
#define LD_ZPY(op) { uint8 EA; uint8 x; GetZPI(EA,HU_Y); x=HU_Page1[EA]; op; break; }
#define LD_AB(op) { unsigned int EA; uint8 x; GetAB(EA); x=RdMem(EA); op; break; }
#define LD_ABI(reg,op) { unsigned int EA; uint8 x; GetABI(EA,reg); x=RdMem(EA); op; break; }
#define LD_ABX(op) LD_ABI(HU_X,op)
#define LD_ABY(op) LD_ABI(HU_Y,op)
#define LD_IND(op) { unsigned int EA; uint8 x; GetIND(EA); x=RdMem(EA); op; break; }
#define LD_IX(op) { unsigned int EA; uint8 x; GetIX(EA); x=RdMem(EA); op; break; }
#define LD_IY(op) { unsigned int EA; uint8 x; GetIY(EA); x=RdMem(EA); op; break; }
#define BMT_PREHONK(pork) HuCPU.in_block_move = IBM_##pork;
#define BMT_HONKHONK(pork) if(HuCPU.timestamp >= next_user_event) goto GetOutBMT; continue_the_##pork:
#define BMT_TDD BMT_PREHONK(TDD); do { ADDCYC(6); WrMem(HuCPU.bmt_dest, RdMem(HuCPU.bmt_src)); HuCPU.bmt_src--; HuCPU.bmt_dest--; BMT_HONKHONK(TDD); HuCPU.bmt_length--; } while(HuCPU.bmt_length);
#define BMT_TAI BMT_PREHONK(TAI); {HuCPU.bmt_alternate = 0; do { ADDCYC(6); WrMem(HuCPU.bmt_dest, RdMem(HuCPU.bmt_src + HuCPU.bmt_alternate)); HuCPU.bmt_dest++; HuCPU.bmt_alternate ^= 1; BMT_HONKHONK(TAI); HuCPU.bmt_length--; } while(HuCPU.bmt_length); }
#define BMT_TIA BMT_PREHONK(TIA); {HuCPU.bmt_alternate = 0; do { ADDCYC(6); WrMem(HuCPU.bmt_dest + HuCPU.bmt_alternate, RdMem(HuCPU.bmt_src)); HuCPU.bmt_src++; HuCPU.bmt_alternate ^= 1; BMT_HONKHONK(TIA); HuCPU.bmt_length--; } while(HuCPU.bmt_length); }
#define BMT_TII BMT_PREHONK(TII); do { ADDCYC(6); WrMem(HuCPU.bmt_dest, RdMem(HuCPU.bmt_src)); HuCPU.bmt_src++; HuCPU.bmt_dest++; BMT_HONKHONK(TII); HuCPU.bmt_length--; } while(HuCPU.bmt_length);
#define BMT_TIN BMT_PREHONK(TIN); do { ADDCYC(6); WrMem(HuCPU.bmt_dest, RdMem(HuCPU.bmt_src)); HuCPU.bmt_src++; BMT_HONKHONK(TIN); HuCPU.bmt_length--; } while(HuCPU.bmt_length);
// Block memory transfer load
#define LD_BMT(op) { PUSH(HU_Y); PUSH(HU_A); PUSH(HU_X); GetAB(HuCPU.bmt_src); GetAB(HuCPU.bmt_dest); GetAB(HuCPU.bmt_length); op; HuCPU.in_block_move = 0; HU_X = POP(); HU_A = POP(); HU_Y = POP(); break; }
#define ST_ZP(r) {uint8 EA; GetZP(EA); HU_Page1[EA] = r; break;}
#define ST_ZPX(r) {uint8 EA; GetZPI(EA,HU_X); HU_Page1[EA] = r; break;}
#define ST_ZPY(r) {uint8 EA; GetZPI(EA,HU_Y); HU_Page1[EA] = r; break;}
#define ST_AB(r) {unsigned int EA; GetAB(EA); WrMem(EA, r); break;}
#define ST_ABI(reg,r) {unsigned int EA; GetABI(EA,reg); WrMem(EA,r); break; }
#define ST_ABX(r) ST_ABI(HU_X,r)
#define ST_ABY(r) ST_ABI(HU_Y,r)
#define ST_IND(r) {unsigned int EA; GetIND(EA); WrMem(EA,r); break; }
#define ST_IX(r) {unsigned int EA; GetIX(EA); WrMem(EA,r); break; }
#define ST_IY(r) {unsigned int EA; GetIY(EA); WrMem(EA,r); break; }
static const uint8 CycTable[256] =
{
/*0x00*/ 8, 7, 3, 4, 6, 4, 6, 7, 3, 2, 2, 2, 7, 5, 7, 6,
/*0x10*/ 2, 7, 7, 4, 6, 4, 6, 7, 2, 5, 2, 2, 7, 5, 7, 6,
/*0x20*/ 7, 7, 3, 4, 4, 4, 6, 7, 4, 2, 2, 2, 5, 5, 7, 6,
/*0x30*/ 2, 7, 7, 2, 4, 4, 6, 7, 2, 5, 2, 2, 5, 5, 7, 6,
/*0x40*/ 7, 7, 3, 4, 8, 4, 6, 7, 3, 2, 2, 2, 4, 5, 7, 6,
/*0x50*/ 2, 7, 7, 5, 3, 4, 6, 7, 2, 5, 3, 2, 2, 5, 7, 6,
/*0x60*/ 7, 7, 2, 2, 4, 4, 6, 7, 4, 2, 2, 2, 7, 5, 7, 6,
/*0x70*/ 2, 7, 7, 17, 4, 4, 6, 7, 2, 5, 4, 2, 7, 5, 7, 6,
/*0x80*/ 4, 7, 2, 7, 4, 4, 4, 7, 2, 2, 2, 2, 5, 5, 5, 6,
/*0x90*/ 2, 7, 7, 8, 4, 4, 4, 7, 2, 5, 2, 2, 5, 5, 5, 6,
/*0xA0*/ 2, 7, 2, 7, 4, 4, 4, 7, 2, 2, 2, 2, 5, 5, 5, 6,
/*0xB0*/ 2, 7, 7, 8, 4, 4, 4, 7, 2, 5, 2, 2, 5, 5, 5, 6,
/*0xC0*/ 2, 7, 2, 17, 4, 4, 6, 7, 2, 2, 2, 2, 5, 5, 7, 6,
/*0xD0*/ 2, 7, 7, 17, 3, 4, 6, 7, 2, 5, 3, 2, 2, 5, 7, 6,
/*0xE0*/ 2, 7, 2, 17, 4, 4, 6, 7, 2, 2, 2, 2, 5, 5, 7, 6,
/*0xF0*/ 2, 7, 7, 17, 2, 4, 6, 7, 2, 5, 4, 2, 2, 5, 7, 6,
};
#if 0
static bool WillIRQOccur(void) NO_INLINE;
static bool WillIRQOccur(void)
{
bool ret = false;
if(HU_IRQlow)
{
if(!(HU_PI&I_FLAG))
{
if(HU_IRQlow & MDFN_IQTIMER & HuCPU.IRQMaskDelay)
ret = true;
else if((HU_IRQlow & MDFN_IQIRQ1 & HuCPU.IRQMaskDelay) || ((HU_IRQlow >> 8) & MDFN_IQIRQ1 & HuCPU.IRQMaskDelay))
ret = true;
else if(HU_IRQlow & MDFN_IQIRQ2 & HuCPU.IRQMaskDelay)
ret = true;
}
}
return(true);
}
#endif
void HuC6280_IRQBegin(int w)
{
HU_IRQlow|=w;
}
void HuC6280_IRQEnd(int w)
{
HU_IRQlow&=~w;
}
void HuC6280_Reset(void)
{
HuCPU.timer_next_timestamp = HuCPU.timestamp + 1024;
HuCPU.timer_load = 0;
HuCPU.timer_value = 0;
HuCPU.timer_status = 0;
HuCPU.in_block_move = 0;
unsigned int npc;
HuCPU.IRQMask = HuCPU.IRQMaskDelay = 7;
HuC6280_SetMPR(0, 0xFF);
HuC6280_SetMPR(1, 0xF8);
for(int i = 2; i < 8; i++)
HuC6280_SetMPR(i, 0);
npc = RdMem16(0xFFFE);
#define PC_local HuCPU.PC
SetPC(npc);
#undef PC_local
HuCPU.mooPI = I_FLAG;
HuCPU.P = I_FLAG;
HU_IRQlow = 0;
}
void HuC6280_Init(void)
{
memset((void *)&HuCPU,0,sizeof(HuCPU));
memset(dummy_bank, 0, sizeof(dummy_bank));
#ifdef HUC6280_LAZY_FLAGS
#else
for(int x=0; x < 256; x++)
if(!x) ZNTable[x]=Z_FLAG;
else if (x&0x80) ZNTable[x]=N_FLAG;
else ZNTable[x]=0;
#endif
}
void HuC6280_Power(void)
{
HuCPU.IRQlow = 0;
HuCPU.A = 0;
HuCPU.X = 0;
HuCPU.Y = 0;
HuCPU.S = 0;
HuCPU.P = 0;
HuCPU.mooPI = 0;
#if 0
HU_PC = HU_PC_base = NULL;
#else
HuCPU.PC = 0;
#endif
HuCPU.timestamp = 0;
for(int i = 0; i < 9; i++)
{
HuCPU.MPR[i] = 0;
HuCPU.FastPageR[i] = NULL;
}
HuC6280_Reset();
}
void HuC6280_Run(int32 cycles)
{
const int32 next_user_event = HuCPU.previous_next_user_event + cycles * pce_overclocked;
HuCPU.previous_next_user_event = next_user_event;
LOAD_LOCALS();
if(HuCPU.timestamp >= next_user_event)
return;
int32 next_event;
if(HuCPU.in_block_move)
{
next_event = (next_user_event < HuCPU.timer_next_timestamp) ? next_user_event : HuCPU.timer_next_timestamp;
switch(HuCPU.in_block_move)
{
case IBM_TIA: goto continue_the_TIA;
case IBM_TAI: goto continue_the_TAI;
case IBM_TDD: goto continue_the_TDD;
case IBM_TII: goto continue_the_TII;
case IBM_TIN: goto continue_the_TIN;
}
}
while(HuCPU.timestamp < next_user_event)
{
next_event = (next_user_event < HuCPU.timer_next_timestamp) ? next_user_event : HuCPU.timer_next_timestamp;
while(HuCPU.timestamp < next_event)
{
uint8 b1;
if(HU_IRQlow)
{
if(!(HU_PI&I_FLAG))
{
uint32 tmpa = 0;
if(HU_IRQlow & MDFN_IQTIMER & HuCPU.IRQMaskDelay)
tmpa = 0xFFFA;
else if((HU_IRQlow & MDFN_IQIRQ1 & HuCPU.IRQMaskDelay) || ((HU_IRQlow >> 8) & MDFN_IQIRQ1 & HuCPU.IRQMaskDelay))
tmpa = 0xFFF8;
else if(HU_IRQlow & MDFN_IQIRQ2 & HuCPU.IRQMaskDelay)
tmpa = 0xFFF6;
if(tmpa)
{
unsigned int npc;
ADDCYC(8);
PUSH_PC();
COMPRESS_FLAGS();
PUSH((HU_P&~B_FLAG));
HU_P |= I_FLAG;
HU_P &= ~(T_FLAG | D_FLAG);
HU_PI = HU_P;
npc = RdMem16(tmpa);
SetPC(npc);
if(tmpa == 0xFFF8)
HU_IRQlow &= ~0x200;
continue;
}
}
} // end if(HU_IRQlow)
//printf("%04x\n", GetRealPC());
HU_PI = HU_P;
HuCPU.IRQMaskDelay = HuCPU.IRQMask;
b1 = RdAtPC();
ADDCYC(CycTable[b1]);
IncPC();
switch(b1)
{
#include "huc6280_ops.inc"
}
#ifndef HUC6280_EXTRA_CRAZY
FixPC_PC();
#endif
} // end while(HuCPU.timestamp < next_event)
while(HuCPU.timestamp >= HuCPU.timer_next_timestamp)
{
HuCPU.timer_next_timestamp += 1024 * pce_overclocked;
if(HuCPU.timer_status)
{
HuCPU.timer_value --;
if(HuCPU.timer_value < 0)
{
HuCPU.timer_value = HuCPU.timer_load;
HuC6280_IRQBegin(MDFN_IQTIMER);
}
}
}
} // end while(HuCPU.timestamp < next_user_event)
GetOutBMT:
SAVE_LOCALS();
}
void HuC6280_ResetTS(void)
{
HuCPU.timer_next_timestamp -= HuCPU.timestamp;
HuCPU.previous_next_user_event -= HuCPU.timestamp;
HuCPU.timestamp = 0;
}
int HuC6280_StateAction(StateMem *sm, int load, int data_only)
{
uint16 tmp_PC = GetRealPC_EXTERNAL();
#define P_local HuCPU.P
COMPRESS_FLAGS();
SFORMAT SFCPU[]=
{
SFVARN(tmp_PC, "PC"),
SFVARN(HuCPU.A, "A"),
SFVARN(HuCPU.P, "P"),
SFVARN(HuCPU.X, "X"),
SFVARN(HuCPU.Y, "Y"),
SFVARN(HuCPU.S, "S"),
SFVARN(HuCPU.mooPI, "PI"),
SFVARN(HuCPU.IRQMask, "IRQMask"),
SFVARN(HuCPU.IRQMaskDelay, "IRQMaskDelay"),
SFARRAYN(HuCPU.MPR, 8, "MPR"),
SFVARN(HuCPU.timer_status, "timer_status"),
SFVARN(HuCPU.timer_value, "timer_value"),
SFVARN(HuCPU.timer_load, "timer_load"),
SFVARN(HuCPU.IRQlow, "IRQlow"),
SFVARN(HuCPU.in_block_move, "IBM"),
SFVARN(HuCPU.bmt_src, "IBM_SRC"),
SFVARN(HuCPU.bmt_dest, "IBM_DEST"),
SFVARN(HuCPU.bmt_length, "IBM_LENGTH"),
SFVARN(HuCPU.bmt_alternate, "IBM_ALTERNATE"),
SFVARN(HuCPU.timestamp, "timestamp"),
SFVARN(HuCPU.timer_next_timestamp, "timer_next_timestamp"),
SFVARN(HuCPU.previous_next_user_event, "previous_next_user_event"),
SFEND
};
int ret = MDFNSS_StateAction(sm, load, data_only, SFCPU, "CPU");
if(load)
{
// Update MPR cache
HuC6280_FlushMPRCache();
// This must be after the MPR cache is updated:
SetPC_EXTERNAL(tmp_PC);
}
EXPAND_FLAGS();
#undef P_local
return(ret);
}
};