unsigned char cdrRead1(void) {
if (cdr.ResultReady) { // && cdr.Ctrl & 0x1) {
psxHu8(0x1801) = cdr.Result[cdr.ResultP++];
if (cdr.ResultP == cdr.ResultC) cdr.ResultReady = 0;
} else psxHu8(0x1801) = 0;
#ifdef CDR_LOG
CDR_LOG("cdrRead1() Log: CD1 Read: %x\n", psxHu8(0x1801));
#endif
return psxHu8(0x1801);
}
unsigned char cdrRead3(void) {
if (cdr.Stat) {
if (cdr.Ctrl & 0x1) psxHu8(0x1803) = cdr.Stat | 0xE0;
else psxHu8(0x1803) = 0xff;
} else psxHu8(0x1803) = 0;
#ifdef CDR_LOG
CDR_LOG("cdrRead3() Log: CD3 Read: %x\n", psxHu8(0x1803));
#endif
return psxHu8(0x1803);
}
u8 cdrRead3(void) {
if (cdr.Stat) {
if (cdr.Ctrl & 0x1)
psxHu8(0x1803) = cdr.Stat | 0xE0;
else
psxHu8(0x1803) = 0xff;
} else psxHu8(0x1803) = 0;
CDVD_LOG("CD3 Read: %x", psxHu8(0x1803));
return psxHu8(0x1803);
}
u8 cdrRead1(void) {
if (cdr.ResultReady && cdr.Ctrl & 0x1) {
psxHu8(0x1801) = cdr.Result[cdr.ResultP++];
if (cdr.ResultP == cdr.ResultC) cdr.ResultReady = 0;
}
else
psxHu8(0x1801) = 0;
CDVD_LOG("CD1 Read: %x", psxHu8(0x1801));
return psxHu8(0x1801);
}
u8 psxHwRead8(u32 add) {
unsigned char hard;
switch (add) {
case 0x1f801040: hard = sioRead8();break;
#ifdef ENABLE_SIO1API
case 0x1f801050: hard = SIO1_readData8(); break;
#endif
case 0x1f801800: hard = cdrRead0(); break;
case 0x1f801801: hard = cdrRead1(); break;
case 0x1f801802: hard = cdrRead2(); break;
case 0x1f801803: hard = cdrRead3(); break;
default:
hard = psxHu8(add);
#ifdef PSXHW_LOG
PSXHW_LOG("*Unkwnown 8bit read at address %x\n", add);
#endif
return hard;
}
#ifdef PSXHW_LOG
PSXHW_LOG("*Known 8bit read at address %x value %x\n", add, hard);
#endif
return hard;
}
void psxMemWrite8(u32 mem, u8 value) {
char *p;
u32 t;
psxRegs.cycle += 1;
t = mem >> 16;
if (t == 0x1f80 || t == 0x9f80 || t == 0xbf80) {
if ((mem & 0xffff) < 0x400)
psxHu8(mem) = value;
else
psxHwWrite8(mem, value);
} else {
p = (char *)(psxMemWLUT[t]);
if (p != NULL) {
if (Config.Debug)
DebugCheckBP((mem & 0xffffff) | 0x80000000, BW1);
*(u8 *)(p + (mem & 0xffff)) = value;
#ifdef PSXREC
psxCpu->Clear((mem & (~3)), 1);
#endif
} else {
#ifdef PSXMEM_LOG
PSXMEM_LOG("err sb %8.8lx\n", mem);
#endif
}
}
}
u8 psxMemRead8(u32 mem) {
char *p;
u32 t;
psxRegs.cycle += 0;
t = mem >> 16;
if (t == 0x1f80 || t == 0x9f80 || t == 0xbf80) {
if ((mem & 0xffff) < 0x400)
return psxHu8(mem);
else
return psxHwRead8(mem);
} else {
p = (char *)(psxMemRLUT[t]);
if (p != NULL) {
if (Config.Debug)
DebugCheckBP((mem & 0xffffff) | 0x80000000, BR1);
return *(u8 *)(p + (mem & 0xffff));
} else {
#ifdef PSXMEM_LOG
PSXMEM_LOG("err lb %8.8lx\n", mem);
#endif
return 0;
}
}
}
void psxHwWrite8(u32 add, u8 value) {
switch (add) {
case 0x1f801040: sioWrite8(value); break;
#ifdef ENABLE_SIO1API
case 0x1f801050: SIO1_writeData8(value); break;
#endif
case 0x1f801800: cdrWrite0(value); break;
case 0x1f801801: cdrWrite1(value); break;
case 0x1f801802: cdrWrite2(value); break;
case 0x1f801803: cdrWrite3(value); break;
default:
psxHu8(add) = value;
#ifdef PSXHW_LOG
PSXHW_LOG("*Unknown 8bit write at address %x value %x\n", add, value);
#endif
return;
}
psxHu8(add) = value;
#ifdef PSXHW_LOG
PSXHW_LOG("*Known 8bit write at address %x value %x\n", add, value);
#endif
}
mem8_t __fastcall iopHwRead8_Page8( u32 addr )
{
HwAddrPrep( 8 );
mem8_t ret;
if( addr == HW_SIO2_FIFO )
ret = sio2_fifoOut();//sio2 serial data feed/fifo_out
else
ret = psxHu8( addr );
PSXHW_LOG( "HwRead8 from %s, addr 0x%08x = 0x%02x", _log_GetIopHwName<mem8_t>( addr ), addr, psxHu8(addr) );
return ret;
}
mem8_t __fastcall iopHwRead8_Page3( u32 addr )
{
// all addresses are assumed to be prefixed with 0x1f803xxx:
HwAddrPrep( 3 );
mem8_t ret;
if( addr == 0x1f803100 ) // PS/EE/IOP conf related
ret = 0x10; // Dram 2M
else
ret = psxHu8( addr );
PSXHW_LOG( "HwRead8 from %s, addr 0x%08x = 0x%02x", _log_GetIopHwName<mem8_t>( addr ), addr, psxHu8(addr) );
return ret;
}
unsigned char cdrRead0(void) {
if (cdr.ResultReady) cdr.Ctrl|= 0x20;
else cdr.Ctrl&=~0x20;
if (cdr.OCUP) cdr.Ctrl|= 0x40;
// else cdr.Ctrl&=~0x40;
// what means the 0x10 and the 0x08 bits? i only saw it used by the bios
cdr.Ctrl|=0x18;
#ifdef CDR_LOG
CDR_LOG("cdrRead0() Log: CD0 Read: %x\n", cdr.Ctrl);
#endif
return psxHu8(0x1800) = cdr.Ctrl;
}
u8 cdrRead0(void) {
if (cdr.ResultReady)
cdr.Ctrl |= 0x20;
else
cdr.Ctrl &= ~0x20;
if (cdr.OCUP)
cdr.Ctrl |= 0x40;
else
cdr.Ctrl &= ~0x40;
// what means the 0x10 and the 0x08 bits? i only saw it used by the bios
cdr.Ctrl|=0x18;
CDVD_LOG("CD0 Read: %x", cdr.Ctrl);
return psxHu8(0x1800) = cdr.Ctrl;
}
u8 psxMemRead8(u32 mem) {
u32 t;
t = mem >> 16;
if (t == 0x1f80) {
if (mem < 0x1f801000)
return psxHu8(mem);
else
return psxHwRead8(mem);
} else {
char *p = (char *)(psxMemRLUT[t]);
if (p != NULL) {
return *(u8 *)(p + (mem & 0xffff));
} else {
#ifdef PSXMEM_LOG
PSXMEM_LOG("err lb %8.8lx\n", mem);
#endif
return 0;
}
}
}
void psxMemWrite8(u32 mem, u8 value) {
u32 t;
t = mem >> 16;
if (t == 0x1f80) {
if (mem < 0x1f801000)
psxHu8(mem) = value;
else
psxHwWrite8(mem, value);
} else {
char *p = (char *)(psxMemWLUT[t]);
if (p != NULL) {
*(u8 *)(p + (mem & 0xffff)) = value;
#ifdef PSXREC
psxCpu->Clear((mem&(~3)), 1);
#endif
} else {
#ifdef PSXMEM_LOG
PSXMEM_LOG("err sb %8.8lx\n", mem);
#endif
}
}
}
u8 psxHwRead8(u32 add) {
return psxHu8(add);
}
void psxHwWrite8(u32 add, u8 value) {
psxHu8(add) = value;
}
