np2/i386c/memory.c - diff

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Diff for /np2/i386c/memory.c between versions 1.32 and 1.40

version 1.32, 2005/03/16 06:05:18	version 1.40, 2012/01/29 14:53:54
Line 30 typedef REG16 (MEMCALL * MEM16READ)(UINT	Line 30 typedef REG16 (MEMCALL * MEM16READ)(UINT

static REG8 MEMCALL memmain_rd8(UINT32 address) {	static REG8 MEMCALL memmain_rd8(UINT32 address) {

return(mem[address & CPU_ADRSMASK]);	return(mem[address]);
}	}

static REG16 MEMCALL memmain_rd16(UINT32 address) {	static REG16 MEMCALL memmain_rd16(UINT32 address) {

const UINT8 *ptr;	const UINT8 *ptr;

ptr = mem + (address & CPU_ADRSMASK);	ptr = mem + address;
return(LOADINTELWORD(ptr));	return(LOADINTELWORD(ptr));
}	}

static void MEMCALL memmain_wr8(UINT32 address, REG8 value) {	static void MEMCALL memmain_wr8(UINT32 address, REG8 value) {

mem[address & CPU_ADRSMASK] = (UINT8)value;	mem[address] = (UINT8)value;
}	}

static void MEMCALL memmain_wr16(UINT32 address, REG16 value) {	static void MEMCALL memmain_wr16(UINT32 address, REG16 value) {

UINT8 *ptr;	UINT8 *ptr;

ptr = mem + (address & CPU_ADRSMASK);	ptr = mem + address;
STOREINTELWORD(ptr, value);	STOREINTELWORD(ptr, value);
}	}

Line 82 static void MEMCALL memnc_wr16(UINT32 ad	Line 82 static void MEMCALL memnc_wr16(UINT32 ad
}	}


// ---- memory 000000-0ffffff	// ---- memory 000000-0ffffff + 64KB

typedef struct {	typedef struct {
MEM8READ rd8[0x20];	MEM8READ rd8[0x22];
MEM8WRITE wr8[0x20];	MEM8WRITE wr8[0x22];
MEM16READ rd16[0x20];	MEM16READ rd16[0x22];
MEM16WRITE wr16[0x20];	MEM16WRITE wr16[0x22];
} MEMFN0;	} MEMFN0;

typedef struct {	typedef struct {
Line 115 static MEMFN0 memfn0 = {	Line 115 static MEMFN0 memfn0 = {
memmain_rd8, memmain_rd8, memmain_rd8, memmain_rd8, // 80	memmain_rd8, memmain_rd8, memmain_rd8, memmain_rd8, // 80
memtram_rd8, memvram0_rd8, memvram0_rd8, memvram0_rd8, // a0	memtram_rd8, memvram0_rd8, memvram0_rd8, memvram0_rd8, // a0
memems_rd8, memems_rd8, memmain_rd8, memmain_rd8, // c0	memems_rd8, memems_rd8, memmain_rd8, memmain_rd8, // c0
memvram0_rd8, memmain_rd8, memmain_rd8, memf800_rd8}, // e0	memvram0_rd8, memmain_rd8, memmain_rd8, memf800_rd8, // e0
	memmain_rd8, memmain_rd8},

{memmain_wr8, memmain_wr8, memmain_wr8, memmain_wr8, // 00	{memmain_wr8, memmain_wr8, memmain_wr8, memmain_wr8, // 00
memmain_wr8, memmain_wr8, memmain_wr8, memmain_wr8, // 20	memmain_wr8, memmain_wr8, memmain_wr8, memmain_wr8, // 20
Line 124 static MEMFN0 memfn0 = {	Line 125 static MEMFN0 memfn0 = {
memmain_wr8, memmain_wr8, memmain_wr8, memmain_wr8, // 80	memmain_wr8, memmain_wr8, memmain_wr8, memmain_wr8, // 80
memtram_wr8, memvram0_wr8, memvram0_wr8, memvram0_wr8, // a0	memtram_wr8, memvram0_wr8, memvram0_wr8, memvram0_wr8, // a0
memems_wr8, memems_wr8, memd000_wr8, memd000_wr8, // c0	memems_wr8, memems_wr8, memd000_wr8, memd000_wr8, // c0
memvram0_wr8, memnc_wr8, memnc_wr8, memnc_wr8}, // e0	memvram0_wr8, memnc_wr8, memnc_wr8, memnc_wr8, // e0
	memmain_wr8, memmain_wr8},

{memmain_rd16, memmain_rd16, memmain_rd16, memmain_rd16, // 00	{memmain_rd16, memmain_rd16, memmain_rd16, memmain_rd16, // 00
memmain_rd16, memmain_rd16, memmain_rd16, memmain_rd16, // 20	memmain_rd16, memmain_rd16, memmain_rd16, memmain_rd16, // 20
Line 133 static MEMFN0 memfn0 = {	Line 135 static MEMFN0 memfn0 = {
memmain_rd16, memmain_rd16, memmain_rd16, memmain_rd16, // 80	memmain_rd16, memmain_rd16, memmain_rd16, memmain_rd16, // 80
memtram_rd16, memvram0_rd16, memvram0_rd16, memvram0_rd16, // a0	memtram_rd16, memvram0_rd16, memvram0_rd16, memvram0_rd16, // a0
memems_rd16, memems_rd16, memmain_rd16, memmain_rd16, // c0	memems_rd16, memems_rd16, memmain_rd16, memmain_rd16, // c0
memvram0_rd16, memmain_rd16, memmain_rd16, memf800_rd16}, // e0	memvram0_rd16, memmain_rd16, memmain_rd16, memf800_rd16, // e0
	memmain_rd16, memmain_rd16},

{memmain_wr16, memmain_wr16, memmain_wr16, memmain_wr16, // 00	{memmain_wr16, memmain_wr16, memmain_wr16, memmain_wr16, // 00
memmain_wr16, memmain_wr16, memmain_wr16, memmain_wr16, // 20	memmain_wr16, memmain_wr16, memmain_wr16, memmain_wr16, // 20
Line 142 static MEMFN0 memfn0 = {	Line 145 static MEMFN0 memfn0 = {
memmain_wr16, memmain_wr16, memmain_wr16, memmain_wr16, // 80	memmain_wr16, memmain_wr16, memmain_wr16, memmain_wr16, // 80
memtram_wr16, memvram0_wr16, memvram0_wr16, memvram0_wr16, // a0	memtram_wr16, memvram0_wr16, memvram0_wr16, memvram0_wr16, // a0
memems_wr16, memems_wr16, memd000_wr16, memd000_wr16, // c0	memems_wr16, memems_wr16, memd000_wr16, memd000_wr16, // c0
memvram0_wr16, memnc_wr16, memnc_wr16, memnc_wr16}}; // e0	memvram0_wr16, memnc_wr16, memnc_wr16, memnc_wr16, // e0
	memmain_wr16, memmain_wr16}};

static const MMAPTBL mmaptbl[2] = {	static const MMAPTBL mmaptbl[2] = {
{memmain_rd8, memf800_rd8, memnc_wr8,	{memmain_rd8, memf800_rd8, memnc_wr8,
Line 169 static const VACCTBL vacctbl[0x10] = {	Line 173 static const VACCTBL vacctbl[0x10] = {
{memegc_rd8, memegc_wr8, memegc_rd16, memegc_wr16}};	{memegc_rd8, memegc_wr8, memegc_rd16, memegc_wr16}};


void MEMCALL i286_memorymap(UINT type) {	void MEMCALL memm_arch(UINT type) {

const MMAPTBL *mm;	const MMAPTBL *mm;

Line 190 const MMAPTBL *mm;	Line 194 const MMAPTBL *mm;
memfn0.wr16[0xf8000 >> 15] = mm->bwr16;	memfn0.wr16[0xf8000 >> 15] = mm->bwr16;
}	}

void MEMCALL i286_vram_dispatch(UINT func) {	void MEMCALL memm_vram(UINT func) {

const VACCTBL *vacc;	const VACCTBL *vacc;

#if defined(SUPPORT_PC9821)	#if defined(SUPPORT_PC9821)
if (!(func & 0x20)) {	if (!(func & 0x20)) {
#endif	#endif // defined(SUPPORT_PC9821)
vacc = vacctbl + (func & 0x0f);	vacc = vacctbl + (func & 0x0f);

memfn0.rd8[0xa8000 >> 15] = vacc->rd8;	memfn0.rd8[0xa8000 >> 15] = vacc->rd8;
memfn0.rd8[0xb0000 >> 15] = vacc->rd8;	memfn0.rd8[0xb0000 >> 15] = vacc->rd8;
memfn0.rd8[0xb8000 >> 15] = vacc->rd8;	memfn0.rd8[0xb8000 >> 15] = vacc->rd8;
Line 218 const VACCTBL *vacc;	Line 223 const VACCTBL *vacc;
memfn0.wr16[0xb8000 >> 15] = vacc->wr16;	memfn0.wr16[0xb8000 >> 15] = vacc->wr16;
memfn0.wr16[0xe0000 >> 15] = vacc->wr16;	memfn0.wr16[0xe0000 >> 15] = vacc->wr16;

if (!(func & 0x10)) { // digital	if (!(func & (1 << VOPBIT_ANALOG))) { // digital
memfn0.rd8[0xe0000 >> 15] = memnc_rd8;	memfn0.rd8[0xe0000 >> 15] = memnc_rd8;
memfn0.wr8[0xe0000 >> 15] = memnc_wr8;	memfn0.wr8[0xe0000 >> 15] = memnc_wr8;
memfn0.rd16[0xe0000 >> 15] = memnc_rd16;	memfn0.rd16[0xe0000 >> 15] = memnc_rd16;
Line 228 const VACCTBL *vacc;	Line 233 const VACCTBL *vacc;
}	}
else {	else {
memfn0.rd8[0xa8000 >> 15] = memvga0_rd8;	memfn0.rd8[0xa8000 >> 15] = memvga0_rd8;
memfn0.rd8[0xb0000 >> 15] = memvga0_rd8;	memfn0.rd8[0xb0000 >> 15] = memvga1_rd8;
memfn0.rd8[0xb8000 >> 15] = memnc_rd8;	memfn0.rd8[0xb8000 >> 15] = memnc_rd8;
memfn0.rd8[0xe0000 >> 15] = memvgaio_rd8;	memfn0.rd8[0xe0000 >> 15] = memvgaio_rd8;

memfn0.wr8[0xa8000 >> 15] = memvga0_wr8;	memfn0.wr8[0xa8000 >> 15] = memvga0_wr8;
memfn0.wr8[0xb0000 >> 15] = memvga0_wr8;	memfn0.wr8[0xb0000 >> 15] = memvga1_wr8;
memfn0.wr8[0xb8000 >> 15] = memnc_wr8;	memfn0.wr8[0xb8000 >> 15] = memnc_wr8;
memfn0.wr8[0xe0000 >> 15] = memvgaio_wr8;	memfn0.wr8[0xe0000 >> 15] = memvgaio_wr8;

memfn0.rd16[0xa8000 >> 15] = memvga0_rd16;	memfn0.rd16[0xa8000 >> 15] = memvga0_rd16;
memfn0.rd16[0xb0000 >> 15] = memvga0_rd16;	memfn0.rd16[0xb0000 >> 15] = memvga1_rd16;
memfn0.rd16[0xb8000 >> 15] = memnc_rd16;	memfn0.rd16[0xb8000 >> 15] = memnc_rd16;
memfn0.rd16[0xe0000 >> 15] = memvgaio_rd16;	memfn0.rd16[0xe0000 >> 15] = memvgaio_rd16;

memfn0.wr16[0xa8000 >> 15] = memvga0_wr16;	memfn0.wr16[0xa8000 >> 15] = memvga0_wr16;
memfn0.wr16[0xb0000 >> 15] = memvga0_wr16;	memfn0.wr16[0xb0000 >> 15] = memvga1_wr16;
memfn0.wr16[0xb8000 >> 15] = memnc_wr16;	memfn0.wr16[0xb8000 >> 15] = memnc_wr16;
memfn0.wr16[0xe0000 >> 15] = memvgaio_wr16;	memfn0.wr16[0xe0000 >> 15] = memvgaio_wr16;
}	}
#endif	#endif // defined(SUPPORT_PC9821)
}	}


Line 264 typedef struct {	Line 269 typedef struct {
static REG8 MEMCALL memsys_rd8(UINT32 address) {	static REG8 MEMCALL memsys_rd8(UINT32 address) {

address -= 0xf00000;	address -= 0xf00000;
return(memfn0.rd8[(address >> 15) & 0x1f](address));	return(memfn0.rd8[address >> 15](address));
}	}

static REG16 MEMCALL memsys_rd16(UINT32 address) {	static REG16 MEMCALL memsys_rd16(UINT32 address) {

address -= 0xf00000;	address -= 0xf00000;
return(memfn0.rd16[(address >> 15) & 0x1f](address));	return(memfn0.rd16[address >> 15](address));
}	}

static void MEMCALL memsys_wr8(UINT32 address, REG8 value) {	static void MEMCALL memsys_wr8(UINT32 address, REG8 value) {

address -= 0xf00000;	address -= 0xf00000;
memfn0.wr8[(address >> 15) & 0x1f](address, value);	memfn0.wr8[address >> 15](address, value);
}	}

static void MEMCALL memsys_wr16(UINT32 address, REG16 value) {	static void MEMCALL memsys_wr16(UINT32 address, REG16 value) {

address -= 0xf00000;	address -= 0xf00000;
memfn0.wr16[(address >> 15) & 0x1f](address, value);	memfn0.wr16[address >> 15](address, value);
}	}

#if defined(SUPPORT_PC9821)	#if defined(SUPPORT_PC9821)
Line 312 static const MEMFNF memfnf = {	Line 317 static const MEMFNF memfnf = {

// ----	// ----

REG8 MEMCALL i286_memoryread(UINT32 addr) {	REG8 MEMCALL memp_read8(UINT32 address) {

if (addr < I286_MEMREADMAX) {	if (address < I286_MEMREADMAX) {
return(mem[addr]);	return(mem[address]);
}	}
else {	else {
addr = addr & CPU_ADRSMASK;	address = address & CPU_ADRSMASK;
if (addr < USE_HIMEM) {	if (address < USE_HIMEM) {
return(memfn0.rd8[(addr >> 15) & 0x1f](addr));	return(memfn0.rd8[address >> 15](address));
}	}
else if (addr < CPU_EXTLIMIT16) {	else if (address < CPU_EXTLIMIT16) {
return(CPU_EXTMEMBASE[addr]);	return(CPU_EXTMEMBASE[address]);
}	}
else if (addr < 0x00f00000) {	else if (address < 0x00f00000) {
return(0xff);	return(0xff);
}	}
else if (addr < 0x01000000) {	else if (address < 0x01000000) {
return(memfnf.rd8[(addr >> 17) & 7](addr));	return(memfnf.rd8[(address >> 17) & 7](address));
}	}
else if (addr < CPU_EXTLIMIT) {	#if defined(CPU_EXTLIMIT)
return(CPU_EXTMEMBASE[addr]);	else if (address < CPU_EXTLIMIT) {
	return(CPU_EXTMEMBASE[address]);
}	}
	#endif // defined(CPU_EXTLIMIT)
#if defined(SUPPORT_PC9821)	#if defined(SUPPORT_PC9821)
else if ((addr >= 0xfff00000) && (addr < 0xfff80000)) {	else if ((address >= 0xfff00000) && (address < 0xfff80000)) {
return(memvgaf_rd8(addr));	return(memvgaf_rd8(address));
}	}
#endif	#endif // defined(SUPPORT_PC9821)
else {	else {
// TRACEOUT(("out of mem (read8): %x", addr));	// TRACEOUT(("out of mem (read8): %x", address));
return(0xff);	return(0xff);
}	}
}	}
}	}

REG16 MEMCALL i286_memoryread_w(UINT32 addr) {	REG16 MEMCALL memp_read16(UINT32 address) {

REG16 ret;	REG16 ret;

if (addr < (I286_MEMREADMAX - 1)) {	if (address < (I286_MEMREADMAX - 1)) {
return(LOADINTELWORD(mem + addr));	return(LOADINTELWORD(mem + address));
}	}
else if ((addr + 1) & 0x7fff) { // non 32kb boundary	else if ((address + 1) & 0x7fff) { // non 32kb boundary
addr = addr & CPU_ADRSMASK;	address = address & CPU_ADRSMASK;
if (addr < USE_HIMEM) {	if (address < USE_HIMEM) {
return(memfn0.rd16[(addr >> 15) & 0x1f](addr));	return(memfn0.rd16[address >> 15](address));
}	}
else if (addr < CPU_EXTLIMIT16) {	else if (address < CPU_EXTLIMIT16) {
return(LOADINTELWORD(CPU_EXTMEMBASE + addr));	return(LOADINTELWORD(CPU_EXTMEMBASE + address));
}	}
else if (addr < 0x00f00000) {	else if (address < 0x00f00000) {
return(0xffff);	return(0xffff);
}	}
else if (addr < 0x01000000) {	else if (address < 0x01000000) {
return(memfnf.rd16[(addr >> 17) & 7](addr));	return(memfnf.rd16[(address >> 17) & 7](address));
}	}
else if (addr < CPU_EXTLIMIT) {	#if defined(CPU_EXTLIMIT)
return(LOADINTELWORD(CPU_EXTMEMBASE + addr));	else if (address < CPU_EXTLIMIT) {
	return(LOADINTELWORD(CPU_EXTMEMBASE + address));
}	}
	#endif // defined(CPU_EXTLIMIT)
#if defined(SUPPORT_PC9821)	#if defined(SUPPORT_PC9821)
else if ((addr >= 0xfff00000) && (addr < 0xfff80000)) {	else if ((address >= 0xfff00000) && (address < 0xfff80000)) {
return(memvgaf_rd16(addr));	return(memvgaf_rd16(address));
}	}
#endif	#endif // defined(SUPPORT_PC9821)
else {	else {
// TRACEOUT(("out of mem (read16): %x", addr));	// TRACEOUT(("out of mem (read16): %x", address));
return(0xffff);	return(0xffff);
}	}
}	}
else {	else {
ret = i286_memoryread(addr);	ret = memp_read8(address + 0);
ret += (REG16)(i286_memoryread(addr + 1) << 8);	ret += (REG16)(memp_read8(address + 1) << 8);
return(ret);	return(ret);
}	}
}	}

UINT32 MEMCALL i286_memoryread_d(UINT32 addr) {	UINT32 MEMCALL memp_read32(UINT32 address) {

UINT32 pos;	UINT32 pos;
UINT32 ret;	UINT32 ret;

if (addr < (I286_MEMREADMAX - 3)) {	if (address < (I286_MEMREADMAX - 3)) {
return(LOADINTELDWORD(mem + addr));	return(LOADINTELDWORD(mem + address));
}	}
else if (addr >= USE_HIMEM) {	else if (address >= USE_HIMEM) {
pos = (addr & CPU_ADRSMASK) - 0x100000;	pos = address & CPU_ADRSMASK;
if ((pos + 3) < CPU_EXTMEMSIZE) {	if ((pos >= USE_HIMEM) && ((pos + 3) < CPU_EXTLIMIT16)) {
return(LOADINTELDWORD(CPU_EXTMEM + pos));	return(LOADINTELDWORD(CPU_EXTMEMBASE + pos));
}	}
}	}
if (!(addr & 1)) {	if (!(address & 1)) {
ret = i286_memoryread_w(addr);	ret = memp_read16(address + 0);
ret += (UINT32)i286_memoryread_w(addr + 2) << 16;	ret += (UINT32)memp_read16(address + 2) << 16;
}	}
else {	else {
ret = i286_memoryread(addr);	ret = memp_read8(address + 0);
ret += (UINT32)i286_memoryread_w(addr + 1) << 8;	ret += (UINT32)memp_read16(address + 1) << 8;
ret += (UINT32)i286_memoryread(addr + 3) << 24;	ret += (UINT32)memp_read8(address + 3) << 24;
}	}
return(ret);	return(ret);
}	}

void MEMCALL i286_memorywrite(UINT32 addr, REG8 value) {	void MEMCALL memp_write8(UINT32 address, REG8 value) {

if (addr < I286_MEMWRITEMAX) {	if (address < I286_MEMWRITEMAX) {
mem[addr] = (UINT8)value;	mem[address] = (UINT8)value;
}	}
else {	else {
addr = addr & CPU_ADRSMASK;	address = address & CPU_ADRSMASK;
if (addr < USE_HIMEM) {	if (address < USE_HIMEM) {
memfn0.wr8[(addr >> 15) & 0x1f](addr, value);	memfn0.wr8[address >> 15](address, value);
}	}
else if (addr < CPU_EXTLIMIT16) {	else if (address < CPU_EXTLIMIT16) {
CPU_EXTMEMBASE[addr] = (UINT8)value;	CPU_EXTMEMBASE[address] = (UINT8)value;
}	}
else if (addr < 0x00f00000) {	else if (address < 0x00f00000) {
}	}
else if (addr < 0x01000000) {	else if (address < 0x01000000) {
memfnf.wr8[(addr >> 17) & 7](addr, value);	memfnf.wr8[(address >> 17) & 7](address, value);
}	}
else if (addr < CPU_EXTLIMIT) {	#if defined(CPU_EXTLIMIT)
CPU_EXTMEMBASE[addr] = (UINT8)value;	else if (address < CPU_EXTLIMIT) {
	CPU_EXTMEMBASE[address] = (UINT8)value;
}	}
	#endif // defined(CPU_EXTLIMIT)
#if defined(SUPPORT_PC9821)	#if defined(SUPPORT_PC9821)
else if ((addr >= 0xfff00000) && (addr < 0xfff80000)) {	else if ((address >= 0xfff00000) && (address < 0xfff80000)) {
memvgaf_wr8(addr, value);	memvgaf_wr8(address, value);
}	}
#endif	#endif // defined(SUPPORT_PC9821)
else {	else {
// TRACEOUT(("out of mem (write8): %x", addr));	// TRACEOUT(("out of mem (write8): %x", address));
}	}
}	}
}	}

void MEMCALL i286_memorywrite_w(UINT32 addr, REG16 value) {	void MEMCALL memp_write16(UINT32 address, REG16 value) {

if (addr < (I286_MEMWRITEMAX - 1)) {	if (address < (I286_MEMWRITEMAX - 1)) {
STOREINTELWORD(mem + addr, value);	STOREINTELWORD(mem + address, value);
}	}
else if ((addr + 1) & 0x7fff) { // non 32kb boundary	else if ((address + 1) & 0x7fff) { // non 32kb boundary
addr = addr & CPU_ADRSMASK;	address = address & CPU_ADRSMASK;
if (addr < USE_HIMEM) {	if (address < USE_HIMEM) {
memfn0.wr16[(addr >> 15) & 0x1f](addr, value);	memfn0.wr16[address >> 15](address, value);
}	}
else if (addr < CPU_EXTLIMIT16) {	else if (address < CPU_EXTLIMIT16) {
STOREINTELWORD(CPU_EXTMEMBASE + addr, value);	STOREINTELWORD(CPU_EXTMEMBASE + address, value);
}	}
else if (addr < 0x00f00000) {	else if (address < 0x00f00000) {
}	}
else if (addr < 0x01000000) {	else if (address < 0x01000000) {
memfnf.wr16[(addr >> 17) & 7](addr, value);	memfnf.wr16[(address >> 17) & 7](address, value);
}	}
else if (addr < CPU_EXTLIMIT) {	#if defined(CPU_EXTLIMIT)
STOREINTELWORD(CPU_EXTMEMBASE + addr, value);	else if (address < CPU_EXTLIMIT) {
	STOREINTELWORD(CPU_EXTMEMBASE + address, value);
}	}
	#endif // defined(CPU_EXTLIMIT)
#if defined(SUPPORT_PC9821)	#if defined(SUPPORT_PC9821)
else if ((addr >= 0xfff00000) && (addr < 0xfff80000)) {	else if ((address >= 0xfff00000) && (address < 0xfff80000)) {
memvgaf_wr16(addr, value);	memvgaf_wr16(address, value);
}	}
#endif	#endif // defined(SUPPORT_PC9821)
else {	else {
// TRACEOUT(("out of mem (write16): %x", addr));	// TRACEOUT(("out of mem (write16): %x", address));
}	}
}	}
else {	else {
i286_memorywrite(addr, (UINT8)value);	memp_write8(address + 0, (UINT8)value);
i286_memorywrite(addr + 1, (UINT8)(value >> 8));	memp_write8(address + 1, (UINT8)(value >> 8));
}	}
}	}

void MEMCALL i286_memorywrite_d(UINT32 addr, UINT32 value) {	void MEMCALL memp_write32(UINT32 address, UINT32 value) {

UINT32 pos;	UINT32 pos;

if (addr < (I286_MEMWRITEMAX - 3)) {	if (address < (I286_MEMWRITEMAX - 3)) {
STOREINTELDWORD(mem + addr, value);	STOREINTELDWORD(mem + address, value);
return;	return;
}	}
else if (addr >= USE_HIMEM) {	else if (address >= USE_HIMEM) {
pos = (addr & CPU_ADRSMASK) - 0x100000;	pos = address & CPU_ADRSMASK;
if ((pos + 3) < CPU_EXTMEMSIZE) {	if ((pos >= USE_HIMEM) && ((pos + 3) < CPU_EXTLIMIT16)) {
STOREINTELDWORD(CPU_EXTMEM + pos, value);	STOREINTELDWORD(CPU_EXTMEMBASE + pos, value);
return;	return;
}	}
}	}
if (!(addr & 1)) {	if (!(address & 1)) {
i286_memorywrite_w(addr, (UINT16)value);	memp_write16(address + 0, (UINT16)value);
i286_memorywrite_w(addr + 2, (UINT16)(value >> 16));	memp_write16(address + 2, (UINT16)(value >> 16));
}	}
else {	else {
i286_memorywrite(addr, (UINT8)value);	memp_write8(address + 0, (UINT8)value);
i286_memorywrite_w(addr + 1, (UINT16)(value >> 8));	memp_write16(address + 1, (UINT16)(value >> 8));
i286_memorywrite(addr + 3, (UINT8)(value >> 24));	memp_write8(address + 3, (UINT8)(value >> 24));
}	}
}	}

void MEMCALL memp_read(UINT32 address, void *dat, UINT leng) {
	void MEMCALL memp_reads(UINT32 address, void *dat, UINT leng) {

UINT8 out = (UINT8 )dat;	UINT8 out = (UINT8 )dat;
UINT pos;
UINT diff;	UINT diff;

/* fast memory access */	/* fast memory access */
if (address + leng < I286_MEMREADMAX) {	if ((address + leng) < I286_MEMREADMAX) {
CopyMemory(dat, mem + address, leng);	CopyMemory(dat, mem + address, leng);
return;	return;
} else if (address >= USE_HIMEM) {	}
pos = (address & CPU_ADRSMASK) - 0x100000;	address = address & CPU_ADRSMASK;
if (pos + leng < CPU_EXTMEMSIZE) {	if ((address >= USE_HIMEM) && (address < CPU_EXTLIMIT16)) {
CopyMemory(dat, CPU_EXTMEM + pos, leng);	diff = CPU_EXTLIMIT16 - address;
	if (diff >= leng) {
	CopyMemory(dat, CPU_EXTMEMBASE + address, leng);
return;	return;
}	}
if (pos < CPU_EXTMEMSIZE) {	CopyMemory(dat, CPU_EXTMEMBASE + address, diff);
diff = CPU_EXTMEMSIZE - pos;	out += diff;
CopyMemory(out, CPU_EXTMEM + pos, diff);	leng -= diff;
out += diff;	address += diff;
leng -= diff;
address += diff;
}
}	}

/* slow memory access */	/* slow memory access */
while (leng-- > 0) {	while (leng-- > 0) {
*out++ = i286_memoryread(address++);	*out++ = memp_read8(address++);
}	}
}	}

void MEMCALL memp_write(UINT32 address, const void *dat, UINT leng) {	void MEMCALL memp_writes(UINT32 address, const void *dat, UINT leng) {

const UINT8 out = (UINT8 )dat;	const UINT8 out = (UINT8 )dat;
UINT pos;
UINT diff;	UINT diff;

/* fast memory access */	/* fast memory access */
if (address + leng < I286_MEMREADMAX) {	if ((address + leng) < I286_MEMREADMAX) {
CopyMemory(mem + address, dat, leng);	CopyMemory(mem + address, dat, leng);
return;	return;
} else if (address >= USE_HIMEM) {	}
pos = (address & CPU_ADRSMASK) - 0x100000;	address = address & CPU_ADRSMASK;
if (pos + leng < CPU_EXTMEMSIZE) {	if ((address >= USE_HIMEM) && (address < CPU_EXTLIMIT16)) {
CopyMemory(CPU_EXTMEM + pos, dat, leng);	diff = CPU_EXTLIMIT16 - address;
	if (diff >= leng) {
	CopyMemory(CPU_EXTMEMBASE + address, dat, leng);
return;	return;
}	}
if (pos < CPU_EXTMEMSIZE) {	CopyMemory(CPU_EXTMEMBASE + address, dat, diff);
diff = CPU_EXTMEMSIZE - pos;	out += diff;
CopyMemory(CPU_EXTMEM + pos, dat, diff);	leng -= diff;
out += diff;	address += diff;
leng -= diff;
address += diff;
}
}	}

/* slow memory access */	/* slow memory access */
while (leng-- > 0) {	while (leng-- > 0) {
i286_memorywrite(address++, *out++);	memp_write8(address++, *out++);
}	}
}	}


// ---- Logical Space (BIOS)	// ---- Logical Space (BIOS)

static UINT32 physicaladdr(UINT32 addr, BOOL wr) {	static UINT32 MEMCALL physicaladdr(UINT32 addr, BOOL wr) {

UINT32 a;	UINT32 a;
UINT32 pde;	UINT32 pde;
UINT32 pte;	UINT32 pte;

a = CPU_STAT_PDE_BASE + ((addr >> 20) & 0xffc);	a = CPU_STAT_PDE_BASE + ((addr >> 20) & 0xffc);
pde = i286_memoryread_d(a);	pde = memp_read32(a);
if (!(pde & CPU_PDE_PRESENT)) {	if (!(pde & CPU_PDE_PRESENT)) {
goto retdummy;	goto retdummy;
}	}
if (!(pde & CPU_PDE_ACCESS)) {	if (!(pde & CPU_PDE_ACCESS)) {
i286_memorywrite(a, (UINT8)(pde \| CPU_PDE_ACCESS));	memp_write8(a, (UINT8)(pde \| CPU_PDE_ACCESS));
}	}
a = (pde & CPU_PDE_BASEADDR_MASK) + ((addr >> 10) & 0xffc);	a = (pde & CPU_PDE_BASEADDR_MASK) + ((addr >> 10) & 0xffc);
pte = cpu_memoryread_d(a);	pte = cpu_memoryread_d(a);
Line 592 static UINT32 physicaladdr(UINT32 addr,	Line 602 static UINT32 physicaladdr(UINT32 addr,
goto retdummy;	goto retdummy;
}	}
if (!(pte & CPU_PTE_ACCESS)) {	if (!(pte & CPU_PTE_ACCESS)) {
i286_memorywrite(a, (UINT8)(pte \| CPU_PTE_ACCESS));	memp_write8(a, (UINT8)(pte \| CPU_PTE_ACCESS));
}	}
if ((wr) && (!(pte & CPU_PTE_DIRTY))) {	if ((wr) && (!(pte & CPU_PTE_DIRTY))) {
i286_memorywrite(a, (UINT8)(pte \| CPU_PTE_DIRTY));	memp_write8(a, (UINT8)(pte \| CPU_PTE_DIRTY));
}	}
addr = (pte & CPU_PTE_BASEADDR_MASK) + (addr & 0x00000fff);	addr = (pte & CPU_PTE_BASEADDR_MASK) + (addr & 0x00000fff);
return(addr);	return(addr);

retdummy:	retdummy:
return(0x01000000); // �Ƥ��ȡ��˥��꤬¸�ߤ��ʤ��	return(0x01000000); /* XXX */
	}


	void MEMCALL meml_reads(UINT32 address, void *dat, UINT leng) {

	UINT size;

	if (!CPU_STAT_PAGING) {
	memp_reads(address, dat, leng);
	}
	else {
	while(leng) {
	size = 0x1000 - (address & 0xfff);
	size = min(size, leng);
	memp_reads(physicaladdr(address, FALSE), dat, size);
	address += size;
	dat = ((UINT8 *)dat) + size;
	leng -= size;
	}
	}
	}

	void MEMCALL meml_writes(UINT32 address, const void *dat, UINT leng) {

	UINT size;

	if (!CPU_STAT_PAGING) {
	memp_writes(address, dat, leng);
	}
	else {
	while(leng) {
	size = 0x1000 - (address & 0xfff);
	size = min(size, leng);
	memp_writes(physicaladdr(address, TRUE), dat, size);
	address += size;
	dat = ((UINT8 *)dat) + size;
	leng -= size;
	}
	}
}	}


REG8 MEMCALL meml_read8(UINT seg, UINT off) {	REG8 MEMCALL memr_read8(UINT seg, UINT off) {

UINT32 addr;	UINT32 addr;

Line 613 REG8 MEMCALL meml_read8(UINT seg, UINT o	Line 662 REG8 MEMCALL meml_read8(UINT seg, UINT o
if (CPU_STAT_PAGING) {	if (CPU_STAT_PAGING) {
addr = physicaladdr(addr, FALSE);	addr = physicaladdr(addr, FALSE);
}	}
return(i286_memoryread(addr));	return(memp_read8(addr));
}	}

REG16 MEMCALL meml_read16(UINT seg, UINT off) {	REG16 MEMCALL memr_read16(UINT seg, UINT off) {

UINT32 addr;	UINT32 addr;

addr = (seg << 4) + LOW16(off);	addr = (seg << 4) + LOW16(off);
if (!CPU_STAT_PAGING) {	if (!CPU_STAT_PAGING) {
return(i286_memoryread_w(addr));	return(memp_read16(addr));
}	}
else if ((addr + 1) & 0xfff) {	else if ((addr + 1) & 0xfff) {
return(i286_memoryread_w(physicaladdr(addr, FALSE)));	return(memp_read16(physicaladdr(addr, FALSE)));
}	}
return(meml_read8(seg, off) + (meml_read8(seg, off + 1) << 8));	return(memr_read8(seg, off) + (memr_read8(seg, off + 1) << 8));
}	}

void MEMCALL meml_write8(UINT seg, UINT off, REG8 dat) {	void MEMCALL memr_write8(UINT seg, UINT off, REG8 dat) {

UINT32 addr;	UINT32 addr;

Line 638 void MEMCALL meml_write8(UINT seg, UINT	Line 687 void MEMCALL meml_write8(UINT seg, UINT
if (CPU_STAT_PAGING) {	if (CPU_STAT_PAGING) {
addr = physicaladdr(addr, TRUE);	addr = physicaladdr(addr, TRUE);
}	}
i286_memorywrite(addr, dat);	memp_write8(addr, dat);
}	}

void MEMCALL meml_write16(UINT seg, UINT off, REG16 dat) {	void MEMCALL memr_write16(UINT seg, UINT off, REG16 dat) {

UINT32 addr;	UINT32 addr;

addr = (seg << 4) + LOW16(off);	addr = (seg << 4) + LOW16(off);
if (!CPU_STAT_PAGING) {	if (!CPU_STAT_PAGING) {
i286_memorywrite_w(addr, dat);	memp_write16(addr, dat);
}	}
else if ((addr + 1) & 0xfff) {	else if ((addr + 1) & 0xfff) {
i286_memorywrite_w(physicaladdr(addr, TRUE), dat);	memp_write16(physicaladdr(addr, TRUE), dat);
}	}
else {	else {
meml_write8(seg, off, (REG8)dat);	memr_write8(seg, off, (REG8)dat);
meml_write8(seg, off + 1, (REG8)(dat >> 8));	memr_write8(seg, off + 1, (REG8)(dat >> 8));
}	}
}	}

void MEMCALL meml_readstr(UINT seg, UINT off, void *dat, UINT leng) {	void MEMCALL memr_reads(UINT seg, UINT off, void *dat, UINT leng) {

UINT32 addr;	UINT32 addr;
UINT rem;	UINT rem;
Line 674 void MEMCALL meml_readstr(UINT seg, UINT	Line 723 void MEMCALL meml_readstr(UINT seg, UINT
size = min(size, rem);	size = min(size, rem);
addr = physicaladdr(addr, FALSE);	addr = physicaladdr(addr, FALSE);
}	}
memp_read(addr, dat, size);	memp_reads(addr, dat, size);
off += size;	off += size;
dat = ((UINT8 *)dat) + size;	dat = ((UINT8 *)dat) + size;
leng -= size;	leng -= size;
}	}
}	}

void MEMCALL meml_writestr(UINT seg, UINT off, const void *dat, UINT leng) {	void MEMCALL memr_writes(UINT seg, UINT off, const void *dat, UINT leng) {

UINT32 addr;	UINT32 addr;
UINT rem;	UINT rem;
Line 697 void MEMCALL meml_writestr(UINT seg, UIN	Line 746 void MEMCALL meml_writestr(UINT seg, UIN
size = min(size, rem);	size = min(size, rem);
addr = physicaladdr(addr, TRUE);	addr = physicaladdr(addr, TRUE);
}	}
memp_write(addr, dat, size);	memp_writes(addr, dat, size);
off += size;	off += size;
dat = ((UINT8 *)dat) + size;	dat = ((UINT8 *)dat) + size;
leng -= size;	leng -= size;
}	}
}	}

void MEMCALL meml_read(UINT32 address, void *dat, UINT leng) {

UINT size;

if (!CPU_STAT_PAGING) {
memp_read(address, dat, leng);
}
else {
while(leng) {
size = 0x1000 - (address & 0xfff);
size = min(size, leng);
memp_read(physicaladdr(address, FALSE), dat, size);
address += size;
dat = ((UINT8 *)dat) + size;
leng -= size;
}
}
}

void MEMCALL meml_write(UINT32 address, const void *dat, UINT leng) {

UINT size;

if (!CPU_STAT_PAGING) {
memp_write(address, dat, leng);
}
else {
while(leng) {
size = 0x1000 - (address & 0xfff);
size = min(size, leng);
memp_write(physicaladdr(address, TRUE), dat, size);
address += size;
dat = ((UINT8 *)dat) + size;
leng -= size;
}
}
}

#endif	#endif

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	Added in v.1.40