np2/i386c/memory.c - diff

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Diff for /np2/i386c/memory.c between versions 1.16 and 1.26

version 1.16, 2004/03/04 17:36:05	version 1.26, 2004/04/14 20:39:12
Line 3	Line 3
#ifndef NP2_MEMORY_ASM	#ifndef NP2_MEMORY_ASM

#include "cpucore.h"	#include "cpucore.h"
#include "memory.h"
#include "egcmem.h"	#include "egcmem.h"
#include "mem9821.h"	#include "mem9821.h"
#include "pccore.h"	#include "pccore.h"
Line 15	Line 14
BYTE mem[0x200000];	BYTE mem[0x200000];


#define USE_HIMEM 0x110000

// ---- write byte	// ---- write byte

static void MEMCALL i286_wt(UINT32 address, REG8 value) {	static void MEMCALL i286_wt(UINT32 address, REG8 value) { // MAIN

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

static void MEMCALL tram_wt(UINT32 address, REG8 value) {	static void MEMCALL tram_wt(UINT32 address, REG8 value) { // TRAM

CPU_REMCLOCK -= MEMWAIT_TRAM;	CPU_REMCLOCK -= MEMWAIT_TRAM;
if (address < 0xa2000) {	if (address < 0xa2000) {
Line 56 static void MEMCALL tram_wt(UINT32 addre	Line 53 static void MEMCALL tram_wt(UINT32 addre
}	}
}	}

static void MEMCALL vram_w0(UINT32 address, REG8 value) {	static void MEMCALL vram_w0(UINT32 address, REG8 value) { // VRAM

CPU_REMCLOCK -= MEMWAIT_VRAM;	CPU_REMCLOCK -= MEMWAIT_VRAM;
mem[address] = (BYTE)value;	mem[address] = (BYTE)value;
Line 64 static void MEMCALL vram_w0(UINT32 addre	Line 61 static void MEMCALL vram_w0(UINT32 addre
gdcs.grphdisp \|= 1;	gdcs.grphdisp \|= 1;
}	}

static void MEMCALL vram_w1(UINT32 address, REG8 value) {	static void MEMCALL vram_w1(UINT32 address, REG8 value) { // VRAM

CPU_REMCLOCK -= MEMWAIT_VRAM;	CPU_REMCLOCK -= MEMWAIT_VRAM;
mem[address + VRAM_STEP] = (BYTE)value;	mem[address + VRAM_STEP] = (BYTE)value;
Line 72 static void MEMCALL vram_w1(UINT32 addre	Line 69 static void MEMCALL vram_w1(UINT32 addre
gdcs.grphdisp \|= 2;	gdcs.grphdisp \|= 2;
}	}

static void MEMCALL grcg_rmw0(UINT32 address, REG8 value) {	static void MEMCALL grcg_rmw0(UINT32 address, REG8 value) { // VRAM

REG8 mask;	REG8 mask;
BYTE *vram;	BYTE *vram;
Line 101 static void MEMCALL grcg_rmw0(UINT32 add	Line 98 static void MEMCALL grcg_rmw0(UINT32 add
}	}
}	}

static void MEMCALL grcg_rmw1(UINT32 address, REG8 value) {	static void MEMCALL grcg_rmw1(UINT32 address, REG8 value) { // VRAM

REG8 mask;	REG8 mask;
BYTE *vram;	BYTE *vram;
Line 130 static void MEMCALL grcg_rmw1(UINT32 add	Line 127 static void MEMCALL grcg_rmw1(UINT32 add
}	}
}	}

static void MEMCALL grcg_tdw0(UINT32 address, REG8 value) {	static void MEMCALL grcg_tdw0(UINT32 address, REG8 value) { // VRAM

BYTE *vram;	BYTE *vram;

Line 154 static void MEMCALL grcg_tdw0(UINT32 add	Line 151 static void MEMCALL grcg_tdw0(UINT32 add
(void)value;	(void)value;
}	}

static void MEMCALL grcg_tdw1(UINT32 address, REG8 value) {	static void MEMCALL grcg_tdw1(UINT32 address, REG8 value) { // VRAM

BYTE *vram;	BYTE *vram;

Line 178 static void MEMCALL grcg_tdw1(UINT32 add	Line 175 static void MEMCALL grcg_tdw1(UINT32 add
(void)value;	(void)value;
}	}

static void MEMCALL egc_wt(UINT32 address, REG8 value) {	static void MEMCALL egc_wt(UINT32 address, REG8 value) { // VRAM

CPU_REMCLOCK -= MEMWAIT_GRCG;	CPU_REMCLOCK -= MEMWAIT_GRCG;
egc_write(address, value);	egc_write(address, value);
}	}

static void MEMCALL i286_wb(UINT32 address, REG8 value) {	static void MEMCALL emmc_wt(UINT32 address, REG8 value) { // EMS

	CPU_EMSPTR[(address >> 14) & 3][LOW14(address)] = (BYTE)value;
	}

	static void MEMCALL i286_wd(UINT32 address, REG8 value) { // D000��DFFF

	if (CPU_RAM_D000 & (1 << ((address >> 12) & 15))) {
	mem[address] = (BYTE)value;
	}
	}

	static void MEMCALL i286_wb(UINT32 address, REG8 value) { // F800��FFFF

mem[address + 0x1c8000 - 0xe8000] = (BYTE)value;	mem[address + 0x1c8000 - 0xe8000] = (BYTE)value;
}	}

static void MEMCALL i286_wn(UINT32 address, REG8 value) {	static void MEMCALL i286_wn(UINT32 address, REG8 value) { // NONE

(void)address;	(void)address;
(void)value;	(void)value;
Line 198 static void MEMCALL i286_wn(UINT32 addre	Line 207 static void MEMCALL i286_wn(UINT32 addre

// ---- read byte	// ---- read byte

static REG8 MEMCALL i286_rd(UINT32 address) {	static REG8 MEMCALL i286_rd(UINT32 address) { // MAIN

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

static REG8 MEMCALL tram_rd(UINT32 address) {	static REG8 MEMCALL tram_rd(UINT32 address) { // TRAM

CPU_REMCLOCK -= MEMWAIT_TRAM;	CPU_REMCLOCK -= MEMWAIT_TRAM;
if (address < 0xa4000) {	if (address < 0xa4000) {
Line 220 static REG8 MEMCALL tram_rd(UINT32 addre	Line 229 static REG8 MEMCALL tram_rd(UINT32 addre
return(mem[address]);	return(mem[address]);
}	}

static REG8 MEMCALL vram_r0(UINT32 address) {	static REG8 MEMCALL vram_r0(UINT32 address) { // VRAM

CPU_REMCLOCK -= MEMWAIT_VRAM;	CPU_REMCLOCK -= MEMWAIT_VRAM;
return(mem[address]);	return(mem[address]);
}	}

static REG8 MEMCALL vram_r1(UINT32 address) {	static REG8 MEMCALL vram_r1(UINT32 address) { // VRAM

CPU_REMCLOCK -= MEMWAIT_VRAM;	CPU_REMCLOCK -= MEMWAIT_VRAM;
return(mem[address + VRAM_STEP]);	return(mem[address + VRAM_STEP]);
}	}

static REG8 MEMCALL grcg_tcr0(UINT32 address) {	static REG8 MEMCALL grcg_tcr0(UINT32 address) { // VRAM

const BYTE *vram;	const BYTE *vram;
REG8 ret;	REG8 ret;
Line 255 const BYTE *vram;	Line 264 const BYTE *vram;
return(ret ^ 0xff);	return(ret ^ 0xff);
}	}

static REG8 MEMCALL grcg_tcr1(UINT32 address) {	static REG8 MEMCALL grcg_tcr1(UINT32 address) { // VRAM

const BYTE *vram;	const BYTE *vram;
REG8 ret;	REG8 ret;
Line 278 const BYTE *vram;	Line 287 const BYTE *vram;
return(ret ^ 0xff);	return(ret ^ 0xff);
}	}

static REG8 MEMCALL egc_rd(UINT32 address) {	static REG8 MEMCALL egc_rd(UINT32 address) { // VRAM

CPU_REMCLOCK -= MEMWAIT_GRCG;	CPU_REMCLOCK -= MEMWAIT_GRCG;
return(egc_read(address));	return(egc_read(address));
}	}

static REG8 MEMCALL i286_rb(UINT32 address) {	static REG8 MEMCALL emmc_rd(UINT32 address) { // EMS

	return(CPU_EMSPTR[(address >> 14) & 3][LOW14(address)]);
	}

	static REG8 MEMCALL i286_rb(UINT32 address) { // F800-FFFF

if (CPU_ITFBANK) {	if (CPU_ITFBANK) {
address += VRAM_STEP;	address += VRAM_STEP;
Line 339 static void MEMCALL tramw_wt(UINT32 addr	Line 353 static void MEMCALL tramw_wt(UINT32 addr
}	}
}	}
else if (address < 0xa5000) {	else if (address < 0xa5000) {
if (address & 1) {	if (!(address & 1)) {
value >>= 8;	value >>= 8;
}	}
if (cgwindow.writable & 1) {	if (cgwindow.writable & 1) {
Line 441 static void MEMCALL grcgw_tdw1(UINT32 ad	Line 455 static void MEMCALL grcgw_tdw1(UINT32 ad
static void MEMCALL egcw_wt(UINT32 address, REG16 value) {	static void MEMCALL egcw_wt(UINT32 address, REG16 value) {

CPU_REMCLOCK -= MEMWAIT_GRCG;	CPU_REMCLOCK -= MEMWAIT_GRCG;
if (!(address & 1)) {	egc_write_w(address, value);
egc_write_w(address, value);	}

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

	BYTE *ptr;

	if ((address & 0x3fff) != 0x3fff) {
	ptr = CPU_EMSPTR[(address >> 14) & 3] + LOW14(address);
	STOREINTELWORD(ptr, value);
}	}
else {	else {
if (!(egc.sft & 0x1000)) {	CPU_EMSPTR[(address >> 14) & 3][0x3fff] = (BYTE)value;
egc_write(address, (REG8)value);	CPU_EMSPTR[((address + 1) >> 14) & 3][0] = (BYTE)(value >> 8);
egc_write(address + 1, (REG8)(value >> 8));	}
	}

	static void MEMCALL i286w_wd(UINT32 address, REG16 value) {

	BYTE *ptr;
	UINT16 bit;

	ptr = mem + address;
	bit = 1 << ((address >> 12) & 15);
	if ((address + 1) & 0xfff) {
	if (CPU_RAM_D000 & bit) {
	STOREINTELWORD(ptr, value);
}	}
else {	}
egc_write(address + 1, (REG8)(value >> 8));	else {
egc_write(address, (REG8)value);	if (CPU_RAM_D000 & bit) {
	ptr[0] = (UINT8)value;
	}
	if (CPU_RAM_D000 & (bit << 1)) {
	ptr[1] = (UINT8)(value >> 8);
}	}
}	}
}	}

static void MEMCALL i286w_wb(UINT32 address, REG16 value) {	static void MEMCALL i286w_wb(UINT32 address, REG16 value) {

mem[address + 0x1c8000 - 0xe8000] = (BYTE)value;	BYTE *ptr;
mem[address + 0x1c8001 - 0xe8000] = (BYTE)(value >> 8);
	ptr = mem + (address + 0x1c8000 - 0xe8000);
	STOREINTELWORD(ptr, value);
}	}

static void MEMCALL i286w_wn(UINT32 address, REG16 value) {	static void MEMCALL i286w_wn(UINT32 address, REG16 value) {
Line 568 static REG16 MEMCALL grcgw_tcr1(UINT32 a	Line 608 static REG16 MEMCALL grcgw_tcr1(UINT32 a

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

	CPU_REMCLOCK -= MEMWAIT_GRCG;
	return(egc_read_w(address));
	}

	static REG16 MEMCALL emmcw_rd(UINT32 address) {

	const BYTE *ptr;
REG16 ret;	REG16 ret;

CPU_REMCLOCK -= MEMWAIT_GRCG;	if ((address & 0x3fff) != 0x3fff) {
if (!(address & 1)) {	ptr = CPU_EMSPTR[(address >> 14) & 3] + LOW14(address);
return(egc_read_w(address));	return(LOADINTELWORD(ptr));
}	}
else {	else {
if (!(egc.sft & 0x1000)) {	ret = CPU_EMSPTR[(address >> 14) & 3][0x3fff];
ret = egc_read(address);	ret += CPU_EMSPTR[((address + 1) >> 14) & 3][0] << 8;
ret += egc_read(address + 1) << 8;	return(ret);
return(ret);
}
else {
ret = egc_read(address + 1) << 8;
ret += egc_read(address);
return(ret);
}
}	}
}	}

Line 612 typedef struct {	Line 652 typedef struct {
} MEMFN;	} MEMFN;

typedef struct {	typedef struct {
MEM8READ brd8;	MEM8READ brd8; // E8000-F7FFF byte read
MEM8READ ird8;	MEM8READ ird8; // F8000-FFFFF byte read
MEM8WRITE ewr8;	MEM8WRITE bwr8; // E8000-FFFFF byte write
MEM8WRITE bwr8;	MEM16READ brd16; // E8000-F7FFF word read
MEM16READ brd16;	MEM16READ ird16; // F8000-FFFFF word read
MEM16READ ird16;	MEM16WRITE bwr16; // F8000-FFFFF word write
MEM16WRITE ewr16;
MEM16WRITE bwr16;
} MMAPTBL;	} MMAPTBL;

typedef struct {	typedef struct {
Line 636 static MEMFN memfn = {	Line 674 static MEMFN memfn = {
i286_rd, i286_rd, i286_rd, i286_rd, // 60	i286_rd, i286_rd, i286_rd, i286_rd, // 60
i286_rd, i286_rd, i286_rd, i286_rd, // 80	i286_rd, i286_rd, i286_rd, i286_rd, // 80
tram_rd, vram_r0, vram_r0, vram_r0, // a0	tram_rd, vram_r0, vram_r0, vram_r0, // a0
i286_rd, i286_rd, i286_rd, i286_rd, // c0	emmc_rd, emmc_rd, i286_rd, i286_rd, // c0
vram_r0, i286_rd, i286_rd, i286_rb}, // e0	vram_r0, i286_rd, i286_rd, i286_rb}, // e0

{i286_wt, i286_wt, i286_wt, i286_wt, // 00	{i286_wt, i286_wt, i286_wt, i286_wt, // 00
Line 645 static MEMFN memfn = {	Line 683 static MEMFN memfn = {
i286_wt, i286_wt, i286_wt, i286_wt, // 60	i286_wt, i286_wt, i286_wt, i286_wt, // 60
i286_wt, i286_wt, i286_wt, i286_wt, // 80	i286_wt, i286_wt, i286_wt, i286_wt, // 80
tram_wt, vram_w0, vram_w0, vram_w0, // a0	tram_wt, vram_w0, vram_w0, vram_w0, // a0
i286_wn, i286_wn, i286_wn, i286_wn, // c0	emmc_wt, emmc_wt, i286_wd, i286_wd, // c0
vram_w0, i286_wn, i286_wn, i286_wn}, // e0	vram_w0, i286_wn, i286_wn, i286_wn}, // e0

{i286w_rd, i286w_rd, i286w_rd, i286w_rd, // 00	{i286w_rd, i286w_rd, i286w_rd, i286w_rd, // 00
Line 654 static MEMFN memfn = {	Line 692 static MEMFN memfn = {
i286w_rd, i286w_rd, i286w_rd, i286w_rd, // 60	i286w_rd, i286w_rd, i286w_rd, i286w_rd, // 60
i286w_rd, i286w_rd, i286w_rd, i286w_rd, // 80	i286w_rd, i286w_rd, i286w_rd, i286w_rd, // 80
tramw_rd, vramw_r0, vramw_r0, vramw_r0, // a0	tramw_rd, vramw_r0, vramw_r0, vramw_r0, // a0
i286w_rd, i286w_rd, i286w_rd, i286w_rd, // c0	emmcw_rd, emmcw_rd, i286w_rd, i286w_rd, // c0
vramw_r0, i286w_rd, i286w_rd, i286w_rb}, // e0	vramw_r0, i286w_rd, i286w_rd, i286w_rb}, // e0

{i286w_wt, i286w_wt, i286w_wt, i286w_wt, // 00	{i286w_wt, i286w_wt, i286w_wt, i286w_wt, // 00
Line 663 static MEMFN memfn = {	Line 701 static MEMFN memfn = {
i286w_wt, i286w_wt, i286w_wt, i286w_wt, // 60	i286w_wt, i286w_wt, i286w_wt, i286w_wt, // 60
i286w_wt, i286w_wt, i286w_wt, i286w_wt, // 80	i286w_wt, i286w_wt, i286w_wt, i286w_wt, // 80
tramw_wt, vramw_w0, vramw_w0, vramw_w0, // a0	tramw_wt, vramw_w0, vramw_w0, vramw_w0, // a0
i286w_wn, i286w_wn, i286w_wn, i286w_wn, // c0	emmcw_wt, emmcw_wt, i286w_wd, i286w_wd, // c0
vramw_w0, i286w_wn, i286w_wn, i286w_wn}}; // e0	vramw_w0, i286w_wn, i286w_wn, i286w_wn}}; // e0

static const MMAPTBL mmaptbl[2] = {	static const MMAPTBL mmaptbl[2] = {
{i286_rd, i286_rb, i286_wn, i286_wn,	{i286_rd, i286_rb, i286_wn,
i286w_rd, i286w_rb, i286w_wn, i286w_wn},	i286w_rd, i286w_rb, i286w_wn},
{i286_rb, i286_rb, i286_wt, i286_wb,	{i286_rb, i286_rb, i286_wb,
i286w_rb, i286w_rb, i286w_wt, i286w_wb}};	i286w_rb, i286w_rb, i286w_wb}};

static const VACCTBL vacctbl[0x10] = {	static const VACCTBL vacctbl[0x10] = {
{vram_r0, vram_w0, vramw_r0, vramw_w0}, // 00	{vram_r0, vram_w0, vramw_r0, vramw_w0}, // 00
Line 713 const MMAPTBL *mm;	Line 751 const MMAPTBL *mm;
memfn.rd8[0xe8000 >> 15] = mm->brd8;	memfn.rd8[0xe8000 >> 15] = mm->brd8;
memfn.rd8[0xf0000 >> 15] = mm->brd8;	memfn.rd8[0xf0000 >> 15] = mm->brd8;
memfn.rd8[0xf8000 >> 15] = mm->ird8;	memfn.rd8[0xf8000 >> 15] = mm->ird8;

memfn.wr8[0xd0000 >> 15] = mm->ewr8;
memfn.wr8[0xd8000 >> 15] = mm->ewr8;
memfn.wr8[0xe8000 >> 15] = mm->bwr8;	memfn.wr8[0xe8000 >> 15] = mm->bwr8;
memfn.wr8[0xf0000 >> 15] = mm->bwr8;	memfn.wr8[0xf0000 >> 15] = mm->bwr8;
memfn.wr8[0xf8000 >> 15] = mm->bwr8;	memfn.wr8[0xf8000 >> 15] = mm->bwr8;
Line 723 const MMAPTBL *mm;	Line 758 const MMAPTBL *mm;
memfn.rd16[0xe8000 >> 15] = mm->brd16;	memfn.rd16[0xe8000 >> 15] = mm->brd16;
memfn.rd16[0xf0000 >> 15] = mm->brd16;	memfn.rd16[0xf0000 >> 15] = mm->brd16;
memfn.rd16[0xf8000 >> 15] = mm->ird16;	memfn.rd16[0xf8000 >> 15] = mm->ird16;

memfn.wr16[0xd0000 >> 15] = mm->ewr16;
memfn.wr16[0xd8000 >> 15] = mm->ewr16;
memfn.wr16[0xe8000 >> 15] = mm->bwr16;	memfn.wr16[0xe8000 >> 15] = mm->bwr16;
memfn.wr16[0xf0000 >> 15] = mm->bwr16;	memfn.wr16[0xf0000 >> 15] = mm->bwr16;
memfn.wr16[0xf8000 >> 15] = mm->bwr16;	memfn.wr16[0xf8000 >> 15] = mm->bwr16;
Line 735 void MEMCALL i286_vram_dispatch(UINT fun	Line 767 void MEMCALL i286_vram_dispatch(UINT fun

const VACCTBL *vacc;	const VACCTBL *vacc;

vacc = vacctbl + (func & 0x0f);
#if defined(SUPPORT_PC9821)	#if defined(SUPPORT_PC9821)
if (!(func & 0x20)) {	if (!(func & 0x20)) {
#endif	#endif
	vacc = vacctbl + (func & 0x0f);
memfn.rd8[0xa8000 >> 15] = vacc->rd8;	memfn.rd8[0xa8000 >> 15] = vacc->rd8;
memfn.rd8[0xb0000 >> 15] = vacc->rd8;	memfn.rd8[0xb0000 >> 15] = vacc->rd8;
memfn.rd8[0xb8000 >> 15] = vacc->rd8;	memfn.rd8[0xb8000 >> 15] = vacc->rd8;
Line 770 const VACCTBL *vacc;	Line 802 const VACCTBL *vacc;
else {	else {
memfn.rd8[0xa8000 >> 15] = mem9821_b0r;	memfn.rd8[0xa8000 >> 15] = mem9821_b0r;
memfn.rd8[0xb0000 >> 15] = mem9821_b0r;	memfn.rd8[0xb0000 >> 15] = mem9821_b0r;
memfn.rd8[0xb8000 >> 15] = vacc->rd8;	memfn.rd8[0xb8000 >> 15] = i286_nonram_r;
memfn.rd8[0xe0000 >> 15] = mem9821_b2r;	memfn.rd8[0xe0000 >> 15] = mem9821_b2r;

memfn.wr8[0xa8000 >> 15] = mem9821_b0w;	memfn.wr8[0xa8000 >> 15] = mem9821_b0w;
memfn.wr8[0xb0000 >> 15] = mem9821_b0w;	memfn.wr8[0xb0000 >> 15] = mem9821_b0w;
memfn.wr8[0xb8000 >> 15] = vacc->wr8;	memfn.wr8[0xb8000 >> 15] = i286_wn;
memfn.wr8[0xe0000 >> 15] = mem9821_b2w;	memfn.wr8[0xe0000 >> 15] = mem9821_b2w;

memfn.rd16[0xa8000 >> 15] = mem9821_b0rw;	memfn.rd16[0xa8000 >> 15] = mem9821_b0rw;
memfn.rd16[0xb0000 >> 15] = mem9821_b0rw;	memfn.rd16[0xb0000 >> 15] = mem9821_b0rw;
memfn.rd16[0xb8000 >> 15] = vacc->rd16;	memfn.rd16[0xb8000 >> 15] = i286_nonram_rw;
memfn.rd16[0xe0000 >> 15] = mem9821_b2rw;	memfn.rd16[0xe0000 >> 15] = mem9821_b2rw;

memfn.wr16[0xa8000 >> 15] = mem9821_b0ww;	memfn.wr16[0xa8000 >> 15] = mem9821_b0ww;
memfn.wr16[0xb0000 >> 15] = mem9821_b0ww;	memfn.wr16[0xb0000 >> 15] = mem9821_b0ww;
memfn.wr16[0xb8000 >> 15] = vacc->wr16;	memfn.wr16[0xb8000 >> 15] = i286w_wn;
memfn.wr16[0xe0000 >> 15] = mem9821_b2ww;	memfn.wr16[0xe0000 >> 15] = mem9821_b2ww;
}	}
#endif	#endif
Line 808 REG8 MEMCALL i286_memoryread(UINT32 addr	Line 840 REG8 MEMCALL i286_memoryread(UINT32 addr
return(memfn.rd8[(addr >> 15) & 0x1f](addr - 0x00f00000));	return(memfn.rd8[(addr >> 15) & 0x1f](addr - 0x00f00000));
}	}
#if defined(SUPPORT_PC9821)	#if defined(SUPPORT_PC9821)
else if (addr >= 0xfff00000) {	else if ((addr >= 0x00f00000) && (addr < 0x00f80000)) {
	return(mem9821_r(addr));
	}
	else if ((addr >= 0xfff00000) && (addr < 0xfff80000)) {
return(mem9821_r(addr));	return(mem9821_r(addr));
}	}
#endif	#endif
else {	else {
	// TRACEOUT(("out of mem (read8): %x", addr));
return(0xff);	return(0xff);
}	}
}	}
Line 839 REG16 MEMCALL i286_memoryread_w(UINT32 a	Line 875 REG16 MEMCALL i286_memoryread_w(UINT32 a
return(memfn.rd16[(addr >> 15) & 0x1f](addr - 0x00f00000));	return(memfn.rd16[(addr >> 15) & 0x1f](addr - 0x00f00000));
}	}
#if defined(SUPPORT_PC9821)	#if defined(SUPPORT_PC9821)
else if (addr >= 0xfff00000) {	else if ((addr >= 0x00f00000) && (addr < 0x00f80000)) {
	return(mem9821_rw(addr));
	}
	else if ((addr >= 0xfff00000) && (addr < 0xfff80000)) {
return(mem9821_rw(addr));	return(mem9821_rw(addr));
}	}
#endif	#endif
else {	else {
	// TRACEOUT(("out of mem (read16): %x", addr));
return(0xffff);	return(0xffff);
}	}
}	}
Line 898 void MEMCALL i286_memorywrite(UINT32 add	Line 938 void MEMCALL i286_memorywrite(UINT32 add
memfn.wr8[(addr >> 15) & 0x1f](addr - 0x00f00000, value);	memfn.wr8[(addr >> 15) & 0x1f](addr - 0x00f00000, value);
}	}
#if defined(SUPPORT_PC9821)	#if defined(SUPPORT_PC9821)
else if (addr >= 0xfff00000) {	else if ((addr >= 0x00f00000) && (addr < 0x00f80000)) {
	mem9821_w(addr, value);
	}
	else if ((addr >= 0xfff00000) && (addr < 0xfff80000)) {
mem9821_w(addr, value);	mem9821_w(addr, value);
}	}
#endif	#endif
	else {
	// TRACEOUT(("out of mem (write8): %x", addr));
	}
}	}
else {	else {
memfn.wr8[(addr >> 15) & 0x1f](addr, value);	memfn.wr8[(addr >> 15) & 0x1f](addr, value);
Line 925 void MEMCALL i286_memorywrite_w(UINT32 a	Line 971 void MEMCALL i286_memorywrite_w(UINT32 a
memfn.wr16[(addr >> 15) & 0x1f](addr - 0x00f00000, value);	memfn.wr16[(addr >> 15) & 0x1f](addr - 0x00f00000, value);
}	}
#if defined(SUPPORT_PC9821)	#if defined(SUPPORT_PC9821)
else if (addr >= 0xfff00000) {	else if ((addr >= 0x00f00000) && (addr < 0x00f80000)) {
	mem9821_ww(addr, value);
	}
	else if ((addr >= 0xfff00000) && (addr < 0xfff80000)) {
mem9821_ww(addr, value);	mem9821_ww(addr, value);
}	}
#endif	#endif
	else {
	// TRACEOUT(("out of mem (write16): %x", addr));
	}
}	}
else {	else {
memfn.wr16[(addr >> 15) & 0x1f](addr, value);	memfn.wr16[(addr >> 15) & 0x1f](addr, value);
Line 1085 void MEMCALL memp_write(UINT32 address,	Line 1137 void MEMCALL memp_write(UINT32 address,

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

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

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

if (CPU_STAT_PAGING) {	a = CPU_STAT_PDE_BASE + ((addr >> 20) & 0xffc);
pde = i286_memoryread_d(CPU_STAT_PDE_BASE + ((addr >> 20) & 0xffc));	pde = i286_memoryread_d(a);
if (!(pde & CPU_PDE_PRESENT)) {	if (!(pde & CPU_PDE_PRESENT)) {
goto retdummy;	goto retdummy;
}	}
pte = cpu_memoryread_d((pde & CPU_PDE_BASEADDR_MASK) + ((addr >> 10) & 0xffc));	if (!(pde & CPU_PDE_ACCESS)) {
if (!(pte & CPU_PTE_PRESENT)) {	i286_memorywrite(a, (UINT8)(pde \| CPU_PDE_ACCESS));
goto retdummy;	}
}	a = (pde & CPU_PDE_BASEADDR_MASK) + ((addr >> 10) & 0xffc);
addr = (pte & CPU_PTE_BASEADDR_MASK) + (addr & 0x00000fff);	pte = cpu_memoryread_d(a);
	if (!(pte & CPU_PTE_PRESENT)) {
	goto retdummy;
	}
	if (!(pte & CPU_PTE_ACCESS)) {
	i286_memorywrite(a, (UINT8)(pte \| CPU_PTE_ACCESS));
}	}
	if ((wr) && (!(pte & CPU_PTE_DIRTY))) {
	i286_memorywrite(a, (UINT8)(pte \| CPU_PTE_DIRTY));
	}
	addr = (pte & CPU_PTE_BASEADDR_MASK) + (addr & 0x00000fff);
return(addr);	return(addr);

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


	REG8 MEMCALL meml_read8(UINT seg, UINT off) {

	UINT32 addr;

	addr = (seg << 4) + LOW16(off);
	if (CPU_STAT_PAGING) {
	addr = physicaladdr(addr, FALSE);
	}
	return(i286_memoryread(addr));
	}

	REG16 MEMCALL meml_read16(UINT seg, UINT off) {

	UINT32 addr;

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

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

	UINT32 addr;

	addr = (seg << 4) + LOW16(off);
	if (CPU_STAT_PAGING) {
	addr = physicaladdr(addr, TRUE);
	}
	i286_memorywrite(addr, dat);
	}

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

	UINT32 addr;

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

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

UINT32 adrs;	UINT32 addr;
	UINT rem;
UINT size;	UINT size;

while(leng) {	while(leng) {
off = LOW16(off);	off = LOW16(off);
adrs = (seg << 4) + off;	addr = (seg << 4) + off;
size = 0x1000 - (adrs & 0xfff);	rem = 0x10000 - off;
size = min(size, leng);	size = min(leng, rem);
size = min(size, 0x10000 - off);	if (CPU_STAT_PAGING) {
memp_read(physicaladdr(adrs), dat, size);	rem = 0x1000 - (addr & 0xfff);
	size = min(size, rem);
	addr = physicaladdr(addr, FALSE);
	}
	memp_read(addr, dat, size);
off += size;	off += size;
dat = ((BYTE *)dat) + size;	dat = ((BYTE *)dat) + size;
leng -= size;	leng -= size;
Line 1127 void MEMCALL meml_readstr(UINT seg, UINT	Line 1248 void MEMCALL meml_readstr(UINT seg, UINT

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

UINT32 adrs;	UINT32 addr;
	UINT rem;
UINT size;	UINT size;

while(leng) {	while(leng) {
off = LOW16(off);	off = LOW16(off);
adrs = (seg << 4) + off;	addr = (seg << 4) + off;
size = 0x1000 - (adrs & 0xfff);	rem = 0x10000 - off;
size = min(size, leng);	size = min(leng, rem);
size = min(size, 0x10000 - off);	if (CPU_STAT_PAGING) {
memp_write(physicaladdr(adrs), dat, size);	rem = 0x1000 - (addr & 0xfff);
	size = min(size, rem);
	addr = physicaladdr(addr, TRUE);
	}
	memp_write(addr, dat, size);
off += size;	off += size;
dat = ((BYTE *)dat) + size;	dat = ((BYTE *)dat) + size;
leng -= size;	leng -= size;
Line 1147 void MEMCALL meml_read(UINT32 address, v	Line 1273 void MEMCALL meml_read(UINT32 address, v

UINT size;	UINT size;

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

Line 1161 void MEMCALL meml_write(UINT32 address,	Line 1292 void MEMCALL meml_write(UINT32 address,

UINT size;	UINT size;

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

#endif	#endif

RetroPC.NET-CVS <cvs@retropc.net>

Removed from v.1.16
changed lines
	Added in v.1.26