np2/io/gdc.c - diff

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Diff for /np2/io/gdc.c between versions 1.6 and 1.26

version 1.6, 2003/11/28 08:01:33	version 1.26, 2004/02/29 07:36:56
Line 1	Line 1
#include "compiler.h"	#include "compiler.h"
#include "scrnmng.h"	#include "scrnmng.h"
#include "i286.h"	#include "cpucore.h"
#include "memory.h"
#include "pccore.h"	#include "pccore.h"
#include "iocore.h"	#include "iocore.h"
	#include "gdc_cmd.tbl"
	#include "gdc_sub.h"
#include "vram.h"	#include "vram.h"
#include "palettes.h"	#include "palettes.h"
#include "gdc_cmd.tbl"	#include "timing.h"


#define SEARHC_SYNC	#define SEARCH_SYNC
#define TURE_SYNC	#define TURE_SYNC

	typedef struct {
	UINT32 clock;
	UINT minx;
	UINT maxx;
	UINT miny;
	UINT maxy;
	} GDCCLK;

	// 31kHzの時の動作クロックが不明…
	static const GDCCLK gdcclk[] = {
	{14318180 / 8, 112 - 8, 112 + 8, 200, 300},
	{21052600 / 8, 106 - 6, 106 + 6, 400, 575},
	{25260000 / 8, 100 - 8, 100 + 8, 400, 575}};


	typedef struct {
	UINT8 master[8];
	UINT8 slave[8];
	} GDCSYNC;

	static const UINT8 defsyncm15[8] = {0x10,0x4e,0x07,0x25,0x0d,0x0f,0xc8,0x94};
	static const UINT8 defsyncs15[8] = {0x06,0x26,0x03,0x11,0x86,0x0f,0xc8,0x94};

	static const UINT8 defsyncm24[8] = {0x10,0x4e,0x07,0x25,0x07,0x07,0x90,0x65};
	static const UINT8 defsyncs24[8] = {0x06,0x26,0x03,0x11,0x83,0x07,0x90,0x65};

static const BYTE defdegpal[4] = {0x04,0x15,0x26,0x37};	static const UINT8 defsyncm31[8] = {0x10,0x4e,0x47,0x0c,0x07,0x0d,0x90,0x89};
static const BYTE defsync[8] = {0x10,0x4e,0x07,0x25,0x07,0x07,0x90,0x65};	static const UINT8 defsyncs31[8] = {0x06,0x26,0x41,0x0c,0x83,0x0d,0x90,0x89};


void gdc_setdegitalpal(int color, BYTE value) {	static const UINT8 defdegpal[4] = {0x04,0x15,0x26,0x37};




	void gdc_setdegitalpal(int color, REG8 value) {

if (color & 4) {	if (color & 4) {
color &= 3;	color &= 3;
Line 39 void gdc_setdegitalpal(int color, BYTE v	Line 70 void gdc_setdegitalpal(int color, BYTE v
}	}
}	}

void gdc_setanalogpal(int color, int rgb, BYTE value) {	void gdc_setanalogpal(int color, int rgb, REG8 value) {

BYTE *ptr;	UINT8 *ptr;
PAL1EVENT *event;	PAL1EVENT *event;

ptr = ((BYTE *)(gdc.anapal + color)) + rgb;	ptr = ((UINT8 *)(gdc.anapal + color)) + rgb;
if (((*ptr) ^ value) & 0x0f) {	if (((*ptr) ^ value) & 0x0f) {
gdcs.palchange = GDCSCRN_REDRAW;	gdcs.palchange = GDCSCRN_REDRAW;
if (palevent.events < PALEVENTMAX) {	if (palevent.events < PALEVENTMAX) {
if (!gdc.vsync) {	if (!gdc.vsync) {
event = palevent.event + palevent.events;	event = palevent.event + palevent.events;
event->clock = nevent.item[NEVENT_FLAMES].clock -	event->clock = nevent.item[NEVENT_FLAMES].clock -
(I286_BASECLOCK - I286_REMCLOCK);	(CPU_BASECLOCK - CPU_REMCLOCK);
event->color = (color * sizeof(RGB32)) + rgb;	event->color = (color * sizeof(RGB32)) + rgb;
event->value = value;	event->value = (UINT8)value;
palevent.events++;	palevent.events++;
}	}
else {	else {
Line 64 void gdc_setanalogpal(int color, int rgb	Line 95 void gdc_setanalogpal(int color, int rgb
*ptr = value;	*ptr = value;
}	}

void gdc_setdegpalpack(int color, BYTE value) {	void gdc_setdegpalpack(int color, REG8 value) {

if ((gdc.degpal[color] ^ value) & 0x77) {	if ((gdc.degpal[color] ^ value) & 0x77) {
gdcs.palchange = GDCSCRN_REDRAW;	gdcs.palchange = GDCSCRN_REDRAW;
}	}
gdc.degpal[color] = value;	gdc.degpal[color] = (UINT8)value;
}	}

void gdc_paletteinit(void) {	void gdc_paletteinit(void) {

BYTE c;	int c;

CopyMemory(gdc.degpal, defdegpal, 4);	CopyMemory(gdc.degpal, defdegpal, 4);
for (c=0; c<8; c++) {	for (c=0; c<8; c++) {
Line 91 void gdc_paletteinit(void) {	Line 122 void gdc_paletteinit(void) {
gdcs.palchange = GDCSCRN_REDRAW;	gdcs.palchange = GDCSCRN_REDRAW;
}	}

	#if defined(SUPPORT_PC9821)
	void gdc_analogext(BOOL extend) {

	if (extend) {
	gdc.analog \|= (1 << GDCANALOG_256);
	vramop.operate \|= 0x20;
	}
	else {
	gdc.analog &= ~(1 << (GDCANALOG_256));
	vramop.operate &= ~0x20;
	}
	gdcs.palchange = GDCSCRN_REDRAW;
	gdcs.grphdisp \|= GDCSCRN_EXT \| GDCSCRN_ALLDRAW2;
	i286_vram_dispatch(vramop.operate);
	}
	#endif


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

	void gdc_vectreset(GDCDATA item) {

	item->para[GDC_VECTW+1] = 0x00;
	item->para[GDC_VECTW+2] = 0x00;
	item->para[GDC_VECTW+3] = 0x08;
	item->para[GDC_VECTW+4] = 0x00;
	item->para[GDC_VECTW+5] = 0x08;
	item->para[GDC_VECTW+6] = 0x00;
	item->para[GDC_VECTW+7] = 0xff;
	item->para[GDC_VECTW+8] = 0xff;
	item->para[GDC_VECTW+9] = 0xff;
	item->para[GDC_VECTW+10] = 0xff;
	}

static void vectdraw(void) {	static void vectdraw(void) {

UINT32 csrw;	UINT32 csrw;
UINT16 textw;	const GDCVECT *vect;
	REG16 textw;
	REG8 ope;

csrw = LOADINTELDWORD(gdc.s.para + GDC_CSRW);	csrw = LOADINTELDWORD(gdc.s.para + GDC_CSRW);
	vect = (GDCVECT *)(gdc.s.para + GDC_VECTW);
textw = LOADINTELWORD(gdc.s.para + GDC_TEXTW);	textw = LOADINTELWORD(gdc.s.para + GDC_TEXTW);
	ope = gdc.s.para[GDC_WRITE];

if (gdc.s.para[GDC_VECTW] & 0x8) {	if (vect->ope & 0x08) {
gdcsub_line(csrw, (GDCVECT *)(gdc.s.para + GDC_VECTW),	gdcsub_vectl(csrw, vect, textw, ope);
textw, gdc.s.para[GDC_WRITE]);
}	}
if (gdc.s.para[GDC_VECTW] & 0x20) {	if (vect->ope & 0x10) { // undocumented
gdcsub_circle(csrw, (GDCVECT *)(gdc.s.para + GDC_VECTW),	gdcsub_vectt(csrw, vect, textw, ope);
textw, gdc.s.para[GDC_WRITE]);
}	}
if (gdc.s.para[GDC_VECTW] & 0x40) {	if (vect->ope & 0x20) {
gdcsub_box(csrw, (GDCVECT *)(gdc.s.para + GDC_VECTW),	gdcsub_vectc(csrw, vect, textw, ope);
textw, gdc.s.para[GDC_WRITE]);
}	}
	if (vect->ope & 0x40) {
	gdcsub_vectr(csrw, vect, textw, ope);
	}
	gdc_vectreset(&gdc.s);
}	}

static void textdraw(void) { // ver0.30	static void textdraw(void) {

	UINT32 csrw;
	const GDCVECT *vect;
	REG16 textw;
	REG8 ope;

UINT32 csrw;	csrw = LOADINTELDWORD(gdc.s.para + GDC_CSRW);
UINT16 textw;	vect = (GDCVECT *)(gdc.s.para + GDC_VECTW);
	textw = gdc.s.para[GDC_TEXTW + 7];
	textw = (textw << 8) + textw;
	ope = gdc.s.para[GDC_WRITE];

if (gdc.s.para[GDC_VECTW] & 0x10) {	if (vect->ope & 0x08) { // undocumented
csrw = LOADINTELDWORD(gdc.s.para + GDC_CSRW);	gdcsub_vectl(csrw, vect, textw, ope);
textw = LOADINTELWORD(gdc.s.para + GDC_TEXTW);
gdcsub_text(csrw, (GDCVECT *)(gdc.s.para + GDC_VECTW),
textw, gdc.s.para[GDC_WRITE]);
}	}
	if (vect->ope & 0x10) {
	gdcsub_text(csrw, vect, gdc.s.para + GDC_TEXTW, ope);
	}
	if (vect->ope & 0x20) { // undocumented
	gdcsub_vectc(csrw, vect, textw, ope);
	}
	if (vect->ope & 0x40) { // undocumented
	gdcsub_vectr(csrw, vect, textw, ope);
	}
	gdc_vectreset(&gdc.s);
}	}

void gdc_work(int id) {	void gdc_work(int id) {

UINT16 i;
BYTE data;
GDCDATA item;	GDCDATA item;
BYTE *dispflag;	UINT8 *dispflag;
	UINT i;
	UINT8 data;

item = ((id==GDCWORK_MASTER)?(&gdc.m):(&gdc.s));	item = (id == GDCWORK_MASTER)?&gdc.m:&gdc.s;
dispflag = ((id==GDCWORK_MASTER)?(&gdcs.textdisp):(&gdcs.grphdisp));	dispflag = (id == GDCWORK_MASTER)?&gdcs.textdisp:&gdcs.grphdisp;

for (i=0; i<item->cnt; i++) {	for (i=0; i<item->cnt; i++) {
data = (BYTE)item->fifo[i];	data = (UINT8)item->fifo[i];
if (item->fifo[i] & 0xff00) {	if (item->fifo[i] & 0xff00) {
item->cmd = data; // ver0.29	item->cmd = data;
item->paracb = 0;	item->paracb = 0;
if ((data & 0x60) == 0x20) {	if ((data & 0x60) == 0x20) {
item->para[GDC_WRITE] = data;	item->para[GDC_WRITE] = data;
Line 151 void gdc_work(int id) {	Line 233 void gdc_work(int id) {
item->rcv = 2;	item->rcv = 2;
item->paracb = 1;	item->paracb = 1;
break;	break;

case 0x10:	case 0x10:
case 0x18:	case 0x18:
item->rcv = 1;	item->rcv = 1;
item->paracb = 1;	item->paracb = 1;
break;	break;

default:	default:
item->rcv = 0;	item->rcv = 0;
break;	break;
Line 169 void gdc_work(int id) {	Line 253 void gdc_work(int id) {
case CMD_START:	case CMD_START:
case CMD_SYNC_ON:	case CMD_SYNC_ON:
(*dispflag) \|= GDCSCRN_ENABLE \| GDCSCRN_ALLDRAW2;	(*dispflag) \|= GDCSCRN_ENABLE \| GDCSCRN_ALLDRAW2;
screenupdate \|= 2; // ver0.28	screenupdate \|= 2;
break;	break;

	case CMD_STOP_:
case CMD_STOP:	case CMD_STOP:
case CMD_SYNC_OFF:	case CMD_SYNC_OFF:
(*dispflag) &= (~GDCSCRN_ENABLE);	(*dispflag) &= (~GDCSCRN_ENABLE);
// (*dispflag) \|= GDCSCRN_ALLDRAW2;	// (*dispflag) \|= GDCSCRN_ALLDRAW2;
screenupdate \|= 2; // ver0.28	screenupdate \|= 2;
break;	break;

case CMD_VECTE:	case CMD_VECTE:
Line 185 void gdc_work(int id) {	Line 270 void gdc_work(int id) {
}	}
break;	break;

case CMD_TEXTE: // ver0.30	case CMD_TEXTE:
if (id != GDCWORK_MASTER) {	if (id != GDCWORK_MASTER) {
textdraw();	textdraw();
}	}
break;	break;

}	}
item->ptr = gdc_cmd[data].pos;	item->ptr = gdc_cmd[data].pos;
item->rcv = gdc_cmd[data].outdatas;	item->rcv = gdc_cmd[data].outdatas;
Line 213 void gdc_work(int id) {	Line 297 void gdc_work(int id) {
(*dispflag) \|= gdc_dirtyflag[id][item->ptr];	(*dispflag) \|= gdc_dirtyflag[id][item->ptr];
}	}
(item->ptr)++;	(item->ptr)++;
(item->rcv)--; // ver0.29	(item->rcv)--;
if ((!(item->rcv)) && (id == GDCWORK_SLAVE) &&	if ((!(item->rcv)) && (id == GDCWORK_SLAVE) &&
(((item->cmd) & 0xe4) == 0x20)) {	(((item->cmd) & 0xe4) == 0x20)) {
gdcsub_write();	gdcsub_write();
item->paracb = 0; // ver0.29	item->paracb = 0;
}	}
}	}
}	}
Line 225 void gdc_work(int id) {	Line 309 void gdc_work(int id) {
}	}

// BIOSとかで弄った時にリセット	// BIOSとかで弄った時にリセット
void gdc_forceready(GDCDATA item) {	void gdc_forceready(int id) {

	GDCDATA item;
	item = (id == GDCWORK_MASTER)?&gdc.m:&gdc.s;
	if (item->cnt) {
	gdc_work(id);
	}
item->rcv = 0;	item->rcv = 0;
item->snd = 0;	item->snd = 0;
}	}


	void gdc_updateclock(void) {

	UINT tmp;
	UINT cr;
	UINT hfbs;
	UINT vfbs;
	UINT lf;
	UINT x;
	UINT y;
	UINT cnt;
	const GDCCLK *clk;
	UINT32 hclock;

	cr = gdc.m.para[GDC_SYNC + 1] + 2;
	tmp = LOADINTELWORD(gdc.m.para + GDC_SYNC + 2);
	hfbs = tmp & 0x1f; // HS
	hfbs += tmp >> 10; // HFP
	vfbs = (tmp >> 5) & 0x1f; // VS
	hfbs += gdc.m.para[GDC_SYNC + 4] & 0x3f; // HFP
	vfbs += gdc.m.para[GDC_SYNC + 5] & 0x3f; // VFP
	tmp = LOADINTELWORD(gdc.m.para + GDC_SYNC + 6);
	lf = ((tmp - 1) & 0x3ff) + 1;
	vfbs += tmp >> 10; // VBP

	hfbs += 3;
	x = cr + hfbs;
	if (!vfbs) {
	vfbs = 1;
	}
	y = lf + vfbs;
	// TRACEOUT(("h %d:%d / v %d:%d", cr, x, lf, y));

	#if defined(SUPPORT_CRT31KHZ)
	if (gdc.display & (1 << GDCDISP_31)) {
	clk = gdcclk + 2;
	}
	else
	#endif
	if (!(gdc.crt15khz & 2)) { // 24.83±300Hz
	clk = gdcclk + 1;
	}
	else { // 15.98±300Hz
	clk = gdcclk;
	}

	if (x < clk->minx) {
	cr = (clk->minx * cr) / x;
	x = clk->minx;
	}
	else if (x > clk->maxx) {
	cr = (clk->maxx * cr) / x;
	x = clk->maxx;
	}
	if (y < clk->miny) {
	lf = (clk->miny * lf) / y;
	y = clk->miny;
	}
	else if (y > clk->maxy) {
	lf = (clk->maxy * lf) / y;
	y = clk->maxy;
	}
	hclock = clk->clock / x;
	cnt = (pccore.baseclock * y) / hclock;
	cnt *= pccore.multiple;
	gdc.rasterclock = cnt / y;
	gdc.hsyncclock = (gdc.rasterclock * cr) / x;
	gdc.dispclock = gdc.rasterclock * lf;
	gdc.vsyncclock = cnt - gdc.dispclock;
	timing_setrate(y, hclock);
	}

void gdc_restorekacmode(void) {	void gdc_restorekacmode(void) {

BYTE bit;	BYTE bit;
Line 243 void gdc_restorekacmode(void) {	Line 404 void gdc_restorekacmode(void) {
}	}


// ---- I/O	// ---- I/O master

static void IOOUTCALL gdc_o60(UINT port, BYTE dat) {	static void IOOUTCALL gdc_o60(UINT port, REG8 dat) {

if (gdc.m.cnt < GDCCMD_MAX) {	if (gdc.m.cnt < GDCCMD_MAX) {
gdc.m.fifo[gdc.m.cnt++] = dat;	gdc.m.fifo[gdc.m.cnt++] = dat;
Line 253 static void IOOUTCALL gdc_o60(UINT port,	Line 414 static void IOOUTCALL gdc_o60(UINT port,
(void)port;	(void)port;
}	}

static void IOOUTCALL gdc_o62(UINT port, BYTE dat) {	static void IOOUTCALL gdc_o62(UINT port, REG8 dat) {

if (gdc.m.cnt < GDCCMD_MAX) {	if (gdc.m.cnt < GDCCMD_MAX) {
gdc.m.fifo[gdc.m.cnt++] = 0x100 \| dat;	gdc.m.fifo[gdc.m.cnt++] = 0x100 \| dat;
Line 262 static void IOOUTCALL gdc_o62(UINT port,	Line 423 static void IOOUTCALL gdc_o62(UINT port,
(void)port;	(void)port;
}	}

static void IOOUTCALL gdc_o64(UINT port, BYTE dat) {	static void IOOUTCALL gdc_o64(UINT port, REG8 dat) {

gdc.vsyncint = 1;	gdc.vsyncint = 1;
(void)port;	(void)port;
(void)dat;	(void)dat;
}	}

static void IOOUTCALL gdc_o68(UINT port, BYTE dat) {	static void IOOUTCALL gdc_o68(UINT port, REG8 dat) {

BYTE bit;	REG8 bit;

if (!(dat & 0xf0)) { // ver0.28	if (!(dat & 0xf0)) {
bit = 1 << ((dat >> 1) & 7);	bit = 1 << ((dat >> 1) & 7);
if (dat & 1) {	if (dat & 1) {
gdc.mode1 \|= bit;	gdc.mode1 \|= bit;
Line 284 static void IOOUTCALL gdc_o68(UINT port,	Line 445 static void IOOUTCALL gdc_o68(UINT port,
if (bit & (0x01 \| 0x04 \| 0x10)) {	if (bit & (0x01 \| 0x04 \| 0x10)) {
gdcs.grphdisp \|= GDCSCRN_ALLDRAW2;	gdcs.grphdisp \|= GDCSCRN_ALLDRAW2;
}	}
else if (bit == 0x02) { // ver0.28	else if (bit == 0x02) {
gdcs.grphdisp \|= GDCSCRN_ALLDRAW2;	gdcs.grphdisp \|= GDCSCRN_ALLDRAW2;
gdcs.palchange = GDCSCRN_REDRAW;	gdcs.palchange = GDCSCRN_REDRAW;
}	}
	else if (bit == 0x08) {
	gdcs.textdisp \|= GDCSCRN_ALLDRAW2;
	}
else if (bit == 0x20) {	else if (bit == 0x20) {
gdc_restorekacmode();	gdc_restorekacmode();
}	}
Line 299 static void IOOUTCALL gdc_o68(UINT port,	Line 463 static void IOOUTCALL gdc_o68(UINT port,
(void)port;	(void)port;
}	}

static void IOOUTCALL gdc_o6a(UINT port, BYTE dat) {	static void IOOUTCALL gdc_o6a(UINT port, REG8 dat) {

BYTE bit;	REG8 bit;

if (!(dat & 0xf8)) {	if (!(dat & 0xf8)) {
bit = (dat >> 1) & 3;	bit = (dat >> 1) & 3;
Line 312 static void IOOUTCALL gdc_o6a(UINT port,	Line 476 static void IOOUTCALL gdc_o6a(UINT port,
gdc.mode2 ^= (1 << bit);	gdc.mode2 ^= (1 << bit);
switch(bit) {	switch(bit) {
case 0:	case 0:
if (gdc.display & 2) {	if (gdc.display & (1 << GDCDISP_ANALOG)) {
gdc.analog = dat;	gdc.analog &= ~(1 << GDCANALOG_16);
	gdc.analog \|= (dat << GDCANALOG_16);
gdcs.palchange = GDCSCRN_REDRAW;	gdcs.palchange = GDCSCRN_REDRAW;
vramop.operate &= VOP_ANALOGMASK;	vramop.operate &= VOP_ANALOGMASK;
vramop.operate \|= dat << 4;	vramop.operate \|= dat << 4;
Line 333 static void IOOUTCALL gdc_o6a(UINT port,	Line 498 static void IOOUTCALL gdc_o6a(UINT port,
}	}
else {	else {
switch(dat) {	switch(dat) {
	#if defined(SUPPORT_PC9821)
	case 0x20:
	if (gdc.mode2 & 0x08) {
	gdc_analogext(FALSE);
	}
	break;

	case 0x21:
	if (gdc.mode2 & 0x08) {
	gdc_analogext(TRUE);
	}
	break;

	case 0x68:
	gdc.analog &= ~(1 << GDCANALOG_256E);
	break;

	case 0x69:
	gdc.analog \|= (1 << GDCANALOG_256E);
	break;
	#endif
case 0x40:	case 0x40:
gdc.display &= ~1;	case 0x80: // EPSON?
	gdc.display &= ~(1 << GDCDISP_PLAZMA);
gdcs.textdisp \|= GDCSCRN_EXT;	gdcs.textdisp \|= GDCSCRN_EXT;
break;	break;

case 0x41:	case 0x41:
gdc.display \|= 1;	case 0x81: // EPSON?
	gdc.display \|= (1 << GDCDISP_PLAZMA);
gdcs.textdisp \|= GDCSCRN_EXT;	gdcs.textdisp \|= GDCSCRN_EXT;
break;	break;

Line 367 static void IOOUTCALL gdc_o6a(UINT port,	Line 555 static void IOOUTCALL gdc_o6a(UINT port,
(void)port;	(void)port;
}	}

static BYTE IOINPCALL gdc_i60(UINT port) {	static void IOOUTCALL gdc_o6e(UINT port, REG8 dat) {

	switch(dat) {
	case 0:
	gdc.crt15khz &= ~1;
	gdcs.textdisp \|= GDCSCRN_ALLDRAW2;
	break;

BYTE ret;	case 1:
long remain;	gdc.crt15khz \|= 1;
	gdcs.textdisp \|= GDCSCRN_ALLDRAW2;
	break;
	}
	(void)port;
	}

	static REG8 IOINPCALL gdc_i60(UINT port) {

	REG8 ret;
	SINT32 remain;

ret = 0x80 \| gdc.vsync; // \| m_drawing;	ret = 0x80 \| gdc.vsync; // \| m_drawing;
remain = nevent_getremain(NEVENT_FLAMES);	remain = nevent_getremain(NEVENT_FLAMES);
if (remain >= 0) {	if (remain >= 0) {
if ((remain % pc.raster) < pc.hsync) {	if ((remain % gdc.rasterclock) < gdc.hsyncclock) {
ret \|= 0x40;	ret \|= 0x40;
}	}
}	}
Line 391 static BYTE IOINPCALL gdc_i60(UINT port)	Line 595 static BYTE IOINPCALL gdc_i60(UINT port)
else {	else {
gdc_work(GDCWORK_MASTER);	gdc_work(GDCWORK_MASTER);
}	}
#ifdef SEARHC_SYNC	#ifdef SEARCH_SYNC
if ((i286reg.inport) && (I286_REMCLOCK >= 5)) {	if ((CPU_INPADRS) && (CPU_REMCLOCK >= 5)) {
UINT16 jadr = 0xfa74;	UINT16 jadr = 0xfa74;
UINT16 memv;	UINT16 memv;
memv = i286_memoryread_w(i286reg.inport);	memv = i286_memoryread_w(CPU_INPADRS);
while((memv == 0x00eb) \|\| (memv == 0x5fe6)) {	while((memv == 0x00eb) \|\| (memv == 0x5fe6)) {
jadr -= 0x200;	jadr -= 0x200;
i286reg.inport += 2;	CPU_INPADRS += 2;
memv = i286_memoryread_w(i286reg.inport);	memv = i286_memoryread_w(CPU_INPADRS);
}	}
if ((memv == 0x20a8) \|\| (memv == 0x2024)) {	if ((memv == 0x20a8) \|\| (memv == 0x2024)) {
memv = i286_memoryread_w(i286reg.inport + 2);	memv = i286_memoryread_w(CPU_INPADRS + 2);
if (memv == jadr) { // je	if (memv == jadr) { // je
if (!gdc.vsync) {	if (!gdc.vsync) {
I286_REMCLOCK = -1;	CPU_REMCLOCK = -1;
}	}
}	}
else if (memv == (jadr + 1)) { // jne	else if (memv == (jadr + 1)) { // jne
if (gdc.vsync) {	if (gdc.vsync) {
I286_REMCLOCK = -1;	CPU_REMCLOCK = -1;
}	}
}	}
}	}
}	}
#endif	#endif
#ifdef TURE_SYNC // クロックイベントの誤差修正	#ifdef TURE_SYNC // クロックイベントの誤差修正
if (nevent.item[NEVENT_FLAMES].clock < (I286_BASECLOCK - I286_REMCLOCK)) {	if (nevent.item[NEVENT_FLAMES].clock < (CPU_BASECLOCK - CPU_REMCLOCK)) {
ret ^= 0x20;	ret ^= 0x20;
}	}
#endif	#endif
Line 425 static BYTE IOINPCALL gdc_i60(UINT port)	Line 629 static BYTE IOINPCALL gdc_i60(UINT port)
return(ret);	return(ret);
}	}

static BYTE IOINPCALL gdc_i62(UINT port) {	static REG8 IOINPCALL gdc_i62(UINT port) {

if (gdc.m.snd) {	if (gdc.m.snd) {
gdc.m.snd--;	gdc.m.snd--;
Line 435 static BYTE IOINPCALL gdc_i62(UINT port)	Line 639 static BYTE IOINPCALL gdc_i62(UINT port)
return(0xff);	return(0xff);
}	}

static BYTE IOINPCALL gdc_i68(UINT port) {	static REG8 IOINPCALL gdc_i68(UINT port) {

(void)port;	(void)port;
return(gdc.mode1);	return(gdc.mode1);
}	}

static BYTE IOINPCALL gdc_i6a(UINT port) {	static REG8 IOINPCALL gdc_i6a(UINT port) {

(void)port;	(void)port;
return(gdc.mode2);	return(gdc.mode2);
}	}


static void IOOUTCALL gdc_oa0(UINT port, BYTE dat) {	// ---- I/O slave

	static void IOOUTCALL gdc_oa0(UINT port, REG8 dat) {

if (gdc.s.cnt < GDCCMD_MAX) {	if (gdc.s.cnt < GDCCMD_MAX) {
gdc.s.fifo[gdc.s.cnt++] = dat;	gdc.s.fifo[gdc.s.cnt++] = dat;
}	}
// TRACEOUT(("GDC-B %.2x", dat));	// TRACEOUT(("GDC-B %.2x [%.4x:%.4x]", dat, CPU_CS, CPU_IP));
if (gdc.s.paracb) { // ver0.29	if (gdc.s.paracb) {
gdc_work(GDCWORK_SLAVE);	gdc_work(GDCWORK_SLAVE);
}	}
(void)port;	(void)port;
}	}

static void IOOUTCALL gdc_oa2(UINT port, BYTE dat) {	static void IOOUTCALL gdc_oa2(UINT port, REG8 dat) {

if (gdc.s.cnt < GDCCMD_MAX) {	if (gdc.s.cnt < GDCCMD_MAX) {
gdc.s.fifo[gdc.s.cnt++] = 0x100 \| dat;	gdc.s.fifo[gdc.s.cnt++] = 0x100 \| dat;
Line 470 static void IOOUTCALL gdc_oa2(UINT port,	Line 676 static void IOOUTCALL gdc_oa2(UINT port,
(void)port;	(void)port;
}	}

static void IOOUTCALL gdc_oa4(UINT port, BYTE dat) {	static void IOOUTCALL gdc_oa4(UINT port, REG8 dat) {

if ((gdcs.disp ^ dat) & 1) {	if ((gdcs.disp ^ dat) & 1) {
gdcs.disp = dat & 1;	gdcs.disp = dat & 1;
Line 479 static void IOOUTCALL gdc_oa4(UINT port,	Line 685 static void IOOUTCALL gdc_oa4(UINT port,
(void)port;	(void)port;
}	}

static void IOOUTCALL gdc_oa6(UINT port, BYTE dat) {	static void IOOUTCALL gdc_oa6(UINT port, REG8 dat) {

if ((gdcs.access ^ dat) & 1) {	if ((gdcs.access ^ dat) & 1) {
gdcs.access = dat & 1;	gdcs.access = dat & 1;
Line 490 static void IOOUTCALL gdc_oa6(UINT port,	Line 696 static void IOOUTCALL gdc_oa6(UINT port,
(void)port;	(void)port;
}	}

static void IOOUTCALL gdc_oa8(UINT port, BYTE dat) {	static REG8 IOINPCALL gdc_ia0(UINT port) {

if (gdc.analog) {
gdc.palnum = dat & 0x0f;
}
else {
gdc_setdegpalpack(3, dat);
}
(void)port;
}

static void IOOUTCALL gdc_oaa(UINT port, BYTE dat) {

if (gdc.analog) {
gdc_setanalogpal(gdc.palnum, offsetof(RGB32, p.g), dat);
}
else {
gdc_setdegpalpack(1, dat);
}
(void)port;
}

static void IOOUTCALL gdc_oac(UINT port, BYTE dat) {

if (gdc.analog) {	REG8 ret;
gdc_setanalogpal(gdc.palnum, offsetof(RGB32, p.r), dat);
}
else {
gdc_setdegpalpack(2, dat);
}
(void)port;
}

static void IOOUTCALL gdc_oae(UINT port, BYTE dat) {

if (gdc.analog) {
gdc_setanalogpal(gdc.palnum, offsetof(RGB32, p.b), dat);
}
else {
gdc_setdegpalpack(0, dat);
}
(void)port;
}

static BYTE IOINPCALL gdc_ia0(UINT port) {

BYTE ret;
SINT32 remain;	SINT32 remain;

ret = 0x80 \| gdc.vsync \| gdc.s_drawing;	ret = 0x80 \| gdc.vsync \| gdc.s_drawing;
remain = nevent_getremain(NEVENT_FLAMES);	remain = nevent_getremain(NEVENT_FLAMES);
if (remain >= 0) {	if (remain >= 0) {
if ((remain % pc.raster) < (pc.hsync)) {	if ((remain % gdc.rasterclock) < (gdc.hsyncclock)) {
ret \|= 0x40;	ret \|= 0x40;
}	}
}	}
Line 558 static BYTE IOINPCALL gdc_ia0(UINT port)	Line 720 static BYTE IOINPCALL gdc_ia0(UINT port)
else {	else {
gdc_work(GDCWORK_SLAVE);	gdc_work(GDCWORK_SLAVE);
}	}
#ifdef SEARHC_SYNC	#ifdef SEARCH_SYNC
if ((i286reg.inport) && (I286_REMCLOCK >= 5)) {	if ((CPU_INPADRS) && (CPU_REMCLOCK >= 5)) {
UINT16 jadr = 0xfa74;	UINT16 jadr = 0xfa74;
UINT16 memv;	UINT16 memv;
memv = i286_memoryread_w(i286reg.inport);	memv = i286_memoryread_w(CPU_INPADRS);
while((memv == 0x00eb) \|\| (memv == 0x5fe6)) {	while((memv == 0x00eb) \|\| (memv == 0x5fe6)) {
jadr -= 0x200;	jadr -= 0x200;
i286reg.inport += 2;	CPU_INPADRS += 2;
memv = i286_memoryread_w(i286reg.inport);	memv = i286_memoryread_w(CPU_INPADRS);
}	}
if ((memv == 0x20a8) \|\| (memv == 0x2024)) {	if ((memv == 0x20a8) \|\| (memv == 0x2024)) {
memv = i286_memoryread_w(i286reg.inport + 2);	memv = i286_memoryread_w(CPU_INPADRS + 2);
if (memv == jadr) { // je	if (memv == jadr) { // je
if (!gdc.vsync) {	if (!gdc.vsync) {
I286_REMCLOCK = -1;	CPU_REMCLOCK = -1;
}	}
}	}
else if (memv == (jadr + 1)) { // jne	else if (memv == (jadr + 1)) { // jne
if (gdc.vsync) {	if (gdc.vsync) {
I286_REMCLOCK = -1;	CPU_REMCLOCK = -1;
}	}
}	}
}	}
}	}
#endif	#endif
#ifdef TURE_SYNC // クロックイベントの誤差修正	#ifdef TURE_SYNC // クロックイベントの誤差修正
if (nevent.item[NEVENT_FLAMES].clock < (I286_BASECLOCK - I286_REMCLOCK)) {	if (nevent.item[NEVENT_FLAMES].clock < (CPU_BASECLOCK - CPU_REMCLOCK)) {
ret ^= 0x20;	ret ^= 0x20;
}	}
#endif	#endif
Line 592 static BYTE IOINPCALL gdc_ia0(UINT port)	Line 754 static BYTE IOINPCALL gdc_ia0(UINT port)
return(ret);	return(ret);
}	}

static BYTE IOINPCALL gdc_ia2(UINT port) {	static REG8 IOINPCALL gdc_ia2(UINT port) {

if (gdc.s.snd) {	if (gdc.s.snd) {
gdc.s.snd--;	gdc.s.snd--;
Line 602 static BYTE IOINPCALL gdc_ia2(UINT port)	Line 764 static BYTE IOINPCALL gdc_ia2(UINT port)
return(0xff);	return(0xff);
}	}

static BYTE IOINPCALL gdc_ia4(UINT port) {	static REG8 IOINPCALL gdc_ia4(UINT port) {

(void)port;	(void)port;
return(gdcs.disp);	return(gdcs.disp);
}	}

static BYTE IOINPCALL gdc_ia6(UINT port) {	static REG8 IOINPCALL gdc_ia6(UINT port) {

(void)port;	(void)port;
return(gdcs.access);	return(gdcs.access);
}	}


	// ---- I/O palette

	static void IOOUTCALL gdc_oa8(UINT port, REG8 dat) {

	if (gdc.analog & ((1 << GDCANALOG_256) + (1 << GDCANALOG_16))) {
	gdc.palnum = dat;
	}
	else {
	gdc_setdegpalpack(3, dat);
	}
	(void)port;
	}

	static void IOOUTCALL gdc_oaa(UINT port, REG8 dat) {

	#if defined(SUPPORT_PC9821)
	if (gdc.analog & (1 << GDCANALOG_256)) {
	gdcs.palchange = GDCSCRN_REDRAW;
	gdc.anareg[(16 * 3) + (gdc.palnum * 4) + 0] = dat;
	}
	else
	#endif
	if (gdc.analog & (1 << GDCANALOG_16)) {
	#if defined(SUPPORT_PC9821)
	gdc.anareg[(gdc.palnum * 3) + 2] = dat;
	#endif
	gdc_setanalogpal(gdc.palnum & 15, offsetof(RGB32, p.g), dat);
	}
	else {
	gdc_setdegpalpack(1, dat);
	}
	(void)port;
	}

	static void IOOUTCALL gdc_oac(UINT port, REG8 dat) {

	#if defined(SUPPORT_PC9821)
	if (gdc.analog & (1 << GDCANALOG_256)) {
	gdcs.palchange = GDCSCRN_REDRAW;
	gdc.anareg[(16 * 3) + (gdc.palnum * 4) + 1] = dat;
	}
	else
	#endif
	if (gdc.analog & (1 << GDCANALOG_16)) {
	#if defined(SUPPORT_PC9821)
	gdc.anareg[(gdc.palnum * 3) + 2] = dat;
	#endif
	gdc_setanalogpal(gdc.palnum & 15, offsetof(RGB32, p.r), dat);
	}
	else {
	gdc_setdegpalpack(2, dat);
	}
	(void)port;
	}

	static void IOOUTCALL gdc_oae(UINT port, REG8 dat) {

	#if defined(SUPPORT_PC9821)
	if (gdc.analog & (1 << GDCANALOG_256)) {
	gdcs.palchange = GDCSCRN_REDRAW;
	gdc.anareg[(16 * 3) + (gdc.palnum * 4) + 2] = dat;
	}
	else
	#endif
	if (gdc.analog & (1 << GDCANALOG_16)) {
	gdc_setanalogpal(gdc.palnum & 15, offsetof(RGB32, p.b), dat);
	}
	else {
	gdc_setdegpalpack(0, dat);
	}
	(void)port;
	}

	#if defined(SUPPORT_PC9821)
	static REG8 IOINPCALL gdc_ia8(UINT port) {

	if (gdc.analog & ((1 << GDCANALOG_256) + (1 << GDCANALOG_16))) {
	return(gdc.palnum);
	}
	(void)port;
	return(gdc.degpal[3]);
	}

	static REG8 IOINPCALL gdc_iaa(UINT port) {

	if (gdc.analog & (1 << GDCANALOG_256)) {
	return(gdc.anareg[(16 * 3) + (gdc.palnum * 4) + 0]);
	}
	if (gdc.analog & (1 << GDCANALOG_16)) {
	return(gdc.anareg[(gdc.palnum * 3) + 2]);
	}
	(void)port;
	return(gdc.degpal[1]);
	}

	static REG8 IOINPCALL gdc_iac(UINT port) {

	if (gdc.analog & (1 << GDCANALOG_256)) {
	return(gdc.anareg[(16 * 3) + (gdc.palnum * 4) + 1]);
	}
	if (gdc.analog & (1 << GDCANALOG_16)) {
	return(gdc.anareg[(gdc.palnum * 3) + 2]);
	}
	(void)port;
	return(gdc.degpal[2]);
	}

	static REG8 IOINPCALL gdc_iae(UINT port) {

	if (gdc.analog & (1 << GDCANALOG_256)) {
	return(gdc.anareg[(16 * 3) + (gdc.palnum * 4) + 2]);
	}
	if (gdc.analog & (1 << GDCANALOG_16)) {
	return(gdc.anareg[(gdc.palnum * 3) + 2]);
	}
	(void)port;
	return(gdc.degpal[0]);
	}
	#endif


	// ---- extend

	#if defined(SUPPORT_PC9821)
	static void IOOUTCALL gdc_o9a0(UINT port, REG8 dat) {

	(void)port;
	(void)dat;
	}

	static REG8 IOINPCALL gdc_i9a0(UINT port) {

	(void)port;
	return(0);
	}
	#endif

	#if defined(SUPPORT_CRT31KHZ)
	static void IOOUTCALL gdc_o9a8(UINT port, REG8 dat) {

	if ((gdc.display ^ (dat << GDCDISP_31)) & (1 << GDCDISP_31)) {
	gdc.display ^= (1 << GDCDISP_31);
	gdcs.textdisp \|= GDCSCRN_EXT;
	}
	(void)port;
	}

	static REG8 IOINPCALL gdc_i9a8(UINT port) {

	(void)port;
	return((gdc.display >> GDCDISP_31) & 1);
	}
	#endif


// ---- I/F	// ---- I/F

static const IOOUT gdco60[8] = {	static const IOOUT gdco60[8] = {
gdc_o60, gdc_o62, gdc_o64, NULL,	gdc_o60, gdc_o62, gdc_o64, NULL,
gdc_o68, gdc_o6a, NULL, NULL};	gdc_o68, gdc_o6a, NULL, gdc_o6e};

static const IOOUT gdcoa0[8] = {	static const IOOUT gdcoa0[8] = {
gdc_oa0, gdc_oa2, gdc_oa4, gdc_oa6,	gdc_oa0, gdc_oa2, gdc_oa4, gdc_oa6,
Line 629 static const IOINP gdci60[8] = {	Line 946 static const IOINP gdci60[8] = {
gdc_i60, gdc_i62, NULL, NULL,	gdc_i60, gdc_i62, NULL, NULL,
gdc_i68, gdc_i6a, NULL, NULL};	gdc_i68, gdc_i6a, NULL, NULL};

	#if defined(SUPPORT_PC9821)
	static const IOINP gdcia0[8] = {
	gdc_ia0, gdc_ia2, gdc_ia4, gdc_ia6,
	gdc_ia8, gdc_iaa, gdc_iac, gdc_iae};
	#else
static const IOINP gdcia0[8] = {	static const IOINP gdcia0[8] = {
gdc_ia0, gdc_ia2, gdc_ia4, gdc_ia6,	gdc_ia0, gdc_ia2, gdc_ia4, gdc_ia6,
NULL, NULL, NULL, NULL};	NULL, NULL, NULL, NULL};
	#endif


void gdc_reset(void) {	void gdc_reset(void) {

ZeroMemory(&gdc, sizeof(gdc));	ZeroMemory(&gdc, sizeof(gdc));
ZeroMemory(&gdcs, sizeof(gdcs));	ZeroMemory(&gdcs, sizeof(gdcs));

gdc.mode1 = 0x98;	if (!(np2cfg.dipsw[0] & 0x01)) {
	gdc.mode1 = 0x98;
gdc.m.para[GDC_CSRFORM + 0] = 0x0f;	gdc.m.para[GDC_CSRFORM + 0] = 0x0f;
gdc.m.para[GDC_CSRFORM + 1] = 0xc0;	gdc.m.para[GDC_CSRFORM + 1] = 0xc0;
gdc.m.para[GDC_CSRFORM + 2] = 0x7b;	gdc.m.para[GDC_CSRFORM + 2] = 0x7b;
CopyMemory(gdc.m.para + GDC_SYNC, defsync, 8);	CopyMemory(gdc.m.para + GDC_SYNC, defsyncm24, 8);
CopyMemory(gdc.s.para + GDC_SYNC, defsync, 8);	gdc.s.para[GDC_CSRFORM + 0] = 1;
	CopyMemory(gdc.s.para + GDC_SYNC, defsyncs24, 8);
	}
	else {
	gdc.crt15khz = 3;
	gdc.mode1 = 0x80;
	gdc.m.para[GDC_CSRFORM + 0] = 0x07;
	gdc.m.para[GDC_CSRFORM + 1] = 0xc0;
	gdc.m.para[GDC_CSRFORM + 2] = 0x3b;
	CopyMemory(gdc.m.para + GDC_SYNC, defsyncm15, 8);
	CopyMemory(gdc.s.para + GDC_SYNC, defsyncs15, 8);
	}
	gdc_vectreset(&gdc.m);
	gdc_vectreset(&gdc.s);

gdc.s.para[GDC_CSRFORM] = 1;
gdc.clock = 0;	gdc.clock = 0;
gdc.m.para[GDC_PITCH] = 80; // ver0.26	gdc.m.para[GDC_PITCH] = 80;
gdc.s.para[GDC_PITCH] = 40;	gdc.s.para[GDC_PITCH] = 40;

gdc_paletteinit();	gdc_paletteinit();

	if (np2cfg.color16 & 1) {
	gdc.s.para[GDC_SYNC] = 0x16;
	gdc.display = (1 << GDCDISP_ANALOG);
	}
	gdc.bitac = 0xff;

	if (!(np2cfg.dipsw[0] & 0x04)) { // dipsw1-3 on
	gdc.display \|= (1 << GDCDISP_PLAZMA2);
	}

gdcs.textdisp = GDCSCRN_ENABLE \| GDCSCRN_ALLDRAW2 \| GDCSCRN_EXT;	gdcs.textdisp = GDCSCRN_ENABLE \| GDCSCRN_ALLDRAW2 \| GDCSCRN_EXT;
gdcs.grphdisp = GDCSCRN_ALLDRAW2 \| GDCSCRN_EXT;	gdcs.grphdisp = GDCSCRN_ALLDRAW2 \| GDCSCRN_EXT;
gdc.display = (np2cfg.color16 & 1) << 1;
gdc.bitac = 0xff;
}	}

void gdc_bind(void) {	void gdc_bind(void) {

	gdc_updateclock();
	#if defined(SUPPORT_CRT31KHZ)
	iocore_attachout(0x09a8, gdc_o9a8);
	iocore_attachinp(0x09a8, gdc_i9a8);
	#endif
iocore_attachsysoutex(0x0060, 0x0cf1, gdco60, 8);	iocore_attachsysoutex(0x0060, 0x0cf1, gdco60, 8);
iocore_attachsysinpex(0x0060, 0x0cf1, gdci60, 8);	iocore_attachsysinpex(0x0060, 0x0cf1, gdci60, 8);
iocore_attachsysoutex(0x00a0, 0x0cf1, gdcoa0, 8);	iocore_attachsysoutex(0x00a0, 0x0cf1, gdcoa0, 8);

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

Removed from v.1.6
changed lines
	Added in v.1.26