np2/bios/bios1b.c - diff

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Diff for /np2/bios/bios1b.c between versions 1.8 and 1.35

version 1.8, 2003/12/28 14:33:34	version 1.35, 2005/05/15 18:48:36
Line 2	Line 2
#include "cpucore.h"	#include "cpucore.h"
#include "pccore.h"	#include "pccore.h"
#include "iocore.h"	#include "iocore.h"
	#include "scsicmd.h"
#include "bios.h"	#include "bios.h"
#include "biosmem.h"	#include "biosmem.h"
	#include "sxsibios.h"
#include "fddfile.h"	#include "fddfile.h"
#include "fdd_mtr.h"	#include "fdd_mtr.h"
#include "sxsi.h"	#include "sxsi.h"
Line 15 enum {	Line 17 enum {
};	};


char fdmode = 0;	// ---- FDD
static BYTE work[65536];
static BYTE mtr_c = 0;
static UINT mtr_r = 0;

	static BOOL setfdcmode(REG8 drv, REG8 type, REG8 rpm) {

// ---- FDD	if (drv >= 4) {
	return(FAILURE);
	}
	if ((rpm) && (!fdc.support144)) {
	return(FAILURE);
	}
	fdc.chgreg = type;
	fdc.rpm[drv] = rpm;
	if (type & 2) {
	CTRL_FDMEDIA = DISKTYPE_2HD;
	}
	else {
	CTRL_FDMEDIA = DISKTYPE_2DD;
	}
	return(SUCCESS);
	}

static void init_fdd_equip(void) {	void fddbios_equip(REG8 type, BOOL clear) {

UINT16 diskequip;	REG16 diskequip;

diskequip = GETBIOSMEM16(MEMW_DISK_EQUIP);	diskequip = GETBIOSMEM16(MEMW_DISK_EQUIP);
diskequip &= 0x0f00;	if (clear) {
diskequip \|= (UINT16)(~fdmode) & 3;	diskequip &= 0x0f00;
diskequip \|= (UINT16)fdmode << 12;	}
	if (type & 1) {
	diskequip &= 0xfff0;
	diskequip \|= (fdc.equip & 0x0f);
	}
	else {
	diskequip &= 0x0fff;
	diskequip \|= (fdc.equip & 0x0f) << 12;
	}
SETBIOSMEM16(MEMW_DISK_EQUIP, diskequip);	SETBIOSMEM16(MEMW_DISK_EQUIP, diskequip);
}	}

Line 45 static void biosfd_setchrn(void) {	Line 68 static void biosfd_setchrn(void) {
#if 0	#if 0
static void biosfd_resultout(UINT32 result) {	static void biosfd_resultout(UINT32 result) {

BYTE *ptr;	UINT8 *ptr;

ptr = mem + 0x00564 + (fdc.us*8);	ptr = mem + 0x00564 + (fdc.us*8);
ptr[0] = (BYTE)(result & 0xff) \| (fdc.hd << 2) \| fdc.us;	ptr[0] = (UINT8)(result & 0xff) \| (fdc.hd << 2) \| fdc.us;
ptr[1] = (BYTE)(result >> 8);	ptr[1] = (UINT8)(result >> 8);
ptr[2] = (BYTE)(result >> 16);	ptr[2] = (UINT8)(result >> 16);
ptr[3] = fdc.C;	ptr[3] = fdc.C;
ptr[4] = fdc.H;	ptr[4] = fdc.H;
ptr[5] = fdc.R;	ptr[5] = fdc.R;
Line 59 static void biosfd_resultout(UINT32 resu	Line 82 static void biosfd_resultout(UINT32 resu
}	}
#endif	#endif

static BOOL biosfd_seek(BYTE track, BOOL ndensity) {	static BOOL biosfd_seek(REG8 track, BOOL ndensity) {

if (ndensity) {	if (ndensity) {
if (track < 42) {	if (track < 42) {
Line 70 static BOOL biosfd_seek(BYTE track, BOOL	Line 93 static BOOL biosfd_seek(BYTE track, BOOL
}	}
}	}
fdc.ncn = track;	fdc.ncn = track;
mtr_c = track;
if (fdd_seek()) {	if (fdd_seek()) {
return(FAILURE);	return(FAILURE);
}	}
return(SUCCESS);	return(SUCCESS);
}	}

static UINT16 fdfmt_biospara(BYTE fmt, BYTE rpm) { // ver0.31	static UINT16 fdfmt_biospara(REG8 type, REG8 rpm, REG8 fmt) {

UINT seg;	UINT seg;
UINT off;	UINT off;
Line 87 static UINT16 fdfmt_biospara(BYTE fmt, B	Line 109 static UINT16 fdfmt_biospara(BYTE fmt, B
if (n >= 4) {	if (n >= 4) {
n = 3;	n = 3;
}	}
if (CTRL_FDMEDIA == DISKTYPE_2HD) {	if (type & 2) {
seg = GETBIOSMEM16(MEMW_F2HD_P_SEG);	seg = GETBIOSMEM16(MEMW_F2HD_P_SEG);
off = GETBIOSMEM16(MEMW_F2HD_P_OFF);	off = GETBIOSMEM16(MEMW_F2HD_P_OFF);
}	}
Line 99 static UINT16 fdfmt_biospara(BYTE fmt, B	Line 121 static UINT16 fdfmt_biospara(BYTE fmt, B
off = 0x2361; // see bios.cpp	off = 0x2361; // see bios.cpp
}	}
off += fdc.us * 2;	off += fdc.us * 2;
off = i286_memword_read(seg, off);	off = MEML_READ16(seg, off);
off += n * 8;	off += n * 8;
if (!(CPU_AH & 0x40)) {	if (!(CPU_AH & 0x40)) {
off += 4;	off += 4;
Line 107 static UINT16 fdfmt_biospara(BYTE fmt, B	Line 129 static UINT16 fdfmt_biospara(BYTE fmt, B
if (fmt) {	if (fmt) {
off += 2;	off += 2;
}	}
return(i286_memword_read(seg, LOW16(off)));	return(MEML_READ16(seg, off));
}

static void change_rpm(BYTE rpm) { // ver0.31

if (np2cfg.usefd144) {
fdc.rpm = rpm;
}
}	}



enum {	enum {
FDCBIOS_NORESULT,	FDCBIOS_NORESULT,
FDCBIOS_SUCCESS,	FDCBIOS_SUCCESS,
Line 133 enum {	Line 147 enum {

static void fdd_int(int result) {	static void fdd_int(int result) {

if (result == FDCBIOS_NORESULT) { // ver0.29	if (result == FDCBIOS_NORESULT) {
return;	return;
}	}
switch(CPU_AH & 0x0f) {	switch(CPU_AH & 0x0f) {
Line 146 static void fdd_int(int result) {	Line 160 static void fdd_int(int result) {
case 0x0a: // READ ID	case 0x0a: // READ ID
case 0x0d: // �ե��ޥå�	case 0x0d: // �ե��ޥå�
break;	break;

default:	default:
return;	return;
}	}
Line 182 static void fdd_int(int result) {	Line 197 static void fdd_int(int result) {
fdc.stat[fdc.us] \|= FDCRLT_IC0 \| FDCRLT_NW;	fdc.stat[fdc.us] \|= FDCRLT_IC0 \| FDCRLT_NW;
fdcsend_error7();	fdcsend_error7();
break;	break;

	default:
	return;
}	}
	if (fdc.chgreg & 1) {
	mem[MEMB_DISK_INTL] &= ~(0x01 << fdc.us);
	}
	else {
	mem[MEMB_DISK_INTH] &= ~(0x10 << fdc.us);
	}
	CPU_IP = BIOSOFST_WAIT;
}	}

#if 1	#if 1
Line 210 static void b0patch(void) {	Line 235 static void b0patch(void) {
REG8 c;	REG8 c;
REG8 cl;	REG8 cl;
REG8 last;	REG8 last;
addr = ES_BASE + CPU_BP;	addr = CPU_BP;
size = CPU_BX;	size = CPU_BX;
cnt = 0;	cnt = 0;
last = 0;	last = 0;
while(size--) {	while(size--) {
c = i286_memoryread(addr++);	c = MEML_READ8(ES_BASE, addr++);
cl = 0;	cl = 0;
do {	do {
REG8 now = c & 0x80;	REG8 now = c & 0x80;
Line 239 static void b0patch(void) {	Line 264 static void b0patch(void) {
}	}
}	}
if ((b0p.pos >> 3) < CPU_BX) {	if ((b0p.pos >> 3) < CPU_BX) {
UINT32 addr;	UINT addr;
REG8 c;	REG8 c;
addr = ES_BASE + CPU_BP + (b0p.pos >> 3);	addr = CPU_BP + (b0p.pos >> 3);
c = i286_memoryread(addr);	c = MEML_READ8(CPU_ES, addr);
c ^= (1 << (b0p.pos & 7));	c ^= (1 << (b0p.pos & 7));
b0p.pos++;	b0p.pos++;
i286_memorywrite(addr, c);	MEML_WRITE8(CPU_ES, addr, c);
}	}
}	}
}	}
Line 255 static void b0clr(void) {	Line 280 static void b0clr(void) {
}	}
#endif	#endif

static BYTE fdd_operate(BYTE type, BOOL ndensity, BYTE rpm) { // ver0.31	static REG8 fdd_operate(REG8 type, REG8 rpm, BOOL ndensity) {

BYTE ret_ah = 0x60;	REG8 ret_ah = 0x60;
UINT16 size;	UINT16 size;
UINT16 pos;	UINT16 pos;
UINT16 accesssize;	UINT16 accesssize;
UINT16 secsize;	UINT16 secsize;
UINT16 para;	UINT16 para;
BYTE s;	UINT8 s;
BYTE ID[4];	UINT8 ID[4];
BYTE hd;	UINT8 hd;
int result = FDCBIOS_NORESULT;	int result = FDCBIOS_NORESULT;
UINT32 addr;	UINT32 addr;
	UINT8 mtr_c;
	UINT mtr_r;
	UINT fmode;

mtr_c = 0xff;	mtr_c = fdc.ncn;
mtr_r = 0;	mtr_r = 0;


// �Ȥꤢ��BIOS�λ��̵�뤹��	// �Ȥꤢ��BIOS�λ��̵�뤹��
fdc.mf = 0xff; // ver0.29	fdc.mf = 0xff;

// TRACE_("int 1Bh", CPU_AH);	// TRACE_("int 1Bh", CPU_AH);

change_rpm(rpm); // ver0.31	if (setfdcmode((REG8)(CPU_AL & 3), type, rpm) != SUCCESS) {
	return(0x40);
	}

if ((CPU_AH & 0x0f) != 0x0a) {	if ((CPU_AH & 0x0f) != 0x0a) {
fdc.crcn = 0;	fdc.crcn = 0;
}	}
if ((CPU_AH & 0x0f) != 0x03) {	if ((CPU_AH & 0x0f) != 0x03) {
CTRL_FDMEDIA = type;	if (type & 2) {
switch(type) {	if (pic.pi[1].imr & PIC_INT42) {
case DISKTYPE_2HD:	return(0x40);
if (pic.pi[1].imr & PIC_INT42) {	}
return(0xd0);	}
}	else {
break;	if (pic.pi[1].imr & PIC_INT41) {
case DISKTYPE_2DD:	return(0x40);
if (pic.pi[1].imr & PIC_INT41) {	}
return(0xd0);
}
break;
}	}
if (fdc.us != (CPU_AL & 0x03)) {	if (fdc.us != (CPU_AL & 0x03)) {
fdc.us = CPU_AL & 0x03;	fdc.us = CPU_AL & 0x03;
Line 307 static BYTE fdd_operate(BYTE type, BOOL	Line 334 static BYTE fdd_operate(BYTE type, BOOL
}	}
if (!fdd_diskready(fdc.us)) {	if (!fdd_diskready(fdc.us)) {
fdd_int(FDCBIOS_NONREADY);	fdd_int(FDCBIOS_NONREADY);
if (CPU_AH == 0x84) { // ver0.28	ret_ah = 0x60;
return(0x68); // ��󥹤� ξ�ѥɥ饤�־��	if ((CPU_AX & 0x8f40) == 0x8400) {
}	ret_ah \|= 8; // 1MB/640KBξ�ѥɥ饤��
if (CPU_AH == 0xc4) { // ver0.31	if ((CPU_AH & 0x40) && (fdc.support144)) {
if (np2cfg.usefd144) {	ret_ah \|= 4; // 1.44�б��ɥ饤��
return(0x6c);
}	}
return(0x68);
}	}
return(0x60);	return(ret_ah);
}	}
}	}

// 2DD�Υ⡼�� // ver0.29	// �⡼�� // ver0.78
if (type == DISKTYPE_2DD) {	fmode = (type & 1)?MEMB_F2HD_MODE:MEMB_F2DD_MODE;
if (!(mem[MEMB_F2DD_MODE] & (0x10 << fdc.us))) {	if (!(CPU_AL & 0x80)) {
ndensity = 1;	if (!(mem[fmode] & (0x10 << fdc.us))) {
	ndensity = TRUE;
}	}
}	}

Line 352 static BYTE fdd_operate(BYTE type, BOOL	Line 378 static BYTE fdd_operate(BYTE type, BOOL
}	}
}	}
biosfd_setchrn();	biosfd_setchrn();
para = fdfmt_biospara(0, rpm);	para = fdfmt_biospara(type, rpm, 0);
if (!para) {	if (!para) {
ret_ah = 0xd0;	ret_ah = 0xd0;
break;	break;
Line 375 static BYTE fdd_operate(BYTE type, BOOL	Line 401 static BYTE fdd_operate(BYTE type, BOOL
break;	break;
}	}
size -= accesssize;	size -= accesssize;
mtr_r += accesssize; // ver0.26	mtr_r += accesssize;
if ((fdc.R++ == (BYTE)para) && (CPU_AH & 0x80) && (!fdc.hd)) {	if ((fdc.R++ == (UINT8)para) &&
	(CPU_AH & 0x80) && (!fdc.hd)) {
fdc.hd = 1;	fdc.hd = 1;
fdc.H = 1;	fdc.H = 1;
fdc.R = 1;	fdc.R = 1;
Line 396 static BYTE fdd_operate(BYTE type, BOOL	Line 423 static BYTE fdd_operate(BYTE type, BOOL
break;	break;

case 0x03: // ��	case 0x03: // ��
init_fdd_equip();	fddbios_equip(type, FALSE);
ret_ah = 0x00;	ret_ah = 0x00;
break;	break;

Line 412 static BYTE fdd_operate(BYTE type, BOOL	Line 439 static BYTE fdd_operate(BYTE type, BOOL
ret_ah \|= 0x01;	ret_ah \|= 0x01;
}	}
else { // 2DD	else { // 2DD
if (mem[0x005ca] & (0x01 << fdc.us)) {	if (mem[fmode] & (0x01 << fdc.us)) {
ret_ah++;	ret_ah \|= 0x01;
}	}
if (mem[0x005ca] & (0x10 << fdc.us)) { // ver0.30	if (mem[fmode] & (0x10 << fdc.us)) {
ret_ah \|= 0x04;	ret_ah \|= 0x04;
}	}
}	}
if (CPU_AH & 0x80) { // ver0.30	if ((CPU_AX & 0x8f40) == 0x8400) {
ret_ah \|= 8; // 1MB/640KBξ�ѥɥ饤��	ret_ah \|= 8; // 1MB/640KBξ�ѥɥ饤��
if ((CPU_AH & 0x40) &&	if ((CPU_AH & 0x40) && (fdc.support144)) {
(np2cfg.usefd144)) { // ver0.31
ret_ah \|= 4; // 1.44�б��ɥ饤��	ret_ah \|= 4; // 1.44�б��ɥ饤��
}	}
}	}
Line 440 static BYTE fdd_operate(BYTE type, BOOL	Line 466 static BYTE fdd_operate(BYTE type, BOOL
}	}
}	}
biosfd_setchrn();	biosfd_setchrn();
para = fdfmt_biospara(0, rpm);	para = fdfmt_biospara(type, rpm, 0);
if (!para) {	if (!para) {
ret_ah = 0xd0;	ret_ah = 0xd0;
break;	break;
Line 465 static BYTE fdd_operate(BYTE type, BOOL	Line 491 static BYTE fdd_operate(BYTE type, BOOL
else {	else {
accesssize = size;	accesssize = size;
}	}
i286_memx_read(addr, fdc.buf, accesssize);	MEML_READ(addr, fdc.buf, accesssize);
if (fdd_write()) {	if (fdd_write()) {
break;	break;
}	}
addr += accesssize;	addr += accesssize;
size -= accesssize;	size -= accesssize;
mtr_r += accesssize; // ver0.26	mtr_r += accesssize;
if ((fdc.R++ == (BYTE)para) && (CPU_AH & 0x80) && (!fdc.hd)) {	if ((fdc.R++ == (UINT8)para) &&
	(CPU_AH & 0x80) && (!fdc.hd)) {
fdc.hd = 1;	fdc.hd = 1;
fdc.H = 1;	fdc.H = 1;
fdc.R = 1;	fdc.R = 1;
Line 486 static BYTE fdd_operate(BYTE type, BOOL	Line 513 static BYTE fdd_operate(BYTE type, BOOL
result = FDCBIOS_SUCCESS;	result = FDCBIOS_SUCCESS;
}	}
else {	else {
ret_ah = fddlasterror; // 0xc0 // ver0.28	ret_ah = fddlasterror; // 0xc0
result = FDCBIOS_WRITEERROR;	result = FDCBIOS_WRITEERROR;
}	}
break;	break;
Line 504 static BYTE fdd_operate(BYTE type, BOOL	Line 531 static BYTE fdd_operate(BYTE type, BOOL
}	}
}	}
biosfd_setchrn();	biosfd_setchrn();
para = fdfmt_biospara(0, rpm);	para = fdfmt_biospara(type, rpm, 0);
if (!para) {	if (!para) {
ret_ah = 0xd0;	ret_ah = 0xd0;
break;	break;
Line 533 static BYTE fdd_operate(BYTE type, BOOL	Line 560 static BYTE fdd_operate(BYTE type, BOOL
if (fdd_read()) {	if (fdd_read()) {
break;	break;
}	}
i286_memx_write(addr, fdc.buf, accesssize);	MEML_WRITE(addr, fdc.buf, accesssize);
addr += accesssize;	addr += accesssize;
size -= accesssize;	size -= accesssize;
mtr_r += accesssize; // ver0.26	mtr_r += accesssize;
if (fdc.R++ == (BYTE)para) {	if (fdc.R++ == (UINT8)para) {
if ((CPU_AH & 0x80) && (!fdc.hd)) {	if ((CPU_AH & 0x80) && (!fdc.hd)) {
fdc.hd = 1;	fdc.hd = 1;
fdc.H = 1;	fdc.H = 1;
Line 574 static BYTE fdd_operate(BYTE type, BOOL	Line 601 static BYTE fdd_operate(BYTE type, BOOL
}	}
#endif	#endif
else {	else {
ret_ah = fddlasterror; // 0xc0; // ver0.28	ret_ah = fddlasterror; // 0xc0;
result = FDCBIOS_READERROR;	result = FDCBIOS_READERROR;
}	}
break;	break;
Line 586 static BYTE fdd_operate(BYTE type, BOOL	Line 613 static BYTE fdd_operate(BYTE type, BOOL
break;	break;

case 0x0a: // READ ID	case 0x0a: // READ ID
fdc.mf = CPU_AH & 0x40; // ver0.29	fdc.mf = CPU_AH & 0x40;
if (CPU_AH & 0x10) { // ver0.28	if (CPU_AH & 0x10) {
if (!biosfd_seek(CPU_CL, ndensity)) {	if (!biosfd_seek(CPU_CL, ndensity)) {
result = FDCBIOS_SEEKSUCCESS;	result = FDCBIOS_SEEKSUCCESS;
}	}
Line 598 static BYTE fdd_operate(BYTE type, BOOL	Line 625 static BYTE fdd_operate(BYTE type, BOOL
}	}
}	}
if (fdd_readid()) {	if (fdd_readid()) {
ret_ah = fddlasterror; // 0xa0; // ver0.28	ret_ah = fddlasterror; // 0xa0;
break;	break;
}	}
if (fdc.N < 8) { // ver0.26	if (fdc.N < 8) {
mtr_r += 128 << fdc.N;	mtr_r += 128 << fdc.N;
}	}
else {	else {
Line 625 static BYTE fdd_operate(BYTE type, BOOL	Line 652 static BYTE fdd_operate(BYTE type, BOOL
}	}
fdc.d = CPU_DL;	fdc.d = CPU_DL;
fdc.N = CPU_CH;	fdc.N = CPU_CH;
para = fdfmt_biospara(1, rpm);	para = fdfmt_biospara(type, rpm, 1);
if (!para) {	if (!para) {
ret_ah = 0xd0;	ret_ah = 0xd0;
break;	break;
}	}
fdc.sc = (BYTE)para;	fdc.sc = (UINT8)para;
fdd_formatinit();	fdd_formatinit();
pos = CPU_BP;	pos = CPU_BP;
for (s=0; s<fdc.sc; s++) {	for (s=0; s<fdc.sc; s++) {
i286_memstr_read(CPU_ES, pos, ID, 4);	MEML_READSTR(CPU_ES, pos, ID, 4);
fdd_formating(ID);	fdd_formating(ID);
pos += 4;	pos += 4;
	if (ID[3] < 8) {
	mtr_r += 128 << ID[3];
	}
	else {
	mtr_r += 128 << 8;
	}
}	}
ret_ah = 0x00;	ret_ah = 0x00;
break;	break;
}
fdd_int(result);
fddmtr_seek(fdc.us, mtr_c, mtr_r);
CPU_IP = BIOSOFST_WAIT; // ver0.30
return(ret_ah);
}


// ---- SASI

static void init_sasi_equip(void) {

UINT16 diskequip;
UINT i;
UINT16 bit;

diskequip = GETBIOSMEM16(MEMW_DISK_EQUIP);
diskequip &= 0xf0ff;
for (i=0, bit=0x0100; i<2; i++, bit<<=1) {
if (sxsi_hd[i].fname[0]) {
diskequip \|= bit;
}
}
SETBIOSMEM16(MEMW_DISK_EQUIP, diskequip);
}

static void init_scsi_equip(void) {

UINT i;
BYTE bit;
UINT16 w;

mem[MEMB_DISK_EQUIPS] = 0;
ZeroMemory(&mem[0x00460], 0x20);
for (i=0, bit=1; i<2; i++, bit<<=1) {
if (sxsi_hd[i+2].fname[0]) {
mem[MEMB_DISK_EQUIPS] \|= bit;
mem[0x00460+i*4] = sxsi_hd[i+2].sectors;
mem[0x00461+i*4] = sxsi_hd[i+2].surfaces;
switch(sxsi_hd[i+2].size) {
case 256:
w = 0 << 12;
break;

case 512:
w = 1 << 12;
break;

default:
w = 2 << 12;
break;
}
w \|= sxsi_hd[i+2].tracks;
SETBIOSMEM16(0x00462+i*4, w);
}
}
}

static BYTE sxsi_pos(long *pos) {

SXSIHDD sxsi;
int np2drv;

*pos = 0;
np2drv = (CPU_AL & 0x20) >> 4;
if ((CPU_AL & 0x0f) >= 2) {
return(0x60);
}
np2drv \|= (CPU_AL & 1);
sxsi = &sxsi_hd[np2drv];
if (CPU_AL & 0x80) {
if ((CPU_DL >= sxsi->sectors) \|\|
(CPU_DH >= sxsi->surfaces) \|\|
(CPU_CX >= sxsi->tracks)) {
return(0xd0);
}
(pos) = ((CPU_CX sxsi->surfaces) + CPU_DH) * sxsi->sectors
+ CPU_DL;
}
else {
*pos = (CPU_DL << 16) \| CPU_CX;
if (!(CPU_AL & 0x20)) {
(*pos) &= 0x1fffff;
}
if ((*pos) >= sxsi->totals) {
return(0xd0);
}
}
return(0x00);
}


UINT8 sxsi_operate(UINT8 type) {

BYTE ret_ah = 0x00;
BYTE drv;
long pos;
// int i;

drv = (CPU_AL & 0x20) >> 4;
if ((CPU_AL & 0x0f) >= 2) {
return(0x60);
}
drv \|= (CPU_AL & 1);

switch(CPU_AH & 0x0f) {
case 0x01: // �٥�ե��
case 0x07: // ��ȥ饯��
case 0x0f: // ��ȥ饯��
break;

case 0x03: // ��˥��饤��	case 0x0e: // ver0.78
if (type == HDDTYPE_SASI) {	if (CPU_AH & 0x80) { // ̩��
init_sasi_equip();	mem[fmode] &= 0x0f;
	mem[fmode] \|= (UINT8)((CPU_AH & 0x0f) << 4);
	}
	else { // ��
	mem[fmode] &= 0xf0;
	mem[fmode] \|= (UINT8)(CPU_AH & 0x0f);
}	}
else if (type == HDDTYPE_SCSI) {
init_scsi_equip();
}
break;

case 0x04: // ��
ret_ah = 0x00;	ret_ah = 0x00;
if ((CPU_AH == 0x04) && (type == HDDTYPE_SASI)) {
ret_ah = 0x04;
}
else if ((CPU_AH == 0x44) && (type == HDDTYPE_SCSI)) {
CPU_BX = 1;
}
else if (CPU_AH == 0x84) {
CPU_BX = sxsi_hd[drv].size;
CPU_CX = sxsi_hd[drv].tracks;
CPU_DH = sxsi_hd[drv].surfaces;
CPU_DL = sxsi_hd[drv].sectors;
}
break;

case 0x05: // �ǡ��ν񤭹��
i286_memx_read(ES_BASE + CPU_BP, work, CPU_BX);
ret_ah = sxsi_pos(&pos);
if (!ret_ah) {
ret_ah = sxsi_write(CPU_AL, pos, work, CPU_BX);
}
break;

case 0x06: // �ǡ��ɤ߹��
ret_ah = sxsi_pos(&pos);
if (!ret_ah) {
ret_ah = sxsi_read(CPU_AL, pos, work, CPU_BX);
if (ret_ah < 0x20) {
i286_memx_write(ES_BASE + CPU_BP, work, CPU_BX);
}
}
break;

case 0x0d: // �ե��ޥå�
if (CPU_DL) {
ret_ah = 0x30;
break;
}
i286_memstr_read(CPU_ES, CPU_BP, work, CPU_BX);
ret_ah = sxsi_pos(&pos);
if (!ret_ah) {
ret_ah = sxsi_format(CPU_AL, pos);
}
break;

default:
ret_ah = 0x40;
break;	break;
}	}
	fdd_int(result);
	if (mtr_c != fdc.ncn) {
	fddmtr_seek(fdc.us, mtr_c, mtr_r);
	}
return(ret_ah);	return(ret_ah);
}	}


// -------------------------------------------------------------------- BIOS	// -------------------------------------------------------------------- BIOS

static UINT16 boot_fd1(BYTE rpm) { // ver0.31	static UINT16 boot_fd1(REG8 type, REG8 rpm) {

UINT remain;	UINT remain;
UINT size;	UINT size;
UINT32 pos;	UINT32 pos;
UINT16 bootseg;	UINT16 bootseg;

change_rpm(rpm); // ver0.31	if (setfdcmode(fdc.us, type, rpm) != SUCCESS) {
	return(0);
	}
if (biosfd_seek(0, 0)) {	if (biosfd_seek(0, 0)) {
return(0);	return(0);
}	}
Line 867 static UINT16 boot_fd1(BYTE rpm) {	Line 749 static UINT16 boot_fd1(BYTE rpm) {
return(bootseg);	return(bootseg);
}	}

static UINT16 boot_fd(BYTE drv, BYTE type) { // ver0.27	static UINT16 boot_fd(REG8 drv, REG8 type) {

UINT16 bootseg;	UINT16 bootseg;

if (drv >= 4) {	if (drv >= 4) {
return(0);	return(0);
}	}
fdc.us = drv & 3;	fdc.us = drv;
if (!fdd_diskready(fdc.us)) {	if (!fdd_diskready(fdc.us)) {
return(0);	return(0);
}	}

// 2HD	// 2HD
if (type & 1) {	if (type & 1) {
CTRL_FDMEDIA = DISKTYPE_2HD;
// 1.25MB	// 1.25MB
bootseg = boot_fd1(0);	bootseg = boot_fd1(3, 0);
if (bootseg) {	if (bootseg) {
mem[MEMB_DISK_BOOT] = (BYTE)(0x90+drv);	mem[MEMB_DISK_BOOT] = (UINT8)(0x90 + drv);
	fddbios_equip(3, TRUE);
return(bootseg);	return(bootseg);
}	}
// 1.44MB	// 1.44MB
bootseg = boot_fd1(1);	bootseg = boot_fd1(3, 1);
if (bootseg) {	if (bootseg) {
mem[MEMB_DISK_BOOT] = (BYTE)(0x30+drv);	mem[MEMB_DISK_BOOT] = (UINT8)(0x30 + drv);
	fddbios_equip(3, TRUE);
return(bootseg);	return(bootseg);
}	}
}	}
if (type & 2) { // ver0.29	if (type & 2) {
// 2DD	// 2DD
CTRL_FDMEDIA = DISKTYPE_2DD;	bootseg = boot_fd1(0, 0);
bootseg = boot_fd1(0);
if (bootseg) {	if (bootseg) {
mem[MEMB_DISK_BOOT] = (BYTE)(0x70+drv);	mem[MEMB_DISK_BOOT] = (UINT8)(0x70 + drv);
fdmode = 3;	fddbios_equip(0, TRUE);
return(bootseg);	return(bootseg);
}	}
}	}
return(0);	return(0);
}	}

static UINT16 boot_hd(BYTE drv) { // ver0.27	static REG16 boot_hd(REG8 drv) {

BYTE ret;	REG8 ret;

ret = sxsi_read(drv, 0, mem + 0x1fc00, 0x400);	ret = sxsi_read(drv, 0, mem + 0x1fc00, 0x400);
if (ret < 0x20) {	if (ret < 0x20) {
Line 920 static UINT16 boot_hd(BYTE drv) {	Line 802 static UINT16 boot_hd(BYTE drv) {
return(0);	return(0);
}	}

UINT16 bootstrapload(void) { // ver0.27	REG16 bootstrapload(void) {

BYTE i;	UINT8 i;
UINT16 bootseg;	REG16 bootseg;

fdmode = 0;	// fdmode = 0;
bootseg = 0;	bootseg = 0;
switch(mem[MEMB_MSW5] & 0xf0) { // ��AL�쥸��ͤ��	switch(mem[MEMB_MSW5] & 0xf0) { // ��AL�쥸��ͤ��
case 0x00: // �Ρ��ޥ�	case 0x00: // �Ρ��ޥ�
break;	break;

case 0x20: // 640KB FDD	case 0x20: // 640KB FDD
for (i=0; (i<4) && (!bootseg); i++) {	for (i=0; (i<4) && (!bootseg); i++) {
if (fdd_diskready(i)) {	if (fdd_diskready(i)) {
Line 937 UINT16 bootstrapload(void) { //	Line 820 UINT16 bootstrapload(void) { //
}	}
}	}
break;	break;

case 0x40: // 1.2MB FDD	case 0x40: // 1.2MB FDD
for (i=0; (i<4) && (!bootseg); i++) {	for (i=0; (i<4) && (!bootseg); i++) {
if (fdd_diskready(i)) {	if (fdd_diskready(i)) {
Line 944 UINT16 bootstrapload(void) { //	Line 828 UINT16 bootstrapload(void) { //
}	}
}	}
break;	break;

case 0x60: // MO	case 0x60: // MO
break;	break;

case 0xa0: // SASI 1	case 0xa0: // SASI 1
if (sxsi_hd[0].fname[0]) {	bootseg = boot_hd(0x80);
bootseg = boot_hd(0x80);
}
break;	break;

case 0xb0: // SASI 2	case 0xb0: // SASI 2
if (sxsi_hd[1].fname[0]) {	bootseg = boot_hd(0x81);
bootseg = boot_hd(0x81);
}
break;	break;

case 0xc0: // SCSI	case 0xc0: // SCSI
for (i=0; (i<2) && (!bootseg); i++) {	for (i=0; (i<4) && (!bootseg); i++) {
if (sxsi_hd[i+2].fname[0]) {	bootseg = boot_hd((REG8)(0xa0 + i));
bootseg = boot_hd((BYTE)(0xa0 \| i));
}
}	}
break;	break;

default: // ROM	default: // ROM
return(0);	return(0);
}	}
Line 972 UINT16 bootstrapload(void) { //	Line 855 UINT16 bootstrapload(void) { //
}	}
}	}
for (i=0; (i<2) && (!bootseg); i++) {	for (i=0; (i<2) && (!bootseg); i++) {
if (sxsi_hd[i].fname[0]) {	bootseg = boot_hd((REG8)(0x80 + i));
bootseg = boot_hd((BYTE)(0x80 \| i));
}
}	}
for (i=0; (i<2) && (!bootseg); i++) {	for (i=0; (i<4) && (!bootseg); i++) {
if (sxsi_hd[i+2].fname[0]) {	bootseg = boot_hd((REG8)(0xa0 + i));
bootseg = boot_hd((BYTE)(0xa0 \| i));
}
}	}

init_fdd_equip();
init_sasi_equip();
init_scsi_equip();
return(bootseg);	return(bootseg);
}	}


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

void bios0x1b(void) {	void bios0x1b(void) {

BYTE ret_ah;	REG8 ret_ah;
REG8 flag;	REG8 flag;

	#if 1 // bypass to disk bios
	REG8 seg;
	UINT sp;

	seg = mem[MEMX_DISK_XROM + (CPU_AL >> 4)];
	if (seg) {
	sp = CPU_SP;
	MEML_WRITE16(CPU_SS, sp - 2, CPU_DS);
	MEML_WRITE16(CPU_SS, sp - 4, CPU_SI);
	MEML_WRITE16(CPU_SS, sp - 6, CPU_DI);
	MEML_WRITE16(CPU_SS, sp - 8, CPU_ES); // +a
	MEML_WRITE16(CPU_SS, sp - 10, CPU_BP); // +8
	MEML_WRITE16(CPU_SS, sp - 12, CPU_DX); // +6
	MEML_WRITE16(CPU_SS, sp - 14, CPU_CX); // +4
	MEML_WRITE16(CPU_SS, sp - 16, CPU_BX); // +2
	MEML_WRITE16(CPU_SS, sp - 18, CPU_AX); // +0
	#if 0
	TRACEOUT(("call by %.4x:%.4x",
	MEML_READ16(CPU_SS, CPU_SP+2),
	MEML_READ16(CPU_SS, CPU_SP)));
	TRACEOUT(("bypass to %.4x:0018", seg << 8));
	TRACEOUT(("AX=%04x BX=%04x %02x:%02x:%02x:%02x ES=%04x BP=%04x",
	CPU_AX, CPU_BX, CPU_CL, CPU_DH, CPU_DL, CPU_CH,
	CPU_ES, CPU_BP));
	#endif
	sp -= 18;
	CPU_SP = sp;
	CPU_BP = sp;
	CPU_DS = 0x0000;
	CPU_BX = 0x04B0;
	CPU_AX = seg << 8;
	CPU_CS = seg << 8;
	CPU_IP = 0x18;
	return;
	}
	#endif

	#if defined(SUPPORT_SCSI)
	if ((CPU_AL & 0xf0) == 0xc0) {
	TRACEOUT(("%.4x:%.4x AX=%.4x BX=%.4x CX=%.4x DX=%.4 ES=%.4x BP=%.4x",
	MEML_READ16(CPU_SS, CPU_SP+2),
	MEML_READ16(CPU_SS, CPU_SP),
	CPU_AX, CPU_BX, CPU_CX, CPU_DX, CPU_ES, CPU_BP));
	scsicmd_bios();
	return;
	}
	#endif

switch(CPU_AL & 0xf0) {	switch(CPU_AL & 0xf0) {
case 0x90:	case 0x90:
ret_ah = fdd_operate(DISKTYPE_2HD, 0, 0);	ret_ah = fdd_operate(3, 0, FALSE);
break;	break;

case 0x30:	case 0x30:
case 0xb0:	case 0xb0:
ret_ah = fdd_operate(DISKTYPE_2HD, 0, 1);	ret_ah = fdd_operate(3, 1, FALSE);
break;	break;

case 0x10:	case 0x10:
	ret_ah = fdd_operate(1, 0, FALSE);
	break;

case 0x70:	case 0x70:
case 0xf0:	case 0xf0:
ret_ah = fdd_operate(DISKTYPE_2DD, 0, 0);	ret_ah = fdd_operate(0, 0, FALSE);
break;	break;

case 0x50:	case 0x50:
ret_ah = fdd_operate(DISKTYPE_2DD, 1, 0);	ret_ah = fdd_operate(0, 0, TRUE);
break;	break;

case 0x00:	case 0x00:
case 0x80:	case 0x80:
ret_ah = sxsi_operate(HDDTYPE_SASI);	ret_ah = sasibios_operate();
break;	break;
#if 0
	#if defined(SUPPORT_SCSI)
case 0x20:	case 0x20:
case 0xa0:	case 0xa0:
ret_ah = sxsi_operate(HDDTYPE_SCSI);	ret_ah = scsibios_operate();
break;	break;
#endif	#endif

Line 1031 void bios0x1b(void) {	Line 959 void bios0x1b(void) {
break;	break;
}	}
#if 0	#if 0
{
static BYTE p = 0;
if ((CPU_CL == 0x4d) && (ret_ah == 0xe0)) {
if (!p) {
trace_sw = 1;
p++;
debug_status();
memorydump();
}
}
}
#endif
#if 0
TRACEOUT(("%04x:%04x AX=%04x BX=%04x %02x:%02x:%02x:%02x\n" \	TRACEOUT(("%04x:%04x AX=%04x BX=%04x %02x:%02x:%02x:%02x\n" \
"ES=%04x BP=%04x \nret=%02x",	"ES=%04x BP=%04x \nret=%02x",
i286_memword_read(CPU_SS, CPU_SP+2),	MEML_READ16(CPU_SS, CPU_SP+2),
i286_memword_read(CPU_SS, CPU_SP),	MEML_READ16(CPU_SS, CPU_SP),
CPU_AX, CPU_BX, CPU_CL, CPU_DH, CPU_DL, CPU_CH,	CPU_AX, CPU_BX, CPU_CL, CPU_DH, CPU_DL, CPU_CH,
CPU_ES, CPU_BP, ret_ah));	CPU_ES, CPU_BP, ret_ah));
#endif	#endif
CPU_AH = ret_ah;	CPU_AH = ret_ah;
flag = i286_membyte_read(CPU_SS, CPU_SP+4) & 0xfe;	flag = MEML_READ8(CPU_SS, CPU_SP+4) & 0xfe;
if (ret_ah >= 0x20) {	if (ret_ah >= 0x20) {
flag += 1;	flag += 1;
}	}
i286_membyte_write(CPU_SS, CPU_SP + 4, flag);	MEML_WRITE8(CPU_SS, CPU_SP + 4, flag);
	}

	UINT bios0x1b_wait(void) {

	UINT addr;
	REG8 bit;

	if (fddmtr.busy) {
	CPU_REMCLOCK = -1;
	}
	else {
	if (fdc.chgreg & 1) {
	addr = MEMB_DISK_INTL;
	bit = 0x01;
	}
	else {
	addr = MEMB_DISK_INTH;
	bit = 0x10;
	}
	bit <<= fdc.us;
	if (mem[addr] & bit) {
	mem[addr] &= ~bit;
	return(0);
	}
	else {
	CPU_REMCLOCK -= 1000;
	}
	}
	CPU_IP--;
	return(1);
}	}

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

Removed from v.1.8
changed lines
	Added in v.1.35