np2/i386c/ia32/segments.c - diff

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Diff for /np2/i386c/ia32/segments.c between versions 1.16 and 1.21

version 1.16, 2004/03/23 22:39:40	version 1.21, 2011/12/23 04:17:47
Line 1	Line 1
/* $Id$ */

/*	/*
* Copyright (c) 2003 NONAKA Kimihiro	* Copyright (c) 2003 NONAKA Kimihiro
* All rights reserved.	* All rights reserved.
Line 12	Line 10
* 2. Redistributions in binary form must reproduce the above copyright	* 2. Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the	* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.	* documentation and/or other materials provided with the distribution.
* 3. The name of the author may not be used to endorse or promote products
* derived from this software without specific prior written permission.
*	*
* THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR	* THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR
* IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES	* IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES
Line 33	Line 29


void	void
load_segreg(int idx, UINT16 selector, int exc)	load_segreg(int idx, UINT16 selector, UINT16 sregp, descriptor_t sdp, int exc)
{	{
selector_t sel;	selector_t sel;
int rv;	int rv;

__ASSERT((unsigned int)idx < CPU_SEGREG_NUM);	__ASSERT((unsigned int)idx < CPU_SEGREG_NUM);
	__ASSERT((sregp != NULL));
	__ASSERT((sdp != NULL));

if (!CPU_STAT_PM \|\| CPU_STAT_VM86) {	if (!CPU_STAT_PM \|\| CPU_STAT_VM86) {
descriptor_t sd;

/* real-mode or vm86 mode */	/* real-mode or vm86 mode */
CPU_REGS_SREG(idx) = selector;	*sregp = selector;
	segdesc_clear(&sel.desc);
memset(&sd, 0, sizeof(sd));	sel.desc.u.seg.limit = CPU_STAT_SREGLIMIT(idx);
if (idx == CPU_CS_INDEX) {	segdesc_set_default(idx, selector, &sel.desc);
sd.rpl = CPU_STAT_CPL;	*sdp = sel.desc;
}
sd.u.seg.limit = CPU_STAT_SREGLIMIT(idx);
CPU_SET_SEGDESC_DEFAULT(&sd, idx, selector);
CPU_STAT_SREG(idx) = sd;
return;	return;
}	}

	VERBOSE(("load_segreg: EIP = %04x:%08x, idx = %d, selector = %04x, sregp = %p, dp = %p, exc = %d", CPU_CS, CPU_PREV_EIP, idx, selector, sregp, sdp, exc));

/*	/*
* protected mode	* protected mode
*/	*/
VERBOSE(("load_segreg: EIP = %04x:%08x, idx = %d, selector = %04x, exc = %d", CPU_CS, CPU_PREV_EIP, idx, selector, exc));

if (idx == CPU_CS_INDEX) {	if (idx == CPU_CS_INDEX) {
ia32_panic("load_segreg: CS");	ia32_panic("load_segreg: CS");
}	}
Line 70 load_segreg(int idx, UINT16 selector, in	Line 62 load_segreg(int idx, UINT16 selector, in
if ((rv != -2) \|\| (idx == CPU_SS_INDEX)) {	if ((rv != -2) \|\| (idx == CPU_SS_INDEX)) {
EXCEPTION(exc, sel.idx);	EXCEPTION(exc, sel.idx);
}	}
CPU_REGS_SREG(idx) = sel.selector;	*sregp = sel.selector;
CPU_STAT_SREG_CLEAR(idx);	segdesc_clear(sdp);
return;	return;
}	}

Line 79 load_segreg(int idx, UINT16 selector, in	Line 71 load_segreg(int idx, UINT16 selector, in
case CPU_SS_INDEX:	case CPU_SS_INDEX:
if ((CPU_STAT_CPL != sel.rpl)	if ((CPU_STAT_CPL != sel.rpl)
\|\| (CPU_STAT_CPL != sel.desc.dpl)	\|\| (CPU_STAT_CPL != sel.desc.dpl)
\|\| !sel.desc.s	\|\| SEG_IS_SYSTEM(&sel.desc)
\|\| sel.desc.u.seg.c	\|\| SEG_IS_CODE(&sel.desc)
\|\| !sel.desc.u.seg.wr) {	\|\| !SEG_IS_WRITABLE_DATA(&sel.desc)) {
EXCEPTION(exc, sel.idx);	EXCEPTION(exc, sel.idx);
}	}

Line 91 load_segreg(int idx, UINT16 selector, in	Line 83 load_segreg(int idx, UINT16 selector, in
EXCEPTION(SS_EXCEPTION, sel.idx);	EXCEPTION(SS_EXCEPTION, sel.idx);
}	}

load_ss(sel.selector, &sel.desc, sel.selector & 3);	load_ss(sel.selector, &sel.desc, CPU_STAT_CPL);
break;	break;

case CPU_ES_INDEX:	case CPU_ES_INDEX:
case CPU_DS_INDEX:	case CPU_DS_INDEX:
case CPU_FS_INDEX:	case CPU_FS_INDEX:
case CPU_GS_INDEX:	case CPU_GS_INDEX:
/* !(system segment \|\| non-readable code segment) */	if (SEG_IS_SYSTEM(&sel.desc)
if (!sel.desc.s	\|\| (SEG_IS_CODE(&sel.desc) && !SEG_IS_READABLE_CODE(&sel.desc))) {
\|\| (sel.desc.u.seg.c && !sel.desc.u.seg.wr)) {
EXCEPTION(exc, sel.idx);	EXCEPTION(exc, sel.idx);
}	}
/* data segment \|\| non-conforming code segment */	if (SEG_IS_DATA(&sel.desc)
if (!sel.desc.u.seg.c \|\| !sel.desc.u.seg.ec) {	\|\| !SEG_IS_CONFORMING_CODE(&sel.desc)) {
/* check privilege level */	/* check privilege level */
if ((sel.rpl > sel.desc.dpl) \|\| (CPU_STAT_CPL > sel.desc.dpl)) {	if ((sel.rpl > sel.desc.dpl)
	\|\| (CPU_STAT_CPL > sel.desc.dpl)) {
EXCEPTION(exc, sel.idx);	EXCEPTION(exc, sel.idx);
}	}
}	}
Line 117 load_segreg(int idx, UINT16 selector, in	Line 109 load_segreg(int idx, UINT16 selector, in
EXCEPTION(NP_EXCEPTION, sel.idx);	EXCEPTION(NP_EXCEPTION, sel.idx);
}	}

CPU_REGS_SREG(idx) = sel.selector;	*sregp = sel.selector;
CPU_STAT_SREG(idx) = sel.desc;	*sdp = sel.desc;
break;	break;

default:	default:
Line 131 load_segreg(int idx, UINT16 selector, in	Line 123 load_segreg(int idx, UINT16 selector, in
* load SS register	* load SS register
*/	*/
void	void
load_ss(UINT16 selector, const descriptor_t *sd, UINT cpl)	load_ss(UINT16 selector, const descriptor_t *sdp, int cpl)
{	{

CPU_STAT_SS32 = sd->d;	CPU_STAT_SS32 = sdp->d;
CPU_REGS_SREG(CPU_SS_INDEX) = (UINT16)((selector & ~3) \| (cpl & 3));	CPU_SS = (UINT16)((selector & ~3) \| (cpl & 3));
CPU_STAT_SREG(CPU_SS_INDEX) = *sd;	CPU_SS_DESC = *sdp;
}	}

/*	/*
* load CS register	* load CS register
*/	*/
void	void
load_cs(UINT16 selector, const descriptor_t *sd, UINT cpl)	load_cs(UINT16 selector, const descriptor_t *sdp, int new_cpl)
{	{
	int cpl = new_cpl & 3;

CPU_INST_OP32 = CPU_INST_AS32 =	CPU_INST_OP32 = CPU_INST_AS32 =
CPU_STATSAVE.cpu_inst_default.op_32 =	CPU_STATSAVE.cpu_inst_default.op_32 =
CPU_STATSAVE.cpu_inst_default.as_32 = sd->d;	CPU_STATSAVE.cpu_inst_default.as_32 = sdp->d;
CPU_REGS_SREG(CPU_CS_INDEX) = (UINT16)((selector & ~3) \| (cpl & 3));	CPU_CS = (UINT16)((selector & ~3) \| cpl);
CPU_STAT_SREG(CPU_CS_INDEX) = *sd;	CPU_CS_DESC = *sdp;
CPU_SET_CPL(cpl & 3);	set_cpl(cpl);
}	}

/*	/*
Line 163 load_ldtr(UINT16 selector, int exc)	Line 156 load_ldtr(UINT16 selector, int exc)
selector_t sel;	selector_t sel;
int rv;	int rv;

	memset(&sel, 0, sizeof(sel));

rv = parse_selector(&sel, selector);	rv = parse_selector(&sel, selector);
if (rv < 0 \|\| sel.ldt) {	if (rv < 0 \|\| sel.ldt) {
if (rv == -2) {	if (rv == -2) {
Line 175 load_ldtr(UINT16 selector, int exc)	Line 170 load_ldtr(UINT16 selector, int exc)
}	}

/* check descriptor type */	/* check descriptor type */
if (sel.desc.s \|\| (sel.desc.type != CPU_SYSDESC_TYPE_LDT)) {	if (!SEG_IS_SYSTEM(&sel.desc)
	\|\| (sel.desc.type != CPU_SYSDESC_TYPE_LDT)) {
EXCEPTION(exc, sel.selector);	EXCEPTION(exc, sel.selector);
}	}

/* check limit */
if (sel.desc.u.seg.limit < 7) {
ia32_panic("load_ldtr: LDTR descriptor limit < 7 (limit = %d)", sel.desc.u.seg.limit);
}

/* not present */	/* not present */
rv = selector_is_not_present(&sel);	rv = selector_is_not_present(&sel);
if (rv < 0) {	if (rv < 0) {
Line 199 load_ldtr(UINT16 selector, int exc)	Line 190 load_ldtr(UINT16 selector, int exc)
}	}

void	void
load_descriptor(descriptor_t *descp, UINT32 addr)	load_descriptor(descriptor_t *sdp, UINT32 addr)
{	{
UINT32 l, h;	UINT32 l, h;

memset(descp, 0, sizeof(*descp));	__ASSERT(sdp != NULL);

	VERBOSE(("load_descriptor: address = 0x%08x", addr));

l = cpu_kmemoryread_d(addr);	l = cpu_kmemoryread_d(addr);
h = cpu_kmemoryread_d(addr + 4);	h = cpu_kmemoryread_d(addr + 4);
VERBOSE(("load_descriptor: descriptor address = 0x%08x, h = 0x%08x, l = %08x", addr, h, l));	VERBOSE(("descriptor value = 0x%08x%08x", h, l));

descp->flag = 0;

descp->p = (h & CPU_DESC_H_P) == CPU_DESC_H_P;	segdesc_clear(sdp);
descp->type = (UINT8)((h & CPU_DESC_H_TYPE) >> 8);	sdp->flag = 0;
descp->dpl = (UINT8)((h & CPU_DESC_H_DPL) >> 13);
descp->s = (h & CPU_DESC_H_S) == CPU_DESC_H_S;

VERBOSE(("load_descriptor: present = %s, type = %d, DPL = %d", descp->p ? "true" : "false", descp->type, descp->dpl));	sdp->p = (h & CPU_DESC_H_P) ? 1 : 0;
	sdp->type = (UINT8)((h & CPU_DESC_H_TYPE) >> CPU_DESC_H_TYPE_SHIFT);
	sdp->dpl = (UINT8)((h & CPU_DESC_H_DPL) >> CPU_DESC_H_DPL_SHIFT);
	sdp->s = (h & CPU_DESC_H_S) ? 1 : 0;

if (descp->s) {	if (!SEG_IS_SYSTEM(sdp)) {
/* code/data */	/* code/data */
descp->valid = 1;	sdp->valid = 1;
descp->d = (h & CPU_SEGDESC_H_D) ? 1 : 0;	sdp->d = (h & CPU_SEGDESC_H_D) ? 1 : 0;

descp->u.seg.c = (h & CPU_SEGDESC_H_D_C) ? 1 : 0;	sdp->u.seg.c = (h & CPU_SEGDESC_H_D_C) ? 1 : 0;
descp->u.seg.g = (h & CPU_SEGDESC_H_G) ? 1 : 0;	sdp->u.seg.g = (h & CPU_SEGDESC_H_G) ? 1 : 0;
descp->u.seg.wr = (descp->type & CPU_SEGDESC_TYPE_WR) ? 1 : 0;	sdp->u.seg.wr = (sdp->type & CPU_SEGDESC_TYPE_WR) ? 1 : 0;
descp->u.seg.ec = (descp->type & CPU_SEGDESC_TYPE_EC) ? 1 : 0;	sdp->u.seg.ec = (sdp->type & CPU_SEGDESC_TYPE_EC) ? 1 : 0;

descp->u.seg.segbase = (l >> 16) & 0xffff;	sdp->u.seg.segbase = (l >> 16) & 0xffff;
descp->u.seg.segbase \|= (h & 0xff) << 16;	sdp->u.seg.segbase \|= (h & 0xff) << 16;
descp->u.seg.segbase \|= h & 0xff000000;	sdp->u.seg.segbase \|= h & 0xff000000;
descp->u.seg.limit = (h & 0xf0000) \| (l & 0xffff);	sdp->u.seg.limit = (h & 0xf0000) \| (l & 0xffff);
if (descp->u.seg.g) {	if (sdp->u.seg.g) {
descp->u.seg.limit <<= 12;	sdp->u.seg.limit <<= 12;
descp->u.seg.limit \|= 0xfff;	if (SEG_IS_CODE(sdp) \|\| !SEG_IS_EXPANDDOWN_DATA(sdp)) {
}	/* expand-up segment */
descp->u.seg.segend = descp->u.seg.segbase + descp->u.seg.limit;	sdp->u.seg.limit \|= 0xfff;
	}
VERBOSE(("load_descriptor: %s segment descriptor", descp->u.seg.c ? "code" : "data"));	}
VERBOSE(("load_descriptor: segment base address = 0x%08x, segment limit = 0x%08x", descp->u.seg.segbase, descp->u.seg.limit));
VERBOSE(("load_descriptor: d = %s, g = %s", descp->d ? "on" : "off", descp->u.seg.g ? "on" : "off"));
VERBOSE(("load_descriptor: %s, %s", descp->u.seg.c ? (descp->u.seg.wr ? "executable/readable" : "execute-only") : (descp->u.seg.wr ? "writable" : "read-only"), (descp->u.seg.c ? (descp->u.seg.ec ? "conforming" : "non-conforming") : (descp->u.seg.ec ? "expand-down" : "expand-up"))));
} else {	} else {
/* system */	/* system */
switch (descp->type) {	switch (sdp->type) {
case CPU_SYSDESC_TYPE_LDT: /* LDT */	case CPU_SYSDESC_TYPE_LDT: /* LDT */
descp->valid = 1;	sdp->valid = 1;
descp->u.seg.g = (h & CPU_SEGDESC_H_G) ? 1 : 0;	sdp->u.seg.g = (h & CPU_SEGDESC_H_G) ? 1 : 0;

descp->u.seg.segbase = h & 0xff000000;	sdp->u.seg.segbase = h & 0xff000000;
descp->u.seg.segbase \|= (h & 0xff) << 16;	sdp->u.seg.segbase \|= (h & 0xff) << 16;
descp->u.seg.segbase \|= l >> 16;	sdp->u.seg.segbase \|= l >> 16;
descp->u.seg.limit = h & 0xf0000;	sdp->u.seg.limit = h & 0xf0000;
descp->u.seg.limit \|= l & 0xffff;	sdp->u.seg.limit \|= l & 0xffff;
if (descp->u.seg.g) {	if (sdp->u.seg.g) {
descp->u.seg.limit <<= 12;	sdp->u.seg.limit <<= 12;
descp->u.seg.limit \|= 0xfff;	sdp->u.seg.limit \|= 0xfff;
}	}
descp->u.seg.segend = descp->u.seg.segbase + descp->u.seg.limit;

VERBOSE(("load_descriptor: LDT descriptor"));
VERBOSE(("load_descriptor: LDT base address = 0x%08x, limit size = 0x%08x", descp->u.seg.segbase, descp->u.seg.limit));
break;	break;

case CPU_SYSDESC_TYPE_TASK: /* task gate */	case CPU_SYSDESC_TYPE_TASK: /* task gate */
descp->valid = 1;	sdp->valid = 1;
descp->u.gate.selector = (UINT16)(l >> 16);	sdp->u.gate.selector = (UINT16)(l >> 16);

VERBOSE(("load_descriptor: task descriptor: selector = 0x%04x", descp->u.gate.selector));
break;	break;

case CPU_SYSDESC_TYPE_TSS_16: /* 286 TSS */	case CPU_SYSDESC_TYPE_TSS_16: /* 286 TSS */
case CPU_SYSDESC_TYPE_TSS_BUSY_16: /* 286 TSS Busy */	case CPU_SYSDESC_TYPE_TSS_BUSY_16: /* 286 TSS Busy */
case CPU_SYSDESC_TYPE_TSS_32: /* 386 TSS */	case CPU_SYSDESC_TYPE_TSS_32: /* 386 TSS */
case CPU_SYSDESC_TYPE_TSS_BUSY_32: /* 386 TSS Busy */	case CPU_SYSDESC_TYPE_TSS_BUSY_32: /* 386 TSS Busy */
descp->valid = 1;	sdp->valid = 1;
descp->d = (h & CPU_GATEDESC_H_D) ? 1 : 0;	sdp->d = (h & CPU_GATEDESC_H_D) ? 1 : 0;
descp->u.seg.g = (h & CPU_SEGDESC_H_G) ? 1 : 0;	sdp->u.seg.g = (h & CPU_SEGDESC_H_G) ? 1 : 0;

descp->u.seg.segbase = h & 0xff000000;	sdp->u.seg.segbase = h & 0xff000000;
descp->u.seg.segbase \|= (h & 0xff) << 16;	sdp->u.seg.segbase \|= (h & 0xff) << 16;
descp->u.seg.segbase \|= l >> 16;	sdp->u.seg.segbase \|= l >> 16;
descp->u.seg.limit = h & 0xf0000;	sdp->u.seg.limit = h & 0xf0000;
descp->u.seg.limit \|= l & 0xffff;	sdp->u.seg.limit \|= l & 0xffff;
if (descp->u.seg.g) {	if (sdp->u.seg.g) {
descp->u.seg.limit <<= 12;	sdp->u.seg.limit <<= 12;
descp->u.seg.limit \|= 0xfff;	sdp->u.seg.limit \|= 0xfff;
}	}
descp->u.seg.segend = descp->u.seg.segbase + descp->u.seg.limit;

VERBOSE(("load_descriptor: %dbit %sTSS descriptor", descp->d ? 32 : 16, (descp->type & CPU_SYSDESC_TYPE_TSS_BUSY_IND) ? "busy " : ""));
VERBOSE(("load_descriptor: TSS base address = 0x%08x, limit = 0x%08x", descp->u.seg.segbase, descp->u.seg.limit));
VERBOSE(("load_descriptor: d = %s, g = %s", descp->d ? "on" : "off", descp->u.seg.g ? "on" : "off"));
break;	break;

case CPU_SYSDESC_TYPE_CALL_16: /* 286 call gate */	case CPU_SYSDESC_TYPE_CALL_16: /* 286 call gate */
Line 302 load_descriptor(descriptor_t *descp, UIN	Line 280 load_descriptor(descriptor_t *descp, UIN
case CPU_SYSDESC_TYPE_INTR_32: /* 386 interrupt gate */	case CPU_SYSDESC_TYPE_INTR_32: /* 386 interrupt gate */
case CPU_SYSDESC_TYPE_TRAP_32: /* 386 trap gate */	case CPU_SYSDESC_TYPE_TRAP_32: /* 386 trap gate */
if ((h & 0x0000000e0) == 0) {	if ((h & 0x0000000e0) == 0) {
descp->valid = 1;	sdp->valid = 1;
descp->d = (h & CPU_GATEDESC_H_D) ? 1:0;	sdp->d = (h & CPU_GATEDESC_H_D) ? 1 : 0;
descp->u.gate.selector = (UINT16)(l >> 16);	sdp->u.gate.selector = (UINT16)(l >> 16);
descp->u.gate.offset = h & 0xffff0000;	sdp->u.gate.offset = h & 0xffff0000;
descp->u.gate.offset \|= l & 0xffff;	sdp->u.gate.offset \|= l & 0xffff;
descp->u.gate.count = (BYTE)(h & 0x1f);	sdp->u.gate.count = (UINT8)(h & 0x1f);

VERBOSE(("load_descriptor: %dbit %s gate descriptor", descp->d ? 32 : 16, ((descp->type & CPU_SYSDESC_TYPE_MASKBIT) == CPU_SYSDESC_TYPE_CALL) ? "call" : (((descp->type & CPU_SYSDESC_TYPE_MASKBIT) == CPU_SYSDESC_TYPE_INTR) ? "interrupt" : "trap")));
VERBOSE(("load_descriptor: selector = 0x%04x, offset = 0x%08x, count = %d, d = %s", descp->u.gate.selector, descp->u.gate.offset, descp->u.gate.count, descp->d ? "on" : "off"));
} else {	} else {
ia32_panic("load_descriptor: 386 gate is invalid");	sdp->valid = 0;
	VERBOSE(("load_descriptor: gate is invalid"));
}	}
break;	break;

case 0: case 8: case 10: case 13: /* reserved */	case 0: case 8: case 10: case 13: /* reserved */
default:	default:
descp->valid = 0;	sdp->valid = 0;
break;	break;
}	}
}	}
	#if defined(DEBUG)
	segdesc_dump(sdp);
	#endif
}	}

int	int
Line 342 parse_selector(selector_t *ssp, UINT16 s	Line 321 parse_selector(selector_t *ssp, UINT16 s
idx = selector & CPU_SEGMENT_SELECTOR_INDEX_MASK;	idx = selector & CPU_SEGMENT_SELECTOR_INDEX_MASK;
if (ssp->ldt) {	if (ssp->ldt) {
/* LDT */	/* LDT */
if (!CPU_LDTR_DESC.valid) {	if (!SEG_IS_VALID(&CPU_LDTR_DESC)) {
VERBOSE(("parse_selector: LDT is invalid"));	VERBOSE(("parse_selector: LDT is invalid"));
return -1;	return -1;
}	}
Line 358 parse_selector(selector_t *ssp, UINT16 s	Line 337 parse_selector(selector_t *ssp, UINT16 s
limit = CPU_GDTR_LIMIT;	limit = CPU_GDTR_LIMIT;
}	}
if (idx + 7 > limit) {	if (idx + 7 > limit) {
VERBOSE(("parse_selector: segment limit check failed"));	VERBOSE(("parse_selector: segment limit check failed: 0x%08x > 0x%08x", idx + 7, limit));
return -3;	return -3;
}	}

/* load descriptor */	/* load descriptor */
ssp->addr = base + idx;	ssp->addr = base + idx;
load_descriptor(&ssp->desc, ssp->addr);	load_descriptor(&ssp->desc, ssp->addr);
if (!ssp->desc.valid) {	if (!SEG_IS_VALID(&ssp->desc)) {
VERBOSE(("parse_selector: segment descriptor is invalid"));	VERBOSE(("parse_selector: segment descriptor is invalid"));
return -4;	return -4;
}	}
Line 379 selector_is_not_present(const selector_t	Line 358 selector_is_not_present(const selector_t
UINT32 h;	UINT32 h;

/* not present */	/* not present */
if (!ssp->desc.p) {	if (!SEG_IS_PRESENT(&ssp->desc)) {
VERBOSE(("selector_is_not_present: not present"));	VERBOSE(("selector_is_not_present: not present"));
return -1;	return -1;
}	}

/* set access bit if code/data segment descriptor */	/* set access bit if code/data segment descriptor */
if (ssp->desc.s) {	if (!SEG_IS_SYSTEM(&ssp->desc)) {
h = cpu_kmemoryread_d(ssp->addr + 4);	h = cpu_kmemoryread_d(ssp->addr + 4);
if (!(h & CPU_SEGDESC_H_A)) {	if (!(h & CPU_SEGDESC_H_A)) {
h \|= CPU_SEGDESC_H_A;	h \|= CPU_SEGDESC_H_A;
Line 395 selector_is_not_present(const selector_t	Line 374 selector_is_not_present(const selector_t

return 0;	return 0;
}	}

	void
	segdesc_init(int idx, UINT16 sreg, descriptor_t *sdp)
	{

	__ASSERT(((unsigned int)idx < CPU_SEGREG_NUM));
	__ASSERT((sdp != NULL));

	CPU_REGS_SREG(idx) = sreg;
	segdesc_clear(sdp);
	sdp->u.seg.limit = 0xffff;
	segdesc_set_default(idx, sreg, sdp);
	}

	void
	segdesc_set_default(int idx, UINT16 selector, descriptor_t *sdp)
	{

	__ASSERT(((unsigned int)idx < CPU_SEGREG_NUM));
	__ASSERT((sdp != NULL));

	sdp->u.seg.segbase = (UINT32)selector << 4;
	/* sdp->u.seg.limit */
	sdp->u.seg.c = (idx == CPU_CS_INDEX) ? 1 : 0; /* code or data */
	sdp->u.seg.g = 0; /* non 4k factor scale */
	sdp->u.seg.wr = 1; /* execute/read(CS) or read/write(others) */
	sdp->u.seg.ec = 0; /* nonconforming(CS) or expand-up(others) */
	sdp->valid = 1; /* valid */
	sdp->p = 1; /* present */
	sdp->type = (CPU_SEGDESC_TYPE_WR << CPU_DESC_H_TYPE_SHIFT)
	\| ((idx == CPU_CS_INDEX) ? CPU_SEGDESC_H_D_C : 0);
	/* readable code/writable data segment */
	sdp->dpl = CPU_STAT_VM86 ? 3 : 0; /* descriptor privilege level */
	sdp->rpl = CPU_STAT_VM86 ? 3 : 0; /* request privilege level */
	sdp->s = 1; /* code/data */
	sdp->d = 0; /* 16bit */
	sdp->flag = CPU_DESC_FLAG_READABLE\|CPU_DESC_FLAG_WRITABLE;
	}

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

Removed from v.1.16
changed lines
	Added in v.1.21