np2/i386c/ia32/task.c - diff

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Diff for /np2/i386c/ia32/task.c between versions 1.14 and 1.22

version 1.14, 2004/03/02 16:29:16	version 1.22, 2008/01/25 18:12:13
Line 12	Line 12
* 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 37 load_tr(UINT16 selector)	Line 35 load_tr(UINT16 selector)
{	{
selector_t task_sel;	selector_t task_sel;
int rv;	int rv;
	#if defined(IA32_SUPPORT_DEBUG_REGISTER)
	int i;
	#endif
UINT16 iobase;	UINT16 iobase;

rv = parse_selector(&task_sel, selector);	rv = parse_selector(&task_sel, selector);
Line 62 load_tr(UINT16 selector)	Line 63 load_tr(UINT16 selector)

default:	default:
EXCEPTION(GP_EXCEPTION, task_sel.idx);	EXCEPTION(GP_EXCEPTION, task_sel.idx);
break;	return;
}	}

/* not present */	/* not present */
Line 90 load_tr(UINT16 selector)	Line 91 load_tr(UINT16 selector)
} else {	} else {
CPU_STAT_IOLIMIT = 0;	CPU_STAT_IOLIMIT = 0;
}	}

	#if defined(IA32_SUPPORT_DEBUG_REGISTER)
	/* clear local break point flags */
	CPU_DR7 &= ~(CPU_DR7_L(0)\|CPU_DR7_L(1)\|CPU_DR7_L(2)\|CPU_DR7_L(3)\|CPU_DR7_LE);
	CPU_STAT_BP = 0;
	for (i = 0; i < CPU_DEBUG_REG_INDEX_NUM; i++) {
	if (CPU_DR7 & CPU_DR7_G(i)) {
	CPU_STAT_BP \|= (1 << i);
	}
	}
	#endif
}	}

void	void
Line 150 task_switch(selector_t *task_sel, task_s	Line 162 task_switch(selector_t *task_sel, task_s
UINT32 regs[CPU_REG_NUM];	UINT32 regs[CPU_REG_NUM];
UINT32 eip;	UINT32 eip;
UINT32 new_flags;	UINT32 new_flags;
UINT32 mask;
UINT32 cr3 = 0;	UINT32 cr3 = 0;
UINT16 sreg[CPU_SEGREG_NUM];	UINT16 sreg[CPU_SEGREG_NUM];
UINT16 ldtr;	UINT16 ldtr;
UINT16 t, iobase;	UINT16 iobase;
	UINT16 t;

selector_t cs_sel;	selector_t cs_sel;
int rv;	int rv;
Line 163 task_switch(selector_t *task_sel, task_s	Line 175 task_switch(selector_t *task_sel, task_s
UINT32 task_base; /* new task state */	UINT32 task_base; /* new task state */
UINT32 old_flags = REAL_EFLAGREG;	UINT32 old_flags = REAL_EFLAGREG;
BOOL task16;	BOOL task16;
UINT nsreg;
UINT i;	UINT i;

VERBOSE(("task_switch: start"));	VERBOSE(("task_switch: start"));
Line 176 task_switch(selector_t *task_sel, task_s	Line 187 task_switch(selector_t *task_sel, task_s
EXCEPTION(TS_EXCEPTION, task_sel->idx);	EXCEPTION(TS_EXCEPTION, task_sel->idx);
}	}
task16 = FALSE;	task16 = FALSE;
nsreg = CPU_SEGREG_NUM;
break;	break;

case CPU_SYSDESC_TYPE_TSS_16:	case CPU_SYSDESC_TYPE_TSS_16:
Line 185 task_switch(selector_t *task_sel, task_s	Line 195 task_switch(selector_t *task_sel, task_s
EXCEPTION(TS_EXCEPTION, task_sel->idx);	EXCEPTION(TS_EXCEPTION, task_sel->idx);
}	}
task16 = TRUE;	task16 = TRUE;
nsreg = CPU_SEGREG286_NUM;
break;	break;

default:	default:
ia32_panic("task_switch: descriptor type is invalid.");	ia32_panic("task_switch: descriptor type is invalid.");
task16 = FALSE; /* compiler happy */	task16 = FALSE; /* compiler happy */
nsreg = CPU_SEGREG_NUM; /* compiler happy */
break;	break;
}	}

Line 215 task_switch(selector_t *task_sel, task_s	Line 223 task_switch(selector_t *task_sel, task_s

if (CPU_STAT_PAGING) {	if (CPU_STAT_PAGING) {
/* task state paging check */	/* task state paging check */
paging_check(cur_base, CPU_TR_DESC.u.seg.limit, CPU_PAGE_WRITE_DATA, CPU_MODE_SUPERVISER);	paging_check(cur_base, CPU_TR_DESC.u.seg.limit, CPU_PAGE_WRITE_DATA\|CPU_MODE_SUPERVISER);
paging_check(task_base, task_sel->desc.u.seg.limit, CPU_PAGE_WRITE_DATA, CPU_MODE_SUPERVISER);	paging_check(task_base, task_sel->desc.u.seg.limit, CPU_PAGE_WRITE_DATA\|CPU_MODE_SUPERVISER);
}	}

/* load task state */	/* load task state */
Line 230 task_switch(selector_t *task_sel, task_s	Line 238 task_switch(selector_t *task_sel, task_s
for (i = 0; i < CPU_REG_NUM; i++) {	for (i = 0; i < CPU_REG_NUM; i++) {
regs[i] = cpu_kmemoryread_d(task_base + 40 + i * 4);	regs[i] = cpu_kmemoryread_d(task_base + 40 + i * 4);
}	}
for (i = 0; i < nsreg; i++) {	for (i = 0; i < CPU_SEGREG_NUM; i++) {
sreg[i] = cpu_kmemoryread_w(task_base + 72 + i * 4);	sreg[i] = cpu_kmemoryread_w(task_base + 72 + i * 4);
}	}
ldtr = cpu_kmemoryread_w(task_base + 96);	ldtr = cpu_kmemoryread_w(task_base + 96);
t = cpu_kmemoryread_w(task_base + 100);	t = cpu_kmemoryread_w(task_base + 100);
t &= 1;	if (t & 1) {
	CPU_STAT_BP_EVENT \|= CPU_STAT_BP_EVENT_TASK;
	}
iobase = cpu_kmemoryread_w(task_base + 102);	iobase = cpu_kmemoryread_w(task_base + 102);
} else {	} else {
eip = cpu_kmemoryread_w(task_base + 14);	eip = cpu_kmemoryread_w(task_base + 14);
Line 243 task_switch(selector_t *task_sel, task_s	Line 253 task_switch(selector_t *task_sel, task_s
for (i = 0; i < CPU_REG_NUM; i++) {	for (i = 0; i < CPU_REG_NUM; i++) {
regs[i] = cpu_kmemoryread_w(task_base + 18 + i * 2);	regs[i] = cpu_kmemoryread_w(task_base + 18 + i * 2);
}	}
for (i = 0; i < nsreg; i++) {	for (i = 0; i < CPU_SEGREG286_NUM; i++) {
sreg[i] = cpu_kmemoryread_w(task_base + 34 + i * 2);	sreg[i] = cpu_kmemoryread_w(task_base + 34 + i * 2);
}	}
ldtr = cpu_kmemoryread_w(task_base + 42);	ldtr = cpu_kmemoryread_w(task_base + 42);
t = 0;
iobase = 0;	iobase = 0;
	t = 0;
}	}

#if defined(DEBUG)	#if defined(DEBUG)
VERBOSE(("task_switch: current task"));	VERBOSE(("task_switch: current task"));
	if (!task16) {
	VERBOSE(("task_switch: CR3 = 0x%08x", CPU_CR3));
	}
VERBOSE(("task_switch: eip = 0x%08x", CPU_EIP));	VERBOSE(("task_switch: eip = 0x%08x", CPU_EIP));
VERBOSE(("task_switch: eflags = 0x%08x", old_flags));	VERBOSE(("task_switch: eflags = 0x%08x", old_flags));
for (i = 0; i < CPU_REG_NUM; i++) {	for (i = 0; i < CPU_REG_NUM; i++) {
VERBOSE(("task_switch: regs[%d] = 0x%08x", i, CPU_REGS_DWORD(i)));	VERBOSE(("task_switch: regs[%d] = 0x%08x", i, CPU_REGS_DWORD(i)));
}	}
for (i = 0; i < nsreg; i++) {	for (i = 0; i < CPU_SEGREG_NUM; i++) {
VERBOSE(("task_switch: sreg[%d] = 0x%04x", i, CPU_REGS_SREG(i)));	VERBOSE(("task_switch: sreg[%d] = 0x%04x", i, CPU_REGS_SREG(i)));
}	}
	VERBOSE(("task_switch: ldtr = 0x%04x", CPU_LDTR));

VERBOSE(("task_switch: new task"));	VERBOSE(("task_switch: new task"));
if (!task16) {	if (!task16) {
Line 271 task_switch(selector_t *task_sel, task_s	Line 285 task_switch(selector_t *task_sel, task_s
for (i = 0; i < CPU_REG_NUM; i++) {	for (i = 0; i < CPU_REG_NUM; i++) {
VERBOSE(("task_switch: regs[%d] = 0x%08x", i, regs[i]));	VERBOSE(("task_switch: regs[%d] = 0x%08x", i, regs[i]));
}	}
for (i = 0; i < nsreg; i++) {	for (i = 0; i < CPU_SEGREG_NUM; i++) {
VERBOSE(("task_switch: sreg[%d] = 0x%04x", i, sreg[i]));	VERBOSE(("task_switch: sreg[%d] = 0x%04x", i, sreg[i]));
}	}
VERBOSE(("task_switch: ldtr = 0x%04x", ldtr));	VERBOSE(("task_switch: ldtr = 0x%04x", ldtr));
Line 310 task_switch(selector_t *task_sel, task_s	Line 324 task_switch(selector_t *task_sel, task_s
for (i = 0; i < CPU_REG_NUM; i++) {	for (i = 0; i < CPU_REG_NUM; i++) {
cpu_kmemorywrite_d(cur_base + 40 + i * 4, CPU_REGS_DWORD(i));	cpu_kmemorywrite_d(cur_base + 40 + i * 4, CPU_REGS_DWORD(i));
}	}
for (i = 0; i < nsreg; i++) {	for (i = 0; i < CPU_SEGREG_NUM; i++) {
cpu_kmemorywrite_w(cur_base + 72 + i * 4, CPU_REGS_SREG(i));	cpu_kmemorywrite_w(cur_base + 72 + i * 4, CPU_REGS_SREG(i));
}	}
} else {	} else {
Line 319 task_switch(selector_t *task_sel, task_s	Line 333 task_switch(selector_t *task_sel, task_s
for (i = 0; i < CPU_REG_NUM; i++) {	for (i = 0; i < CPU_REG_NUM; i++) {
cpu_kmemorywrite_w(cur_base + 18 + i * 2, CPU_REGS_WORD(i));	cpu_kmemorywrite_w(cur_base + 18 + i * 2, CPU_REGS_WORD(i));
}	}
for (i = 0; i < nsreg; i++) {	for (i = 0; i < CPU_SEGREG286_NUM; i++) {
cpu_kmemorywrite_w(cur_base + 34 + i * 2, CPU_REGS_SREG(i));	cpu_kmemorywrite_w(cur_base + 34 + i * 2, CPU_REGS_SREG(i));
}	}
}	}
Line 335 task_switch(selector_t *task_sel, task_s	Line 349 task_switch(selector_t *task_sel, task_s
}	}
}	}
#endif	#endif

/* set back link selector */	/* set back link selector */
switch (type) {	switch (type) {
case TASK_SWITCH_CALL:	case TASK_SWITCH_CALL:
Line 408 task_switch(selector_t *task_sel, task_s	Line 423 task_switch(selector_t *task_sel, task_s
}	}

/* set new EFLAGS */	/* set new EFLAGS */
mask = I_FLAG\|IOPL_FLAG\|RF_FLAG\|VM_FLAG\|VIF_FLAG\|VIP_FLAG;	set_eflags(new_flags, I_FLAG\|IOPL_FLAG\|RF_FLAG\|VM_FLAG\|VIF_FLAG\|VIP_FLAG);
set_eflags(new_flags, mask);
	/* I/O deny bitmap */
	if (!task16) {
	if (iobase != 0 && iobase < task_sel->desc.u.seg.limit) {
	CPU_STAT_IOLIMIT = (UINT16)(task_sel->desc.u.seg.limit - iobase);
	CPU_STAT_IOADDR = task_sel->desc.u.seg.segbase + iobase;
	} else {
	CPU_STAT_IOLIMIT = 0;
	}
	} else {
	CPU_STAT_IOLIMIT = 0;
	}
	VERBOSE(("task_switch: ioaddr = %08x, limit = %08x", CPU_STAT_IOADDR, CPU_STAT_IOLIMIT));

	#if defined(IA32_SUPPORT_DEBUG_REGISTER)
	/* check resume flag */
	if (CPU_EFLAG & RF_FLAG) {
	CPU_STAT_BP_EVENT \|= CPU_STAT_BP_EVENT_RF;
	}

	/* clear local break point flags */
	CPU_DR7 &= ~(CPU_DR7_L(0)\|CPU_DR7_L(1)\|CPU_DR7_L(2)\|CPU_DR7_L(3)\|CPU_DR7_LE);
	CPU_STAT_BP = 0;
	for (i = 0; i < CPU_DEBUG_REG_INDEX_NUM; i++) {
	if (CPU_DR7 & CPU_DR7_G(i)) {
	CPU_STAT_BP \|= (1 << i);
	}
	}
	#endif

/* load new LDTR */	/* load new LDTR */
load_ldtr(ldtr, TS_EXCEPTION);	load_ldtr(ldtr, TS_EXCEPTION);
Line 463 task_switch(selector_t *task_sel, task_s	Line 506 task_switch(selector_t *task_sel, task_s
}	}
}	}

/* I/O deny bitmap */
if (!task16) {
if (iobase != 0 && iobase < task_sel->desc.u.seg.limit) {
CPU_STAT_IOLIMIT = (UINT16)(task_sel->desc.u.seg.limit - iobase);
CPU_STAT_IOADDR = task_sel->desc.u.seg.segbase + iobase;
} else {
CPU_STAT_IOLIMIT = 0;
}
} else {
CPU_STAT_IOLIMIT = 0;
}
VERBOSE(("task_switch: ioaddr = %08x, limit = %08x", CPU_STAT_IOADDR, CPU_STAT_IOLIMIT));

/* out of range */	/* out of range */
if (CPU_EIP > CPU_STAT_CS_LIMIT) {	if (CPU_EIP > CPU_STAT_CS_LIMIT) {
VERBOSE(("task_switch: new_ip is out of range. new_ip = %08x, limit = %08x", CPU_EIP, CPU_STAT_CS_LIMIT));	VERBOSE(("task_switch: new_ip is out of range. new_ip = %08x, limit = %08x", CPU_EIP, CPU_STAT_CS_LIMIT));

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

Removed from v.1.14
changed lines
	Added in v.1.22