np2/i386c/ia32/task.c - diff

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Diff for /np2/i386c/ia32/task.c between versions 1.26 and 1.38

version 1.26, 2011/12/17 02:08:04	version 1.38, 2012/02/07 09:11:11
Line 32	Line 32
#define TSS_32_SIZE 104	#define TSS_32_SIZE 104
#define TSS_32_LIMIT (TSS_32_SIZE - 1)	#define TSS_32_LIMIT (TSS_32_SIZE - 1)

static void	static void CPUCALL
set_task_busy(UINT16 selector)	set_task_busy(UINT16 selector)
{	{
UINT32 addr;	UINT32 addr;
Line 44 set_task_busy(UINT16 selector)	Line 44 set_task_busy(UINT16 selector)
h \|= CPU_TSS_H_BUSY;	h \|= CPU_TSS_H_BUSY;
cpu_kmemorywrite_d(addr + 4, h);	cpu_kmemorywrite_d(addr + 4, h);
} else {	} else {
ia32_panic("set_task_busy: already busy(%04x:%08x)",selector,h);	ia32_panic("set_task_busy: already busy(%04x:%08x)",
	selector, h);
}	}
}	}

static void	static void CPUCALL
set_task_free(UINT16 selector)	set_task_free(UINT16 selector)
{	{
UINT32 addr;	UINT32 addr;
Line 60 set_task_free(UINT16 selector)	Line 61 set_task_free(UINT16 selector)
h &= ~CPU_TSS_H_BUSY;	h &= ~CPU_TSS_H_BUSY;
cpu_kmemorywrite_d(addr + 4, h);	cpu_kmemorywrite_d(addr + 4, h);
} else {	} else {
ia32_panic("set_task_free: already free(%04x:%08x)",selector,h);	ia32_panic("set_task_free: already free(%04x:%08x)",
	selector, h);
}	}
}	}

void	void CPUCALL
load_tr(UINT16 selector)	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 118 load_tr(UINT16 selector)	Line 117 load_tr(UINT16 selector)
/* I/O deny bitmap */	/* I/O deny bitmap */
CPU_STAT_IOLIMIT = 0;	CPU_STAT_IOLIMIT = 0;
if (CPU_TR_DESC.type == CPU_SYSDESC_TYPE_TSS_BUSY_32) {	if (CPU_TR_DESC.type == CPU_SYSDESC_TYPE_TSS_BUSY_32) {
if (iobase != 0 && iobase < CPU_TR_DESC.u.seg.limit) {	if (iobase < CPU_TR_LIMIT) {
CPU_STAT_IOLIMIT = (UINT16)(CPU_TR_DESC.u.seg.limit - iobase);	CPU_STAT_IOLIMIT = (UINT16)(CPU_TR_LIMIT - iobase);
CPU_STAT_IOADDR = CPU_TR_DESC.u.seg.segbase + iobase;	CPU_STAT_IOADDR = CPU_TR_BASE + iobase;
	VERBOSE(("load_tr: enable ioport control: iobase=0x%04x, base=0x%08x, limit=0x%08x", iobase, CPU_STAT_IOADDR, CPU_STAT_IOLIMIT));
}	}
}	}
	if (CPU_STAT_IOLIMIT == 0) {
#if defined(IA32_SUPPORT_DEBUG_REGISTER)	VERBOSE(("load_tr: disable ioport control."));
/* 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 CPUCALL
get_stack_pointer_from_tss(UINT pl, UINT16 new_ss, UINT32 new_esp)	get_stack_pointer_from_tss(UINT pl, UINT16 new_ss, UINT32 new_esp)
{	{
UINT32 tss_stack_addr;	UINT32 tss_stack_addr;

VERBOSE(("get_stack_pointer_from_tss: pl = %d", pl));	VERBOSE(("get_stack_pointer_from_tss: pl = %d", pl));
VERBOSE(("CPU_TR type = %d, base = 0x%08x, limit = 0x%08x", CPU_TR_DESC.type, CPU_TR_BASE, CPU_TR_LIMIT));	VERBOSE(("get_stack_pointer_from_tss: CPU_TR type = %d, base = 0x%08x, limit = 0x%08x", CPU_TR_DESC.type, CPU_TR_BASE, CPU_TR_LIMIT));

__ASSERT(pl < 3);	__ASSERT(pl < 3);

Line 165 get_stack_pointer_from_tss(UINT pl, UINT	Line 157 get_stack_pointer_from_tss(UINT pl, UINT
} else {	} else {
ia32_panic("get_stack_pointer_from_tss: task register is invalid (%d)\n", CPU_TR_DESC.type);	ia32_panic("get_stack_pointer_from_tss: task register is invalid (%d)\n", CPU_TR_DESC.type);
}	}
VERBOSE(("new stack pointer = %04x:%08x", new_ss, new_esp));	VERBOSE(("get_stack_pointer_from_tss: new stack pointer = %04x:%08x",
	new_ss, new_esp));
}	}

UINT16	UINT16
Line 186 get_backlink_selector_from_tss(void)	Line 179 get_backlink_selector_from_tss(void)
}	}

backlink = cpu_kmemoryread_w(CPU_TR_BASE);	backlink = cpu_kmemoryread_w(CPU_TR_BASE);
VERBOSE(("get_backlink_selector_from_tss: backlink selector = 0x%04x", backlink));	VERBOSE(("get_backlink_selector_from_tss: backlink selector = 0x%04x",
	backlink));
return backlink;	return backlink;
}	}

void	void CPUCALL
task_switch(selector_t *task_sel, task_switch_type_t type)	task_switch(selector_t *task_sel, task_switch_type_t type)
{	{
UINT32 regs[CPU_REG_NUM];	UINT32 regs[CPU_REG_NUM];
Line 240 task_switch(selector_t *task_sel, task_s	Line 234 task_switch(selector_t *task_sel, task_s
cur_paddr = laddr_to_paddr(cur_base, CPU_PAGE_WRITE_DATA\|CPU_MODE_SUPERVISER);	cur_paddr = laddr_to_paddr(cur_base, CPU_PAGE_WRITE_DATA\|CPU_MODE_SUPERVISER);
task_base = task_sel->desc.u.seg.segbase;	task_base = task_sel->desc.u.seg.segbase;
task_paddr = laddr_to_paddr(task_base, CPU_PAGE_WRITE_DATA\|CPU_MODE_SUPERVISER);	task_paddr = laddr_to_paddr(task_base, CPU_PAGE_WRITE_DATA\|CPU_MODE_SUPERVISER);
VERBOSE(("task_switch: current task (%04x) = 0x%08x:%08x", CPU_TR, cur_base, CPU_TR_LIMIT));	VERBOSE(("task_switch: current task (%04x) = 0x%08x:%08x (p0x%08x)",
VERBOSE(("task_switch: new task (%04x) = 0x%08x:%08x", task_sel->selector, task_base, task_sel->desc.u.seg.limit));	CPU_TR, cur_base, CPU_TR_LIMIT, cur_paddr));
	VERBOSE(("task_switch: new task (%04x) = 0x%08x:%08x (p0x%08x)",
	task_sel->selector, task_base, task_sel->desc.u.seg.limit,
	task_paddr));
VERBOSE(("task_switch: %dbit task switch", task16 ? 16 : 32));	VERBOSE(("task_switch: %dbit task switch", task16 ? 16 : 32));

#if defined(MORE_DEBUG)	#if defined(MORE_DEBUG)
{	VERBOSE(("task_switch: new task"));
UINT32 v;	for (i = 0; i < task_sel->desc.u.seg.limit; i += 4) {
	VERBOSE(("task_switch: 0x%08x: %08x", task_base + i,
VERBOSE(("task_switch: new task"));	cpu_memoryread_d(task_paddr + i)));
for (i = 0; i < task_sel->desc.u.seg.limit; i += 4) {
v = cpu_memoryread_d(task_paddr + i);
VERBOSE(("task_switch: 0x%08x: %08x", task_base + i,v));
}
}	}
#endif	#endif

/* load task state */	/* load task state */
memset(sreg, 0, sizeof(sreg));
if (!task16) {	if (!task16) {
if (CPU_STAT_PAGING) {	if (CPU_STAT_PAGING) {
cr3 = cpu_memoryread_d(task_paddr + 28);	cr3 = cpu_memoryread_d(task_paddr + 28);
Line 285 task_switch(selector_t *task_sel, task_s	Line 277 task_switch(selector_t *task_sel, task_s
for (i = 0; i < CPU_SEGREG286_NUM; i++) {	for (i = 0; i < CPU_SEGREG286_NUM; i++) {
sreg[i] = cpu_memoryread_w(task_paddr + 34 + i * 2);	sreg[i] = cpu_memoryread_w(task_paddr + 34 + i * 2);
}	}
	for (; i < CPU_SEGREG_NUM; i++) {
	sreg[i] = 0;
	}
ldtr = cpu_memoryread_w(task_paddr + 42);	ldtr = cpu_memoryread_w(task_paddr + 42);
iobase = 0;	iobase = 0;
t = 0;	t = 0;
Line 298 task_switch(selector_t *task_sel, task_s	Line 293 task_switch(selector_t *task_sel, task_s
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: %s = 0x%08x", reg32_str[i],
	CPU_REGS_DWORD(i)));
}	}
for (i = 0; i < CPU_SEGREG_NUM; i++) {	for (i = 0; i < CPU_SEGREG_NUM; i++) {
VERBOSE(("task_switch: sreg[%d] = 0x%04x", i, CPU_REGS_SREG(i)));	VERBOSE(("task_switch: %s = 0x%04x", sreg_str[i],
	CPU_REGS_SREG(i)));
}	}
VERBOSE(("task_switch: ldtr = 0x%04x", CPU_LDTR));	VERBOSE(("task_switch: ldtr = 0x%04x", CPU_LDTR));

Line 312 task_switch(selector_t *task_sel, task_s	Line 309 task_switch(selector_t *task_sel, task_s
VERBOSE(("task_switch: eip = 0x%08x", eip));	VERBOSE(("task_switch: eip = 0x%08x", eip));
VERBOSE(("task_switch: eflags = 0x%08x", new_flags));	VERBOSE(("task_switch: eflags = 0x%08x", new_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, regs[i]));	VERBOSE(("task_switch: %s = 0x%08x", reg32_str[i], regs[i]));
}	}
for (i = 0; i < CPU_SEGREG_NUM; i++) {	for (i = 0; i < CPU_SEGREG_NUM; i++) {
VERBOSE(("task_switch: sreg[%d] = 0x%04x", i, sreg[i]));	VERBOSE(("task_switch: %s = 0x%04x", sreg_str[i], sreg[i]));
}	}
VERBOSE(("task_switch: ldtr = 0x%04x", ldtr));	VERBOSE(("task_switch: ldtr = 0x%04x", ldtr));
if (!task16) {	if (!task16) {
Line 342 task_switch(selector_t *task_sel, task_s	Line 339 task_switch(selector_t *task_sel, task_s
break;	break;

default:	default:
ia32_panic("task_switch(): task switch type is invalid");	ia32_panic("task_switch: task switch type is invalid");
break;	break;
}	}

Line 351 task_switch(selector_t *task_sel, task_s	Line 348 task_switch(selector_t *task_sel, task_s
cpu_memorywrite_d(cur_paddr + 32, CPU_EIP);	cpu_memorywrite_d(cur_paddr + 32, CPU_EIP);
cpu_memorywrite_d(cur_paddr + 36, old_flags);	cpu_memorywrite_d(cur_paddr + 36, old_flags);
for (i = 0; i < CPU_REG_NUM; i++) {	for (i = 0; i < CPU_REG_NUM; i++) {
cpu_memorywrite_d(cur_paddr + 40 + i * 4, CPU_REGS_DWORD(i));	cpu_memorywrite_d(cur_paddr + 40 + i * 4,
	CPU_REGS_DWORD(i));
}	}
for (i = 0; i < CPU_SEGREG_NUM; i++) {	for (i = 0; i < CPU_SEGREG_NUM; i++) {
cpu_memorywrite_w(cur_paddr + 72 + i * 4, CPU_REGS_SREG(i));	cpu_memorywrite_w(cur_paddr + 72 + i * 4,
	CPU_REGS_SREG(i));
}	}
} else {	} else {
cpu_memorywrite_w(cur_paddr + 14, CPU_IP);	cpu_memorywrite_w(cur_paddr + 14, CPU_IP);
cpu_memorywrite_w(cur_paddr + 16, (UINT16)old_flags);	cpu_memorywrite_w(cur_paddr + 16, (UINT16)old_flags);
for (i = 0; i < CPU_REG_NUM; i++) {	for (i = 0; i < CPU_REG_NUM; i++) {
cpu_memorywrite_w(cur_paddr + 18 + i * 2, CPU_REGS_WORD(i));	cpu_memorywrite_w(cur_paddr + 18 + i * 2,
	CPU_REGS_WORD(i));
}	}
for (i = 0; i < CPU_SEGREG286_NUM; i++) {	for (i = 0; i < CPU_SEGREG286_NUM; i++) {
cpu_memorywrite_w(cur_paddr + 34 + i * 2, CPU_REGS_SREG(i));	cpu_memorywrite_w(cur_paddr + 34 + i * 2,
	CPU_REGS_SREG(i));
}	}
}	}

Line 374 task_switch(selector_t *task_sel, task_s	Line 375 task_switch(selector_t *task_sel, task_s
/* set back link selector */	/* set back link selector */
cpu_memorywrite_w(task_paddr, CPU_TR);	cpu_memorywrite_w(task_paddr, CPU_TR);
break;	break;

case TASK_SWITCH_IRET:	case TASK_SWITCH_IRET:
case TASK_SWITCH_JMP:	case TASK_SWITCH_JMP:
/* Nothing to do */	/* Nothing to do */
break;	break;

default:	default:
ia32_panic("task_switch(): task switch type is invalid");	ia32_panic("task_switch: task switch type is invalid");
break;	break;
}	}

#if defined(MORE_DEBUG)	#if defined(MORE_DEBUG)
{	VERBOSE(("task_switch: current task"));
UINT32 v;	for (i = 0; i < CPU_TR_LIMIT; i += 4) {
	VERBOSE(("task_switch: 0x%08x: %08x", cur_base + i,
VERBOSE(("task_switch: current task"));	cpu_memoryread_d(cur_paddr + i)));
for (i = 0; i < CPU_TR_LIMIT; i += 4) {
v = cpu_memoryread_d(cur_paddr + i);
VERBOSE(("task_switch: 0x%08x: %08x", cur_base + i, v));
}
}	}
#endif	#endif

Line 423 task_switch(selector_t *task_sel, task_s	Line 420 task_switch(selector_t *task_sel, task_s
break;	break;

default:	default:
ia32_panic("task_switch(): task switch type is invalid");	ia32_panic("task_switch: task switch type is invalid");
break;	break;
}	}

Line 436 task_switch(selector_t *task_sel, task_s	Line 433 task_switch(selector_t *task_sel, task_s
CPU_CR0 \|= CPU_CR0_TS;	CPU_CR0 \|= CPU_CR0_TS;

/*	/*
* load task state (CR3, EFLAG, EIP, GPR, segreg, LDTR)	* load task state (CR3, EIP, GPR, segregs, LDTR, EFLAGS)
*/	*/

/* set new CR3 */	/* set new CR3 */
Line 444 task_switch(selector_t *task_sel, task_s	Line 441 task_switch(selector_t *task_sel, task_s
set_cr3(cr3);	set_cr3(cr3);
}	}

/* set new EIP, GPR */	/* set new EIP, GPR, segregs */
CPU_EIP = eip;	CPU_EIP = eip;
for (i = 0; i < CPU_REG_NUM; i++) {	for (i = 0; i < CPU_REG_NUM; i++) {
CPU_REGS_DWORD(i) = regs[i];	CPU_REGS_DWORD(i) = regs[i];
}	}
for (i = 0; i < CPU_SEGREG_NUM; i++) {	for (i = 0; i < CPU_SEGREG_NUM; i++) {
segdesc_init(i, sreg[i], &CPU_STAT_SREG(i));	segdesc_init(i, sreg[i], &CPU_STAT_SREG(i));
	/* invalidate segreg descriptor */
	CPU_STAT_SREG(i).valid = 0;
}	}

	CPU_CLEAR_PREV_ESP();

/* load new LDTR */	/* load new LDTR */
	CPU_LDTR_DESC.valid = 0;
load_ldtr(ldtr, TS_EXCEPTION);	load_ldtr(ldtr, TS_EXCEPTION);

/* I/O deny bitmap */	/* I/O deny bitmap */
Line 462 task_switch(selector_t *task_sel, task_s	Line 464 task_switch(selector_t *task_sel, task_s
CPU_STAT_IOLIMIT = (UINT16)(CPU_TR_DESC.u.seg.limit - iobase);	CPU_STAT_IOLIMIT = (UINT16)(CPU_TR_DESC.u.seg.limit - iobase);
CPU_STAT_IOADDR = task_base + iobase;	CPU_STAT_IOADDR = task_base + iobase;
}	}
VERBOSE(("task_switch: ioaddr = %08x, limit = %08x", CPU_STAT_IOADDR, CPU_STAT_IOLIMIT));	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

/* set new EFLAGS */	/* set new EFLAGS */
set_eflags(new_flags, 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 new segment register */	/* set new segment register */
if (!CPU_STAT_VM86) {	if (!CPU_STAT_VM86) {
/* clear segment descriptor cache */
for (i = 0; i < CPU_SEGREG_NUM; i++) {
segdesc_clear(&CPU_STAT_SREG(i));
}

/* load CS */	/* load CS */
rv = parse_selector(&cs_sel, sreg[CPU_CS_INDEX]);	rv = parse_selector(&cs_sel, sreg[CPU_CS_INDEX]);
if (rv < 0) {	if (rv < 0) {
Line 547 task_switch(selector_t *task_sel, task_s	Line 529 task_switch(selector_t *task_sel, task_s
EXCEPTION(SS_EXCEPTION, ss_sel.idx);	EXCEPTION(SS_EXCEPTION, ss_sel.idx);
}	}

/* Now loading CS/SS register */	/* Now loading SS register */
load_cs(cs_sel.selector, &cs_sel.desc, cs_sel.rpl);
load_ss(ss_sel.selector, &ss_sel.desc, cs_sel.rpl);	load_ss(ss_sel.selector, &ss_sel.desc, cs_sel.rpl);

/* load ES, DS, FS, GS segment register */	/* load ES, DS, FS, GS segment register */
for (i = 0; i < CPU_SEGREG_NUM; i++) {	LOAD_SEGREG1(CPU_ES_INDEX, sreg[CPU_ES_INDEX], TS_EXCEPTION);
if (i != CPU_CS_INDEX \|\| i != CPU_SS_INDEX) {	LOAD_SEGREG1(CPU_DS_INDEX, sreg[CPU_DS_INDEX], TS_EXCEPTION);
LOAD_SEGREG1(i, sreg[i], TS_EXCEPTION);	LOAD_SEGREG1(CPU_FS_INDEX, sreg[CPU_FS_INDEX], TS_EXCEPTION);
}	LOAD_SEGREG1(CPU_GS_INDEX, sreg[CPU_GS_INDEX], TS_EXCEPTION);
}
}

/* out of range */	/* Now loading CS register */
if (CPU_EIP > CPU_STAT_CS_LIMIT) {	load_cs(cs_sel.selector, &cs_sel.desc, cs_sel.rpl);
VERBOSE(("task_switch: new_ip is out of range. new_ip = %08x, limit = %08x", CPU_EIP, CPU_STAT_CS_LIMIT));
EXCEPTION(GP_EXCEPTION, 0);
}	}

VERBOSE(("task_switch: done."));	VERBOSE(("task_switch: done."));

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

Removed from v.1.26
changed lines
	Added in v.1.38