np2/i386c/ia32/paging.c - diff

Return to paging.c CVS log

Up to [RetroPC.NET] / np2 / i386c / ia32

Diff for /np2/i386c/ia32/paging.c between versions 1.29 and 1.31

version 1.29, 2007/02/06 14:20:57	version 1.31, 2011/01/15 17:17:23
Line 1	Line 1
/* $Id$ */

/*	/*
* Copyright (c) 2003-2004 NONAKA Kimihiro	* Copyright (c) 2003-2004 NONAKA Kimihiro
* All rights reserved.	* All rights reserved.
Line 187 static UINT32 MEMCALL paging(const UINT3	Line 185 static UINT32 MEMCALL paging(const UINT3
static void MEMCALL tlb_update(const UINT32 laddr, const UINT entry, const int ucrw);	static void MEMCALL tlb_update(const UINT32 laddr, const UINT entry, const int ucrw);
#endif	#endif

	#define PAGE_SIZE 0x1000
	#define PAGE_MASK (PAGE_SIZE - 1)

UINT8 MEMCALL	UINT8 MEMCALL
cpu_memory_access_la_RMW_b(UINT32 laddr, UINT32 (func)(UINT32, void ), void *arg)	cpu_memory_access_la_RMW_b(UINT32 laddr, UINT32 (func)(UINT32, void ), void *arg)
{	{
const int ucrw = CPU_PAGE_WRITE\|CPU_PAGE_DATA\|CPU_STAT_USER_MODE;	const int ucrw = CPU_PAGE_WRITE_DATA\|CPU_STAT_USER_MODE;
UINT32 result, value;	UINT32 result, value;
UINT32 paddr;	UINT32 paddr;

Line 205 cpu_memory_access_la_RMW_b(UINT32 laddr,	Line 206 cpu_memory_access_la_RMW_b(UINT32 laddr,
UINT16 MEMCALL	UINT16 MEMCALL
cpu_memory_access_la_RMW_w(UINT32 laddr, UINT32 (func)(UINT32, void ), void *arg)	cpu_memory_access_la_RMW_w(UINT32 laddr, UINT32 (func)(UINT32, void ), void *arg)
{	{
const int ucrw = CPU_PAGE_WRITE\|CPU_PAGE_DATA\|CPU_STAT_USER_MODE;	const int ucrw = CPU_PAGE_WRITE_DATA\|CPU_STAT_USER_MODE;
UINT32 result, value;	UINT32 result, value;
UINT32 paddr[2];	UINT32 paddr[2];

paddr[0] = paging(laddr, ucrw);	paddr[0] = paging(laddr, ucrw);
if ((laddr + 1) & 0x00000fff) {	if ((laddr + 1) & PAGE_MASK) {
value = cpu_memoryread_w(paddr[0]);	value = cpu_memoryread_w(paddr[0]);
result = (*func)(value, arg);	result = (*func)(value, arg);
cpu_memorywrite_w(paddr[0], (UINT16)result);	cpu_memorywrite_w(paddr[0], (UINT16)result);
Line 228 cpu_memory_access_la_RMW_w(UINT32 laddr,	Line 229 cpu_memory_access_la_RMW_w(UINT32 laddr,
UINT32 MEMCALL	UINT32 MEMCALL
cpu_memory_access_la_RMW_d(UINT32 laddr, UINT32 (func)(UINT32, void ), void *arg)	cpu_memory_access_la_RMW_d(UINT32 laddr, UINT32 (func)(UINT32, void ), void *arg)
{	{
const int ucrw = CPU_PAGE_WRITE\|CPU_PAGE_DATA\|CPU_STAT_USER_MODE;	const int ucrw = CPU_PAGE_WRITE_DATA\|CPU_STAT_USER_MODE;
UINT32 result, value;	UINT32 result, value;
UINT32 paddr[2];	UINT32 paddr[2];
UINT remain;	UINT remain;

paddr[0] = paging(laddr, ucrw);	paddr[0] = paging(laddr, ucrw);
remain = 0x1000 - (laddr & 0x00000fff);	remain = PAGE_SIZE - (laddr & PAGE_MASK);
if (remain >= 4) {	if (remain >= 4) {
value = cpu_memoryread_d(paddr[0]);	value = cpu_memoryread_d(paddr[0]);
result = (*func)(value, arg);	result = (*func)(value, arg);
Line 294 cpu_linear_memory_read_w(UINT32 laddr, c	Line 295 cpu_linear_memory_read_w(UINT32 laddr, c
UINT16 value;	UINT16 value;

paddr[0] = paging(laddr, ucrw);	paddr[0] = paging(laddr, ucrw);
if ((laddr + 1) & 0x00000fff) {	if ((laddr + 1) & PAGE_MASK) {
return cpu_memoryread_w(paddr[0]);	return cpu_memoryread_w(paddr[0]);
} else {	} else {
paddr[1] = paging(laddr + 1, ucrw);	paddr[1] = paging(laddr + 1, ucrw);
Line 312 cpu_linear_memory_read_d(UINT32 laddr, c	Line 313 cpu_linear_memory_read_d(UINT32 laddr, c
UINT remain;	UINT remain;

paddr[0] = paging(laddr, ucrw);	paddr[0] = paging(laddr, ucrw);
remain = 0x1000 - (laddr & 0x00000fff);	remain = PAGE_SIZE - (laddr & PAGE_MASK);
if (remain >= 4) {	if (remain >= 4) {
return cpu_memoryread_d(paddr[0]);	return cpu_memoryread_d(paddr[0]);
} else {	} else {
Line 352 cpu_linear_memory_read_q(UINT32 laddr, c	Line 353 cpu_linear_memory_read_q(UINT32 laddr, c
UINT remain;	UINT remain;

paddr[0] = paging(laddr, ucrw);	paddr[0] = paging(laddr, ucrw);
remain = 0x1000 - (laddr & 0x00000fff);	remain = PAGE_SIZE - (laddr & PAGE_MASK);
if (remain >= 8) {	if (remain >= 8) {
return cpu_memoryread_q(paddr[0]);	return cpu_memoryread_q(paddr[0]);
} else {	} else {
Line 375 cpu_linear_memory_read_q(UINT32 laddr, c	Line 376 cpu_linear_memory_read_q(UINT32 laddr, c
value = cpu_memoryread(paddr[0]);	value = cpu_memoryread(paddr[0]);
value += (UINT64)cpu_memoryread_d(paddr[0] + 1) << 8;	value += (UINT64)cpu_memoryread_d(paddr[0] + 1) << 8;
value += (UINT64)cpu_memoryread_w(paddr[1]) << 40;	value += (UINT64)cpu_memoryread_w(paddr[1]) << 40;
value += (UINT64)cpu_memoryread(paddr[1] + 1) << 56;	value += (UINT64)cpu_memoryread(paddr[1] + 2) << 56;
break;	break;

case 4:	case 4:
Line 421 cpu_linear_memory_read_f(UINT32 laddr, c	Line 422 cpu_linear_memory_read_f(UINT32 laddr, c
UINT i, j;	UINT i, j;

paddr[0] = paging(laddr, ucrw);	paddr[0] = paging(laddr, ucrw);
remain = 0x1000 - (laddr & 0x00000fff);	remain = PAGE_SIZE - (laddr & PAGE_MASK);
if (remain >= 10) {	if (remain >= 10) {
return cpu_memoryread_f(paddr[0]);	return cpu_memoryread_f(paddr[0]);
} else {	} else {
Line 439 cpu_linear_memory_read_f(UINT32 laddr, c	Line 440 cpu_linear_memory_read_f(UINT32 laddr, c
void MEMCALL	void MEMCALL
cpu_linear_memory_write_b(UINT32 laddr, UINT8 value, const int user_mode)	cpu_linear_memory_write_b(UINT32 laddr, UINT8 value, const int user_mode)
{	{
const int ucrw = CPU_PAGE_WRITE\|CPU_PAGE_DATA\|user_mode;	const int ucrw = CPU_PAGE_WRITE_DATA\|user_mode;
UINT32 paddr;	UINT32 paddr;

paddr = paging(laddr, ucrw);	paddr = paging(laddr, ucrw);
Line 449 cpu_linear_memory_write_b(UINT32 laddr,	Line 450 cpu_linear_memory_write_b(UINT32 laddr,
void MEMCALL	void MEMCALL
cpu_linear_memory_write_w(UINT32 laddr, UINT16 value, const int user_mode)	cpu_linear_memory_write_w(UINT32 laddr, UINT16 value, const int user_mode)
{	{
const int ucrw = CPU_PAGE_WRITE\|CPU_PAGE_DATA\|user_mode;	const int ucrw = CPU_PAGE_WRITE_DATA\|user_mode;
UINT32 paddr[2];	UINT32 paddr[2];

paddr[0] = paging(laddr, ucrw);	paddr[0] = paging(laddr, ucrw);
if ((laddr + 1) & 0x00000fff) {	if ((laddr + 1) & PAGE_MASK) {
cpu_memorywrite_w(paddr[0], value);	cpu_memorywrite_w(paddr[0], value);
} else {	} else {
paddr[1] = paging(laddr + 1, ucrw);	paddr[1] = paging(laddr + 1, ucrw);
Line 465 cpu_linear_memory_write_w(UINT32 laddr,	Line 466 cpu_linear_memory_write_w(UINT32 laddr,
void MEMCALL	void MEMCALL
cpu_linear_memory_write_d(UINT32 laddr, UINT32 value, const int user_mode)	cpu_linear_memory_write_d(UINT32 laddr, UINT32 value, const int user_mode)
{	{
const int ucrw = CPU_PAGE_WRITE\|CPU_PAGE_DATA\|user_mode;	const int ucrw = CPU_PAGE_WRITE_DATA\|user_mode;
UINT32 paddr[2];	UINT32 paddr[2];
UINT remain;	UINT remain;

paddr[0] = paging(laddr, ucrw);	paddr[0] = paging(laddr, ucrw);
remain = 0x1000 - (laddr & 0x00000fff);	remain = PAGE_SIZE - (laddr & PAGE_MASK);
if (remain >= 4) {	if (remain >= 4) {
cpu_memorywrite_d(paddr[0], value);	cpu_memorywrite_d(paddr[0], value);
} else {	} else {
Line 499 cpu_linear_memory_write_d(UINT32 laddr,	Line 500 cpu_linear_memory_write_d(UINT32 laddr,
void MEMCALL	void MEMCALL
cpu_linear_memory_write_q(UINT32 laddr, UINT64 value, const int user_mode)	cpu_linear_memory_write_q(UINT32 laddr, UINT64 value, const int user_mode)
{	{
const int ucrw = CPU_PAGE_WRITE\|CPU_PAGE_DATA\|user_mode;	const int ucrw = CPU_PAGE_WRITE_DATA\|user_mode;
UINT32 paddr[2];	UINT32 paddr[2];
UINT remain;	UINT remain;

paddr[0] = paging(laddr, ucrw);	paddr[0] = paging(laddr, ucrw);
remain = 0x1000 - (laddr & 0x00000fff);	remain = PAGE_SIZE - (laddr & PAGE_MASK);
if (remain >= 8) {	if (remain >= 8) {
cpu_memorywrite_q(paddr[0], value);	cpu_memorywrite_q(paddr[0], value);
} else {	} else {
Line 518 cpu_linear_memory_write_q(UINT32 laddr,	Line 519 cpu_linear_memory_write_q(UINT32 laddr,
break;	break;

case 6:	case 6:
	cpu_memorywrite_w(paddr[0], (UINT16)value);
cpu_memorywrite_d(paddr[0] + 2, (UINT32)(value >> 16));	cpu_memorywrite_d(paddr[0] + 2, (UINT32)(value >> 16));
cpu_memorywrite_w(paddr[1], (UINT16)(value >> 48));	cpu_memorywrite_w(paddr[1], (UINT16)(value >> 48));
break;	break;
Line 560 cpu_linear_memory_write_q(UINT32 laddr,	Line 562 cpu_linear_memory_write_q(UINT32 laddr,
void MEMCALL	void MEMCALL
cpu_linear_memory_write_f(UINT32 laddr, const REG80 *value, const int user_mode)	cpu_linear_memory_write_f(UINT32 laddr, const REG80 *value, const int user_mode)
{	{
const int ucrw = CPU_PAGE_WRITE\|CPU_PAGE_DATA\|user_mode;	const int ucrw = CPU_PAGE_WRITE_DATA\|user_mode;
UINT32 paddr[2];	UINT32 paddr[2];
UINT remain;	UINT remain;
UINT i, j;	UINT i, j;

paddr[0] = paging(laddr, ucrw);	paddr[0] = paging(laddr, ucrw);
remain = 0x1000 - (laddr & 0x00000fff);	remain = PAGE_SIZE - (laddr & PAGE_MASK);
if (remain >= 10) {	if (remain >= 10) {
cpu_memorywrite_f(paddr[0], value);	cpu_memorywrite_f(paddr[0], value);
} else {	} else {
Line 582 cpu_linear_memory_write_f(UINT32 laddr,	Line 584 cpu_linear_memory_write_f(UINT32 laddr,


void MEMCALL	void MEMCALL
cpu_memory_access_la_region(UINT32 laddr, UINT length, const int ucrw, BYTE *data)	cpu_memory_access_la_region(UINT32 laddr, UINT length, const int ucrw, UINT8 *data)
{	{
UINT32 paddr;	UINT32 paddr;
UINT remain; /* page remain */	UINT remain; /* page remain */
Line 591 cpu_memory_access_la_region(UINT32 laddr	Line 593 cpu_memory_access_la_region(UINT32 laddr
if (length == 0)	if (length == 0)
return;	return;

remain = 0x1000 - (laddr & 0x00000fff);	remain = PAGE_SIZE - (laddr & PAGE_MASK);
for (;;) {	for (;;) {
if (!CPU_STAT_PAGING) {	if (!CPU_STAT_PAGING) {
paddr = laddr;	paddr = laddr;
Line 615 cpu_memory_access_la_region(UINT32 laddr	Line 617 cpu_memory_access_la_region(UINT32 laddr
remain -= r;	remain -= r;
if (remain <= 0) {	if (remain <= 0) {
/* next page */	/* next page */
remain += 0x1000;	remain += PAGE_SIZE;
}	}
}	}
}	}

void MEMCALL	UINT32 MEMCALL
paging_check(UINT32 laddr, UINT length, const int ucrw)	laddr2paddr(const UINT32 laddr, const int ucrw)
{	{
UINT32 paddr;
UINT remain; /* page remain */
UINT r;

remain = 0x1000 - (laddr & 0x00000fff);
for (;;) {
paddr = paging(laddr, ucrw);

r = (remain > length) ? length : remain;

length -= r;
if (length == 0)
break;

laddr += r;	return paging(laddr, ucrw);
remain -= r;
if (remain <= 0) {
/* next page */
remain += 0x1000;
}
}
}	}

static UINT32 MEMCALL	static UINT32 MEMCALL
Line 661 paging(const UINT32 laddr, const int ucr	Line 644 paging(const UINT32 laddr, const int ucr

ep = tlb_lookup(laddr, ucrw);	ep = tlb_lookup(laddr, ucrw);
if (ep != NULL)	if (ep != NULL)
return ep->paddr + (laddr & 0xfff);	return ep->paddr + (laddr & PAGE_MASK);
#endif	#endif

pde_addr = CPU_STAT_PDE_BASE + ((laddr >> 20) & 0xffc);	pde_addr = CPU_STAT_PDE_BASE + ((laddr >> 20) & 0xffc);
Line 693 paging(const UINT32 laddr, const int ucr	Line 676 paging(const UINT32 laddr, const int ucr
}	}

/* make physical address */	/* make physical address */
paddr = (pte & CPU_PTE_BASEADDR_MASK) + (laddr & 0x00000fff);	paddr = (pte & CPU_PTE_BASEADDR_MASK) + (laddr & PAGE_MASK);

bit = ucrw & (CPU_PAGE_WRITE\|CPU_PAGE_USER_MODE);	bit = ucrw & (CPU_PAGE_WRITE\|CPU_PAGE_USER_MODE);
bit \|= (pde & pte & (CPU_PTE_WRITABLE\|CPU_PTE_USER_MODE));	bit \|= (pde & pte & (CPU_PTE_WRITABLE\|CPU_PTE_USER_MODE));
Line 758 do { \	Line 741 do { \
#if (CPU_FEATURES & CPU_FEATURE_PGE) == CPU_FEATURE_PGE	#if (CPU_FEATURES & CPU_FEATURE_PGE) == CPU_FEATURE_PGE
#define TLB_IS_GLOBAL(ep) ((ep)->tag & TLB_ENTRY_TAG_GLOBAL)	#define TLB_IS_GLOBAL(ep) ((ep)->tag & TLB_ENTRY_TAG_GLOBAL)
#else	#else
#define TLB_IS_GLOBAL(ep) FALSE	#define TLB_IS_GLOBAL(ep) 0
#endif	#endif

#define TLB_SET_TAG_FLAGS(ep, entry, bit) \	#define TLB_SET_TAG_FLAGS(ep, entry, bit) \

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

Removed from v.1.29
changed lines
	Added in v.1.31