Bochs/bochs/cpu/io.cc

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/////////////////////////////////////////////////////////////////////////
// $Id: io.cc,v 1.59 2008-05-03 17:33:30 sshwarts Exp $
/////////////////////////////////////////////////////////////////////////
//
// Copyright (C) 2001 MandrakeSoft S.A.
//
// MandrakeSoft S.A.
// 43, rue d'Aboukir
// 75002 Paris - France
// http://www.linux-mandrake.com/
// http://www.mandrakesoft.com/
//
// This library is free software; you can redistribute it and/or
// modify it under the terms of the GNU Lesser General Public
// License as published by the Free Software Foundation; either
// version 2 of the License, or (at your option) any later version.
//
// This library is distributed in the hope that it will be useful,
// but WITHOUT ANY WARRANTY; without even the implied warranty of
// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
// Lesser General Public License for more details.
//
// You should have received a copy of the GNU Lesser General Public
// License along with this library; if not, write to the Free Software
// Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
//
/////////////////////////////////////////////////////////////////////////
#define NEED_CPU_REG_SHORTCUTS 1
#include "bochs.h"
#include "cpu.h"
#define LOG_THIS BX_CPU_THIS_PTR
#include "iodev/iodev.h"
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#if BX_SUPPORT_X86_64==0
// Make life easier for merging cpu64 and cpu32 code.
#define RDI EDI
#define RSI ESI
#define RAX EAX
#define RCX ECX
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#endif
//
// Repeat Speedups methods
//
#if BX_SupportRepeatSpeedups
Bit32u BX_CPU_C::FastRepINSW(bxInstruction_c *i, bx_address dstOff, Bit16u port, Bit32u wordCount)
{
Bit32u wordsFitDst;
signed int pointerDelta;
Bit8u *hostAddrDst;
unsigned count;
bx_segment_reg_t *dstSegPtr = &BX_CPU_THIS_PTR sregs[BX_SEG_REG_ES];
if (!(dstSegPtr->cache.valid & SegAccessWOK4G))
return 0;
bx_address laddrDst = BX_CPU_THIS_PTR get_laddr(BX_SEG_REG_ES, dstOff);
// check that the address is word aligned
if (laddrDst & 1) return 0;
#if BX_SupportGuest2HostTLB
hostAddrDst = v2h_write_byte(laddrDst, CPL);
#else
bx_phy_address paddrDst;
if (BX_CPU_THIS_PTR cr0.get_PG())
paddrDst = dtranslate_linear(laddrDst, CPL, BX_WRITE);
else
paddrDst = laddrDst;
// If we want to write directly into the physical memory array,
// we need the A20 address.
hostAddrDst = BX_MEM(0)->getHostMemAddr(BX_CPU_THIS,
A20ADDR(paddrDst), BX_WRITE, DATA_ACCESS);
#endif
// Check that native host access was not vetoed for that page
if (!hostAddrDst) return 0;
// See how many words can fit in the rest of this page.
if (BX_CPU_THIS_PTR get_DF()) {
// Counting downward
// 1st word must cannot cross page boundary because it is word aligned
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wordsFitDst = (2 + (PAGE_OFFSET(laddrDst))) >> 1;
pointerDelta = -2;
}
else {
// Counting upward
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wordsFitDst = (0x1000 - PAGE_OFFSET(laddrDst)) >> 1;
pointerDelta = 2;
}
// Restrict word count to the number that will fit in this page.
if (wordCount > wordsFitDst)
wordCount = wordsFitDst;
// If after all the restrictions, there is anything left to do...
if (wordCount) {
for (count=0; count<wordCount; ) {
bx_devices.bulkIOQuantumsTransferred = 0;
if (BX_CPU_THIS_PTR get_DF()==0) { // Only do accel for DF=0
bx_devices.bulkIOHostAddr = hostAddrDst;
bx_devices.bulkIOQuantumsRequested = (wordCount - count);
}
else
bx_devices.bulkIOQuantumsRequested = 0;
Bit16u temp16 = BX_INP(port, 2);
if (bx_devices.bulkIOQuantumsTransferred) {
hostAddrDst = bx_devices.bulkIOHostAddr;
count += bx_devices.bulkIOQuantumsTransferred;
}
else {
WriteHostWordToLittleEndian(hostAddrDst, temp16);
hostAddrDst += pointerDelta;
count++;
}
// Terminate early if there was an event.
if (BX_CPU_THIS_PTR async_event) break;
}
// Reset for next non-bulk IO
bx_devices.bulkIOQuantumsRequested = 0;
return count;
}
return 0;
}
Bit32u BX_CPU_C::FastRepOUTSW(bxInstruction_c *i, unsigned srcSeg, bx_address srcOff, Bit16u port, Bit32u wordCount)
{
Bit32u wordsFitSrc;
signed int pointerDelta;
Bit8u *hostAddrSrc;
unsigned count;
bx_segment_reg_t *srcSegPtr = &BX_CPU_THIS_PTR sregs[srcSeg];
if (!(srcSegPtr->cache.valid & SegAccessROK4G))
return 0;
bx_address laddrSrc = BX_CPU_THIS_PTR get_laddr(srcSeg, srcOff);
// check that the address is word aligned
if (laddrSrc & 1) return 0;
#if BX_SupportGuest2HostTLB
hostAddrSrc = v2h_read_byte(laddrSrc, CPL);
#else
bx_phy_address paddrSrc;
if (BX_CPU_THIS_PTR cr0.get_PG())
paddrSrc = dtranslate_linear(laddrSrc, CPL, BX_READ);
else
paddrSrc = laddrSrc;
// If we want to write directly into the physical memory array,
// we need the A20 address.
hostAddrSrc = BX_MEM(0)->getHostMemAddr(BX_CPU_THIS,
A20ADDR(paddrSrc), BX_READ, DATA_ACCESS);
#endif
// Check that native host access was not vetoed for that page
if (!hostAddrSrc) return 0;
// See how many words can fit in the rest of this page.
if (BX_CPU_THIS_PTR get_DF()) {
// Counting downward
// 1st word must cannot cross page boundary because it is word aligned
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wordsFitSrc = (2 + (PAGE_OFFSET(laddrSrc))) >> 1;
pointerDelta = (unsigned) -2;
}
else {
// Counting upward
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wordsFitSrc = (0x1000 - PAGE_OFFSET(laddrSrc)) >> 1;
pointerDelta = 2;
}
// Restrict word count to the number that will fit in this page.
if (wordCount > wordsFitSrc)
wordCount = wordsFitSrc;
// If after all the restrictions, there is anything left to do...
if (wordCount) {
for (count=0; count<wordCount; ) {
bx_devices.bulkIOQuantumsTransferred = 0;
if (BX_CPU_THIS_PTR get_DF()==0) { // Only do accel for DF=0
bx_devices.bulkIOHostAddr = hostAddrSrc;
bx_devices.bulkIOQuantumsRequested = (wordCount - count);
}
else
bx_devices.bulkIOQuantumsRequested = 0;
Bit16u temp16;
ReadHostWordFromLittleEndian(hostAddrSrc, temp16);
BX_OUTP(port, temp16, 2);
if (bx_devices.bulkIOQuantumsTransferred) {
hostAddrSrc = bx_devices.bulkIOHostAddr;
count += bx_devices.bulkIOQuantumsTransferred;
}
else {
hostAddrSrc += pointerDelta;
count++;
}
// Terminate early if there was an event.
if (BX_CPU_THIS_PTR async_event) break;
}
// Reset for next non-bulk IO
bx_devices.bulkIOQuantumsRequested = 0;
return count;
}
return 0;
}
#endif
//
// REP INS methods
//
void BX_CPP_AttrRegparmN(1) BX_CPU_C::REP_INSB_YbDX(bxInstruction_c *i)
{
BX_CPU_THIS_PTR repeat(i, &BX_CPU_C::INSB_YbDX);
#if BX_SUPPORT_X86_64
if (i->as32L()) {
BX_CLEAR_64BIT_HIGH(BX_64BIT_REG_RDI); // always clear upper part of RDI
}
#endif
}
void BX_CPP_AttrRegparmN(1) BX_CPU_C::REP_INSW_YwDX(bxInstruction_c *i)
{
BX_CPU_THIS_PTR repeat(i, &BX_CPU_C::INSW_YwDX);
#if BX_SUPPORT_X86_64
if (i->as32L()) {
BX_CLEAR_64BIT_HIGH(BX_64BIT_REG_RDI); // always clear upper part of RDI
}
#endif
}
void BX_CPP_AttrRegparmN(1) BX_CPU_C::REP_INSD_YdDX(bxInstruction_c *i)
{
BX_CPU_THIS_PTR repeat(i, &BX_CPU_C::INSD_YdDX);
#if BX_SUPPORT_X86_64
if (i->as32L()) {
BX_CLEAR_64BIT_HIGH(BX_64BIT_REG_RDI); // always clear upper part of RDI
}
#endif
}
//
// INSB/INSW/INSD methods
//
void BX_CPP_AttrRegparmN(1) BX_CPU_C::INSB_YbDX(bxInstruction_c *i)
{
Bit8u value8=0;
if (! BX_CPU_THIS_PTR allow_io(DX, 1)) {
BX_DEBUG(("INSB_YbDX: I/O access not allowed !"));
exception(BX_GP_EXCEPTION, 0, 0);
}
#if BX_SUPPORT_X86_64
if (i->as64L()) {
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// Write a zero to memory, to trigger any segment or page
// faults before reading from IO port.
write_virtual_byte(BX_SEG_REG_ES, RDI, value8);
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value8 = BX_INP(DX, 1);
/* no seg override possible */
write_virtual_byte(BX_SEG_REG_ES, RDI, value8);
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if (BX_CPU_THIS_PTR get_DF())
RDI--;
else
RDI++;
}
else
#endif
if (i->as32L()) {
// Write a zero to memory, to trigger any segment or page
// faults before reading from IO port.
write_virtual_byte(BX_SEG_REG_ES, EDI, value8);
value8 = BX_INP(DX, 1);
/* no seg override possible */
write_virtual_byte(BX_SEG_REG_ES, EDI, value8);
if (BX_CPU_THIS_PTR get_DF()) {
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RDI = EDI - 1;
}
else {
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RDI = EDI + 1;
}
}
else {
// Write a zero to memory, to trigger any segment or page
// faults before reading from IO port.
write_virtual_byte(BX_SEG_REG_ES, DI, value8);
value8 = BX_INP(DX, 1);
/* no seg override possible */
write_virtual_byte(BX_SEG_REG_ES, DI, value8);
if (BX_CPU_THIS_PTR get_DF())
DI--;
else
DI++;
}
}
// input word from port to string
void BX_CPP_AttrRegparmN(1) BX_CPU_C::INSW_YwDX(bxInstruction_c *i)
{
Bit16u value16=0;
#if BX_SUPPORT_X86_64
if (i->as64L()) {
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Bit64u rdi = RDI;
// Write a zero to memory, to trigger any segment or page
// faults before reading from IO port.
write_virtual_word(BX_SEG_REG_ES, rdi, value16);
value16 = BX_INP(DX, 2);
/* no seg override allowed */
write_virtual_word(BX_SEG_REG_ES, rdi, value16);
if (BX_CPU_THIS_PTR get_DF())
rdi -= 2;
else
rdi += 2;
RDI = rdi;
}
else
#endif
{
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Bit32u edi;
Bit32u incr = 2;
if (i->as32L())
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edi = EDI;
else
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edi = DI;
#if (BX_SupportRepeatSpeedups) && (BX_DEBUGGER == 0)
/* If conditions are right, we can transfer IO to physical memory
* in a batch, rather than one instruction at a time.
*/
if (i->repUsedL() && !BX_CPU_THIS_PTR async_event)
{
Bit32u wordCount;
if (i->as32L())
wordCount = ECX;
else
wordCount = CX;
BX_ASSERT(wordCount > 0);
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wordCount = FastRepINSW(i, edi, DX, wordCount);
if (wordCount)
{
// Decrement the ticks count by the number of iterations, minus
// one, since the main cpu loop will decrement one. Also,
// the count is predecremented before examined, so defintely
// don't roll it under zero.
BX_TICKN(wordCount-1);
if (i->as32L())
RCX = ECX - (wordCount-1);
else
CX -= (wordCount-1);
incr = wordCount << 1; // count * 2.
goto doIncr;
}
}
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#endif
// Write a zero to memory, to trigger any segment or page
// faults before reading from IO port.
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write_virtual_word(BX_SEG_REG_ES, edi, value16);
value16 = BX_INP(DX, 2);
/* no seg override allowed */
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write_virtual_word(BX_SEG_REG_ES, edi, value16);
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#if (BX_SupportRepeatSpeedups) && (BX_DEBUGGER == 0)
doIncr:
#endif
if (i->as32L()) {
if (BX_CPU_THIS_PTR get_DF())
RDI = EDI - incr;
else
RDI = EDI + incr;
}
else {
if (BX_CPU_THIS_PTR get_DF())
DI -= incr;
else
DI += incr;
}
}
}
// input doubleword from port to string
void BX_CPP_AttrRegparmN(1) BX_CPU_C::INSD_YdDX(bxInstruction_c *i)
{
if (! BX_CPU_THIS_PTR allow_io(DX, 4)) {
BX_DEBUG(("INSD_YdDX: I/O access not allowed !"));
exception(BX_GP_EXCEPTION, 0, 0);
}
#if BX_SUPPORT_X86_64
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if (i->as64L()) {
Bit64u rdi = RDI;
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// Write a zero to memory, to trigger any segment or page
// faults before reading from IO port.
write_virtual_dword(BX_SEG_REG_ES, rdi, 0);
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Bit32u value32 = BX_INP(DX, 4);
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/* no seg override allowed */
write_virtual_dword(BX_SEG_REG_ES, rdi, value32);
if (BX_CPU_THIS_PTR get_DF())
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rdi -= 4;
else
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rdi += 4;
RDI = rdi;
}
else
#endif
if (i->as32L()) {
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Bit32u edi = EDI;
// Write a zero to memory, to trigger any segment or page
// faults before reading from IO port.
write_virtual_dword(BX_SEG_REG_ES, edi, 0);
Bit32u value32 = BX_INP(DX, 4);
/* no seg override allowed */
write_virtual_dword(BX_SEG_REG_ES, edi, value32);
if (BX_CPU_THIS_PTR get_DF())
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edi -= 4;
else
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edi += 4;
RDI = edi;
}
else {
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Bit16u di = DI;
// Write a zero to memory, to trigger any segment or page
// faults before reading from IO port.
write_virtual_dword(BX_SEG_REG_ES, di, 0);
Bit32u value32 = BX_INP(DX, 4);
/* no seg override allowed */
write_virtual_dword(BX_SEG_REG_ES, di, value32);
if (BX_CPU_THIS_PTR get_DF())
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di -= 4;
else
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di += 4;
DI = di;
}
}
//
// REP OUTS methods
//
void BX_CPP_AttrRegparmN(1) BX_CPU_C::REP_OUTSB_DXXb(bxInstruction_c *i)
{
BX_CPU_THIS_PTR repeat(i, &BX_CPU_C::OUTSB_DXXb);
#if BX_SUPPORT_X86_64
if (i->as32L()) {
BX_CLEAR_64BIT_HIGH(BX_64BIT_REG_RSI); // always clear upper part of RSI
}
#endif
}
void BX_CPP_AttrRegparmN(1) BX_CPU_C::REP_OUTSW_DXXw(bxInstruction_c *i)
{
BX_CPU_THIS_PTR repeat(i, &BX_CPU_C::OUTSW_DXXw);
#if BX_SUPPORT_X86_64
if (i->as32L()) {
BX_CLEAR_64BIT_HIGH(BX_64BIT_REG_RSI); // always clear upper part of RSI
}
#endif
}
void BX_CPP_AttrRegparmN(1) BX_CPU_C::REP_OUTSD_DXXd(bxInstruction_c *i)
{
BX_CPU_THIS_PTR repeat(i, &BX_CPU_C::OUTSD_DXXd);
#if BX_SUPPORT_X86_64
if (i->as32L()) {
BX_CLEAR_64BIT_HIGH(BX_64BIT_REG_RSI); // always clear upper part of RSI
}
#endif
}
//
// OUTSB/OUTSW/OUTSD methods
//
void BX_CPP_AttrRegparmN(1) BX_CPU_C::OUTSB_DXXb(bxInstruction_c *i)
{
if (! BX_CPU_THIS_PTR allow_io(DX, 1)) {
BX_DEBUG(("OUTSB_DXXb: I/O access not allowed !"));
exception(BX_GP_EXCEPTION, 0, 0);
}
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Bit8u value8;
#if BX_SUPPORT_X86_64
if (i->as64L()) {
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Bit64u rsi = RSI;
value8 = read_virtual_byte(i->seg(), rsi);
BX_OUTP(DX, value8, 1);
if (BX_CPU_THIS_PTR get_DF())
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rsi--;
else
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rsi++;
RSI = rsi;
}
else
#endif
if (i->as32L()) {
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Bit32u esi = ESI;
value8 = read_virtual_byte(i->seg(), esi);
BX_OUTP(DX, value8, 1);
if (BX_CPU_THIS_PTR get_DF())
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esi--;
else
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esi++;
RSI = esi;
}
else {
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Bit16u si = SI;
value8 = read_virtual_byte(i->seg(), si);
BX_OUTP(DX, value8, 1);
if (BX_CPU_THIS_PTR get_DF())
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si--;
else
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si++;
SI = si;
}
}
// output word string to port
void BX_CPP_AttrRegparmN(1) BX_CPU_C::OUTSW_DXXw(bxInstruction_c *i)
{
if (! BX_CPU_THIS_PTR allow_io(DX, 2)) {
BX_DEBUG(("OUTSW_DXXw: I/O access not allowed !"));
exception(BX_GP_EXCEPTION, 0, 0);
}
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Bit16u value16;
#if BX_SUPPORT_X86_64
if (i->as64L()) {
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Bit64u rsi = RSI;
value16 = read_virtual_word(i->seg(), rsi);
BX_OUTP(DX, value16, 2);
if (BX_CPU_THIS_PTR get_DF())
rsi -= 2;
else
rsi += 2;
RSI = rsi;
}
else
#endif
{
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Bit32u esi;
Bit32u incr = 2;
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if (i->as32L())
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esi = ESI;
else
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esi = SI;
#if (BX_SupportRepeatSpeedups) && (BX_DEBUGGER == 0)
/* If conditions are right, we can transfer IO to physical memory
* in a batch, rather than one instruction at a time.
*/
if (i->repUsedL() && !BX_CPU_THIS_PTR async_event) {
Bit32u wordCount;
if (i->as32L())
wordCount = ECX;
else
wordCount = CX;
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wordCount = FastRepOUTSW(i, i->seg(), esi, DX, wordCount);
if (wordCount) {
// Decrement eCX. Note, the main loop will decrement 1 also, so
// decrement by one less than expected, like the case above.
BX_TICKN(wordCount-1); // Main cpu loop also decrements one more.
if (i->as32L())
RCX = ECX - (wordCount-1);
else
CX -= (wordCount-1);
incr = wordCount << 1; // count * 2.
}
else {
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value16 = read_virtual_word(i->seg(), esi);
BX_OUTP(DX, value16, 2);
}
}
else
#endif
{
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value16 = read_virtual_word(i->seg(), esi);
BX_OUTP(DX, value16, 2);
}
if (i->as32L()) {
if (BX_CPU_THIS_PTR get_DF())
RSI = ESI - incr;
else
RSI = ESI + incr;
}
else {
if (BX_CPU_THIS_PTR get_DF())
SI = SI - incr;
else
SI = SI + incr;
}
}
}
// output doubleword string to port
void BX_CPP_AttrRegparmN(1) BX_CPU_C::OUTSD_DXXd(bxInstruction_c *i)
{
if (! BX_CPU_THIS_PTR allow_io(DX, 4)) {
BX_DEBUG(("OUTSD_DXXd: I/O access not allowed !"));
exception(BX_GP_EXCEPTION, 0, 0);
}
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Bit32u value32;
#if BX_SUPPORT_X86_64
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if (i->as64L()) {
Bit64u rsi = RSI;
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value32 = read_virtual_dword(i->seg(), rsi);
BX_OUTP(DX, value32, 4);
if (BX_CPU_THIS_PTR get_DF())
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rsi -= 4;
else
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rsi += 4;
RSI = rsi;
}
else
#endif
if (i->as32L()) {
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Bit32u esi = ESI;
value32 = read_virtual_dword(i->seg(), esi);
BX_OUTP(DX, value32, 4);
if (BX_CPU_THIS_PTR get_DF())
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esi -= 4;
else
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esi += 4;
RSI = esi;
}
else {
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Bit16u si = SI;
value32 = read_virtual_dword(i->seg(), si);
BX_OUTP(DX, value32, 4);
if (BX_CPU_THIS_PTR get_DF())
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si -= 4;
else
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si += 4;
SI = si;
}
}
//
// non repeatable IN/OUT methods
//
void BX_CPP_AttrRegparmN(1) BX_CPU_C::IN_ALIb(bxInstruction_c *i)
{
AL = BX_CPU_THIS_PTR inp8(i->Ib());
}
void BX_CPP_AttrRegparmN(1) BX_CPU_C::IN_AXIb(bxInstruction_c *i)
{
AX = BX_CPU_THIS_PTR inp16(i->Ib());
}
void BX_CPP_AttrRegparmN(1) BX_CPU_C::IN_EAXIb(bxInstruction_c *i)
{
RAX = BX_CPU_THIS_PTR inp32(i->Ib());
}
void BX_CPP_AttrRegparmN(1) BX_CPU_C::OUT_IbAL(bxInstruction_c *i)
{
BX_CPU_THIS_PTR outp8(i->Ib(), AL);
}
void BX_CPP_AttrRegparmN(1) BX_CPU_C::OUT_IbAX(bxInstruction_c *i)
{
BX_CPU_THIS_PTR outp16(i->Ib(), AX);
}
void BX_CPP_AttrRegparmN(1) BX_CPU_C::OUT_IbEAX(bxInstruction_c *i)
{
BX_CPU_THIS_PTR outp32(i->Ib(), EAX);
}
void BX_CPP_AttrRegparmN(1) BX_CPU_C::IN_ALDX(bxInstruction_c *i)
{
AL = BX_CPU_THIS_PTR inp8(DX);
}
void BX_CPP_AttrRegparmN(1) BX_CPU_C::IN_AXDX(bxInstruction_c *i)
{
AX = BX_CPU_THIS_PTR inp16(DX);
}
void BX_CPP_AttrRegparmN(1) BX_CPU_C::IN_EAXDX(bxInstruction_c *i)
{
RAX = BX_CPU_THIS_PTR inp32(DX);
}
void BX_CPP_AttrRegparmN(1) BX_CPU_C::OUT_DXAL(bxInstruction_c *i)
{
BX_CPU_THIS_PTR outp8(DX, AL);
}
void BX_CPP_AttrRegparmN(1) BX_CPU_C::OUT_DXAX(bxInstruction_c *i)
{
BX_CPU_THIS_PTR outp16(DX, AX);
}
void BX_CPP_AttrRegparmN(1) BX_CPU_C::OUT_DXEAX(bxInstruction_c *i)
{
BX_CPU_THIS_PTR outp32(DX, EAX);
}