project64/Source/Project64-core/N64System/Recompiler/x86/x86RegInfo.cpp

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#include "stdafx.h"
#if defined(__i386__) || defined(_M_IX86)
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#include <Project64-core/N64System/SystemGlobals.h>
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#include <Project64-core/N64System/N64System.h>
#include <Project64-core/N64System/Recompiler/Recompiler.h>
#include <Project64-core/N64System/Recompiler/RecompilerCodeLog.h>
#include <Project64-core/N64System/Recompiler/x86/x86RegInfo.h>
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#include <stdio.h>
#include <string.h>
#include <float.h>
uint32_t CX86RegInfo::m_fpuControl = 0;
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const char *Format_Name[] = { "Unknown", "dword", "qword", "float", "double" };
CX86RegInfo::CX86RegInfo() :
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m_Stack_TopPos(0)
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{
for (int32_t i = 0; i < 32; i++)
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{
m_RegMapLo[i] = x86_Unknown;
m_RegMapHi[i] = x86_Unknown;
}
for (int32_t i = 0, n = sizeof(m_x86reg_MappedTo) / sizeof(m_x86reg_MappedTo[0]); i < n; i++)
{
m_x86reg_MappedTo[i] = NotMapped;
m_x86reg_Protected[i] = false;
m_x86reg_MapOrder[i] = 0;
}
for (int32_t i = 0, n = sizeof(m_x86fpu_MappedTo) / sizeof(m_x86fpu_MappedTo[0]); i < n; i++)
{
m_x86fpu_MappedTo[i] = -1;
m_x86fpu_State[i] = FPU_Unknown;
m_x86fpu_StateChanged[i] = false;
m_x86fpu_RoundingModel[i] = RoundDefault;
}
}
CX86RegInfo::CX86RegInfo(const CX86RegInfo& rhs)
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{
*this = rhs;
}
CX86RegInfo::~CX86RegInfo()
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{
}
CX86RegInfo& CX86RegInfo::operator=(const CX86RegInfo& right)
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{
CRegBase::operator=(right);
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m_Stack_TopPos = right.m_Stack_TopPos;
memcpy(&m_RegMapLo, &right.m_RegMapLo, sizeof(m_RegMapLo));
memcpy(&m_RegMapHi, &right.m_RegMapHi, sizeof(m_RegMapHi));
memcpy(&m_x86reg_MappedTo, &right.m_x86reg_MappedTo, sizeof(m_x86reg_MappedTo));
memcpy(&m_x86reg_Protected, &right.m_x86reg_Protected, sizeof(m_x86reg_Protected));
memcpy(&m_x86reg_MapOrder, &right.m_x86reg_MapOrder, sizeof(m_x86reg_MapOrder));
memcpy(&m_x86fpu_MappedTo, &right.m_x86fpu_MappedTo, sizeof(m_x86fpu_MappedTo));
memcpy(&m_x86fpu_State, &right.m_x86fpu_State, sizeof(m_x86fpu_State));
memcpy(&m_x86fpu_StateChanged, &right.m_x86fpu_StateChanged, sizeof(m_x86fpu_StateChanged));
memcpy(&m_x86fpu_RoundingModel, &right.m_x86fpu_RoundingModel, sizeof(m_x86fpu_RoundingModel));
#ifdef _DEBUG
if (*this != right)
{
g_Notify->BreakPoint(__FILE__, __LINE__);
}
#endif
return *this;
}
bool CX86RegInfo::operator==(const CX86RegInfo& right) const
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{
if (!CRegBase::operator==(right))
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{
return false;
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}
int32_t count;
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for (count = 0; count < 10; count++)
{
if (m_x86reg_MappedTo[count] != right.m_x86reg_MappedTo[count]) { return false; }
if (m_x86reg_Protected[count] != right.m_x86reg_Protected[count]) { return false; }
if (m_x86reg_MapOrder[count] != right.m_x86reg_MapOrder[count]) { return false; }
}
if (m_Stack_TopPos != right.m_Stack_TopPos) { return false; }
for (count = 0; count < 8; count++)
{
if (m_x86fpu_MappedTo[count] != right.m_x86fpu_MappedTo[count]) { return false; }
if (m_x86fpu_State[count] != right.m_x86fpu_State[count]) { return false; }
if (m_x86fpu_RoundingModel[count] != right.m_x86fpu_RoundingModel[count]) { return false; }
}
return true;
}
bool CX86RegInfo::operator!=(const CX86RegInfo& right) const
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{
return !(right == *this);
}
CX86RegInfo::REG_STATE CX86RegInfo::ConstantsType(int64_t Value)
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{
if (((Value >> 32) == -1) && ((Value & 0x80000000) != 0)) { return STATE_CONST_32_SIGN; }
if (((Value >> 32) == 0) && ((Value & 0x80000000) == 0)) { return STATE_CONST_32_SIGN; }
return STATE_CONST_64;
}
void CX86RegInfo::BeforeCallDirect(void)
{
UnMap_AllFPRs();
Pushad();
}
void CX86RegInfo::AfterCallDirect(void)
{
Popad();
SetRoundingModel(CRegInfo::RoundUnknown);
}
void CX86RegInfo::FixRoundModel(FPU_ROUND RoundMethod)
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{
if (GetRoundingModel() == RoundMethod)
{
return;
}
CPU_Message(" FixRoundModel: CurrentRoundingModel: %s targetRoundModel: %s", RoundingModelName(GetRoundingModel()), RoundingModelName(RoundMethod));
m_fpuControl = 0;
fpuStoreControl(&m_fpuControl, "m_fpuControl");
x86Reg reg = Map_TempReg(x86_Any, -1, false);
MoveVariableToX86reg(&m_fpuControl, "m_fpuControl", reg);
AndConstToX86Reg(reg, 0xF3FF);
if (RoundMethod == RoundDefault)
{
#ifdef _WIN32
static const unsigned int msRound[4] =
{
0x00000000, //_RC_NEAR
0x00000300, //_RC_CHOP
0x00000200, //_RC_UP
0x00000100, //_RC_DOWN
};
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x86Reg RoundReg = Map_TempReg(x86_Any, -1, false);
MoveVariableToX86reg(&g_Reg->m_RoundingModel, "m_RoundingModel", RoundReg);
MoveVariableDispToX86Reg((void *)&msRound[0], "msRound", RoundReg, RoundReg, Multip_x4);
ShiftLeftSignImmed(RoundReg, 2);
OrX86RegToX86Reg(reg, RoundReg);
#else
x86Reg RoundReg = Map_TempReg(x86_Any, -1, false);
MoveVariableToX86reg(_RoundingModel, "_RoundingModel", RoundReg);
OrX86RegToX86Reg(reg, RoundReg);
#endif
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SetX86Protected(RoundReg, false);
}
else
{
switch (RoundMethod)
{
case RoundTruncate: OrConstToX86Reg(0x0C00, reg); break;
case RoundNearest: OrConstToX86Reg(0x0000, reg); break;
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case RoundDown: OrConstToX86Reg(0x0400, reg); break;
case RoundUp: OrConstToX86Reg(0x0800, reg); break;
default:
g_Notify->DisplayError("Unknown Rounding model");
}
}
MoveX86regToVariable(reg, &m_fpuControl, "m_fpuControl");
SetX86Protected(reg, false);
fpuLoadControl(&m_fpuControl, "m_fpuControl");
SetRoundingModel(RoundMethod);
}
void CX86RegInfo::ChangeFPURegFormat(int32_t Reg, FPU_STATE OldFormat, FPU_STATE NewFormat, FPU_ROUND RoundingModel)
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{
for (uint32_t i = 0; i < 8; i++)
{
if (m_x86fpu_MappedTo[i] != Reg)
{
continue;
}
if (m_x86fpu_State[i] != OldFormat || m_x86fpu_StateChanged[i])
{
UnMap_FPR(Reg, true);
Load_FPR_ToTop(Reg, Reg, OldFormat);
}
else
{
CPU_Message(" regcache: Changed format of ST(%d) from %s to %s", (i - StackTopPos() + 8) & 7, Format_Name[OldFormat], Format_Name[NewFormat]);
}
FpuRoundingModel(i) = RoundingModel;
m_x86fpu_State[i] = NewFormat;
m_x86fpu_StateChanged[i] = true;
return;
}
if (HaveDebugger())
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{
g_Notify->DisplayError("ChangeFormat: Register not on stack!!");
}
}
void CX86RegInfo::Load_FPR_ToTop(int32_t Reg, int32_t RegToLoad, FPU_STATE Format)
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{
if (GetRoundingModel() != RoundDefault)
{
FixRoundModel(RoundDefault);
}
CPU_Message("CurrentRoundingModel: %s FpuRoundingModel(StackTopPos()): %s", RoundingModelName(GetRoundingModel()), RoundingModelName(FpuRoundingModel(StackTopPos())));
int32_t i;
if (RegToLoad < 0) { g_Notify->DisplayError("Load_FPR_ToTop\nRegToLoad < 0 ???"); return; }
if (Reg < 0) { g_Notify->DisplayError("Load_FPR_ToTop\nReg < 0 ???"); return; }
if (Format == FPU_Double || Format == FPU_Qword)
{
UnMap_FPR(Reg + 1, true);
UnMap_FPR(RegToLoad + 1, true);
}
else
{
if ((Reg & 1) != 0)
{
for (i = 0; i < 8; i++)
{
if (m_x86fpu_MappedTo[i] == (Reg - 1))
{
if (m_x86fpu_State[i] == FPU_Double || m_x86fpu_State[i] == FPU_Qword)
{
UnMap_FPR(Reg, true);
}
i = 8;
}
}
}
if ((RegToLoad & 1) != 0)
{
for (i = 0; i < 8; i++)
{
if (m_x86fpu_MappedTo[i] == (RegToLoad - 1))
{
if (m_x86fpu_State[i] == FPU_Double || m_x86fpu_State[i] == FPU_Qword)
{
UnMap_FPR(RegToLoad, true);
}
i = 8;
}
}
}
}
if (Reg == RegToLoad)
{
//if different format then unmap original reg from stack
for (i = 0; i < 8; i++)
{
if (m_x86fpu_MappedTo[i] != Reg)
{
continue;
}
if (m_x86fpu_State[i] != Format)
{
UnMap_FPR(Reg, true);
}
break;
}
}
else
{
//if different format then unmap original reg from stack
for (i = 0; i < 8; i++)
{
if (m_x86fpu_MappedTo[i] != Reg)
{
continue;
}
UnMap_FPR(Reg, m_x86fpu_State[i] != Format);
break;
}
}
if (RegInStack(RegToLoad, Format))
{
if (Reg != RegToLoad)
{
if (m_x86fpu_MappedTo[(StackTopPos() - 1) & 7] != RegToLoad)
{
UnMap_FPR(m_x86fpu_MappedTo[(StackTopPos() - 1) & 7], true);
CPU_Message(" regcache: allocate ST(0) to %s", CRegName::FPR[Reg]);
fpuLoadReg(&StackTopPos(), StackPosition(RegToLoad));
FpuRoundingModel(StackTopPos()) = RoundDefault;
m_x86fpu_MappedTo[StackTopPos()] = Reg;
m_x86fpu_State[StackTopPos()] = Format;
m_x86fpu_StateChanged[StackTopPos()] = false;
}
else
{
UnMap_FPR(m_x86fpu_MappedTo[(StackTopPos() - 1) & 7], true);
Load_FPR_ToTop(Reg, RegToLoad, Format);
}
}
else
{
x86FpuValues RegPos = x86_ST_Unknown;
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for (uint32_t z = 0; z < 8; z++)
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{
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if (m_x86fpu_MappedTo[z] == Reg)
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{
RegPos = (x86FpuValues)i;
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z = 8;
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}
}
if (RegPos == StackTopPos())
{
return;
}
x86FpuValues StackPos = StackPosition(Reg);
FpuRoundingModel(RegPos) = FpuRoundingModel(StackTopPos());
m_x86fpu_MappedTo[RegPos] = m_x86fpu_MappedTo[StackTopPos()];
m_x86fpu_State[RegPos] = m_x86fpu_State[StackTopPos()];
m_x86fpu_StateChanged[RegPos] = m_x86fpu_StateChanged[StackTopPos()];
CPU_Message(" regcache: allocate ST(%d) to %s", StackPos, CRegName::FPR[m_x86fpu_MappedTo[RegPos]]);
CPU_Message(" regcache: allocate ST(0) to %s", CRegName::FPR[Reg]);
fpuExchange(StackPos);
FpuRoundingModel(StackTopPos()) = RoundDefault;
m_x86fpu_MappedTo[StackTopPos()] = Reg;
m_x86fpu_State[StackTopPos()] = Format;
m_x86fpu_StateChanged[StackTopPos()] = false;
}
}
else
{
char Name[50];
x86Reg TempReg;
UnMap_FPR(m_x86fpu_MappedTo[(StackTopPos() - 1) & 7], true);
for (i = 0; i < 8; i++)
{
if (m_x86fpu_MappedTo[i] == RegToLoad)
{
UnMap_FPR(RegToLoad, true);
i = 8;
}
}
CPU_Message(" regcache: allocate ST(0) to %s", CRegName::FPR[Reg]);
TempReg = Map_TempReg(x86_Any, -1, false);
switch (Format)
{
case FPU_Dword:
sprintf(Name, "m_FPR_S[%d]", RegToLoad);
MoveVariableToX86reg(&g_Reg->m_FPR_S[RegToLoad], Name, TempReg);
fpuLoadIntegerDwordFromX86Reg(&StackTopPos(), TempReg);
break;
case FPU_Qword:
sprintf(Name, "m_FPR_D[%d]", RegToLoad);
MoveVariableToX86reg(&g_Reg->m_FPR_D[RegToLoad], Name, TempReg);
fpuLoadIntegerQwordFromX86Reg(&StackTopPos(), TempReg);
break;
case FPU_Float:
sprintf(Name, "m_FPR_S[%d]", RegToLoad);
MoveVariableToX86reg(&g_Reg->m_FPR_S[RegToLoad], Name, TempReg);
fpuLoadDwordFromX86Reg(&StackTopPos(), TempReg);
break;
case FPU_Double:
sprintf(Name, "m_FPR_D[%d]", RegToLoad);
MoveVariableToX86reg(&g_Reg->m_FPR_D[RegToLoad], Name, TempReg);
fpuLoadQwordFromX86Reg(&StackTopPos(), TempReg);
break;
default:
if (HaveDebugger()) { g_Notify->DisplayError(stdstr_f("Load_FPR_ToTop\nUnkown format to load %d", Format).c_str()); }
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}
SetX86Protected(TempReg, false);
FpuRoundingModel(StackTopPos()) = RoundDefault;
m_x86fpu_MappedTo[StackTopPos()] = Reg;
m_x86fpu_State[StackTopPos()] = Format;
m_x86fpu_StateChanged[StackTopPos()] = false;
}
}
CX86RegInfo::x86FpuValues CX86RegInfo::StackPosition(int32_t Reg)
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{
int32_t i;
for (i = 0; i < 8; i++)
{
if (m_x86fpu_MappedTo[i] == Reg)
{
return (x86FpuValues)((i - StackTopPos()) & 7);
}
}
return x86_ST_Unknown;
}
CX86Ops::x86Reg CX86RegInfo::FreeX86Reg()
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{
if (GetX86Mapped(x86_EDI) == NotMapped && !GetX86Protected(x86_EDI)) { return x86_EDI; }
if (GetX86Mapped(x86_ESI) == NotMapped && !GetX86Protected(x86_ESI)) { return x86_ESI; }
if (GetX86Mapped(x86_EBX) == NotMapped && !GetX86Protected(x86_EBX)) { return x86_EBX; }
if (GetX86Mapped(x86_EAX) == NotMapped && !GetX86Protected(x86_EAX)) { return x86_EAX; }
if (GetX86Mapped(x86_EDX) == NotMapped && !GetX86Protected(x86_EDX)) { return x86_EDX; }
if (GetX86Mapped(x86_ECX) == NotMapped && !GetX86Protected(x86_ECX)) { return x86_ECX; }
x86Reg Reg = UnMap_TempReg();
if (Reg != x86_Unknown) { return Reg; }
int32_t count, MapCount[10];
x86Reg MapReg[10];
for (count = 0; count < 10; count++)
{
MapCount[count] = GetX86MapOrder((x86Reg)count);
MapReg[count] = (x86Reg)count;
}
for (count = 0; count < 10; count++)
{
int32_t i;
for (i = 0; i < 9; i++)
{
x86Reg tempReg;
uint32_t temp;
if (MapCount[i] < MapCount[i + 1])
{
temp = MapCount[i];
MapCount[i] = MapCount[i + 1];
MapCount[i + 1] = temp;
tempReg = MapReg[i];
MapReg[i] = MapReg[i + 1];
MapReg[i + 1] = tempReg;
}
}
}
x86Reg StackReg = x86_Unknown;
for (count = 0; count < 10; count++)
{
if (MapCount[count] > 0 && GetX86Mapped(MapReg[count]) != Stack_Mapped)
{
if (UnMap_X86reg((x86Reg)MapReg[count]))
{
return (x86Reg)MapReg[count];
}
}
if (GetX86Mapped(MapReg[count]) == Stack_Mapped) { StackReg = MapReg[count]; }
}
if (StackReg != x86_Unknown)
{
UnMap_X86reg(StackReg);
return StackReg;
}
return x86_Unknown;
}
CX86Ops::x86Reg CX86RegInfo::Free8BitX86Reg()
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{
if (GetX86Mapped(x86_EBX) == NotMapped && !GetX86Protected(x86_EBX)) { return x86_EBX; }
if (GetX86Mapped(x86_EAX) == NotMapped && !GetX86Protected(x86_EAX)) { return x86_EAX; }
if (GetX86Mapped(x86_EDX) == NotMapped && !GetX86Protected(x86_EDX)) { return x86_EDX; }
if (GetX86Mapped(x86_ECX) == NotMapped && !GetX86Protected(x86_ECX)) { return x86_ECX; }
x86Reg Reg = UnMap_8BitTempReg();
if (Reg > 0) { return Reg; }
int32_t count, MapCount[10], MapReg[10];
for (count = 0; count < 10; count++)
{
MapCount[count] = GetX86MapOrder((x86Reg)count);
MapReg[count] = count;
}
for (count = 0; count < 10; count++)
{
int32_t i;
for (i = 0; i < 9; i++)
{
int32_t temp;
if (MapCount[i] < MapCount[i + 1])
{
temp = MapCount[i];
MapCount[i] = MapCount[i + 1];
MapCount[i + 1] = temp;
temp = MapReg[i];
MapReg[i] = MapReg[i + 1];
MapReg[i + 1] = temp;
}
}
}
for (count = 0; count < 10; count++)
{
if (MapCount[count] > 0)
{
if (!Is8BitReg((x86Reg)count)) { continue; }
if (UnMap_X86reg((x86Reg)count))
{
return (x86Reg)count;
}
}
}
return x86_Unknown;
}
CX86Ops::x86Reg CX86RegInfo::UnMap_8BitTempReg()
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{
int32_t count;
for (count = 0; count < 10; count++)
{
if (!Is8BitReg((x86Reg)count)) { continue; }
if (GetX86Mapped((x86Reg)count) == Temp_Mapped)
{
if (GetX86Protected((x86Reg)count) == false)
{
CPU_Message(" regcache: unallocate %s from temp storage", x86_Name((x86Reg)count));
SetX86Mapped((x86Reg)count, CX86RegInfo::NotMapped);
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return (x86Reg)count;
}
}
}
return x86_Unknown;
}
CX86RegInfo::x86Reg CX86RegInfo::Get_MemoryStack() const
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{
for (int32_t i = 0, n = sizeof(x86_Registers) / sizeof(x86_Registers[0]); i < n; i++)
{
if (GetX86Mapped(x86_Registers[i]) == Stack_Mapped)
{
return x86_Registers[i];
}
}
return x86_Unknown;
}
CX86RegInfo::x86Reg CX86RegInfo::Map_MemoryStack(x86Reg Reg, bool bMapRegister, bool LoadValue)
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{
x86Reg CurrentMap = Get_MemoryStack();
if (!bMapRegister)
{
//if not mapping then just return what the current mapping is
return CurrentMap;
}
if (CurrentMap != x86_Unknown && CurrentMap == Reg)
{
//already mapped to correct reg
return CurrentMap;
}
// map a register
if (Reg == x86_Any)
{
if (CurrentMap != x86_Unknown)
{
return CurrentMap;
}
Reg = FreeX86Reg();
if (Reg == x86_Unknown)
{
g_Notify->DisplayError("Map_MemoryStack\n\nOut of registers");
g_Notify->BreakPoint(__FILE__, __LINE__);
}
SetX86Mapped(Reg, CX86RegInfo::Stack_Mapped);
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CPU_Message(" regcache: allocate %s as Memory Stack", x86_Name(Reg));
if (LoadValue)
{
MoveVariableToX86reg(&g_Recompiler->MemoryStackPos(), "MemoryStack", Reg);
}
return Reg;
}
//move to a register/allocate register
UnMap_X86reg(Reg);
if (CurrentMap != x86_Unknown)
{
CPU_Message(" regcache: change allocation of Memory Stack from %s to %s", x86_Name(CurrentMap), x86_Name(Reg));
SetX86Mapped(Reg, CX86RegInfo::Stack_Mapped);
SetX86Mapped(CurrentMap, CX86RegInfo::NotMapped);
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MoveX86RegToX86Reg(CurrentMap, Reg);
}
else
{
SetX86Mapped(Reg, CX86RegInfo::Stack_Mapped);
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CPU_Message(" regcache: allocate %s as Memory Stack", x86_Name(Reg));
if (LoadValue)
{
MoveVariableToX86reg(&g_Recompiler->MemoryStackPos(), "MemoryStack", Reg);
}
}
return Reg;
}
void CX86RegInfo::Map_GPR_32bit(int32_t MipsReg, bool SignValue, int32_t MipsRegToLoad)
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{
int32_t count;
x86Reg Reg;
if (MipsReg == 0)
{
g_Notify->BreakPoint(__FILE__, __LINE__);
return;
}
if (IsUnknown(MipsReg) || IsConst(MipsReg))
{
Reg = FreeX86Reg();
if (Reg < 0)
{
if (HaveDebugger()) { g_Notify->DisplayError("Map_GPR_32bit\n\nOut of registers"); }
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g_Notify->BreakPoint(__FILE__, __LINE__);
return;
}
CPU_Message(" regcache: allocate %s to %s", x86_Name(Reg), CRegName::GPR[MipsReg]);
}
else
{
if (Is64Bit(MipsReg))
{
CPU_Message(" regcache: unallocate %s from high 32bit of %s", x86_Name(GetMipsRegMapHi(MipsReg)), CRegName::GPR_Hi[MipsReg]);
SetX86MapOrder(GetMipsRegMapHi(MipsReg), 0);
SetX86Mapped(GetMipsRegMapHi(MipsReg), NotMapped);
SetX86Protected(GetMipsRegMapHi(MipsReg), false);
SetMipsRegHi(MipsReg, 0);
}
Reg = GetMipsRegMapLo(MipsReg);
}
for (count = 0; count < 10; count++)
{
uint32_t Count = GetX86MapOrder((x86Reg)count);
if (Count > 0)
{
SetX86MapOrder((x86Reg)count, Count + 1);
}
}
SetX86MapOrder(Reg, 1);
if (MipsRegToLoad > 0)
{
if (IsUnknown(MipsRegToLoad))
{
MoveVariableToX86reg(&_GPR[MipsRegToLoad].UW[0], CRegName::GPR_Lo[MipsRegToLoad], Reg);
}
else if (IsMapped(MipsRegToLoad))
{
if (MipsReg != MipsRegToLoad)
{
MoveX86RegToX86Reg(GetMipsRegMapLo(MipsRegToLoad), Reg);
}
}
else
{
MoveConstToX86reg(GetMipsRegLo(MipsRegToLoad), Reg);
}
}
else if (MipsRegToLoad == 0)
{
XorX86RegToX86Reg(Reg, Reg);
}
SetX86Mapped(Reg, GPR_Mapped);
SetX86Protected(Reg, true);
SetMipsRegMapLo(MipsReg, Reg);
SetMipsRegState(MipsReg, SignValue ? STATE_MAPPED_32_SIGN : STATE_MAPPED_32_ZERO);
}
void CX86RegInfo::Map_GPR_64bit(int32_t MipsReg, int32_t MipsRegToLoad)
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{
x86Reg x86Hi, x86lo;
int32_t count;
if (MipsReg == 0)
{
if (HaveDebugger()) { g_Notify->DisplayError("Map_GPR_32bit\n\nWhy are you trying to map reg 0"); }
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return;
}
ProtectGPR(MipsReg);
if (IsUnknown(MipsReg) || IsConst(MipsReg))
{
x86Hi = FreeX86Reg();
if (x86Hi < 0)
{
if (HaveDebugger()) { g_Notify->DisplayError("Map_GPR_64bit\n\nOut of registers"); }
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return;
}
SetX86Protected(x86Hi, true);
x86lo = FreeX86Reg();
if (x86lo < 0) { g_Notify->DisplayError("Map_GPR_64bit\n\nOut of registers"); return; }
SetX86Protected(x86lo, true);
CPU_Message(" regcache: allocate %s to hi word of %s", x86_Name(x86Hi), CRegName::GPR[MipsReg]);
CPU_Message(" regcache: allocate %s to low word of %s", x86_Name(x86lo), CRegName::GPR[MipsReg]);
}
else
{
x86lo = GetMipsRegMapLo(MipsReg);
if (Is32Bit(MipsReg))
{
SetX86Protected(x86lo, true);
x86Hi = FreeX86Reg();
if (x86Hi == x86_Unknown)
{
g_Notify->BreakPoint(__FILE__, __LINE__);
return;
}
SetX86Protected(x86Hi, true);
CPU_Message(" regcache: allocate %s to hi word of %s", x86_Name(x86Hi), CRegName::GPR[MipsReg]);
}
else
{
x86Hi = GetMipsRegMapHi(MipsReg);
}
}
for (count = 0; count < 10; count++)
{
int32_t MapOrder = GetX86MapOrder((x86Reg)count);
if (MapOrder > 0)
{
SetX86MapOrder((x86Reg)count, MapOrder + 1);
}
}
SetX86MapOrder(x86Hi, 1);
SetX86MapOrder(x86lo, 1);
if (MipsRegToLoad > 0)
{
if (IsUnknown(MipsRegToLoad))
{
MoveVariableToX86reg(&_GPR[MipsRegToLoad].UW[1], CRegName::GPR_Hi[MipsRegToLoad], x86Hi);
MoveVariableToX86reg(&_GPR[MipsRegToLoad].UW[0], CRegName::GPR_Lo[MipsRegToLoad], x86lo);
}
else if (IsMapped(MipsRegToLoad))
{
if (Is32Bit(MipsRegToLoad))
{
if (IsSigned(MipsRegToLoad))
{
MoveX86RegToX86Reg(GetMipsRegMapLo(MipsRegToLoad), x86Hi);
ShiftRightSignImmed(x86Hi, 31);
}
else
{
XorX86RegToX86Reg(x86Hi, x86Hi);
}
if (MipsReg != MipsRegToLoad)
{
MoveX86RegToX86Reg(GetMipsRegMapLo(MipsRegToLoad), x86lo);
}
}
else
{
if (MipsReg != MipsRegToLoad)
{
MoveX86RegToX86Reg(GetMipsRegMapHi(MipsRegToLoad), x86Hi);
MoveX86RegToX86Reg(GetMipsRegMapLo(MipsRegToLoad), x86lo);
}
}
}
else
{
CPU_Message("Map_GPR_64bit 11");
if (Is32Bit(MipsRegToLoad))
{
if (IsSigned(MipsRegToLoad))
{
MoveConstToX86reg(GetMipsRegLo_S(MipsRegToLoad) >> 31, x86Hi);
}
else
{
MoveConstToX86reg(0, x86Hi);
}
}
else
{
MoveConstToX86reg(GetMipsRegHi(MipsRegToLoad), x86Hi);
}
MoveConstToX86reg(GetMipsRegLo(MipsRegToLoad), x86lo);
}
}
else if (MipsRegToLoad == 0)
{
XorX86RegToX86Reg(x86Hi, x86Hi);
XorX86RegToX86Reg(x86lo, x86lo);
}
SetX86Mapped(x86Hi, GPR_Mapped);
SetX86Mapped(x86lo, GPR_Mapped);
SetMipsRegMapHi(MipsReg, x86Hi);
SetMipsRegMapLo(MipsReg, x86lo);
SetMipsRegState(MipsReg, STATE_MAPPED_64);
}
CX86Ops::x86Reg CX86RegInfo::Map_TempReg(CX86Ops::x86Reg Reg, int32_t MipsReg, bool LoadHiWord)
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{
int32_t count;
if (Reg == x86_Any)
{
if (GetX86Mapped(x86_EAX) == Temp_Mapped && !GetX86Protected(x86_EAX)) { Reg = x86_EAX; }
else if (GetX86Mapped(x86_EBX) == Temp_Mapped && !GetX86Protected(x86_EBX)) { Reg = x86_EBX; }
else if (GetX86Mapped(x86_ECX) == Temp_Mapped && !GetX86Protected(x86_ECX)) { Reg = x86_ECX; }
else if (GetX86Mapped(x86_EDX) == Temp_Mapped && !GetX86Protected(x86_EDX)) { Reg = x86_EDX; }
else if (GetX86Mapped(x86_ESI) == Temp_Mapped && !GetX86Protected(x86_ESI)) { Reg = x86_ESI; }
else if (GetX86Mapped(x86_EDI) == Temp_Mapped && !GetX86Protected(x86_EDI)) { Reg = x86_EDI; }
else if (GetX86Mapped(x86_EBP) == Temp_Mapped && !GetX86Protected(x86_EBP)) { Reg = x86_EBP; }
else if (GetX86Mapped(x86_ESP) == Temp_Mapped && !GetX86Protected(x86_ESP)) { Reg = x86_ESP; }
if (Reg == x86_Any)
{
Reg = FreeX86Reg();
if (Reg == x86_Unknown)
{
WriteTrace(TraceRegisterCache, TraceError, "Failed to find a free register");
g_Notify->BreakPoint(__FILE__, __LINE__);
return x86_Unknown;
}
}
}
else if (Reg == x86_Any8Bit)
{
if (GetX86Mapped(x86_EAX) == Temp_Mapped && !GetX86Protected(x86_EAX)) { Reg = x86_EAX; }
else if (GetX86Mapped(x86_EBX) == Temp_Mapped && !GetX86Protected(x86_EBX)) { Reg = x86_EBX; }
else if (GetX86Mapped(x86_ECX) == Temp_Mapped && !GetX86Protected(x86_ECX)) { Reg = x86_ECX; }
else if (GetX86Mapped(x86_EDX) == Temp_Mapped && !GetX86Protected(x86_EDX)) { Reg = x86_EDX; }
if (Reg == x86_Any8Bit)
{
Reg = Free8BitX86Reg();
if (Reg < 0)
{
WriteTrace(TraceRegisterCache, TraceError, "Failed to find a free 8 bit register");
g_Notify->BreakPoint(__FILE__, __LINE__);
return x86_Unknown;
}
}
}
else if (GetX86Mapped(Reg) == GPR_Mapped)
{
if (GetX86Protected(Reg))
{
WriteTrace(TraceRegisterCache, TraceError, "Register is protected");
g_Notify->BreakPoint(__FILE__, __LINE__);
return x86_Unknown;
}
SetX86Protected(Reg, true);
x86Reg NewReg = FreeX86Reg();
for (count = 1; count < 32; count++)
{
if (!IsMapped(count))
{
continue;
}
if (GetMipsRegMapLo(count) == Reg)
{
if (NewReg == x86_Unknown)
{
UnMap_GPR(count, true);
break;
}
CPU_Message(" regcache: change allocation of %s from %s to %s", CRegName::GPR[count], x86_Name(Reg), x86_Name(NewReg));
SetX86Mapped(NewReg, GPR_Mapped);
SetX86MapOrder(NewReg, GetX86MapOrder(Reg));
SetMipsRegMapLo(count, NewReg);
MoveX86RegToX86Reg(Reg, NewReg);
if (MipsReg == count && !LoadHiWord)
{
MipsReg = -1;
}
break;
}
if (Is64Bit(count) && GetMipsRegMapHi(count) == Reg)
{
if (NewReg == x86_Unknown)
{
UnMap_GPR(count, true);
break;
}
CPU_Message(" regcache: change allocation of %s from %s to %s", CRegName::GPR_Hi[count], x86_Name(Reg), x86_Name(NewReg));
SetX86Mapped(NewReg, GPR_Mapped);
SetX86MapOrder(NewReg, GetX86MapOrder(Reg));
SetMipsRegMapHi(count, NewReg);
MoveX86RegToX86Reg(Reg, NewReg);
if (MipsReg == count && LoadHiWord)
{
MipsReg = -1;
}
break;
}
}
}
else if (GetX86Mapped(Reg) == Stack_Mapped)
{
UnMap_X86reg(Reg);
}
CPU_Message(" regcache: allocate %s as temp storage", x86_Name(Reg));
if (MipsReg >= 0)
{
if (LoadHiWord)
{
if (IsUnknown(MipsReg))
{
MoveVariableToX86reg(&_GPR[MipsReg].UW[1], CRegName::GPR_Hi[MipsReg], Reg);
}
else if (IsMapped(MipsReg))
{
if (Is64Bit(MipsReg))
{
MoveX86RegToX86Reg(GetMipsRegMapHi(MipsReg), Reg);
}
else if (IsSigned(MipsReg))
{
MoveX86RegToX86Reg(GetMipsRegMapLo(MipsReg), Reg);
ShiftRightSignImmed(Reg, 31);
}
else
{
MoveConstToX86reg(0, Reg);
}
}
else
{
if (Is64Bit(MipsReg))
{
MoveConstToX86reg(GetMipsRegHi(MipsReg), Reg);
}
else
{
MoveConstToX86reg(GetMipsRegLo_S(MipsReg) >> 31, Reg);
}
}
}
else
{
if (IsUnknown(MipsReg))
{
MoveVariableToX86reg(&_GPR[MipsReg].UW[0], CRegName::GPR_Lo[MipsReg], Reg);
}
else if (IsMapped(MipsReg))
{
MoveX86RegToX86Reg(GetMipsRegMapLo(MipsReg), Reg);
}
else
{
MoveConstToX86reg(GetMipsRegLo(MipsReg), Reg);
}
}
}
SetX86Mapped(Reg, Temp_Mapped);
SetX86Protected(Reg, true);
for (count = 0; count < 10; count++)
{
int32_t MapOrder = GetX86MapOrder((x86Reg)count);
if (MapOrder > 0)
{
SetX86MapOrder((x86Reg)count, MapOrder + 1);
}
}
SetX86MapOrder(Reg, 1);
return Reg;
}
void CX86RegInfo::ProtectGPR(uint32_t Reg)
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{
if (IsUnknown(Reg) || IsConst(Reg))
{
return;
}
if (Is64Bit(Reg))
{
SetX86Protected(GetMipsRegMapHi(Reg), true);
}
SetX86Protected(GetMipsRegMapLo(Reg), true);
}
void CX86RegInfo::UnProtectGPR(uint32_t Reg)
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{
if (IsUnknown(Reg) || IsConst(Reg))
{
return;
}
if (Is64Bit(Reg))
{
SetX86Protected(GetMipsRegMapHi(Reg), false);
}
SetX86Protected(GetMipsRegMapLo(Reg), false);
}
void CX86RegInfo::ResetX86Protection()
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{
for (int32_t count = 0; count < 10; count++)
{
SetX86Protected((x86Reg)count, false);
}
}
bool CX86RegInfo::RegInStack(int32_t Reg, FPU_STATE Format)
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{
for (int32_t i = 0; i < 8; i++)
{
if (m_x86fpu_MappedTo[i] == Reg)
{
if (m_x86fpu_State[i] == Format || Format == FPU_Any)
{
return true;
}
return false;
}
}
return false;
}
void CX86RegInfo::UnMap_AllFPRs()
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{
for (;;)
{
int32_t StackPos = StackTopPos();
if (m_x86fpu_MappedTo[StackPos] != -1)
{
UnMap_FPR(m_x86fpu_MappedTo[StackPos], true);
continue;
}
//see if any more registers mapped
int32_t StartPos = StackTopPos();
for (int32_t i = 0; i < 8; i++)
{
if (m_x86fpu_MappedTo[(StartPos + i) & 7] != -1) { fpuIncStack(&StackTopPos()); }
}
if (StackPos != StackTopPos()) { continue; }
return;
}
}
void CX86RegInfo::UnMap_FPR(int32_t Reg, bool WriteBackValue)
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{
char Name[50];
int32_t i;
if (Reg < 0) { return; }
for (i = 0; i < 8; i++)
{
if (m_x86fpu_MappedTo[i] != Reg) { continue; }
CPU_Message(" regcache: unallocate %s from ST(%d)", CRegName::FPR[Reg], (i - StackTopPos() + 8) & 7);
if (WriteBackValue)
{
int32_t RegPos;
if (((i - StackTopPos() + 8) & 7) != 0)
{
if (m_x86fpu_MappedTo[StackTopPos()] == -1 && m_x86fpu_MappedTo[(StackTopPos() + 1) & 7] == Reg)
{
fpuIncStack(&StackTopPos());
}
else
{
CX86RegInfo::FPU_ROUND RoundingModel = FpuRoundingModel(StackTopPos());
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FPU_STATE RegState = m_x86fpu_State[StackTopPos()];
bool Changed = m_x86fpu_StateChanged[StackTopPos()];
uint32_t MappedTo = m_x86fpu_MappedTo[StackTopPos()];
FpuRoundingModel(StackTopPos()) = FpuRoundingModel(i);
m_x86fpu_MappedTo[StackTopPos()] = m_x86fpu_MappedTo[i];
m_x86fpu_State[StackTopPos()] = m_x86fpu_State[i];
m_x86fpu_StateChanged[StackTopPos()] = m_x86fpu_StateChanged[i];
FpuRoundingModel(i) = RoundingModel;
m_x86fpu_MappedTo[i] = MappedTo;
m_x86fpu_State[i] = RegState;
m_x86fpu_StateChanged[i] = Changed;
fpuExchange((x86FpuValues)((i - StackTopPos()) & 7));
}
}
FixRoundModel(FpuRoundingModel(i));
RegPos = StackTopPos();
x86Reg TempReg = Map_TempReg(x86_Any, -1, false);
switch (m_x86fpu_State[StackTopPos()])
{
case FPU_Dword:
sprintf(Name, "_FPR_S[%d]", m_x86fpu_MappedTo[StackTopPos()]);
MoveVariableToX86reg(&_FPR_S[m_x86fpu_MappedTo[StackTopPos()]], Name, TempReg);
fpuStoreIntegerDwordFromX86Reg(&StackTopPos(), TempReg, true);
break;
case FPU_Qword:
sprintf(Name, "_FPR_D[%d]", m_x86fpu_MappedTo[StackTopPos()]);
MoveVariableToX86reg(&_FPR_D[m_x86fpu_MappedTo[StackTopPos()]], Name, TempReg);
fpuStoreIntegerQwordFromX86Reg(&StackTopPos(), TempReg, true);
break;
case FPU_Float:
sprintf(Name, "_FPR_S[%d]", m_x86fpu_MappedTo[StackTopPos()]);
MoveVariableToX86reg(&_FPR_S[m_x86fpu_MappedTo[StackTopPos()]], Name, TempReg);
fpuStoreDwordFromX86Reg(&StackTopPos(), TempReg, true);
break;
case FPU_Double:
sprintf(Name, "_FPR_D[%d]", m_x86fpu_MappedTo[StackTopPos()]);
MoveVariableToX86reg(&_FPR_D[m_x86fpu_MappedTo[StackTopPos()]], Name, TempReg);
fpuStoreQwordFromX86Reg(&StackTopPos(), TempReg, true);
break;
default:
if (HaveDebugger())
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{
g_Notify->DisplayError(stdstr_f("%s\nUnknown format to load %d", __FUNCTION__, m_x86fpu_State[StackTopPos()]).c_str());
}
}
SetX86Protected(TempReg, false);
FpuRoundingModel(RegPos) = RoundDefault;
m_x86fpu_MappedTo[RegPos] = -1;
m_x86fpu_State[RegPos] = FPU_Unknown;
m_x86fpu_StateChanged[RegPos] = false;
}
else
{
fpuFree((x86FpuValues)((i - StackTopPos()) & 7));
FpuRoundingModel(i) = RoundDefault;
m_x86fpu_MappedTo[i] = -1;
m_x86fpu_State[i] = FPU_Unknown;
m_x86fpu_StateChanged[i] = false;
}
return;
}
}
void CX86RegInfo::UnMap_GPR(uint32_t Reg, bool WriteBackValue)
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{
if (Reg == 0)
{
if (HaveDebugger())
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{
g_Notify->DisplayError(stdstr_f("%s\n\nWhy are you trying to unmap reg 0", __FUNCTION__).c_str());
}
return;
}
if (IsUnknown(Reg)) { return; }
//CPU_Message("UnMap_GPR: State: %X\tReg: %s\tWriteBack: %s",State,CRegName::GPR[Reg],WriteBackValue?"true":"false");
if (IsConst(Reg))
{
if (!WriteBackValue)
{
SetMipsRegState(Reg, STATE_UNKNOWN);
return;
}
if (Is64Bit(Reg))
{
MoveConstToVariable(GetMipsRegHi(Reg), &_GPR[Reg].UW[1], CRegName::GPR_Hi[Reg]);
MoveConstToVariable(GetMipsRegLo(Reg), &_GPR[Reg].UW[0], CRegName::GPR_Lo[Reg]);
SetMipsRegState(Reg, STATE_UNKNOWN);
return;
}
if ((GetMipsRegLo(Reg) & 0x80000000) != 0)
{
MoveConstToVariable(0xFFFFFFFF, &_GPR[Reg].UW[1], CRegName::GPR_Hi[Reg]);
}
else
{
MoveConstToVariable(0, &_GPR[Reg].UW[1], CRegName::GPR_Hi[Reg]);
}
MoveConstToVariable(GetMipsRegLo(Reg), &_GPR[Reg].UW[0], CRegName::GPR_Lo[Reg]);
SetMipsRegState(Reg, STATE_UNKNOWN);
return;
}
if (Is64Bit(Reg))
{
CPU_Message(" regcache: unallocate %s from %s", x86_Name(GetMipsRegMapHi(Reg)), CRegName::GPR_Hi[Reg]);
SetX86Mapped(GetMipsRegMapHi(Reg), NotMapped);
SetX86Protected(GetMipsRegMapHi(Reg), false);
}
CPU_Message(" regcache: unallocate %s from %s", x86_Name(GetMipsRegMapLo(Reg)), CRegName::GPR_Lo[Reg]);
SetX86Mapped(GetMipsRegMapLo(Reg), NotMapped);
SetX86Protected(GetMipsRegMapLo(Reg), false);
if (!WriteBackValue)
{
SetMipsRegState(Reg, STATE_UNKNOWN);
return;
}
MoveX86regToVariable(GetMipsRegMapLo(Reg), &_GPR[Reg].UW[0], CRegName::GPR_Lo[Reg]);
if (Is64Bit(Reg))
{
SetMipsRegMapLo(Reg, x86_Unknown);
MoveX86regToVariable(GetMipsRegMapHi(Reg), &_GPR[Reg].UW[1], CRegName::GPR_Hi[Reg]);
SetMipsRegMapHi(Reg, x86_Unknown);
}
else
{
if (!g_System->b32BitCore())
{
if (IsSigned(Reg))
{
ShiftRightSignImmed(GetMipsRegMapLo(Reg), 31);
MoveX86regToVariable(GetMipsRegMapLo(Reg), &_GPR[Reg].UW[1], CRegName::GPR_Hi[Reg]);
}
else
{
MoveConstToVariable(0, &_GPR[Reg].UW[1], CRegName::GPR_Hi[Reg]);
}
}
SetMipsRegMapLo(Reg, x86_Unknown);
}
SetMipsRegState(Reg, STATE_UNKNOWN);
}
CX86Ops::x86Reg CX86RegInfo::UnMap_TempReg()
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{
CX86Ops::x86Reg Reg = x86_Unknown;
if (GetX86Mapped(x86_EAX) == Temp_Mapped && !GetX86Protected(x86_EAX)) { Reg = x86_EAX; }
else if (GetX86Mapped(x86_EBX) == Temp_Mapped && !GetX86Protected(x86_EBX)) { Reg = x86_EBX; }
else if (GetX86Mapped(x86_ECX) == Temp_Mapped && !GetX86Protected(x86_ECX)) { Reg = x86_ECX; }
else if (GetX86Mapped(x86_EDX) == Temp_Mapped && !GetX86Protected(x86_EDX)) { Reg = x86_EDX; }
else if (GetX86Mapped(x86_ESI) == Temp_Mapped && !GetX86Protected(x86_ESI)) { Reg = x86_ESI; }
else if (GetX86Mapped(x86_EDI) == Temp_Mapped && !GetX86Protected(x86_EDI)) { Reg = x86_EDI; }
else if (GetX86Mapped(x86_EBP) == Temp_Mapped && !GetX86Protected(x86_EBP)) { Reg = x86_EBP; }
else if (GetX86Mapped(x86_ESP) == Temp_Mapped && !GetX86Protected(x86_ESP)) { Reg = x86_ESP; }
if (Reg != x86_Unknown)
{
if (GetX86Mapped(Reg) == Temp_Mapped)
{
CPU_Message(" regcache: unallocate %s from temp storage", x86_Name(Reg));
}
SetX86Mapped(Reg, NotMapped);
}
return Reg;
}
bool CX86RegInfo::UnMap_X86reg(CX86Ops::x86Reg Reg)
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{
int32_t count;
if (GetX86Mapped(Reg) == NotMapped)
{
if (!GetX86Protected(Reg))
{
return true;
}
}
else if (GetX86Mapped(Reg) == CX86RegInfo::GPR_Mapped)
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{
for (count = 1; count < 32; count++)
{
if (!IsMapped(count))
{
continue;
}
if (Is64Bit(count) && GetMipsRegMapHi(count) == Reg)
{
if (!GetX86Protected(Reg))
{
UnMap_GPR(count, true);
return true;
}
break;
}
if (GetMipsRegMapLo(count) == Reg)
{
if (!GetX86Protected(Reg))
{
UnMap_GPR(count, true);
return true;
}
break;
}
}
}
else if (GetX86Mapped(Reg) == CX86RegInfo::Temp_Mapped)
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{
if (!GetX86Protected(Reg))
{
CPU_Message(" regcache: unallocate %s from temp storage", x86_Name(Reg));
SetX86Mapped(Reg, NotMapped);
return true;
}
}
else if (GetX86Mapped(Reg) == CX86RegInfo::Stack_Mapped)
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{
CPU_Message(" regcache: unallocate %s from Memory Stack", x86_Name(Reg));
MoveX86regToVariable(Reg, &(g_Recompiler->MemoryStackPos()), "MemoryStack");
SetX86Mapped(Reg, NotMapped);
return true;
}
return false;
}
void CX86RegInfo::WriteBackRegisters()
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{
UnMap_AllFPRs();
int32_t count;
bool bEdiZero = false;
bool bEsiSign = false;
int32_t X86RegCount = sizeof(x86_Registers) / sizeof(x86_Registers[0]);
for (int32_t i = 0; i < X86RegCount; i++) { SetX86Protected(x86_Registers[i], false); }
for (int32_t i = 0; i < X86RegCount; i++) { UnMap_X86reg(x86_Registers[i]); }
/*************************************/
for (count = 1; count < 32; count++)
{
switch (GetMipsRegState(count))
{
case CX86RegInfo::STATE_UNKNOWN: break;
case CX86RegInfo::STATE_CONST_32_SIGN:
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if (!g_System->b32BitCore())
{
if (!bEdiZero && (!GetMipsRegLo(count) || !(GetMipsRegLo(count) & 0x80000000)))
{
XorX86RegToX86Reg(x86_EDI, x86_EDI);
bEdiZero = true;
}
if (!bEsiSign && (GetMipsRegLo(count) & 0x80000000))
{
MoveConstToX86reg(0xFFFFFFFF, x86_ESI);
bEsiSign = true;
}
if ((GetMipsRegLo(count) & 0x80000000) != 0)
{
MoveX86regToVariable(x86_ESI, &_GPR[count].UW[1], CRegName::GPR_Hi[count]);
}
else
{
MoveX86regToVariable(x86_EDI, &_GPR[count].UW[1], CRegName::GPR_Hi[count]);
}
}
if (GetMipsRegLo(count) == 0)
{
if (g_System->b32BitCore())
{
if (!bEdiZero)
{
XorX86RegToX86Reg(x86_EDI, x86_EDI);
bEdiZero = true;
}
}
MoveX86regToVariable(x86_EDI, &_GPR[count].UW[0], CRegName::GPR_Lo[count]);
}
else if (GetMipsRegLo(count) == 0xFFFFFFFF)
{
if (g_System->b32BitCore())
{
if (!bEsiSign)
{
MoveConstToX86reg(0xFFFFFFFF, x86_ESI);
bEsiSign = true;
}
}
MoveX86regToVariable(x86_ESI, &_GPR[count].UW[0], CRegName::GPR_Lo[count]);
}
else
{
MoveConstToVariable(GetMipsRegLo(count), &_GPR[count].UW[0], CRegName::GPR_Lo[count]);
}
SetMipsRegState(count, CX86RegInfo::STATE_UNKNOWN);
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break;
case CX86RegInfo::STATE_CONST_32_ZERO:
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if (!g_System->b32BitCore())
{
if (!bEdiZero)
{
XorX86RegToX86Reg(x86_EDI, x86_EDI);
bEdiZero = true;
}
MoveX86regToVariable(x86_EDI, &_GPR[count].UW[1], CRegName::GPR_Hi[count]);
}
if (GetMipsRegLo(count) == 0)
{
if (g_System->b32BitCore())
{
if (!bEdiZero)
{
XorX86RegToX86Reg(x86_EDI, x86_EDI);
bEdiZero = true;
}
}
MoveX86regToVariable(x86_EDI, &_GPR[count].UW[0], CRegName::GPR_Lo[count]);
}
else
{
MoveConstToVariable(GetMipsRegLo(count), &_GPR[count].UW[0], CRegName::GPR_Lo[count]);
}
SetMipsRegState(count, CX86RegInfo::STATE_UNKNOWN);
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break;
case CX86RegInfo::STATE_CONST_64:
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if (GetMipsRegLo(count) == 0 || GetMipsRegHi(count) == 0)
{
XorX86RegToX86Reg(x86_EDI, x86_EDI);
bEdiZero = true;
}
if (GetMipsRegLo(count) == 0xFFFFFFFF || GetMipsRegHi(count) == 0xFFFFFFFF)
{
MoveConstToX86reg(0xFFFFFFFF, x86_ESI);
bEsiSign = true;
}
if (GetMipsRegHi(count) == 0)
{
MoveX86regToVariable(x86_EDI, &_GPR[count].UW[1], CRegName::GPR_Hi[count]);
}
else if (GetMipsRegLo(count) == 0xFFFFFFFF)
{
MoveX86regToVariable(x86_ESI, &_GPR[count].UW[1], CRegName::GPR_Hi[count]);
}
else
{
MoveConstToVariable(GetMipsRegHi(count), &_GPR[count].UW[1], CRegName::GPR_Hi[count]);
}
if (GetMipsRegLo(count) == 0)
{
MoveX86regToVariable(x86_EDI, &_GPR[count].UW[0], CRegName::GPR_Lo[count]);
}
else if (GetMipsRegLo(count) == 0xFFFFFFFF)
{
MoveX86regToVariable(x86_ESI, &_GPR[count].UW[0], CRegName::GPR_Lo[count]);
}
else
{
MoveConstToVariable(GetMipsRegLo(count), &_GPR[count].UW[0], CRegName::GPR_Lo[count]);
}
SetMipsRegState(count, CX86RegInfo::STATE_UNKNOWN);
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break;
default:
CPU_Message("%s: Unknown State: %d reg %d (%s)", __FUNCTION__, GetMipsRegState(count), count, CRegName::GPR[count]);
g_Notify->BreakPoint(__FILE__, __LINE__);
}
}
}
#endif