project64/Source/Project64-core/N64System/Recompiler/Arm/ArmRegInfo.old.cpp

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#include "stdafx.h"
#if defined(__arm__) || defined(_M_ARM)
#include <Project64-core/N64System/N64System.h>
#include <Project64-core/N64System/Recompiler/Arm/ArmRegInfo.h>
#include <Project64-core/N64System/Recompiler/Recompiler.h>
#include <Project64-core/N64System/SystemGlobals.h>
CArmRegInfo::CArmRegInfo(CCodeBlock & CodeBlock, CArmOps & Assembler) :
m_CodeBlock(CodeBlock),
m_Assembler(Assembler),
m_InCallDirect(false)
{
for (int32_t i = 0; i < 32; i++)
{
m_RegMapLo[i] = CArmOps::Arm_Unknown;
m_RegMapHi[i] = CArmOps::Arm_Unknown;
}
for (int32_t i = 0, n = sizeof(m_ArmReg_MappedTo) / sizeof(m_ArmReg_MappedTo[0]); i < n; i++)
{
m_ArmReg_MapOrder[i] = 0;
m_ArmReg_Protected[i] = false;
m_ArmReg_MappedTo[i] = NotMapped;
m_Variable_MappedTo[i] = VARIABLE_UNKNOWN;
}
}
CArmRegInfo::CArmRegInfo(const CArmRegInfo & rhs) :
m_CodeBlock(rhs.m_CodeBlock),
m_Assembler(rhs.m_CodeBlock.RecompilerOps()->Assembler())
{
*this = rhs;
}
CArmRegInfo::~CArmRegInfo()
{
}
CArmRegInfo & CArmRegInfo::operator=(const CArmRegInfo & right)
{
CRegBase::operator=(right);
m_InCallDirect = right.m_InCallDirect;
memcpy(&m_RegMapLo, &right.m_RegMapLo, sizeof(m_RegMapLo));
memcpy(&m_RegMapHi, &right.m_RegMapHi, sizeof(m_RegMapHi));
memcpy(&m_ArmReg_MapOrder, &right.m_ArmReg_MapOrder, sizeof(m_ArmReg_MapOrder));
memcpy(&m_ArmReg_Protected, &right.m_ArmReg_Protected, sizeof(m_ArmReg_Protected));
memcpy(&m_ArmReg_MappedTo, &right.m_ArmReg_MappedTo, sizeof(m_ArmReg_MappedTo));
memcpy(&m_Variable_MappedTo, &right.m_Variable_MappedTo, sizeof(m_Variable_MappedTo));
#ifdef _DEBUG
if (*this != right)
{
g_Notify->BreakPoint(__FILE__, __LINE__);
}
#endif
return *this;
}
bool CArmRegInfo::operator==(const CArmRegInfo & right) const
{
if (!CRegBase::operator==(right))
{
return false;
}
for (int32_t count = 0; count < 32; count++)
{
if (m_RegMapHi[count] != right.m_RegMapHi[count])
{
return false;
}
if (m_RegMapLo[count] != right.m_RegMapLo[count])
{
return false;
}
}
for (int32_t count = 0; count < 16; count++)
{
if (m_ArmReg_MapOrder[count] != right.m_ArmReg_MapOrder[count])
{
return false;
}
if (m_ArmReg_Protected[count] != right.m_ArmReg_Protected[count])
{
return false;
}
if (m_ArmReg_MappedTo[count] != right.m_ArmReg_MappedTo[count])
{
return false;
}
if (m_Variable_MappedTo[count] != right.m_Variable_MappedTo[count])
{
return false;
}
}
return true;
}
bool CArmRegInfo::ShouldPushPopReg(CArmOps::ArmReg Reg)
{
if (m_ArmReg_MappedTo[Reg] == NotMapped)
{
return false;
}
if (m_ArmReg_MappedTo[Reg] == Temp_Mapped && !GetArmRegProtected(Reg))
{
return false;
}
return true;
}
void CArmRegInfo::BeforeCallDirect(void)
{
static uint32_t PushPopRegisterList[] = {
CArmOps::ArmPushPop_R0,
CArmOps::ArmPushPop_R1,
CArmOps::ArmPushPop_R2,
CArmOps::ArmPushPop_R3,
CArmOps::ArmPushPop_R4,
CArmOps::ArmPushPop_R5,
CArmOps::ArmPushPop_R6,
CArmOps::ArmPushPop_R7,
CArmOps::ArmPushPop_R8,
CArmOps::ArmPushPop_R9,
CArmOps::ArmPushPop_R10,
CArmOps::ArmPushPop_R11,
CArmOps::ArmPushPop_R12,
};
static CArmOps::ArmReg RegisterList[] = {
CArmOps::Arm_R0,
CArmOps::Arm_R1,
CArmOps::Arm_R2,
CArmOps::Arm_R3,
CArmOps::Arm_R4,
CArmOps::Arm_R5,
CArmOps::Arm_R6,
CArmOps::Arm_R7,
CArmOps::Arm_R8,
CArmOps::Arm_R9,
CArmOps::Arm_R10,
CArmOps::Arm_R11,
CArmOps::Arm_R12,
};
if (m_InCallDirect)
{
m_CodeBlock.Log("%s: in CallDirect", __FUNCTION__);
g_Notify->BreakPoint(__FILE__, __LINE__);
return;
}
UnMap_AllFPRs();
int PushPopRegisters = 0;
for (int i = 0; i < (sizeof(RegisterList) / sizeof(RegisterList[0])); i++)
{
if (ShouldPushPopReg(RegisterList[i]))
{
PushPopRegisters |= PushPopRegisterList[i];
}
}
if (PushPopRegisters == 0)
{
m_InCallDirect = true;
return;
}
if ((m_Assembler.PushPopRegisterSize(PushPopRegisters) % 8) != 0)
{
bool Added = false;
for (int i = 0; i < (sizeof(RegisterList) / sizeof(RegisterList[0])); i++)
{
if (ShouldPushPopReg(RegisterList[i]))
{
continue;
}
PushPopRegisters |= PushPopRegisterList[i];
Added = true;
break;
}
if (!Added)
{
CArmOps::ArmReg reg = FreeArmReg(false);
m_CodeBlock.Log(" Freed %s", m_Assembler.ArmRegName(reg));
PushPopRegisters = 0;
for (int i = 0; i < (sizeof(RegisterList) / sizeof(RegisterList[0])); i++)
{
if (ShouldPushPopReg(RegisterList[i]))
{
PushPopRegisters |= PushPopRegisterList[i];
}
}
}
if ((m_Assembler.PushPopRegisterSize(PushPopRegisters) % 8) != 0)
{
g_Notify->BreakPoint(__FILE__, __LINE__);
}
}
m_InCallDirect = true;
m_Assembler.PushArmReg(PushPopRegisters);
}
void CArmRegInfo::AfterCallDirect(void)
{
static uint32_t PushPopRegisterList[] = {
CArmOps::ArmPushPop_R0,
CArmOps::ArmPushPop_R1,
CArmOps::ArmPushPop_R2,
CArmOps::ArmPushPop_R3,
CArmOps::ArmPushPop_R4,
CArmOps::ArmPushPop_R5,
CArmOps::ArmPushPop_R6,
CArmOps::ArmPushPop_R7,
CArmOps::ArmPushPop_R8,
CArmOps::ArmPushPop_R9,
CArmOps::ArmPushPop_R10,
CArmOps::ArmPushPop_R11,
CArmOps::ArmPushPop_R12,
CArmOps::ArmPushPop_LR,
CArmOps::ArmPushPop_PC,
};
static CArmOps::ArmReg RegisterList[] = {
CArmOps::Arm_R0,
CArmOps::Arm_R1,
CArmOps::Arm_R2,
CArmOps::Arm_R3,
CArmOps::Arm_R4,
CArmOps::Arm_R5,
CArmOps::Arm_R6,
CArmOps::Arm_R7,
CArmOps::Arm_R8,
CArmOps::Arm_R9,
CArmOps::Arm_R10,
CArmOps::Arm_R11,
CArmOps::Arm_R12,
CArmOps::ArmRegLR,
CArmOps::ArmRegPC,
};
if (!m_InCallDirect)
{
m_CodeBlock.Log("%s: Not in CallDirect", __FUNCTION__);
g_Notify->BreakPoint(__FILE__, __LINE__);
return;
}
int PushPopRegisters = 0;
for (int i = 0; i < (sizeof(RegisterList) / sizeof(RegisterList[0])); i++)
{
if (ShouldPushPopReg(RegisterList[i]))
{
PushPopRegisters |= PushPopRegisterList[i];
}
}
if (PushPopRegisters != 0)
{
if ((m_Assembler.PushPopRegisterSize(PushPopRegisters) % 8) != 0)
{
for (int i = 0; i < (sizeof(RegisterList) / sizeof(RegisterList[0])); i++)
{
if (ShouldPushPopReg(RegisterList[i]))
{
continue;
}
PushPopRegisters |= PushPopRegisterList[i];
break;
}
}
m_Assembler.PopArmReg(PushPopRegisters);
}
SetRoundingModel(CRegInfo::RoundUnknown);
m_InCallDirect = false;
}
void CArmRegInfo::FixRoundModel(FPU_ROUND RoundMethod)
{
if (m_InCallDirect)
{
m_CodeBlock.Log("%s: in CallDirect", __FUNCTION__);
g_Notify->BreakPoint(__FILE__, __LINE__);
return;
}
if (GetRoundingModel() == RoundMethod)
{
return;
}
m_CodeBlock.Log(" FixRoundModel: CurrentRoundingModel: %s targetRoundModel: %s", RoundingModelName(GetRoundingModel()), RoundingModelName(RoundMethod));
if (RoundMethod == RoundDefault)
{
BeforeCallDirect();
m_Assembler.MoveVariableToArmReg(_RoundingModel, "_RoundingModel", CArmOps::Arm_R0);
m_Assembler.CallFunction((void *)fesetround, "fesetround");
AfterCallDirect();
}
else
{
g_Notify->BreakPoint(__FILE__, __LINE__);
}
}
void CArmRegInfo::Map_GPR_32bit(int32_t MipsReg, bool SignValue, int32_t MipsRegToLoad)
{
if (m_InCallDirect)
{
m_CodeBlock.Log("%s: in CallDirect", __FUNCTION__);
g_Notify->BreakPoint(__FILE__, __LINE__);
return;
}
CArmOps::ArmReg Reg;
if (MipsReg == 0)
{
g_Notify->BreakPoint(__FILE__, __LINE__);
return;
}
if (IsUnknown(MipsReg) || IsConst(MipsReg))
{
Reg = FreeArmReg(false);
if (Reg < 0)
{
if (HaveDebugger())
{
g_Notify->DisplayError("Map_GPR_32bit\n\nOut of registers");
}
g_Notify->BreakPoint(__FILE__, __LINE__);
return;
}
SetArmRegProtected(Reg, true);
m_CodeBlock.Log(" regcache: allocate %s to %s", m_Assembler.ArmRegName(Reg), CRegName::GPR[MipsReg]);
}
else
{
if (Is64Bit(MipsReg))
{
m_CodeBlock.Log(" regcache: unallocate %s from high 32-bit of %s", m_Assembler.ArmRegName(GetMipsRegMapHi(MipsReg)), CRegName::GPR_Hi[MipsReg]);
SetArmRegMapOrder(GetMipsRegMapHi(MipsReg), 0);
SetArmRegMapped(GetMipsRegMapHi(MipsReg), NotMapped);
SetArmRegProtected(GetMipsRegMapHi(MipsReg), false);
SetMipsRegHi(MipsReg, 0);
}
Reg = GetMipsRegMapLo(MipsReg);
}
for (int32_t count = 0; count <= CArmOps::Arm_R15; count++)
{
uint32_t Count = GetArmRegMapOrder((CArmOps::ArmReg)count);
if (Count > 0)
{
SetArmRegMapOrder((CArmOps::ArmReg)count, Count + 1);
}
}
SetArmRegMapOrder(Reg, 1);
if (MipsRegToLoad > 0)
{
if (IsUnknown(MipsRegToLoad))
{
CArmOps::ArmReg GprReg = Map_Variable(VARIABLE_GPR);
m_Assembler.LoadArmRegPointerToArmReg(Reg, GprReg, (uint8_t)(MipsRegToLoad << 3), CRegName::GPR_Lo[MipsRegToLoad]);
SetArmRegProtected(GprReg, false);
}
else if (IsMapped(MipsRegToLoad))
{
if (MipsReg != MipsRegToLoad)
{
m_Assembler.AddConstToArmReg(Reg, GetMipsRegMapLo(MipsRegToLoad), 0);
}
}
else
{
m_Assembler.MoveConstToArmReg(Reg, GetMipsRegLo(MipsRegToLoad));
}
}
else if (MipsRegToLoad == 0)
{
m_Assembler.MoveConstToArmReg(Reg, (uint32_t)0);
}
SetArmRegMapped(Reg, GPR_Mapped);
SetArmRegProtected(Reg, true);
SetMipsRegMapLo(MipsReg, Reg);
SetMipsRegState(MipsReg, SignValue ? STATE_MAPPED_32_SIGN : STATE_MAPPED_32_ZERO);
}
void CArmRegInfo::Map_GPR_64bit(int32_t MipsReg, int32_t MipsRegToLoad)
{
if (m_InCallDirect)
{
m_CodeBlock.Log("%s: in CallDirect", __FUNCTION__);
g_Notify->BreakPoint(__FILE__, __LINE__);
return;
}
CArmOps::ArmReg regHi, reglo;
int32_t count;
if (MipsReg == 0)
{
if (HaveDebugger())
{
g_Notify->DisplayError("Map_GPR_64bit\n\nWhy are you trying to map register 0?");
}
g_Notify->BreakPoint(__FILE__, __LINE__);
return;
}
ProtectGPR(MipsReg);
if (IsUnknown(MipsReg) || IsConst(MipsReg))
{
regHi = FreeArmReg(false);
if (regHi < 0)
{
if (HaveDebugger())
{
g_Notify->DisplayError("Map_GPR_64bit\n\nOut of registers");
}
g_Notify->BreakPoint(__FILE__, __LINE__);
return;
}
SetArmRegProtected(regHi, true);
reglo = FreeArmReg(false);
if (reglo < 0)
{
if (HaveDebugger())
{
g_Notify->DisplayError("Map_GPR_64bit\n\nOut of registers");
}
g_Notify->BreakPoint(__FILE__, __LINE__);
return;
}
SetArmRegProtected(reglo, true);
m_CodeBlock.Log(" regcache: allocate %s to hi word of %s", m_Assembler.ArmRegName(regHi), CRegName::GPR[MipsReg]);
m_CodeBlock.Log(" regcache: allocate %s to low word of %s", m_Assembler.ArmRegName(reglo), CRegName::GPR[MipsReg]);
}
else
{
reglo = GetMipsRegMapLo(MipsReg);
if (Is32Bit(MipsReg))
{
SetArmRegProtected(reglo, true);
regHi = FreeArmReg(false);
if (regHi < 0)
{
if (HaveDebugger())
{
g_Notify->DisplayError("Map_GPR_64bit\n\nOut of registers");
}
g_Notify->BreakPoint(__FILE__, __LINE__);
return;
}
SetArmRegProtected(regHi, true);
m_CodeBlock.Log(" regcache: allocate %s to hi word of %s", m_Assembler.ArmRegName(regHi), CRegName::GPR[MipsReg]);
}
else
{
regHi = GetMipsRegMapHi(MipsReg);
}
}
for (int32_t count = 0; count <= CArmOps::Arm_R15; count++)
{
uint32_t Count = GetArmRegMapOrder((CArmOps::ArmReg)count);
if (Count > 0)
{
SetArmRegMapOrder((CArmOps::ArmReg)count, Count + 1);
}
}
SetArmRegMapOrder(regHi, 1);
SetArmRegMapOrder(reglo, 1);
if (MipsRegToLoad > 0)
{
if (IsUnknown(MipsRegToLoad))
{
CArmOps::ArmReg GprReg = Map_Variable(VARIABLE_GPR);
m_Assembler.LoadArmRegPointerToArmReg(regHi, GprReg, (uint8_t)(MipsRegToLoad << 3) + 4, CRegName::GPR_Hi[MipsRegToLoad]);
m_Assembler.LoadArmRegPointerToArmReg(reglo, GprReg, (uint8_t)(MipsRegToLoad << 3), CRegName::GPR_Lo[MipsRegToLoad]);
SetArmRegProtected(GprReg, false);
}
else if (IsMapped(MipsRegToLoad))
{
if (Is32Bit(MipsRegToLoad))
{
if (IsSigned(MipsRegToLoad))
{
m_Assembler.ShiftRightSignImmed(regHi, GetMipsRegMapLo(MipsRegToLoad), 31);
}
else
{
m_Assembler.MoveConstToArmReg(regHi, (uint32_t)0);
}
if (MipsReg != MipsRegToLoad)
{
m_Assembler.AddConstToArmReg(reglo, GetMipsRegMapLo(MipsRegToLoad), 0);
}
}
else if (MipsReg != MipsRegToLoad)
{
m_Assembler.AddConstToArmReg(regHi, GetMipsRegMapHi(MipsRegToLoad), 0);
m_Assembler.AddConstToArmReg(reglo, GetMipsRegMapLo(MipsRegToLoad), 0);
}
}
else
{
if (Is32Bit(MipsRegToLoad))
{
m_Assembler.MoveConstToArmReg(regHi, (uint32_t)(IsSigned(MipsRegToLoad) ? GetMipsRegLo_S(MipsRegToLoad) >> 31 : 0));
}
else
{
m_Assembler.MoveConstToArmReg(regHi, GetMipsRegHi(MipsRegToLoad));
}
m_Assembler.MoveConstToArmReg(reglo, GetMipsRegLo(MipsRegToLoad));
}
}
else if (MipsRegToLoad == 0)
{
m_Assembler.MoveConstToArmReg(regHi, (uint32_t)0);
m_Assembler.MoveConstToArmReg(reglo, (uint32_t)0);
}
SetArmRegMapped(regHi, GPR_Mapped);
SetArmRegMapped(reglo, GPR_Mapped);
SetArmRegProtected(regHi, true);
SetArmRegProtected(reglo, true);
SetMipsRegMapHi(MipsReg, regHi);
SetMipsRegMapLo(MipsReg, reglo);
SetMipsRegState(MipsReg, STATE_MAPPED_64);
}
void CArmRegInfo::UnMap_GPR(uint32_t MipsReg, bool WriteBackValue)
{
if (m_InCallDirect)
{
m_CodeBlock.Log("%s: in CallDirect", __FUNCTION__);
g_Notify->BreakPoint(__FILE__, __LINE__);
return;
}
if (WriteBackValue)
{
WriteBack_GPR(MipsReg, true);
}
if (MipsReg == 0)
{
if (HaveDebugger())
{
g_Notify->DisplayError(stdstr_f("%s\n\nWhy are you trying to unmap register 0?", __FUNCTION__).c_str());
}
return;
}
if (IsUnknown(MipsReg))
{
return;
}
//m_CodeBlock.Log("UnMap_GPR: State: %X\tReg: %s\tWriteBack: %s",State,CRegName::GPR[Reg],WriteBackValue?"true":"false");
if (IsConst(MipsReg))
{
SetMipsRegState(MipsReg, STATE_UNKNOWN);
return;
}
if (Is64Bit(MipsReg))
{
m_CodeBlock.Log(" regcache: unallocate %s from %s", m_Assembler.ArmRegName(GetMipsRegMapHi(MipsReg)), CRegName::GPR_Hi[MipsReg]);
SetArmRegMapped(GetMipsRegMapHi(MipsReg), NotMapped);
SetArmRegProtected(GetMipsRegMapHi(MipsReg), false);
}
m_CodeBlock.Log(" regcache: unallocate %s from %s", m_Assembler.ArmRegName(GetMipsRegMapLo(MipsReg)), CRegName::GPR_Lo[MipsReg]);
SetArmRegMapped(GetMipsRegMapLo(MipsReg), NotMapped);
SetArmRegProtected(GetMipsRegMapLo(MipsReg), false);
SetMipsRegState(MipsReg, STATE_UNKNOWN);
}
void CArmRegInfo::WriteBack_GPR(uint32_t MipsReg, bool Unmapping)
{
if (m_InCallDirect)
{
m_CodeBlock.Log("%s: in CallDirect", __FUNCTION__);
g_Notify->BreakPoint(__FILE__, __LINE__);
return;
}
if (MipsReg == 0)
{
if (HaveDebugger())
{
g_Notify->DisplayError(stdstr_f("%s\n\nWhy are you trying to unmap register 0?", __FUNCTION__).c_str());
}
return;
}
if (IsUnknown(MipsReg))
{
return;
}
CArmOps::ArmReg GprReg = Map_Variable(VARIABLE_GPR);
if (IsConst(MipsReg))
{
CArmOps::ArmReg TempReg = Map_TempReg(CArmOps::Arm_Any, -1, false);
if (Is64Bit(MipsReg))
{
m_Assembler.MoveConstToArmReg(TempReg, GetMipsRegHi(MipsReg));
m_Assembler.StoreArmRegToArmRegPointer(TempReg, GprReg, (uint8_t)(MipsReg << 3) + 4, CRegName::GPR_Hi[MipsReg]);
}
else if (!g_System->b32BitCore())
{
m_Assembler.MoveConstToArmReg(TempReg, (GetMipsRegLo(MipsReg) & 0x80000000) != 0 ? 0xFFFFFFFF : 0);
m_Assembler.StoreArmRegToArmRegPointer(TempReg, GprReg, (uint8_t)(MipsReg << 3) + 4, CRegName::GPR_Hi[MipsReg]);
}
m_Assembler.MoveConstToArmReg(TempReg, GetMipsRegLo(MipsReg));
m_Assembler.StoreArmRegToArmRegPointer(TempReg, GprReg, (uint8_t)(MipsReg << 3), CRegName::GPR_Lo[MipsReg]);
SetArmRegProtected(TempReg, false);
}
else
{
m_Assembler.StoreArmRegToArmRegPointer(GetMipsRegMapLo(MipsReg), GprReg, (uint8_t)(MipsReg << 3), CRegName::GPR_Lo[MipsReg]);
if (Is64Bit(MipsReg))
{
m_Assembler.StoreArmRegToArmRegPointer(GetMipsRegMapHi(MipsReg), GprReg, (uint8_t)(MipsReg << 3) + 4, CRegName::GPR_Hi[MipsReg]);
}
else if (!g_System->b32BitCore())
{
bool loProtected = GetArmRegProtected(GetMipsRegMapLo(MipsReg));
if (!Unmapping)
{
SetArmRegProtected(GetMipsRegMapLo(MipsReg), true);
CArmOps::ArmReg TempReg = Map_TempReg(CArmOps::Arm_Any, -1, false);
if (IsSigned(MipsReg))
{
m_Assembler.ShiftRightSignImmed(TempReg, GetMipsRegMapLo(MipsReg), 31);
}
else
{
m_Assembler.MoveConstToArmReg(TempReg, (uint32_t)0);
}
m_Assembler.StoreArmRegToArmRegPointer(TempReg, GprReg, (uint8_t)(MipsReg << 3) + 4, CRegName::GPR_Hi[MipsReg]);
SetArmRegProtected(TempReg, false);
}
else
{
m_Assembler.ShiftRightSignImmed(GetMipsRegMapLo(MipsReg), GetMipsRegMapLo(MipsReg), 31);
m_Assembler.StoreArmRegToArmRegPointer(GetMipsRegMapLo(MipsReg), GprReg, (uint8_t)(MipsReg << 3) + 4, CRegName::GPR_Hi[MipsReg]);
}
SetArmRegProtected(GetMipsRegMapLo(MipsReg), loProtected);
}
}
SetArmRegProtected(GprReg, false);
}
void CArmRegInfo::WriteBackRegisters()
{
if (m_InCallDirect)
{
m_CodeBlock.Log("%s: in CallDirect", __FUNCTION__);
g_Notify->BreakPoint(__FILE__, __LINE__);
return;
}
UnMap_AllFPRs();
int32_t ArmRegCount = sizeof(m_ArmReg_MappedTo) / sizeof(m_ArmReg_MappedTo[0]);
for (int32_t i = 1; i < 32; i++)
{
UnMap_GPR(i, true);
}
for (int32_t i = 0; i < ArmRegCount; i++)
{
UnMap_ArmReg((CArmOps::ArmReg)i);
}
for (int32_t i = 0; i < ArmRegCount; i++)
{
SetArmRegProtected((CArmOps::ArmReg)i, false);
}
for (int32_t count = 1; count < 32; count++)
{
switch (GetMipsRegState(count))
{
case STATE_UNKNOWN: break;
case STATE_CONST_32_SIGN:
g_Notify->BreakPoint(__FILE__, __LINE__);
break;
case STATE_CONST_32_ZERO:
g_Notify->BreakPoint(__FILE__, __LINE__);
break;
case STATE_CONST_64:
g_Notify->BreakPoint(__FILE__, __LINE__);
break;
default:
m_CodeBlock.Log("%s: Unknown state: %d reg %d (%s)", __FUNCTION__, GetMipsRegState(count), count, CRegName::GPR[count]);
g_Notify->BreakPoint(__FILE__, __LINE__);
}
}
}
void CArmRegInfo::UnMap_AllFPRs()
{
if (m_InCallDirect)
{
m_CodeBlock.Log("%s: in CallDirect", __FUNCTION__);
g_Notify->BreakPoint(__FILE__, __LINE__);
return;
}
m_CodeBlock.Log("%s", __FUNCTION__);
}
CArmOps::ArmReg CArmRegInfo::UnMap_TempReg(bool TempMapping)
{
if (m_InCallDirect)
{
m_CodeBlock.Log("%s: in CallDirect", __FUNCTION__);
g_Notify->BreakPoint(__FILE__, __LINE__);
return CArmOps::Arm_Unknown;
}
CArmOps::ArmReg Reg = CArmOps::Arm_Unknown;
if (GetArmRegMapped(CArmOps::Arm_R7) == Temp_Mapped && !GetArmRegProtected(CArmOps::Arm_R7))
{
return CArmOps::Arm_R7;
}
if (GetArmRegMapped(CArmOps::Arm_R6) == Temp_Mapped && !GetArmRegProtected(CArmOps::Arm_R6))
{
return CArmOps::Arm_R6;
}
if (GetArmRegMapped(CArmOps::Arm_R5) == Temp_Mapped && !GetArmRegProtected(CArmOps::Arm_R5))
{
return CArmOps::Arm_R5;
}
if (GetArmRegMapped(CArmOps::Arm_R4) == Temp_Mapped && !GetArmRegProtected(CArmOps::Arm_R4))
{
return CArmOps::Arm_R4;
}
if (GetArmRegMapped(CArmOps::Arm_R3) == Temp_Mapped && !GetArmRegProtected(CArmOps::Arm_R3))
{
return CArmOps::Arm_R3;
}
if (GetArmRegMapped(CArmOps::Arm_R2) == Temp_Mapped && !GetArmRegProtected(CArmOps::Arm_R2))
{
return CArmOps::Arm_R2;
}
if (GetArmRegMapped(CArmOps::Arm_R1) == Temp_Mapped && !GetArmRegProtected(CArmOps::Arm_R1))
{
return CArmOps::Arm_R1;
}
if (GetArmRegMapped(CArmOps::Arm_R0) == Temp_Mapped && !GetArmRegProtected(CArmOps::Arm_R0))
{
return CArmOps::Arm_R0;
}
if (TempMapping)
{
if (GetArmRegMapped(CArmOps::Arm_R11) == Temp_Mapped && !GetArmRegProtected(CArmOps::Arm_R11))
{
return CArmOps::Arm_R11;
}
if (GetArmRegMapped(CArmOps::Arm_R10) == Temp_Mapped && !GetArmRegProtected(CArmOps::Arm_R10))
{
return CArmOps::Arm_R10;
}
}
if (GetArmRegMapped(CArmOps::Arm_R9) == Temp_Mapped && !GetArmRegProtected(CArmOps::Arm_R9))
{
return CArmOps::Arm_R9;
}
if (GetArmRegMapped(CArmOps::Arm_R8) == Temp_Mapped && !GetArmRegProtected(CArmOps::Arm_R8))
{
return CArmOps::Arm_R8;
}
if (Reg != CArmOps::Arm_Unknown)
{
if (GetArmRegMapped(Reg) == Temp_Mapped)
{
m_CodeBlock.Log(" regcache: unallocate %s from temp storage", m_Assembler.ArmRegName(Reg));
}
SetArmRegMapped(Reg, NotMapped);
}
return Reg;
}
bool CArmRegInfo::UnMap_ArmReg(CArmOps::ArmReg Reg)
{
if (m_InCallDirect)
{
m_CodeBlock.Log("%s: in CallDirect", __FUNCTION__);
g_Notify->BreakPoint(__FILE__, __LINE__);
return false;
}
if (GetArmRegProtected(Reg))
{
m_CodeBlock.Log("%s: %s is protected", __FUNCTION__, m_Assembler.ArmRegName(Reg));
g_Notify->BreakPoint(__FILE__, __LINE__);
return false;
}
if (GetArmRegMapped(Reg) == NotMapped)
{
return true;
}
else if (GetArmRegMapped(Reg) == GPR_Mapped)
{
for (uint32_t count = 1; count < 32; count++)
{
if (!IsMapped(count))
{
continue;
}
if (Is64Bit(count) && GetMipsRegMapHi(count) == Reg)
{
if (!GetArmRegProtected(Reg))
{
UnMap_GPR(count, true);
return true;
}
break;
}
if (GetMipsRegMapLo(count) == Reg)
{
if (!GetArmRegProtected(Reg))
{
UnMap_GPR(count, true);
return true;
}
break;
}
}
g_Notify->BreakPoint(__FILE__, __LINE__);
}
else if (GetArmRegMapped(Reg) == Temp_Mapped)
{
m_CodeBlock.Log(" regcache: unallocate %s from temporary storage", m_Assembler.ArmRegName(Reg));
SetArmRegMapped(Reg, NotMapped);
return true;
}
else if (GetArmRegMapped(Reg) == Variable_Mapped)
{
m_CodeBlock.Log(" regcache: unallocate %s from variable mapping (%s)", m_Assembler.ArmRegName(Reg), VariableMapName(GetVariableMappedTo(Reg)));
SetArmRegMapped(Reg, NotMapped);
m_Variable_MappedTo[Reg] = VARIABLE_UNKNOWN;
return true;
}
g_Notify->BreakPoint(__FILE__, __LINE__);
return false;
}
void CArmRegInfo::ResetRegProtection()
{
if (m_InCallDirect)
{
m_CodeBlock.Log("%s: in CallDirect", __FUNCTION__);
g_Notify->BreakPoint(__FILE__, __LINE__);
return;
}
for (uint32_t i = 0, n = sizeof(m_ArmReg_Protected) / sizeof(m_ArmReg_Protected[0]); i < n; i++)
{
SetArmRegProtected((CArmOps::ArmReg)i, false);
}
}
CArmOps::ArmReg CArmRegInfo::FreeArmReg(bool TempMapping)
{
if (m_InCallDirect)
{
m_CodeBlock.Log("%s: in CallDirect", __FUNCTION__);
g_Notify->BreakPoint(__FILE__, __LINE__);
return CArmOps::Arm_Unknown;
}
if ((GetArmRegMapped(CArmOps::Arm_R7) == NotMapped || GetArmRegMapped(CArmOps::Arm_R7) == Temp_Mapped) && !GetArmRegProtected(CArmOps::Arm_R7))
{
return CArmOps::Arm_R7;
}
if ((GetArmRegMapped(CArmOps::Arm_R6) == NotMapped || GetArmRegMapped(CArmOps::Arm_R6) == Temp_Mapped) && !GetArmRegProtected(CArmOps::Arm_R6))
{
return CArmOps::Arm_R6;
}
if ((GetArmRegMapped(CArmOps::Arm_R5) == NotMapped || GetArmRegMapped(CArmOps::Arm_R5) == Temp_Mapped) && !GetArmRegProtected(CArmOps::Arm_R5))
{
return CArmOps::Arm_R5;
}
if ((GetArmRegMapped(CArmOps::Arm_R4) == NotMapped || GetArmRegMapped(CArmOps::Arm_R4) == Temp_Mapped) && !GetArmRegProtected(CArmOps::Arm_R4))
{
return CArmOps::Arm_R4;
}
if ((GetArmRegMapped(CArmOps::Arm_R3) == NotMapped || GetArmRegMapped(CArmOps::Arm_R3) == Temp_Mapped) && !GetArmRegProtected(CArmOps::Arm_R3))
{
return CArmOps::Arm_R3;
}
if ((GetArmRegMapped(CArmOps::Arm_R2) == NotMapped || GetArmRegMapped(CArmOps::Arm_R2) == Temp_Mapped) && !GetArmRegProtected(CArmOps::Arm_R2))
{
return CArmOps::Arm_R2;
}
if ((GetArmRegMapped(CArmOps::Arm_R1) == NotMapped || GetArmRegMapped(CArmOps::Arm_R1) == Temp_Mapped) && !GetArmRegProtected(CArmOps::Arm_R1))
{
return CArmOps::Arm_R1;
}
if ((GetArmRegMapped(CArmOps::Arm_R0) == NotMapped || GetArmRegMapped(CArmOps::Arm_R0) == Temp_Mapped) && !GetArmRegProtected(CArmOps::Arm_R0))
{
return CArmOps::Arm_R0;
}
if (TempMapping)
{
if ((GetArmRegMapped(CArmOps::Arm_R11) == NotMapped || GetArmRegMapped(CArmOps::Arm_R11) == Temp_Mapped) && !GetArmRegProtected(CArmOps::Arm_R11))
{
return CArmOps::Arm_R11;
}
if ((GetArmRegMapped(CArmOps::Arm_R10) == NotMapped || GetArmRegMapped(CArmOps::Arm_R10) == Temp_Mapped) && !GetArmRegProtected(CArmOps::Arm_R10))
{
return CArmOps::Arm_R10;
}
}
if ((GetArmRegMapped(CArmOps::Arm_R9) == NotMapped || GetArmRegMapped(CArmOps::Arm_R9) == Temp_Mapped) && !GetArmRegProtected(CArmOps::Arm_R9))
{
return CArmOps::Arm_R9;
}
if ((GetArmRegMapped(CArmOps::Arm_R8) == NotMapped || GetArmRegMapped(CArmOps::Arm_R8) == Temp_Mapped) && !GetArmRegProtected(CArmOps::Arm_R8))
{
return CArmOps::Arm_R8;
}
CArmOps::ArmReg Reg = UnMap_TempReg(TempMapping);
if (Reg != CArmOps::Arm_Unknown)
{
return Reg;
}
int32_t MapCount[CArmOps::Arm_R12];
CArmOps::ArmReg MapReg[CArmOps::Arm_R12];
for (int32_t i = 0, n = TempMapping ? CArmOps::Arm_R12 : CArmOps::Arm_R10; i < n; i++)
{
MapCount[i] = GetArmRegMapOrder((CArmOps::ArmReg)i);
MapReg[i] = (CArmOps::ArmReg)i;
}
for (int32_t i = 0, n = TempMapping ? CArmOps::Arm_R12 : CArmOps::Arm_R10; i < n; i++)
{
bool changed = false;
for (int32_t z = 0; z < n - 1; z++)
{
if (MapCount[z] >= MapCount[z + 1])
{
continue;
}
uint32_t temp = MapCount[z];
MapCount[z] = MapCount[z + 1];
MapCount[z + 1] = temp;
CArmOps::ArmReg tempReg = MapReg[z];
MapReg[z] = MapReg[z + 1];
MapReg[z + 1] = tempReg;
changed = true;
}
if (!changed)
{
break;
}
}
for (int32_t i = 0, n = TempMapping ? CArmOps::Arm_R12 : CArmOps::Arm_R10; i < n; i++)
{
if (((MapCount[i] > 0 && GetArmRegMapped(MapReg[i]) == GPR_Mapped) || GetArmRegMapped(MapReg[i]) == Variable_Mapped) && !GetArmRegProtected((CArmOps::ArmReg)MapReg[i]))
{
if (UnMap_ArmReg((CArmOps::ArmReg)MapReg[i]))
{
return (CArmOps::ArmReg)MapReg[i];
}
}
}
LogRegisterState();
g_Notify->BreakPoint(__FILE__, __LINE__);
return CArmOps::Arm_Unknown;
}
void CArmRegInfo::LogRegisterState(void)
{
if (!CDebugSettings::bRecordRecompilerAsm())
{
return;
}
for (uint32_t i = 0; i < 16; i++)
{
stdstr regname;
if (GetArmRegMapped((CArmOps::ArmReg)i) == CArmRegInfo::GPR_Mapped)
{
for (uint32_t count = 1; count < 32; count++)
{
if (!IsMapped(count))
{
continue;
}
if (Is64Bit(count) && GetMipsRegMapHi(count) == (CArmOps::ArmReg)i)
{
regname = CRegName::GPR_Hi[count];
break;
}
if (GetMipsRegMapLo(count) == (CArmOps::ArmReg)i)
{
regname = CRegName::GPR_Lo[count];
break;
}
}
}
m_CodeBlock.Log("GetArmRegMapped(%s) = %X%s%s Protected: %s MapOrder: %d",
m_Assembler.ArmRegName((CArmOps::ArmReg)i),
GetArmRegMapped((CArmOps::ArmReg)i),
GetArmRegMapped((CArmOps::ArmReg)i) == CArmRegInfo::Variable_Mapped ? stdstr_f(" (%s)", CArmRegInfo::VariableMapName(GetVariableMappedTo((CArmOps::ArmReg)i))).c_str() : "",
regname.length() > 0 ? stdstr_f(" (%s)", regname.c_str()).c_str() : "",
GetArmRegProtected((CArmOps::ArmReg)i) ? "true" : "false",
GetArmRegMapOrder((CArmOps::ArmReg)i));
}
}
CArmOps::ArmReg CArmRegInfo::Map_TempReg(CArmOps::ArmReg Reg, int32_t MipsReg, bool LoadHiWord)
{
if (m_InCallDirect)
{
m_CodeBlock.Log("%s: in CallDirect", __FUNCTION__);
g_Notify->BreakPoint(__FILE__, __LINE__);
return CArmOps::Arm_Unknown;
}
CArmOps::ArmReg GprReg = MipsReg >= 0 ? Map_Variable(VARIABLE_GPR) : CArmOps::Arm_Unknown;
if (Reg == CArmOps::Arm_Any)
{
if (GetArmRegMapped(CArmOps::Arm_R7) == Temp_Mapped && !GetArmRegProtected(CArmOps::Arm_R7))
{
Reg = CArmOps::Arm_R7;
}
else if (GetArmRegMapped(CArmOps::Arm_R6) == Temp_Mapped && !GetArmRegProtected(CArmOps::Arm_R6))
{
Reg = CArmOps::Arm_R6;
}
else if (GetArmRegMapped(CArmOps::Arm_R5) == Temp_Mapped && !GetArmRegProtected(CArmOps::Arm_R5))
{
Reg = CArmOps::Arm_R5;
}
else if (GetArmRegMapped(CArmOps::Arm_R4) == Temp_Mapped && !GetArmRegProtected(CArmOps::Arm_R4))
{
Reg = CArmOps::Arm_R4;
}
else if (GetArmRegMapped(CArmOps::Arm_R3) == Temp_Mapped && !GetArmRegProtected(CArmOps::Arm_R3))
{
Reg = CArmOps::Arm_R3;
}
else if (GetArmRegMapped(CArmOps::Arm_R2) == Temp_Mapped && !GetArmRegProtected(CArmOps::Arm_R2))
{
Reg = CArmOps::Arm_R2;
}
else if (GetArmRegMapped(CArmOps::Arm_R1) == Temp_Mapped && !GetArmRegProtected(CArmOps::Arm_R1))
{
Reg = CArmOps::Arm_R1;
}
else if (GetArmRegMapped(CArmOps::Arm_R0) == Temp_Mapped && !GetArmRegProtected(CArmOps::Arm_R0))
{
Reg = CArmOps::Arm_R0;
}
else if (GetArmRegMapped(CArmOps::Arm_R11) == Temp_Mapped && !GetArmRegProtected(CArmOps::Arm_R11))
{
Reg = CArmOps::Arm_R11;
}
else if (GetArmRegMapped(CArmOps::Arm_R10) == Temp_Mapped && !GetArmRegProtected(CArmOps::Arm_R10))
{
Reg = CArmOps::Arm_R10;
}
else if (GetArmRegMapped(CArmOps::Arm_R9) == Temp_Mapped && !GetArmRegProtected(CArmOps::Arm_R9))
{
Reg = CArmOps::Arm_R9;
}
else if (GetArmRegMapped(CArmOps::Arm_R8) == Temp_Mapped && !GetArmRegProtected(CArmOps::Arm_R8))
{
Reg = CArmOps::Arm_R8;
}
if (Reg == CArmOps::Arm_Any)
{
Reg = FreeArmReg(true);
if (Reg == CArmOps::Arm_Unknown)
{
WriteTrace(TraceRegisterCache, TraceError, "Failed to find a free register");
g_Notify->BreakPoint(__FILE__, __LINE__);
return CArmOps::Arm_Unknown;
}
}
}
else if (GetArmRegMapped(Reg) == NotMapped || GetArmRegMapped(Reg) == Temp_Mapped)
{
if (GetArmRegProtected(Reg))
{
g_Notify->BreakPoint(__FILE__, __LINE__);
}
}
else if (GetArmRegMapped(Reg) == GPR_Mapped)
{
g_Notify->BreakPoint(__FILE__, __LINE__);
}
else
{
g_Notify->BreakPoint(__FILE__, __LINE__);
}
if (MipsReg < 0)
{
m_CodeBlock.Log(" regcache: allocate %s as temporary storage", m_Assembler.ArmRegName(Reg));
}
else
{
m_CodeBlock.Log(" regcache: allocate %s as temporary storage (%s)", m_Assembler.ArmRegName(Reg), LoadHiWord ? CRegName::GPR_Hi[MipsReg] : CRegName::GPR_Lo[MipsReg]);
if (GprReg == CArmOps::Arm_Unknown)
{
g_Notify->BreakPoint(__FILE__, __LINE__);
}
if (LoadHiWord)
{
if (IsUnknown(MipsReg))
{
m_Assembler.LoadArmRegPointerToArmReg(Reg, GprReg, (uint8_t)(MipsReg << 3) + 4, CRegName::GPR_Hi[MipsReg]);
}
else if (IsMapped(MipsReg))
{
if (Is64Bit(MipsReg))
{
g_Notify->BreakPoint(__FILE__, __LINE__);
//MoveArmRegToArmReg(GetMipsRegMapHi(MipsReg), Reg);
}
else if (IsSigned(MipsReg))
{
m_Assembler.ShiftRightSignImmed(Reg, GetMipsRegMapLo(MipsReg), 31);
}
else
{
m_Assembler.MoveConstToArmReg(Reg, (uint32_t)0);
}
}
else
{
if (Is64Bit(MipsReg))
{
g_Notify->BreakPoint(__FILE__, __LINE__);
//m_Assembler.MoveConstToArmReg(Reg, GetMipsRegHi(MipsReg));
}
else
{
g_Notify->BreakPoint(__FILE__, __LINE__);
//m_Assembler.MoveConstToArmReg(Reg, GetMipsRegLo_S(MipsReg) >> 31);
}
}
}
else
{
if (IsUnknown(MipsReg))
{
m_Assembler.LoadArmRegPointerToArmReg(Reg, GprReg, (uint8_t)(MipsReg << 3), CRegName::GPR_Lo[MipsReg]);
}
else if (IsMapped(MipsReg))
{
m_Assembler.AddConstToArmReg(Reg, GetMipsRegMapLo(MipsReg), 0);
}
else
{
m_Assembler.MoveConstToArmReg(Reg, GetMipsRegLo(MipsReg));
}
}
}
SetArmRegMapped(Reg, Temp_Mapped);
SetArmRegProtected(Reg, true);
for (int32_t i = 0, n = sizeof(m_ArmReg_MappedTo) / sizeof(m_ArmReg_MappedTo[0]); i < n; i++)
{
int32_t MapOrder = GetArmRegMapOrder((CArmOps::ArmReg)i);
if (MapOrder > 0)
{
SetArmRegMapOrder((CArmOps::ArmReg)i, MapOrder + 1);
}
}
SetArmRegMapOrder(Reg, 1);
SetArmRegProtected(GprReg, false);
return Reg;
}
CArmOps::ArmReg CArmRegInfo::Map_Variable(VARIABLE_MAPPED variable, CArmOps::ArmReg Reg)
{
m_CodeBlock.Log("%s: variable: %s Reg: %d", __FUNCTION__, VariableMapName(variable), Reg);
if (m_InCallDirect)
{
m_CodeBlock.Log("%s: in CallDirect", __FUNCTION__);
g_Notify->BreakPoint(__FILE__, __LINE__);
return CArmOps::Arm_Unknown;
}
if (Reg == CArmOps::Arm_Unknown)
{
g_Notify->BreakPoint(__FILE__, __LINE__);
return CArmOps::Arm_Unknown;
}
if (variable == VARIABLE_GPR && Reg != CArmOps::Arm_Any && Reg != CArmOps::Arm_R12)
{
g_Notify->BreakPoint(__FILE__, __LINE__);
return CArmOps::Arm_Unknown;
}
if (Reg == CArmOps::Arm_Any)
{
Reg = GetVariableReg(variable);
if (Reg != CArmOps::Arm_Unknown)
{
SetArmRegProtected(Reg, true);
return Reg;
}
Reg = variable == VARIABLE_GPR ? CArmOps::Arm_R12 : FreeArmReg(false);
if (Reg == CArmOps::Arm_Unknown)
{
WriteTrace(TraceRegisterCache, TraceError, "Failed to find a free register");
g_Notify->BreakPoint(__FILE__, __LINE__);
return CArmOps::Arm_Unknown;
}
}
else if (GetArmRegMapped(Reg) == Variable_Mapped && m_Variable_MappedTo[Reg] == variable)
{
return Reg;
}
else if (GetArmRegMapped(Reg) != NotMapped)
{
UnMap_ArmReg(Reg);
}
SetArmRegMapped(Reg, Variable_Mapped);
SetArmRegProtected(Reg, true);
m_CodeBlock.Log(" regcache: allocate %s as pointer to %s", m_Assembler.ArmRegName(Reg), VariableMapName(variable));
m_Variable_MappedTo[Reg] = variable;
if (variable == VARIABLE_GPR)
{
m_Assembler.MoveConstToArmReg(Reg, (uint32_t)_GPR, "_GPR");
}
else if (variable == VARIABLE_FPR)
{
m_Assembler.MoveConstToArmReg(Reg, (uint32_t)_FPR_S, "_FPR_S");
}
else if (variable == VARIABLE_TLB_READMAP)
{
m_Assembler.MoveConstToArmReg(Reg, (uint32_t)(g_MMU->m_TLB_ReadMap), "MMU->TLB_ReadMap");
}
else if (variable == VARIABLE_TLB_WRITEMAP)
{
m_Assembler.MoveConstToArmReg(Reg, (uint32_t)(g_MMU->m_TLB_WriteMap), "MMU->m_TLB_WriteMap");
}
else if (variable == VARIABLE_TLB_LOAD_ADDRESS)
{
m_Assembler.MoveConstToArmReg(Reg, (uint32_t)(g_TLBLoadAddress), "g_TLBLoadAddress");
}
else if (variable == VARIABLE_TLB_STORE_ADDRESS)
{
m_Assembler.MoveConstToArmReg(Reg, (uint32_t)(g_TLBStoreAddress), "g_TLBStoreAddress");
}
else if (variable == VARIABLE_NEXT_TIMER)
{
m_Assembler.MoveConstToArmReg(Reg, (uint32_t)(g_NextTimer), "g_NextTimer");
}
else
{
g_Notify->BreakPoint(__FILE__, __LINE__);
return CArmOps::Arm_Unknown;
}
return Reg;
}
CArmOps::ArmReg CArmRegInfo::GetVariableReg(VARIABLE_MAPPED variable) const
{
for (int32_t i = 0, n = sizeof(m_ArmReg_MappedTo) / sizeof(m_ArmReg_MappedTo[0]); i < n; i++)
{
if (m_ArmReg_MappedTo[i] == Variable_Mapped && m_Variable_MappedTo[i] == variable)
{
return (CArmOps::ArmReg)i;
}
}
return CArmOps::Arm_Unknown;
}
void CArmRegInfo::ProtectGPR(uint32_t Reg)
{
if (m_InCallDirect)
{
m_CodeBlock.Log("%s: in CallDirect", __FUNCTION__);
g_Notify->BreakPoint(__FILE__, __LINE__);
return;
}
if (IsUnknown(Reg) || IsConst(Reg))
{
return;
}
if (Is64Bit(Reg))
{
SetArmRegProtected(GetMipsRegMapHi(Reg), true);
}
SetArmRegProtected(GetMipsRegMapLo(Reg), true);
}
void CArmRegInfo::UnProtectGPR(uint32_t Reg)
{
if (m_InCallDirect)
{
m_CodeBlock.Log("%s: in CallDirect", __FUNCTION__);
g_Notify->BreakPoint(__FILE__, __LINE__);
return;
}
if (IsUnknown(Reg) || IsConst(Reg))
{
return;
}
if (Is64Bit(Reg))
{
SetArmRegProtected(GetMipsRegMapHi(Reg), false);
}
SetArmRegProtected(GetMipsRegMapLo(Reg), false);
}
const char * CArmRegInfo::VariableMapName(VARIABLE_MAPPED variable)
{
switch (variable)
{
case VARIABLE_UNKNOWN: return "UNKNOWN";
case VARIABLE_GPR: return "_GPR";
case VARIABLE_FPR: return "_FPR_S";
case VARIABLE_TLB_READMAP: return "m_TLB_ReadMap";
case VARIABLE_TLB_WRITEMAP: return "m_TLB_WriteMap";
case VARIABLE_TLB_LOAD_ADDRESS: return "g_TLBLoadAddress";
case VARIABLE_TLB_STORE_ADDRESS: return "g_TLBStoreAddress";
case VARIABLE_NEXT_TIMER: return "g_NextTimer";
default:
g_Notify->BreakPoint(__FILE__, __LINE__);
return "unknown VariableMapName";
}
}
#endif