#include "stdafx.h" void InPermLoop ( void ); bool DelaySlotEffectsCompare ( DWORD PC, DWORD Reg1, DWORD Reg2 ); int DelaySlotEffectsJump (DWORD JumpPC) { OPCODE Command; if (!_MMU->LW_VAddr(JumpPC, Command.Hex)) { return TRUE; } switch (Command.op) { case R4300i_SPECIAL: switch (Command.funct) { case R4300i_SPECIAL_JR: return DelaySlotEffectsCompare(JumpPC,Command.rs,0); case R4300i_SPECIAL_JALR: return DelaySlotEffectsCompare(JumpPC,Command.rs,31); } break; case R4300i_REGIMM: switch (Command.rt) { case R4300i_REGIMM_BLTZ: case R4300i_REGIMM_BGEZ: case R4300i_REGIMM_BLTZL: case R4300i_REGIMM_BGEZL: case R4300i_REGIMM_BLTZAL: case R4300i_REGIMM_BGEZAL: return DelaySlotEffectsCompare(JumpPC,Command.rs,0); } break; case R4300i_JAL: case R4300i_SPECIAL_JALR: return DelaySlotEffectsCompare(JumpPC,31,0); break; case R4300i_J: return FALSE; case R4300i_BEQ: case R4300i_BNE: case R4300i_BLEZ: case R4300i_BGTZ: return DelaySlotEffectsCompare(JumpPC,Command.rs,Command.rt); case R4300i_CP1: switch (Command.fmt) { case R4300i_COP1_BC: switch (Command.ft) { case R4300i_COP1_BC_BCF: case R4300i_COP1_BC_BCT: case R4300i_COP1_BC_BCFL: case R4300i_COP1_BC_BCTL: { int EffectDelaySlot; OPCODE NewCommand; if (!_MMU->LW_VAddr(JumpPC + 4, NewCommand.Hex)) { return TRUE; } EffectDelaySlot = FALSE; if (NewCommand.op == R4300i_CP1) { if (NewCommand.fmt == R4300i_COP1_S && (NewCommand.funct & 0x30) == 0x30 ) { EffectDelaySlot = TRUE; } if (NewCommand.fmt == R4300i_COP1_D && (NewCommand.funct & 0x30) == 0x30 ) { EffectDelaySlot = TRUE; } } return EffectDelaySlot; } break; } break; } break; case R4300i_BEQL: case R4300i_BNEL: case R4300i_BLEZL: case R4300i_BGTZL: return DelaySlotEffectsCompare(JumpPC,Command.rs,Command.rt); } return TRUE; } CCodeSection::CCodeSection( CCodeBlock * CodeBlock, DWORD EnterPC, DWORD ID, bool LinkAllowed) : m_BlockInfo(CodeBlock), m_EnterPC(EnterPC), m_EndPC((DWORD)-1), m_SectionID(ID), m_ContinueSection(NULL), m_JumpSection(NULL), m_LinkAllowed(LinkAllowed), m_CompiledLocation(NULL), m_Test(0), m_Test2(0), m_InLoop(false), m_EndSection(false), m_DelaySlot(false) { CPU_Message(__FUNCTION__ ": ID %d EnterPC 0x%08X",ID,EnterPC); } CCodeSection::~CCodeSection( void ) { } void CCodeSection::CompileExit ( DWORD JumpPC, DWORD TargetPC, CRegInfo &ExitRegSet, CExitInfo::EXIT_REASON reason, int CompileNow, void (*x86Jmp)(const char * Label, DWORD Value)) { if (!CompileNow) { char String[100]; sprintf(String,"Exit_%d",m_BlockInfo->m_ExitInfo.size()); if (x86Jmp == NULL) { _Notify->BreakPoint(__FILE__,__LINE__); return; } x86Jmp(String,0); CExitInfo ExitInfo; ExitInfo.ID = m_BlockInfo->m_ExitInfo.size(); ExitInfo.TargetPC = TargetPC; ExitInfo.ExitRegSet = ExitRegSet; ExitInfo.reason = reason; ExitInfo.NextInstruction = m_NextInstruction; ExitInfo.JumpLoc = (DWORD *)(m_RecompPos - 4); m_BlockInfo->m_ExitInfo.push_back(ExitInfo); return; } //CPU_Message("CompileExit: %d",reason); ExitRegSet.WriteBackRegisters(); if (TargetPC != (DWORD)-1) { MoveConstToVariable(TargetPC,&_Reg->m_PROGRAM_COUNTER,"PROGRAM_COUNTER"); UpdateCounters(ExitRegSet,TargetPC <= JumpPC && JumpPC != -1, reason == CExitInfo::Normal); } else { UpdateCounters(ExitRegSet,false,reason == CExitInfo::Normal); } switch (reason) { case CExitInfo::Normal: case CExitInfo::Normal_NoSysCheck: ExitRegSet.SetBlockCycleCount(0); if (TargetPC != (DWORD)-1) { if (TargetPC <= JumpPC && reason == CExitInfo::Normal) { CPU_Message("CompileSystemCheck 1"); CompileSystemCheck((DWORD)-1,ExitRegSet); } } else { if (reason == CExitInfo::Normal) { CPU_Message("CompileSystemCheck 2"); CompileSystemCheck((DWORD)-1,ExitRegSet); } } if (_SyncSystem) { MoveConstToX86reg((DWORD)_BaseSystem,x86_ECX); Call_Direct(AddressOf(&CN64System::SyncSystem), "CN64System::SyncSystem"); } #ifdef LinkBlocks if (bSMM_ValidFunc == false) { if (LookUpMode() == FuncFind_ChangeMemory) { _Notify->BreakPoint(__FILE__,__LINE__); // BYTE * Jump, * Jump2; // if (TargetPC >= 0x80000000 && TargetPC < 0xC0000000) { // DWORD pAddr = TargetPC & 0x1FFFFFFF; // // MoveVariableToX86reg((BYTE *)RDRAM + pAddr,"RDRAM + pAddr",x86_EAX); // Jump2 = NULL; // } else { // MoveConstToX86reg((TargetPC >> 12),x86_ECX); // MoveConstToX86reg(TargetPC,x86_EBX); // MoveVariableDispToX86Reg(TLB_ReadMap,"TLB_ReadMap",x86_ECX,x86_ECX,4); // TestX86RegToX86Reg(x86_ECX,x86_ECX); // JeLabel8("NoTlbEntry",0); // Jump2 = m_RecompPos - 1; // MoveX86regPointerToX86reg(x86_ECX, x86_EBX,x86_EAX); // } // MoveX86RegToX86Reg(x86_EAX,x86_ECX); // AndConstToX86Reg(x86_ECX,0xFFFF0000); // CompConstToX86reg(x86_ECX,0x7C7C0000); // JneLabel8("NoCode",0); // Jump = m_RecompPos - 1; // AndConstToX86Reg(x86_EAX,0xFFFF); // ShiftLeftSignImmed(x86_EAX,4); // AddConstToX86Reg(x86_EAX,0xC); // MoveVariableDispToX86Reg(OrigMem,"OrigMem",x86_ECX,x86_EAX,1); // JmpDirectReg(x86_ECX); // CPU_Message(" NoCode:"); // *((BYTE *)(Jump))=(BYTE)(m_RecompPos - Jump - 1); // if (Jump2 != NULL) { // CPU_Message(" NoTlbEntry:"); // *((BYTE *)(Jump2))=(BYTE)(m_RecompPos - Jump2 - 1); // } } else if (LookUpMode() == FuncFind_VirtualLookup) { MoveConstToX86reg(TargetPC,x86_EDX); MoveConstToX86reg((DWORD)&m_Functions,x86_ECX); Call_Direct(AddressOf(&CFunctionMap::CompilerFindFunction), "CFunctionMap::CompilerFindFunction"); MoveX86RegToX86Reg(x86_EAX,x86_ECX); JecxzLabel8("NullPointer",0); BYTE * Jump = m_RecompPos - 1; MoveX86PointerToX86regDisp(x86_EBX,x86_ECX,0xC); JmpDirectReg(x86_EBX); CPU_Message(" NullPointer:"); *((BYTE *)(Jump))=(BYTE)(m_RecompPos - Jump - 1); } else if (LookUpMode() == FuncFind_PhysicalLookup) { BYTE * Jump2 = NULL; if (TargetPC >= 0x80000000 && TargetPC < 0x90000000) { DWORD pAddr = TargetPC & 0x1FFFFFFF; MoveVariableToX86reg((BYTE *)JumpTable + pAddr,"JumpTable + pAddr",x86_ECX); } else if (TargetPC >= 0x90000000 && TargetPC < 0xC0000000) { } else { MoveConstToX86reg((TargetPC >> 12),x86_ECX); MoveConstToX86reg(TargetPC,x86_EBX); MoveVariableDispToX86Reg(TLB_ReadMap,"TLB_ReadMap",x86_ECX,x86_ECX,4); TestX86RegToX86Reg(x86_ECX,x86_ECX); JeLabel8("NoTlbEntry",0); Jump2 = m_RecompPos - 1; AddConstToX86Reg(x86_ECX,(DWORD)JumpTable - (DWORD)RDRAM); MoveX86regPointerToX86reg(x86_ECX, x86_EBX,x86_ECX); } if (TargetPC < 0x90000000 || TargetPC >= 0xC0000000) { JecxzLabel8("NullPointer",0); BYTE * Jump = m_RecompPos - 1; MoveX86PointerToX86regDisp(x86_EAX,x86_ECX,0xC); JmpDirectReg(x86_EAX); CPU_Message(" NullPointer:"); *((BYTE *)(Jump))=(BYTE)(m_RecompPos - Jump - 1); if (Jump2 != NULL) { CPU_Message(" NoTlbEntry:"); *((BYTE *)(Jump2))=(BYTE)(m_RecompPos - Jump2 - 1); } } } } ExitCodeBlock(); #else ExitCodeBlock(); #endif break; case CExitInfo::DoCPU_Action: MoveConstToX86reg((DWORD)_SystemEvents,x86_ECX); Call_Direct(AddressOf(&CSystemEvents::ExecuteEvents),"CSystemEvents::ExecuteEvents"); if (_SyncSystem) { MoveConstToX86reg((DWORD)_BaseSystem,x86_ECX); Call_Direct(AddressOf(&CN64System::SyncSystem), "CN64System::SyncSystem"); } //_System->SyncCPU(_SyncSystem); ExitCodeBlock(); break; case CExitInfo::DoSysCall: { bool bDelay = m_NextInstruction == JUMP || m_NextInstruction == DELAY_SLOT; PushImm32(bDelay ? "true" : "false", bDelay); MoveConstToX86reg((DWORD)_Reg,x86_ECX); Call_Direct(AddressOf(&CRegisters::DoSysCallException), "CRegisters::DoSysCallException"); if (_SyncSystem) { MoveConstToX86reg((DWORD)_BaseSystem,x86_ECX); Call_Direct(AddressOf(&CN64System::SyncSystem), "CN64System::SyncSystem"); } ExitCodeBlock(); } break; case CExitInfo::COP1_Unuseable: { bool bDelay = m_NextInstruction == JUMP || m_NextInstruction == DELAY_SLOT; PushImm32("1",1); PushImm32(bDelay ? "true" : "false", bDelay); MoveConstToX86reg((DWORD)_Reg,x86_ECX); Call_Direct(AddressOf(&CRegisters::DoCopUnusableException), "CRegisters::DoCopUnusableException"); if (_SyncSystem) { MoveConstToX86reg((DWORD)_BaseSystem,x86_ECX); Call_Direct(AddressOf(&CN64System::SyncSystem), "CN64System::SyncSystem"); } ExitCodeBlock(); } break; case CExitInfo::ExitResetRecompCode: _Notify->BreakPoint(__FILE__,__LINE__); #ifdef tofix if (m_NextInstruction == JUMP || m_NextInstruction == DELAY_SLOT) { X86BreakPoint(__FILE__,__LINE__); } if (_SyncSystem) { MoveConstToX86reg((DWORD)_BaseSystem,x86_ECX); Call_Direct(AddressOf(&CN64System::SyncSystem), "CN64System::SyncSystem"); } X86BreakPoint(__FILE__,__LINE__); MoveVariableToX86reg(this,"this",x86_ECX); Call_Direct(AddressOf(ResetRecompCode), "ResetRecompCode"); #endif ExitCodeBlock(); break; case CExitInfo::TLBReadMiss: MoveVariableToX86reg(_TLBLoadAddress,"_TLBLoadAddress",x86_EDX); Push(x86_EDX); PushImm32(m_NextInstruction == JUMP || m_NextInstruction == DELAY_SLOT); MoveConstToX86reg((DWORD)_Reg,x86_ECX); Call_Direct(AddressOf(&CRegisters::DoTLBReadMiss),"CRegisters::DoTLBReadMiss"); if (_SyncSystem) { MoveConstToX86reg((DWORD)_BaseSystem,x86_ECX); Call_Direct(AddressOf(&CN64System::SyncSystem), "CN64System::SyncSystem"); } ExitCodeBlock(); break; case CExitInfo::DivByZero: AddConstToVariable(4,_PROGRAM_COUNTER,"PROGRAM_COUNTER"); if (!b32BitCore()) { MoveConstToVariable(0,&_RegHI->UW[1],"_RegHI->UW[1]"); MoveConstToVariable(0,&_RegLO->UW[1],"_RegLO->UW[1]"); } MoveConstToVariable(0,&_RegHI->UW[0],"_RegHI->UW[0]"); MoveConstToVariable(0,&_RegLO->UW[0],"_RegLO->UW[0]"); if (_SyncSystem) { MoveConstToX86reg((DWORD)_BaseSystem,x86_ECX); Call_Direct(AddressOf(&CN64System::SyncSystem), "CN64System::SyncSystem"); } ExitCodeBlock(); break; default: _Notify->DisplayError("how did you want to exit on reason (%d) ???",reason); } } void CCodeSection::GenerateSectionLinkage (void) { CCodeSection * TargetSection[] = { m_ContinueSection, m_JumpSection }; CJumpInfo * JumpInfo[] = { &m_Cont, &m_Jump }; int i; for (i = 0; i < 2; i ++) { if (JumpInfo[i]->LinkLocation == NULL && JumpInfo[i]->FallThrough == false) { JumpInfo[i]->TargetPC = (DWORD)-1; } } if ((CompilePC() & 0xFFC) == 0xFFC) { _Notify->BreakPoint(__FILE__,__LINE__); #ifdef tofix //Handle Fall througth BYTE * Jump = NULL; for (i = 0; i < 2; i ++) { if (!JumpInfo[i]->FallThrough) { continue; } JumpInfo[i]->FallThrough = false; if (JumpInfo[i]->LinkLocation != NULL) { SetJump32(JumpInfo[i]->LinkLocation,(DWORD *)m_RecompPos); JumpInfo[i]->LinkLocation = NULL; if (JumpInfo[i]->LinkLocation2 != NULL) { SetJump32(JumpInfo[i]->LinkLocation2,(DWORD *)m_RecompPos); JumpInfo[i]->LinkLocation2 = NULL; } } PushImm32(stdstr_f("0x%08X",JumpInfo[i]->TargetPC).c_str(),JumpInfo[i]->TargetPC); if (JumpInfo[(i + 1) & 1]->LinkLocation == NULL) { break; } JmpLabel8("FinishBlock",0); Jump = m_RecompPos - 1; } for (i = 0; i < 2; i ++) { if (JumpInfo[i]->LinkLocation == NULL) { continue; } JumpInfo[i]->FallThrough = false; if (JumpInfo[i]->LinkLocation != NULL) { SetJump32(JumpInfo[i]->LinkLocation,(DWORD *)m_RecompPos); JumpInfo[i]->LinkLocation = NULL; if (JumpInfo[i]->LinkLocation2 != NULL) { SetJump32(JumpInfo[i]->LinkLocation2,(DWORD *)m_RecompPos); JumpInfo[i]->LinkLocation2 = NULL; } } PushImm32(stdstr_f("0x%08X",JumpInfo[i]->TargetPC).c_str(),JumpInfo[i]->TargetPC); if (JumpInfo[(i + 1) & 1]->LinkLocation == NULL) { break; } JmpLabel8("FinishBlock",0); Jump = m_RecompPos - 1; } if (Jump != NULL) { CPU_Message(" $FinishBlock:"); SetJump8(Jump,m_RecompPos); } //MoveConstToVariable(CompilePC() + 4,_PROGRAM_COUNTER,"PROGRAM_COUNTER"); m_RegWorkingSet.WriteBackRegisters(); UpdateCounters(m_RegWorkingSet,false,true); // WriteBackRegisters(Section); // if (_SyncSystem) { MoveConstToX86reg((DWORD)_BaseSystem,x86_ECX); Call_Direct(AddressOf(&CN64System::SyncSystem), "CN64System::SyncSystem"); } // MoveConstToVariable(DELAY_SLOT,&m_NextInstruction,"m_NextInstruction"); PushImm32(stdstr_f("0x%08X",CompilePC() + 4).c_str(),CompilePC() + 4); // check if there is an existing section MoveConstToX86reg((DWORD)_Recompiler,x86_ECX); Call_Direct(AddressOf(&CRecompiler::CompileDelaySlot), "CRecompiler::CompileDelaySlot"); JmpDirectReg(x86_EAX); ExitCodeBlock(); return; #endif } // Handle Perm Loop if (CRecompilerOps::m_CompilePC == m_Jump.TargetPC && (m_Cont.FallThrough == false)) { if (!DelaySlotEffectsJump(CompilePC())) { MoveConstToVariable(CompilePC(),_PROGRAM_COUNTER,"PROGRAM_COUNTER"); m_Jump.RegSet.WriteBackRegisters(); UpdateCounters(m_Jump.RegSet,false, true); Call_Direct(AddressOf(CInterpreterCPU::InPermLoop),"CInterpreterCPU::InPermLoop"); MoveConstToX86reg((DWORD)_SystemTimer,x86_ECX); Call_Direct(AddressOf(&CSystemTimer::TimerDone),"CSystemTimer::TimerDone"); CPU_Message("CompileSystemCheck 3"); CompileSystemCheck((DWORD)-1,m_Jump.RegSet); } } if (TargetSection[0] != TargetSection[1] || TargetSection[0] == NULL) { for (i = 0; i < 2; i ++) { if (JumpInfo[i]->LinkLocation == NULL && JumpInfo[i]->FallThrough == false) { if (TargetSection[i]) { TargetSection[i]->UnlinkParent(this, i == 0); TargetSection[i] = NULL; } } else if (TargetSection[i] == NULL && JumpInfo[i]->FallThrough) { if (JumpInfo[i]->LinkLocation != NULL) { SetJump32(JumpInfo[i]->LinkLocation,(DWORD *)m_RecompPos); JumpInfo[i]->LinkLocation = NULL; if (JumpInfo[i]->LinkLocation2 != NULL) { SetJump32(JumpInfo[i]->LinkLocation2,(DWORD *)m_RecompPos); JumpInfo[i]->LinkLocation2 = NULL; } } CompileExit (CompilePC(), JumpInfo[i]->TargetPC,JumpInfo[i]->RegSet,CExitInfo::Normal,true,NULL); JumpInfo[i]->FallThrough = false; } else if (TargetSection[i] != NULL && JumpInfo[i] != NULL) { if (!JumpInfo[i]->FallThrough) { continue; } if (JumpInfo[i]->TargetPC == TargetSection[i]->m_EnterPC) { continue; } if (JumpInfo[i]->LinkLocation != NULL) { SetJump32(JumpInfo[i]->LinkLocation,(DWORD *)m_RecompPos); JumpInfo[i]->LinkLocation = NULL; if (JumpInfo[i]->LinkLocation2 != NULL) { SetJump32(JumpInfo[i]->LinkLocation2,(DWORD *)m_RecompPos); JumpInfo[i]->LinkLocation2 = NULL; } } CompileExit (CompilePC(), JumpInfo[i]->TargetPC,JumpInfo[i]->RegSet,CExitInfo::Normal,true,NULL); //FreeSection(TargetSection[i],Section); } } } else { if (m_Cont.LinkLocation == NULL && m_Cont.FallThrough == false) { m_ContinueSection = NULL; } if (m_Jump.LinkLocation == NULL && m_Jump.FallThrough == false) { m_JumpSection = NULL; } if (m_JumpSection == NULL && m_ContinueSection == NULL) { //FreeSection(TargetSection[0],Section); } } TargetSection[0] = m_ContinueSection; TargetSection[1] = m_JumpSection; for (i = 0; i < 2; i ++) { if (TargetSection[i] == NULL) { continue; } if (!JumpInfo[i]->FallThrough) { continue; } if (TargetSection[i]->m_CompiledLocation != NULL) { char Label[100]; sprintf(Label,"Section_%d",TargetSection[i]->m_SectionID); JumpInfo[i]->FallThrough = false; if (JumpInfo[i]->LinkLocation != NULL) { SetJump32(JumpInfo[i]->LinkLocation,(DWORD *)m_RecompPos); JumpInfo[i]->LinkLocation = NULL; if (JumpInfo[i]->LinkLocation2 != NULL) { SetJump32(JumpInfo[i]->LinkLocation2,(DWORD *)m_RecompPos); JumpInfo[i]->LinkLocation2 = NULL; } } if (JumpInfo[i]->TargetPC <= CompilePC()) { if (JumpInfo[i]->PermLoop) { CPU_Message("PermLoop *** 1"); MoveConstToVariable(JumpInfo[i]->TargetPC,_PROGRAM_COUNTER,"PROGRAM_COUNTER"); UpdateCounters(JumpInfo[i]->RegSet,false, true); if (_SyncSystem) { MoveConstToX86reg((DWORD)_BaseSystem,x86_ECX); Call_Direct(AddressOf(&CN64System::SyncSystem), "CN64System::SyncSystem"); } //JumpInfo[i]->RegSet.BlockCycleCount() -= CountPerOp(); Call_Direct(AddressOf(CInterpreterCPU::InPermLoop),"CInterpreterCPU::InPermLoop"); //JumpInfo[i]->RegSet.BlockCycleCount() += CountPerOp(); UpdateCounters(JumpInfo[i]->RegSet,true,true); CPU_Message("CompileSystemCheck 4"); CompileSystemCheck((DWORD)-1,JumpInfo[i]->RegSet); } else { UpdateCounters(JumpInfo[i]->RegSet,true,true); CPU_Message("CompileSystemCheck 5"); CompileSystemCheck(JumpInfo[i]->TargetPC,JumpInfo[i]->RegSet); } } else { UpdateCounters(JumpInfo[i]->RegSet,false,true); } JumpInfo[i]->RegSet.SetBlockCycleCount(0); m_RegWorkingSet = JumpInfo[i]->RegSet; SyncRegState(TargetSection[i]->m_RegEnter); JmpLabel32(Label,0); SetJump32((DWORD *)m_RecompPos - 1,(DWORD *)(TargetSection[i]->m_CompiledLocation)); } } for (i = 0; i < 2; i ++) { if (TargetSection[i] == NULL) { continue; } if (TargetSection[i]->m_ParentSection.empty()) { continue; } for (SECTION_LIST::iterator iter = TargetSection[i]->m_ParentSection.begin(); iter != TargetSection[i]->m_ParentSection.end(); iter++) { CCodeSection * Parent = *iter; if (Parent->m_CompiledLocation != NULL) { continue; } if (Parent->m_InLoop) { continue; } if (JumpInfo[i]->PermLoop) { CPU_Message("PermLoop *** 2"); MoveConstToVariable(JumpInfo[i]->TargetPC,_PROGRAM_COUNTER,"PROGRAM_COUNTER"); UpdateCounters(JumpInfo[i]->RegSet,false, true); Call_Direct(AddressOf(CInterpreterCPU::InPermLoop),"CInterpreterCPU::InPermLoop"); UpdateCounters(JumpInfo[i]->RegSet,true,true); CPU_Message("CompileSystemCheck 6"); CompileSystemCheck((DWORD)-1,JumpInfo[i]->RegSet); } if (JumpInfo[i]->FallThrough) { JumpInfo[i]->FallThrough = false; JmpLabel32(JumpInfo[i]->BranchLabel.c_str(),0); JumpInfo[i]->LinkLocation = (DWORD*)(m_RecompPos - 4); } } } for (i = 0; i < 2; i ++) { if (JumpInfo[i]->FallThrough) { if (JumpInfo[i]->TargetPC < CompilePC()) { UpdateCounters(JumpInfo[i]->RegSet,true,true); CPU_Message("CompileSystemCheck 7"); CompileSystemCheck(JumpInfo[i]->TargetPC,JumpInfo[i]->RegSet); } } } CPU_Message("====== End of Section %d ======",m_SectionID); for (i = 0; i < 2; i ++) { if (JumpInfo[i]->FallThrough && !TargetSection[i]->GenerateX86Code(m_BlockInfo->NextTest())) { JumpInfo[i]->FallThrough = FALSE; JmpLabel32(JumpInfo[i]->BranchLabel.c_str(),0); JumpInfo[i]->LinkLocation = (DWORD *)(m_RecompPos - 4); } } //CPU_Message("Section %d",m_SectionID); for (i = 0; i < 2; i ++) { if (JumpInfo[i]->LinkLocation == NULL) { continue; } if (TargetSection[i] == NULL) { CPU_Message("ExitBlock (from %d):",m_SectionID); SetJump32(JumpInfo[i]->LinkLocation,(DWORD *)m_RecompPos); JumpInfo[i]->LinkLocation = NULL; if (JumpInfo[i]->LinkLocation2 != NULL) { SetJump32(JumpInfo[i]->LinkLocation2,(DWORD *)m_RecompPos); JumpInfo[i]->LinkLocation2 = NULL; } CompileExit (CompilePC(),JumpInfo[i]->TargetPC,JumpInfo[i]->RegSet,CExitInfo::Normal,true,NULL); continue; } if (JumpInfo[i]->TargetPC != TargetSection[i]->m_EnterPC) { _Notify->BreakPoint(__FILE__,__LINE__); } if (TargetSection[i]->m_CompiledLocation == NULL) { TargetSection[i]->GenerateX86Code(m_BlockInfo->NextTest()); } else { stdstr_f Label("Section_%d (from %d):",TargetSection[i]->m_SectionID,m_SectionID); CPU_Message(Label.c_str()); SetJump32(JumpInfo[i]->LinkLocation,(DWORD *)m_RecompPos); JumpInfo[i]->LinkLocation = NULL; if (JumpInfo[i]->LinkLocation2 != NULL) { SetJump32(JumpInfo[i]->LinkLocation2,(DWORD *)m_RecompPos); JumpInfo[i]->LinkLocation2 = NULL; } m_RegWorkingSet = JumpInfo[i]->RegSet; if (JumpInfo[i]->TargetPC <= JumpInfo[i]->JumpPC) { UpdateCounters(JumpInfo[i]->RegSet,true,true); if (JumpInfo[i]->PermLoop) { CPU_Message("PermLoop *** 3"); MoveConstToVariable(JumpInfo[i]->TargetPC,_PROGRAM_COUNTER,"PROGRAM_COUNTER"); Call_Direct(AddressOf(CInterpreterCPU::InPermLoop),"CInterpreterCPU::InPermLoop"); CPU_Message("CompileSystemCheck 8"); CompileSystemCheck((DWORD)-1,JumpInfo[i]->RegSet); } else { CPU_Message("CompileSystemCheck 9"); CompileSystemCheck(JumpInfo[i]->TargetPC,JumpInfo[i]->RegSet); } } else{ UpdateCounters(m_RegWorkingSet,false,true); } m_RegWorkingSet = JumpInfo[i]->RegSet; SyncRegState(TargetSection[i]->m_RegEnter); JmpLabel32(Label.c_str(),0); SetJump32((DWORD *)m_RecompPos - 1,(DWORD *)(TargetSection[i]->m_CompiledLocation)); } } } void CCodeSection::SyncRegState ( const CRegInfo & SyncTo ) { ResetX86Protection(); bool changed = false; UnMap_AllFPRs(); if (m_RegWorkingSet.GetRoundingModel() != SyncTo.GetRoundingModel()) { m_RegWorkingSet.SetRoundingModel(CRegInfo::RoundUnknown); } x86Reg MemStackReg = Get_MemoryStack(); x86Reg TargetStackReg = SyncTo.Get_MemoryStack(); //CPU_Message("MemoryStack for Original State = %s",MemStackReg > 0?x86_Name(MemStackReg):"Not Mapped"); if (MemStackReg != TargetStackReg) { if (TargetStackReg == x86_Unknown) { UnMap_X86reg(MemStackReg); } else if (MemStackReg == x86_Unknown) { UnMap_X86reg(TargetStackReg); CPU_Message(" regcache: allocate %s as Memory Stack",x86_Name(TargetStackReg)); m_RegWorkingSet.SetX86Mapped(TargetStackReg,CRegInfo::Stack_Mapped); MoveVariableToX86reg(&_Recompiler->MemoryStackPos(),"MemoryStack",TargetStackReg); } else { UnMap_X86reg(TargetStackReg); CPU_Message(" regcache: change allocation of Memory Stack from %s to %s",x86_Name(MemStackReg),x86_Name(TargetStackReg)); m_RegWorkingSet.SetX86Mapped(TargetStackReg, CRegInfo::Stack_Mapped); m_RegWorkingSet.SetX86Mapped(MemStackReg,CRegInfo::NotMapped); MoveX86RegToX86Reg(MemStackReg,TargetStackReg); } } for (int i = 1; i < 32; i ++) { if (MipsRegState(i) == SyncTo.MipsRegState(i) || (b32BitCore() && MipsRegState(i) == CRegInfo::STATE_MAPPED_32_ZERO && SyncTo.MipsRegState(i) == CRegInfo::STATE_MAPPED_32_SIGN) || (b32BitCore() && MipsRegState(i) == CRegInfo::STATE_MAPPED_32_SIGN && SyncTo.MipsRegState(i) == CRegInfo::STATE_MAPPED_32_ZERO)) { switch (MipsRegState(i)) { case CRegInfo::STATE_UNKNOWN: continue; case CRegInfo::STATE_MAPPED_64: if (MipsRegMapHi(i) == SyncTo.MipsRegMapHi(i) && MipsRegMapLo(i) == SyncTo.MipsRegMapLo(i)) { continue; } break; case CRegInfo::STATE_MAPPED_32_ZERO: case CRegInfo::STATE_MAPPED_32_SIGN: if (MipsRegMapLo(i) == SyncTo.MipsRegMapLo(i)) { continue; } break; case CRegInfo::STATE_CONST_64: if (MipsReg(i) != SyncTo.MipsReg(i)) { _Notify->BreakPoint(__FILE__,__LINE__); } continue; case CRegInfo::STATE_CONST_32: if (MipsRegLo(i) != SyncTo.cMipsRegLo(i)) { CPU_Message("Value of const is different Reg %d (%s) Value: 0x%08X to 0x%08X",i,CRegName::GPR[i],MipsRegLo(i),SyncTo.cMipsRegLo(i)); _Notify->BreakPoint(__FILE__,__LINE__); } continue; default: CPU_Message("Unhandled Reg state %d\nin SyncRegState",MipsRegState(i)); _Notify->BreakPoint(__FILE__,__LINE__); } } changed = true; switch (SyncTo.MipsRegState(i)) { case CRegInfo::STATE_UNKNOWN: UnMap_GPR(i,true); break; case CRegInfo::STATE_MAPPED_64: { x86Reg Reg = SyncTo.MipsRegMapLo(i); x86Reg x86RegHi = SyncTo.MipsRegMapHi(i); UnMap_X86reg(Reg); UnMap_X86reg(x86RegHi); switch (MipsRegState(i)) { case CRegInfo::STATE_UNKNOWN: MoveVariableToX86reg(&_GPR[i].UW[0],CRegName::GPR_Lo[i],Reg); MoveVariableToX86reg(&_GPR[i].UW[1],CRegName::GPR_Hi[i],x86RegHi); break; case CRegInfo::STATE_MAPPED_64: MoveX86RegToX86Reg(MipsRegMapLo(i),Reg); m_RegWorkingSet.SetX86Mapped(MipsRegMapLo(i),CRegInfo::NotMapped); MoveX86RegToX86Reg(MipsRegMapHi(i),x86RegHi); m_RegWorkingSet.SetX86Mapped(MipsRegMapHi(i),CRegInfo::NotMapped); break; case CRegInfo::STATE_MAPPED_32_SIGN: MoveX86RegToX86Reg(MipsRegMapLo(i),x86RegHi); ShiftRightSignImmed(x86RegHi,31); MoveX86RegToX86Reg(MipsRegMapLo(i),Reg); m_RegWorkingSet.SetX86Mapped(MipsRegMapLo(i),CRegInfo::NotMapped); break; case CRegInfo::STATE_MAPPED_32_ZERO: XorX86RegToX86Reg(x86RegHi,x86RegHi); MoveX86RegToX86Reg(MipsRegMapLo(i),Reg); m_RegWorkingSet.SetX86Mapped(MipsRegMapLo(i), CRegInfo::NotMapped); break; case CRegInfo::STATE_CONST_64: MoveConstToX86reg(MipsRegHi(i),x86RegHi); MoveConstToX86reg(MipsRegLo(i),Reg); break; case CRegInfo::STATE_CONST_32: MoveConstToX86reg(MipsRegLo_S(i) >> 31,x86RegHi); MoveConstToX86reg(MipsRegLo(i),Reg); break; default: CPU_Message("Do something with states in SyncRegState\nSTATE_MAPPED_64\n%d",MipsRegState(i)); _Notify->BreakPoint(__FILE__,__LINE__); continue; } m_RegWorkingSet.SetMipsRegMapLo(i,Reg); m_RegWorkingSet.SetMipsRegMapHi(i,x86RegHi); m_RegWorkingSet.SetMipsRegState(i,CRegInfo::STATE_MAPPED_64); m_RegWorkingSet.SetX86Mapped(Reg,CRegInfo::GPR_Mapped); m_RegWorkingSet.SetX86Mapped(x86RegHi,CRegInfo::GPR_Mapped); m_RegWorkingSet.SetX86MapOrder(Reg,1); m_RegWorkingSet.SetX86MapOrder(x86RegHi,1); } break; case CRegInfo::STATE_MAPPED_32_SIGN: { x86Reg Reg = SyncTo.MipsRegMapLo(i); UnMap_X86reg(Reg); switch (MipsRegState(i)) { case CRegInfo::STATE_UNKNOWN: MoveVariableToX86reg(&_GPR[i].UW[0],CRegName::GPR_Lo[i],Reg); break; case CRegInfo::STATE_CONST_32: MoveConstToX86reg(MipsRegLo(i),Reg); break; case CRegInfo::STATE_MAPPED_32_SIGN: MoveX86RegToX86Reg(MipsRegMapLo(i),Reg); m_RegWorkingSet.SetX86Mapped(MipsRegMapLo(i),CRegInfo::NotMapped); break; case CRegInfo::STATE_MAPPED_32_ZERO: if (MipsRegMapLo(i) != Reg) { MoveX86RegToX86Reg(MipsRegMapLo(i),Reg); m_RegWorkingSet.SetX86Mapped(MipsRegMapLo(i),CRegInfo::NotMapped); } break; case CRegInfo::STATE_MAPPED_64: MoveX86RegToX86Reg(MipsRegMapLo(i),Reg); m_RegWorkingSet.SetX86Mapped(MipsRegMapLo(i),CRegInfo::NotMapped) ; m_RegWorkingSet.SetX86Mapped(MipsRegMapHi(i),CRegInfo::NotMapped); break; case CRegInfo::STATE_CONST_64: CPU_Message("hi %X\nLo %X",MipsRegHi(i),MipsRegLo(i)); default: CPU_Message("Do something with states in SyncRegState\nSTATE_MAPPED_32_SIGN\n%d",MipsRegState(i)); _Notify->BreakPoint(__FILE__,__LINE__); } m_RegWorkingSet.SetMipsRegMapLo(i,Reg); m_RegWorkingSet.SetMipsRegState(i, CRegInfo::STATE_MAPPED_32_SIGN); m_RegWorkingSet.SetX86Mapped(Reg,CRegInfo::GPR_Mapped); m_RegWorkingSet.SetX86MapOrder(Reg,1); } break; case CRegInfo::STATE_MAPPED_32_ZERO: { x86Reg Reg = SyncTo.MipsRegMapLo(i); UnMap_X86reg(Reg); switch (MipsRegState(i)) { case CRegInfo::STATE_MAPPED_64: case CRegInfo::STATE_UNKNOWN: MoveVariableToX86reg(&_GPR[i].UW[0],CRegName::GPR_Lo[i],Reg); break; case CRegInfo::STATE_MAPPED_32_ZERO: MoveX86RegToX86Reg(MipsRegMapLo(i),Reg); m_RegWorkingSet.SetX86Mapped(MipsRegMapLo(i),CRegInfo::NotMapped); break; case CRegInfo::STATE_MAPPED_32_SIGN: if (b32BitCore()) { MoveX86RegToX86Reg(MipsRegMapLo(i),Reg); m_RegWorkingSet.SetX86Mapped(MipsRegMapLo(i),CRegInfo::NotMapped); } else { CPU_Message("Do something with states in SyncRegState\nSTATE_MAPPED_32_ZERO\n%d",MipsRegState(i)); _Notify->BreakPoint(__FILE__,__LINE__); } break; case CRegInfo::STATE_CONST_32: if (!b32BitCore() && MipsRegLo_S(i) < 0) { CPU_Message("Sign Problems in SyncRegState\nSTATE_MAPPED_32_ZERO"); CPU_Message("%s: %X",CRegName::GPR[i],MipsRegLo_S(i)); _Notify->BreakPoint(__FILE__,__LINE__); } MoveConstToX86reg(MipsRegLo(i),Reg); break; default: CPU_Message("Do something with states in SyncRegState\nSTATE_MAPPED_32_ZERO\n%d",MipsRegState(i)); _Notify->BreakPoint(__FILE__,__LINE__); } m_RegWorkingSet.SetMipsRegMapLo(i,Reg); m_RegWorkingSet.SetMipsRegState(i, SyncTo.MipsRegState(i)); m_RegWorkingSet.SetX86Mapped(Reg,CRegInfo::GPR_Mapped); m_RegWorkingSet.SetX86MapOrder(Reg,1); } break; default: CPU_Message("%d - %d reg: %s (%d)",SyncTo.MipsRegState(i),MipsRegState(i),CRegName::GPR[i],i); _Notify->BreakPoint(__FILE__,__LINE__); changed = false; } } } void CCodeSection::SetDelaySlot (void) { m_DelaySlot = true; } void CCodeSection::SetJumpAddress (DWORD JumpPC, DWORD TargetPC, bool PermLoop) { m_Jump.JumpPC = JumpPC; m_Jump.TargetPC = TargetPC; m_Jump.BranchLabel.Format("0x%08X",TargetPC); m_Jump.PermLoop = PermLoop; } void CCodeSection::SetContinueAddress (DWORD JumpPC, DWORD TargetPC) { m_Cont.JumpPC = JumpPC; m_Cont.TargetPC = TargetPC; m_Cont.BranchLabel.Format("0x%08X",TargetPC); } void CCodeSection::CompileCop1Test (void) { if (m_RegWorkingSet.FpuBeenUsed()) { return; } TestVariable(STATUS_CU1,&_Reg->STATUS_REGISTER,"STATUS_REGISTER"); CompileExit(m_CompilePC,m_CompilePC,m_RegWorkingSet,CExitInfo::COP1_Unuseable,FALSE,JeLabel32); m_RegWorkingSet.FpuBeenUsed() = TRUE; } bool CCodeSection::ParentContinue ( void ) { if (m_ParentSection.size() > 0) { for (SECTION_LIST::iterator iter = m_ParentSection.begin(); iter != m_ParentSection.end(); iter++) { CCodeSection * Parent = *iter; if (Parent->m_CompiledLocation != NULL) { continue; } if (IsAllParentLoops(Parent,true,m_BlockInfo->NextTest())) { continue; } return false; } if (!InheritParentInfo()) { return false; } } return true; } /*int TestValue = 0; void TestFunc ( void ) { TestValue += 1; if (TestValue >= 4) { _Notify->BreakPoint(__FILE__,__LINE__); } }*/ bool CCodeSection::GenerateX86Code ( DWORD Test ) { if (this == NULL) { return false; } if (m_CompiledLocation != NULL) { if (m_Test == Test) { return false; } m_Test = Test; if (m_ContinueSection->GenerateX86Code(Test)) { return true; } if (m_JumpSection->GenerateX86Code(Test)) { return true; } return false; } if (!ParentContinue()) { return false; } m_CompiledLocation = m_RecompPos; m_RegWorkingSet = m_RegEnter; m_CompilePC = m_EnterPC; m_NextInstruction = NORMAL; m_Section = this; if (m_CompilePC < m_BlockInfo->VAddrFirst()) { m_BlockInfo->SetVAddrFirst(m_CompilePC); } DWORD ContinueSectionPC = m_ContinueSection ? m_ContinueSection->m_EnterPC : (DWORD)-1; do { __try { if (!_MMU->LW_VAddr(m_CompilePC,m_Opcode.Hex)) { _Notify->DisplayError(GS(MSG_FAIL_LOAD_WORD)); ExitThread(0); } } __except( _MMU->MemoryFilter( GetExceptionCode(), GetExceptionInformation()) ) { _Notify->DisplayError(GS(MSG_UNKNOWN_MEM_ACTION)); ExitThread(0); } if (m_CompilePC > m_BlockInfo->VAddrLast()) { m_BlockInfo->SetVAddrLast(m_CompilePC); } /*if (m_CompilePC == 0x803245C4) { X86BreakPoint(__FILE__,__LINE__); //m_RegWorkingSet.UnMap_AllFPRs(); }*/ /*if (m_CompilePC >= 0x80000000 && m_CompilePC <= 0x80400000 && m_NextInstruction == NORMAL) { m_RegWorkingSet.WriteBackRegisters(); UpdateCounters(m_RegWorkingSet,false,true); MoveConstToVariable(m_CompilePC,&_Reg->m_PROGRAM_COUNTER,"PROGRAM_COUNTER"); if (_SyncSystem) { MoveConstToX86reg((DWORD)_BaseSystem,x86_ECX); Call_Direct(AddressOf(&CN64System::SyncSystem), "CN64System::SyncSystem"); } }*/ /*if ((m_CompilePC == 0x8031C0E4 || m_CompilePC == 0x8031C118 || m_CompilePC == 0x8031CD88 || m_CompilePC == 0x8031CE24 || m_CompilePC == 0x8031CE30 || m_CompilePC == 0x8031CE40) && m_NextInstruction == NORMAL) { m_RegWorkingSet.WriteBackRegisters(); UpdateCounters(m_RegWorkingSet,false,true); MoveConstToVariable(m_CompilePC,&_Reg->m_PROGRAM_COUNTER,"PROGRAM_COUNTER"); if (_SyncSystem) { MoveConstToX86reg((DWORD)_BaseSystem,x86_ECX); Call_Direct(AddressOf(&CN64System::SyncSystem), "CN64System::SyncSystem"); } }*/ /*if (m_CompilePC == 0x801C1B88) { BeforeCallDirect(m_RegWorkingSet); Call_Direct(AddressOf(TestFunc), "TestFunc"); AfterCallDirect(m_RegWorkingSet); }*/ /*if (m_CompilePC >= 0x801C1AF8 && m_CompilePC <= 0x801C1C00 && m_NextInstruction == NORMAL) { UpdateCounters(m_RegWorkingSet,false,true); MoveConstToVariable(m_CompilePC,&_Reg->m_PROGRAM_COUNTER,"PROGRAM_COUNTER"); if (_SyncSystem) { BeforeCallDirect(m_RegWorkingSet); MoveConstToX86reg((DWORD)_BaseSystem,x86_ECX); Call_Direct(AddressOf(&CN64System::SyncSystemPC), "CN64System::SyncSystemPC"); AfterCallDirect(m_RegWorkingSet); } }*/ /*if ((m_CompilePC == 0x80263900) && m_NextInstruction == NORMAL) { X86BreakPoint(__FILE__,__LINE__); }*/ /*if ((m_CompilePC >= 0x80325D80 && m_CompilePC <= 0x80325DF0) && m_NextInstruction == NORMAL) { m_RegWorkingSet.WriteBackRegisters(); UpdateCounters(m_RegWorkingSet,false,true); MoveConstToVariable(m_CompilePC,&_Reg->m_PROGRAM_COUNTER,"PROGRAM_COUNTER"); if (_SyncSystem) { MoveConstToX86reg((DWORD)_BaseSystem,x86_ECX); Call_Direct(AddressOf(&CN64System::SyncSystem), "CN64System::SyncSystem"); } }*/ /*if ((m_CompilePC == 0x80324E14) && m_NextInstruction == NORMAL) { X86BreakPoint(__FILE__,__LINE__); }*/ /*if (m_CompilePC == 0x80324E18 && m_NextInstruction == NORMAL) { m_RegWorkingSet.WriteBackRegisters(); UpdateCounters(m_RegWorkingSet,false,true); MoveConstToVariable(m_CompilePC,&_Reg->m_PROGRAM_COUNTER,"PROGRAM_COUNTER"); if (_SyncSystem) { MoveConstToX86reg((DWORD)_BaseSystem,x86_ECX); Call_Direct(AddressOf(&CN64System::SyncSystem), "CN64System::SyncSystem"); } }*/ /*if (m_CompilePC >= 0x80324E00 && m_CompilePC <= 0x80324E18 && m_NextInstruction == NORMAL) { m_RegWorkingSet.WriteBackRegisters(); UpdateCounters(m_RegWorkingSet,false,true); MoveConstToVariable(m_CompilePC,&_Reg->m_PROGRAM_COUNTER,"PROGRAM_COUNTER"); if (_SyncSystem) { MoveConstToX86reg((DWORD)_BaseSystem,x86_ECX); Call_Direct(AddressOf(&CN64System::SyncSystem), "CN64System::SyncSystem"); } }*/ /* if (m_CompilePC == 0x803245CC && m_NextInstruction == NORMAL) { //m_RegWorkingSet.UnMap_AllFPRs(); _Notify->BreakPoint(__FILE__,__LINE__); //X86HardBreakPoint(); //X86BreakPoint(__FILE__,__LINE__); //m_RegWorkingSet.UnMap_AllFPRs(); }*/ /*if (m_CompilePC >= 0x80179DC4 && m_CompilePC <= 0x80179DF0 && m_NextInstruction == NORMAL) { m_RegWorkingSet.UnMap_AllFPRs(); }*/ m_RegWorkingSet.SetBlockCycleCount(m_RegWorkingSet.GetBlockCycleCount() + CountPerOp()); m_RegWorkingSet.ResetX86Protection(); switch (m_Opcode.op) { case R4300i_SPECIAL: switch (m_Opcode.funct) { case R4300i_SPECIAL_SLL: SPECIAL_SLL(); break; case R4300i_SPECIAL_SRL: SPECIAL_SRL(); break; case R4300i_SPECIAL_SRA: SPECIAL_SRA(); break; case R4300i_SPECIAL_SLLV: SPECIAL_SLLV(); break; case R4300i_SPECIAL_SRLV: SPECIAL_SRLV(); break; case R4300i_SPECIAL_SRAV: SPECIAL_SRAV(); break; case R4300i_SPECIAL_JR: SPECIAL_JR(); break; case R4300i_SPECIAL_JALR: SPECIAL_JALR(); break; case R4300i_SPECIAL_MFLO: SPECIAL_MFLO(); break; case R4300i_SPECIAL_SYSCALL: SPECIAL_SYSCALL(); break; case R4300i_SPECIAL_MTLO: SPECIAL_MTLO(); break; case R4300i_SPECIAL_MFHI: SPECIAL_MFHI(); break; case R4300i_SPECIAL_MTHI: SPECIAL_MTHI(); break; case R4300i_SPECIAL_DSLLV: SPECIAL_DSLLV(); break; case R4300i_SPECIAL_DSRLV: SPECIAL_DSRLV(); break; case R4300i_SPECIAL_DSRAV: SPECIAL_DSRAV(); break; case R4300i_SPECIAL_MULT: SPECIAL_MULT(); break; case R4300i_SPECIAL_DIV: SPECIAL_DIV(); break; case R4300i_SPECIAL_DIVU: SPECIAL_DIVU(); break; case R4300i_SPECIAL_MULTU: SPECIAL_MULTU(); break; case R4300i_SPECIAL_DMULT: SPECIAL_DMULT(); break; case R4300i_SPECIAL_DMULTU: SPECIAL_DMULTU(); break; case R4300i_SPECIAL_DDIV: SPECIAL_DDIV(); break; case R4300i_SPECIAL_DDIVU: SPECIAL_DDIVU(); break; case R4300i_SPECIAL_ADD: SPECIAL_ADD(); break; case R4300i_SPECIAL_ADDU: SPECIAL_ADDU(); break; case R4300i_SPECIAL_SUB: SPECIAL_SUB(); break; case R4300i_SPECIAL_SUBU: SPECIAL_SUBU(); break; case R4300i_SPECIAL_AND: SPECIAL_AND(); break; case R4300i_SPECIAL_OR: SPECIAL_OR(); break; case R4300i_SPECIAL_XOR: SPECIAL_XOR(); break; case R4300i_SPECIAL_NOR: SPECIAL_NOR(); break; case R4300i_SPECIAL_SLT: SPECIAL_SLT(); break; case R4300i_SPECIAL_SLTU: SPECIAL_SLTU(); break; case R4300i_SPECIAL_DADD: SPECIAL_DADD(); break; case R4300i_SPECIAL_DADDU: SPECIAL_DADDU(); break; case R4300i_SPECIAL_DSUB: SPECIAL_DSUB(); break; case R4300i_SPECIAL_DSUBU: SPECIAL_DSUBU(); break; case R4300i_SPECIAL_DSLL: SPECIAL_DSLL(); break; case R4300i_SPECIAL_DSRL: SPECIAL_DSRL(); break; case R4300i_SPECIAL_DSRA: SPECIAL_DSRA(); break; case R4300i_SPECIAL_DSLL32: SPECIAL_DSLL32(); break; case R4300i_SPECIAL_DSRL32: SPECIAL_DSRL32(); break; case R4300i_SPECIAL_DSRA32: SPECIAL_DSRA32(); break; default: UnknownOpcode(); break; } break; case R4300i_REGIMM: switch (m_Opcode.rt) { case R4300i_REGIMM_BLTZ:Compile_Branch(BLTZ_Compare,BranchTypeRs, false); break; case R4300i_REGIMM_BGEZ:Compile_Branch(BGEZ_Compare,BranchTypeRs, false); break; case R4300i_REGIMM_BLTZL:Compile_BranchLikely(BLTZ_Compare, false); break; case R4300i_REGIMM_BGEZL:Compile_BranchLikely(BGEZ_Compare, false); break; case R4300i_REGIMM_BLTZAL:Compile_Branch(BLTZ_Compare,BranchTypeRs, true); break; case R4300i_REGIMM_BGEZAL:Compile_Branch(BGEZ_Compare,BranchTypeRs, true); break; default: UnknownOpcode(); break; } break; case R4300i_BEQ: Compile_Branch(BEQ_Compare,BranchTypeRsRt,false); break; case R4300i_BNE: Compile_Branch(BNE_Compare,BranchTypeRsRt,false); break; case R4300i_BGTZ:Compile_Branch(BGTZ_Compare,BranchTypeRs,false); break; case R4300i_BLEZ:Compile_Branch(BLEZ_Compare,BranchTypeRs,false); break; case R4300i_J: J(); break; case R4300i_JAL: JAL(); break; case R4300i_ADDI: ADDI(); break; case R4300i_ADDIU: ADDIU(); break; case R4300i_SLTI: SLTI(); break; case R4300i_SLTIU: SLTIU(); break; case R4300i_ANDI: ANDI(); break; case R4300i_ORI: ORI(); break; case R4300i_XORI: XORI(); break; case R4300i_LUI: LUI(); break; case R4300i_CP0: switch (m_Opcode.rs) { case R4300i_COP0_MF: COP0_MF(); break; case R4300i_COP0_MT: COP0_MT(); break; default: if ( (m_Opcode.rs & 0x10 ) != 0 ) { switch( m_Opcode.funct ) { case R4300i_COP0_CO_TLBR: COP0_CO_TLBR(); break; case R4300i_COP0_CO_TLBWI: COP0_CO_TLBWI(); break; case R4300i_COP0_CO_TLBWR: COP0_CO_TLBWR(); break; case R4300i_COP0_CO_TLBP: COP0_CO_TLBP(); break; case R4300i_COP0_CO_ERET: COP0_CO_ERET(); break; default: UnknownOpcode(); break; } } else { UnknownOpcode(); } } break; case R4300i_CP1: switch (m_Opcode.rs) { case R4300i_COP1_MF: COP1_MF(); break; case R4300i_COP1_DMF: COP1_DMF(); break; case R4300i_COP1_CF: COP1_CF(); break; case R4300i_COP1_MT: COP1_MT(); break; case R4300i_COP1_DMT: COP1_DMT(); break; case R4300i_COP1_CT: COP1_CT(); break; case R4300i_COP1_BC: switch (m_Opcode.ft) { case R4300i_COP1_BC_BCF: Compile_Branch(COP1_BCF_Compare,BranchTypeCop1,false); break; case R4300i_COP1_BC_BCT: Compile_Branch(COP1_BCT_Compare,BranchTypeCop1,false); break; case R4300i_COP1_BC_BCFL: Compile_BranchLikely(COP1_BCF_Compare,false); break; case R4300i_COP1_BC_BCTL: Compile_BranchLikely(COP1_BCT_Compare,false); break; default: UnknownOpcode(); break; } break; case R4300i_COP1_S: switch (m_Opcode.funct) { case R4300i_COP1_FUNCT_ADD: COP1_S_ADD(); break; case R4300i_COP1_FUNCT_SUB: COP1_S_SUB(); break; case R4300i_COP1_FUNCT_MUL: COP1_S_MUL(); break; case R4300i_COP1_FUNCT_DIV: COP1_S_DIV(); break; case R4300i_COP1_FUNCT_ABS: COP1_S_ABS(); break; case R4300i_COP1_FUNCT_NEG: COP1_S_NEG(); break; case R4300i_COP1_FUNCT_SQRT: COP1_S_SQRT(); break; case R4300i_COP1_FUNCT_MOV: COP1_S_MOV(); break; case R4300i_COP1_FUNCT_TRUNC_L: COP1_S_TRUNC_L(); break; case R4300i_COP1_FUNCT_CEIL_L: COP1_S_CEIL_L(); break; //added by Witten case R4300i_COP1_FUNCT_FLOOR_L: COP1_S_FLOOR_L(); break; //added by Witten case R4300i_COP1_FUNCT_ROUND_W: COP1_S_ROUND_W(); break; case R4300i_COP1_FUNCT_TRUNC_W: COP1_S_TRUNC_W(); break; case R4300i_COP1_FUNCT_CEIL_W: COP1_S_CEIL_W(); break; //added by Witten case R4300i_COP1_FUNCT_FLOOR_W: COP1_S_FLOOR_W(); break; case R4300i_COP1_FUNCT_CVT_D: COP1_S_CVT_D(); break; case R4300i_COP1_FUNCT_CVT_W: COP1_S_CVT_W(); break; case R4300i_COP1_FUNCT_CVT_L: COP1_S_CVT_L(); break; case R4300i_COP1_FUNCT_C_F: case R4300i_COP1_FUNCT_C_UN: case R4300i_COP1_FUNCT_C_EQ: case R4300i_COP1_FUNCT_C_UEQ: case R4300i_COP1_FUNCT_C_OLT: case R4300i_COP1_FUNCT_C_ULT: case R4300i_COP1_FUNCT_C_OLE: case R4300i_COP1_FUNCT_C_ULE: case R4300i_COP1_FUNCT_C_SF: case R4300i_COP1_FUNCT_C_NGLE: case R4300i_COP1_FUNCT_C_SEQ: case R4300i_COP1_FUNCT_C_NGL: case R4300i_COP1_FUNCT_C_LT: case R4300i_COP1_FUNCT_C_NGE: case R4300i_COP1_FUNCT_C_LE: case R4300i_COP1_FUNCT_C_NGT: COP1_S_CMP(); break; default: UnknownOpcode(); break; } break; case R4300i_COP1_D: switch (m_Opcode.funct) { case R4300i_COP1_FUNCT_ADD: COP1_D_ADD(); break; case R4300i_COP1_FUNCT_SUB: COP1_D_SUB(); break; case R4300i_COP1_FUNCT_MUL: COP1_D_MUL(); break; case R4300i_COP1_FUNCT_DIV: COP1_D_DIV(); break; case R4300i_COP1_FUNCT_ABS: COP1_D_ABS(); break; case R4300i_COP1_FUNCT_NEG: COP1_D_NEG(); break; case R4300i_COP1_FUNCT_SQRT: COP1_D_SQRT(); break; case R4300i_COP1_FUNCT_MOV: COP1_D_MOV(); break; case R4300i_COP1_FUNCT_TRUNC_L: COP1_D_TRUNC_L(); break; //added by Witten case R4300i_COP1_FUNCT_CEIL_L: COP1_D_CEIL_L(); break; //added by Witten case R4300i_COP1_FUNCT_FLOOR_L: COP1_D_FLOOR_L(); break; //added by Witten case R4300i_COP1_FUNCT_ROUND_W: COP1_D_ROUND_W(); break; case R4300i_COP1_FUNCT_TRUNC_W: COP1_D_TRUNC_W(); break; case R4300i_COP1_FUNCT_CEIL_W: COP1_D_CEIL_W(); break; //added by Witten case R4300i_COP1_FUNCT_FLOOR_W: COP1_D_FLOOR_W(); break; //added by Witten case R4300i_COP1_FUNCT_CVT_S: COP1_D_CVT_S(); break; case R4300i_COP1_FUNCT_CVT_W: COP1_D_CVT_W(); break; case R4300i_COP1_FUNCT_CVT_L: COP1_D_CVT_L(); break; case R4300i_COP1_FUNCT_C_F: case R4300i_COP1_FUNCT_C_UN: case R4300i_COP1_FUNCT_C_EQ: case R4300i_COP1_FUNCT_C_UEQ: case R4300i_COP1_FUNCT_C_OLT: case R4300i_COP1_FUNCT_C_ULT: case R4300i_COP1_FUNCT_C_OLE: case R4300i_COP1_FUNCT_C_ULE: case R4300i_COP1_FUNCT_C_SF: case R4300i_COP1_FUNCT_C_NGLE: case R4300i_COP1_FUNCT_C_SEQ: case R4300i_COP1_FUNCT_C_NGL: case R4300i_COP1_FUNCT_C_LT: case R4300i_COP1_FUNCT_C_NGE: case R4300i_COP1_FUNCT_C_LE: case R4300i_COP1_FUNCT_C_NGT: COP1_D_CMP(); break; default: UnknownOpcode(); break; } break; case R4300i_COP1_W: switch (m_Opcode.funct) { case R4300i_COP1_FUNCT_CVT_S: COP1_W_CVT_S(); break; case R4300i_COP1_FUNCT_CVT_D: COP1_W_CVT_D(); break; default: UnknownOpcode(); break; } break; case R4300i_COP1_L: switch (m_Opcode.funct) { case R4300i_COP1_FUNCT_CVT_S: COP1_L_CVT_S(); break; case R4300i_COP1_FUNCT_CVT_D: COP1_L_CVT_D(); break; default: UnknownOpcode(); break; } break; default: UnknownOpcode(); break; } break; case R4300i_BEQL: Compile_BranchLikely(BEQ_Compare,false); break; case R4300i_BNEL: Compile_BranchLikely(BNE_Compare,false); break; case R4300i_BGTZL:Compile_BranchLikely(BGTZ_Compare,false); break; case R4300i_BLEZL:Compile_BranchLikely(BLEZ_Compare,false); break; case R4300i_DADDIU: DADDIU(); break; case R4300i_LDL: _MMU->Compile_LDL(); break; case R4300i_LDR: _MMU->Compile_LDR(); break; case R4300i_LB: _MMU->Compile_LB(); break; case R4300i_LH: _MMU->Compile_LH(); break; case R4300i_LWL: _MMU->Compile_LWL(); break; case R4300i_LW: _MMU->Compile_LW(); break; case R4300i_LBU: _MMU->Compile_LBU(); break; case R4300i_LHU: _MMU->Compile_LHU(); break; case R4300i_LWR: _MMU->Compile_LWR(); break; case R4300i_LWU: _MMU->Compile_LWU(); break; //added by Witten case R4300i_SB: _MMU->Compile_SB(); break; case R4300i_SH: _MMU->Compile_SH(); break; case R4300i_SWL: _MMU->Compile_SWL(); break; case R4300i_SW: _MMU->Compile_SW(); break; case R4300i_SWR: _MMU->Compile_SWR(); break; case R4300i_SDL: _MMU->Compile_SDL(); break; case R4300i_SDR: _MMU->Compile_SDR(); break; case R4300i_CACHE: CACHE(); break; case R4300i_LL: LL(); break; case R4300i_LWC1: _MMU->Compile_LWC1(); break; case R4300i_LDC1: _MMU->Compile_LDC1(); break; case R4300i_SC: SC(); break; case R4300i_LD: _MMU->Compile_LD(); break; case R4300i_SWC1: _MMU->Compile_SWC1(); break; case R4300i_SDC1: _MMU->Compile_SDC1(); break; case R4300i_SD: _MMU->Compile_SD(); break; default: UnknownOpcode(); break; } if (!bRegCaching()) { m_RegWorkingSet.WriteBackRegisters(); } m_RegWorkingSet.UnMap_AllFPRs(); if ((m_CompilePC &0xFFC) == 0xFFC) { if (m_NextInstruction == DO_DELAY_SLOT) { _Notify->BreakPoint(__FILE__,__LINE__); } if (m_NextInstruction == NORMAL) { if (m_DelaySlot) { CompileExit (m_CompilePC, m_Jump.TargetPC,m_RegWorkingSet,CExitInfo::Normal,true,NULL); } else { CompileExit (m_CompilePC, m_CompilePC + 4,m_RegWorkingSet,CExitInfo::Normal,true,NULL); } m_NextInstruction = END_BLOCK; } } switch (m_NextInstruction) { case NORMAL: m_CompilePC += 4; break; case DO_DELAY_SLOT: m_NextInstruction = DELAY_SLOT; m_CompilePC += 4; break; case DELAY_SLOT: m_NextInstruction = DELAY_SLOT_DONE; m_RegWorkingSet.SetBlockCycleCount(m_RegWorkingSet.GetBlockCycleCount() - CountPerOp()); m_CompilePC -= 4; break; } if (m_DelaySlot) { if ((CompilePC() & 0xFFC) != 0xFFC) { m_CompilePC = m_Jump.JumpPC; m_Jump.RegSet = m_RegWorkingSet; m_Jump.FallThrough = true; GenerateSectionLinkage(); } else { CompileExit (m_Jump.JumpPC, m_Jump.TargetPC,m_RegWorkingSet,CExitInfo::Normal,true,NULL); } m_NextInstruction = END_BLOCK; } else if (m_NextInstruction != END_BLOCK && m_CompilePC == ContinueSectionPC) { if (m_NextInstruction != NORMAL) { _Notify->BreakPoint(__FILE__,__LINE__); } m_CompilePC -= 4; m_Cont.RegSet = m_RegWorkingSet; m_Cont.FallThrough = true; m_Cont.JumpPC = m_CompilePC; GenerateSectionLinkage(); m_NextInstruction = END_BLOCK; } } while (m_NextInstruction != END_BLOCK); return true; } void CCodeSection::AddParent(CCodeSection * Parent ) { if (this == NULL) { return; } if (Parent == NULL) { m_RegWorkingSet = m_RegEnter; return; } // check to see if we already have the parent in the list for (SECTION_LIST::iterator iter = m_ParentSection.begin(); iter != m_ParentSection.end(); iter++) { if (*iter == Parent) { return; } } m_ParentSection.push_back(Parent); if (m_ParentSection.size() == 1) { if (Parent->m_ContinueSection == this) { m_RegEnter = Parent->m_Cont.RegSet; } else if (Parent->m_JumpSection == this) { m_RegEnter = Parent->m_Jump.RegSet; } else { _Notify->DisplayError("How are these sections joined?????"); } m_RegWorkingSet = m_RegEnter; } else { if (Parent->m_ContinueSection == this) { TestRegConstantStates(Parent->m_Cont.RegSet,m_RegEnter); } if (Parent->m_JumpSection == this) { TestRegConstantStates(Parent->m_Jump.RegSet,m_RegEnter); } m_RegWorkingSet = m_RegEnter; } } void CCodeSection::SwitchParent(CCodeSection * OldParent, CCodeSection * NewParent ) { if (this == NULL) { return; } bool bFoundOldParent = false; for (SECTION_LIST::iterator iter = m_ParentSection.begin(); iter != m_ParentSection.end(); iter++) { if (*iter != OldParent) { continue; } bFoundOldParent = true; m_ParentSection.erase(iter); break; } if (!bFoundOldParent) { _Notify->BreakPoint(__FILE__,__LINE__); } m_ParentSection.push_back(NewParent); } void CCodeSection::TestRegConstantStates( CRegInfo & Base, CRegInfo & Reg ) { for (int i = 0; i < 32; i++) { if (Reg.MipsRegState(i) != Base.MipsRegState(i)) { Reg.SetMipsRegState(i,CRegInfo::STATE_UNKNOWN); } if (Reg.IsConst(i)) { if (Reg.Is32Bit(i)) { if (Reg.MipsRegLo(i) != Base.MipsRegLo(i)) { Reg.SetMipsRegState(i, CRegInfo::STATE_UNKNOWN); } } else { if (Reg.MipsReg(i) != Base.MipsReg(i)) { Reg.SetMipsRegState(i, CRegInfo::STATE_UNKNOWN); } } } } } void CCodeSection::DetermineLoop(DWORD Test, DWORD Test2, DWORD TestID) { if (this == NULL) { return; } if (m_SectionID == TestID) { if (m_Test2 != Test2) { m_Test2 = Test2; m_ContinueSection->DetermineLoop(Test,Test2,TestID); m_JumpSection->DetermineLoop(Test,Test2,TestID); if (m_Test != Test) { m_Test = Test; if (m_ContinueSection != NULL) { m_ContinueSection->DetermineLoop(Test,m_BlockInfo->NextTest(),m_ContinueSection->m_SectionID); } if (m_JumpSection != NULL) { m_JumpSection->DetermineLoop(Test,m_BlockInfo->NextTest(),m_JumpSection->m_SectionID); } } } else { m_InLoop = true; } } else { if (m_Test2 != Test2) { m_Test2 = Test2; m_ContinueSection->DetermineLoop(Test,Test2,TestID); m_JumpSection->DetermineLoop(Test,Test2,TestID); } } } CCodeSection * CCodeSection::ExistingSection(DWORD Addr, DWORD Test) { if (this == NULL) { return NULL; } if (m_EnterPC == Addr && m_LinkAllowed) { return this; } if (m_Test == Test) { return NULL; } m_Test = Test; CCodeSection * Section = m_JumpSection->ExistingSection(Addr,Test); if (Section != NULL) { return Section; } Section = m_ContinueSection->ExistingSection(Addr,Test); if (Section != NULL) { return Section; } return NULL; } bool CCodeSection::SectionAccessible ( DWORD SectionId, DWORD Test ) { if (this == NULL) { return false; } if (m_SectionID == SectionId) { return true; } if (m_Test == Test) { return false; } m_Test = Test; if (m_ContinueSection->SectionAccessible(SectionId,Test)) { return true; } return m_JumpSection->SectionAccessible(SectionId,Test); } void CCodeSection::UnlinkParent( CCodeSection * Parent, bool ContinueSection ) { if (this == NULL) { return; } CPU_Message(__FUNCTION__ ": Section %d Parent: %d ContinueSection = %s",m_SectionID,Parent->m_SectionID,ContinueSection?"Yes" :"No"); if (Parent->m_ContinueSection == this && Parent->m_JumpSection == this) { _Notify->BreakPoint(__FILE__,__LINE__); } SECTION_LIST::iterator iter = m_ParentSection.begin(); while ( iter != m_ParentSection.end()) { CCodeSection * ParentIter = *iter; if (ParentIter == Parent && (Parent->m_ContinueSection != this || Parent->m_JumpSection != this)) { m_ParentSection.erase(iter); iter = m_ParentSection.begin(); } else { iter++; } } if (ContinueSection && Parent->m_ContinueSection == this) { Parent->m_ContinueSection = NULL; } if (!ContinueSection && Parent->m_JumpSection == this) { Parent->m_JumpSection = NULL; } bool bRemove = false; if (m_ParentSection.size() > 0) { if (!m_BlockInfo->SectionAccessible(m_SectionID)) { for (SECTION_LIST::iterator iter = m_ParentSection.begin(); iter != m_ParentSection.end(); iter++) { CCodeSection * ParentIter = *iter; if (ParentIter->m_ContinueSection == this) { if (ParentIter->m_CompiledLocation) { _Notify->BreakPoint(__FILE__,__LINE__); } ParentIter->m_ContinueSection = NULL; } if (ParentIter->m_JumpSection == this) { if (ParentIter->m_CompiledLocation) { _Notify->BreakPoint(__FILE__,__LINE__); } ParentIter->m_JumpSection = NULL; } } bRemove = true; } } else { bRemove = true; } if (bRemove) { if (m_JumpSection != NULL) { m_JumpSection->UnlinkParent(this,false); } if (m_ContinueSection != NULL) { m_ContinueSection->UnlinkParent(this,true); } } } bool CCodeSection::IsAllParentLoops(CCodeSection * Parent, bool IgnoreIfCompiled, DWORD Test) { if (IgnoreIfCompiled && Parent->m_CompiledLocation != NULL) { return true; } if (!m_InLoop) { return false; } if (!Parent->m_InLoop) { return false; } if (Parent->m_ParentSection.empty()) { return false; } if (this == Parent) { return true; } if (Parent->m_Test == Test) { return true; } Parent->m_Test = Test; for (SECTION_LIST::iterator iter = Parent->m_ParentSection.begin(); iter != Parent->m_ParentSection.end(); iter++) { CCodeSection * ParentSection = *iter; if (!IsAllParentLoops(ParentSection,IgnoreIfCompiled,Test)) { return false; } } return true; } bool CCodeSection::SetupRegisterForLoop ( void ) { CRegInfo OriginalReg = m_RegWorkingSet; if (!LoopAnalysis(m_BlockInfo, this).SetupRegisterForLoop()) { return false; } for (int i = 1; i < 32; i++) { if (OriginalReg.MipsRegState(i) != m_RegEnter.MipsRegState(i)) { UnMap_GPR(i,true); } } return true; } bool CCodeSection::InheritParentInfo ( void ) { if (m_CompiledLocation == NULL) { m_CompiledLocation = m_RecompPos; DisplaySectionInformation(); m_CompiledLocation = NULL; } else { DisplaySectionInformation(); } if (m_ParentSection.empty()) { m_RegWorkingSet = m_RegEnter; return true; } if (m_ParentSection.size() == 1) { CCodeSection * Parent = *(m_ParentSection.begin()); if (Parent->m_CompiledLocation == NULL) { _Notify->BreakPoint(__FILE__,__LINE__); } CJumpInfo * JumpInfo = this == Parent->m_ContinueSection ? &Parent->m_Cont : &Parent->m_Jump; m_RegEnter = JumpInfo->RegSet; if (JumpInfo->LinkLocation != NULL) { CPU_Message(" Section_%d:",m_SectionID); SetJump32(JumpInfo->LinkLocation,(DWORD *)m_RecompPos); if (JumpInfo->LinkLocation2 != NULL) { SetJump32(JumpInfo->LinkLocation2,(DWORD *)m_RecompPos); } } m_RegWorkingSet = m_RegEnter; return true; } //Multiple Parents BLOCK_PARENT_LIST ParentList; SECTION_LIST::iterator iter; for (iter = m_ParentSection.begin(); iter != m_ParentSection.end(); iter++) { CCodeSection * Parent = *iter; BLOCK_PARENT BlockParent; if (Parent->m_CompiledLocation == NULL) { continue; } if (Parent->m_JumpSection != Parent->m_ContinueSection) { BlockParent.Parent = Parent; BlockParent.JumpInfo = this == Parent->m_ContinueSection?&Parent->m_Cont:&Parent->m_Jump; ParentList.push_back(BlockParent); } else { BlockParent.Parent = Parent; BlockParent.JumpInfo = &Parent->m_Cont; ParentList.push_back(BlockParent); BlockParent.Parent = Parent; BlockParent.JumpInfo = &Parent->m_Jump; ParentList.push_back(BlockParent); } } size_t NoOfCompiledParents = ParentList.size(); if (NoOfCompiledParents == 0) { _Notify->BreakPoint(__FILE__,__LINE__); return false; } // Add all the uncompiled blocks to the end of the list for (iter = m_ParentSection.begin(); iter != m_ParentSection.end(); iter++) { CCodeSection * Parent = *iter; BLOCK_PARENT BlockParent; if (Parent->m_CompiledLocation != NULL) { continue; } if (Parent->m_JumpSection != Parent->m_ContinueSection) { BlockParent.Parent = Parent; BlockParent.JumpInfo = this == Parent->m_ContinueSection?&Parent->m_Cont:&Parent->m_Jump; ParentList.push_back(BlockParent); } else { BlockParent.Parent = Parent; BlockParent.JumpInfo = &Parent->m_Cont; ParentList.push_back(BlockParent); BlockParent.Parent = Parent; BlockParent.JumpInfo = &Parent->m_Jump; ParentList.push_back(BlockParent); } } int FirstParent = -1; for (size_t i = 0; i < NoOfCompiledParents;i++) { if (!ParentList[i].JumpInfo->FallThrough) { continue; } if (FirstParent != -1) { _Notify->BreakPoint(__FILE__,__LINE__); } FirstParent = i; } if (FirstParent == -1) { FirstParent = 0; } //Link First Parent to start CCodeSection * Parent = ParentList[FirstParent].Parent; CJumpInfo * JumpInfo = ParentList[FirstParent].JumpInfo; m_RegWorkingSet = JumpInfo->RegSet; m_RegWorkingSet.ResetX86Protection(); if (JumpInfo->LinkLocation != NULL) { CPU_Message(" Section_%d (from %d):",m_SectionID,Parent->m_SectionID); SetJump32(JumpInfo->LinkLocation,(DWORD *)m_RecompPos); JumpInfo->LinkLocation = NULL; if (JumpInfo->LinkLocation2 != NULL) { SetJump32(JumpInfo->LinkLocation2,(DWORD *)m_RecompPos); JumpInfo->LinkLocation2 = NULL; } } UpdateCounters(m_RegWorkingSet,m_EnterPC < JumpInfo->JumpPC,true); if (JumpInfo->JumpPC == (DWORD)-1) { _Notify->BreakPoint(__FILE__,__LINE__); } if (m_EnterPC <= JumpInfo->JumpPC) { CPU_Message("CompileSystemCheck 10"); CompileSystemCheck(m_EnterPC,m_RegWorkingSet); } JumpInfo->FallThrough = false; //Fix up initial state UnMap_AllFPRs(); //determine loop reg usage if (m_InLoop && ParentList.size() > 1) { if (!SetupRegisterForLoop()) { return false; } m_RegWorkingSet.SetRoundingModel(CRegInfo::RoundUnknown); } for (size_t i = 0; i < ParentList.size(); i++) { x86Reg MemoryStackPos; int i2; if (i == (size_t)FirstParent) { continue; } Parent = ParentList[i].Parent; if (Parent->m_CompiledLocation == NULL) { continue; } CRegInfo * RegSet = &ParentList[i].JumpInfo->RegSet; if (m_RegWorkingSet.GetRoundingModel() != RegSet->GetRoundingModel()) { m_RegWorkingSet.SetRoundingModel(CRegInfo::RoundUnknown); } //Find Parent MapRegState MemoryStackPos = x86_Unknown; for (i2 = 0; i2 < sizeof(x86_Registers)/ sizeof(x86_Registers[0]); i2++) { if (RegSet->GetX86Mapped(x86_Registers[i2]) == CRegInfo::Stack_Mapped) { MemoryStackPos = x86_Registers[i2]; break; } } if (MemoryStackPos == x86_Unknown) { // if the memory stack position is not mapped then unmap it x86Reg MemStackReg = Get_MemoryStack(); if (MemStackReg != x86_Unknown) { UnMap_X86reg(MemStackReg); } } for (i2 = 1; i2 < 32; i2++) { if (Is32BitMapped(i2)) { switch (RegSet->MipsRegState(i2)) { case CRegInfo::STATE_MAPPED_64: Map_GPR_64bit(i2,i2); break; case CRegInfo::STATE_MAPPED_32_ZERO: break; case CRegInfo::STATE_MAPPED_32_SIGN: if (IsUnsigned(i2)) { m_RegWorkingSet.SetMipsRegState(i2,CRegInfo::STATE_MAPPED_32_SIGN); } break; case CRegInfo::STATE_CONST_64: Map_GPR_64bit(i2,i2); break; case CRegInfo::STATE_CONST_32: if ((RegSet->MipsRegLo_S(i2) < 0) && IsUnsigned(i2)) { m_RegWorkingSet.SetMipsRegState(i2,CRegInfo::STATE_MAPPED_32_SIGN); } break; case CRegInfo::STATE_UNKNOWN: if (b32BitCore()) { Map_GPR_32bit(i2,true,i2); } else { //Map_GPR_32bit(i2,true,i2); Map_GPR_64bit(i2,i2); //?? //UnMap_GPR(Section,i2,true); ?? } break; default: _Notify->DisplayError("Unknown CPU State(%d) in InheritParentInfo",MipsRegState(i2)); } } if (IsConst(i2)) { if (MipsRegState(i2) != RegSet->MipsRegState(i2)) { if (Is32Bit(i2)) { Map_GPR_32bit(i2,true,i2); } else { Map_GPR_32bit(i2,true,i2); } } else if (Is32Bit(i2) && MipsRegLo(i2) != RegSet->MipsRegLo(i2)) { Map_GPR_32bit(i2,true,i2); } else if (Is64Bit(i2) && MipsReg(i2) != RegSet->MipsReg(i2)) { Map_GPR_32bit(i2,true,i2); } } ResetX86Protection(); } if (MemoryStackPos > 0) { Map_MemoryStack(MemoryStackPos,true); } } m_RegEnter = m_RegWorkingSet; //Sync registers for different blocks stdstr_f Label("Section_%d",m_SectionID); int CurrentParent = FirstParent; bool NeedSync = false; for (size_t i = 0; i < NoOfCompiledParents; i++) { CRegInfo * RegSet; int i2; if (i == (size_t)FirstParent) { continue; } Parent = ParentList[i].Parent; JumpInfo = ParentList[i].JumpInfo; RegSet = &ParentList[i].JumpInfo->RegSet; if (JumpInfo->RegSet.GetBlockCycleCount() != 0) { NeedSync = true; } for (i2 = 0; !NeedSync && i2 < 8; i2++) { if (m_RegWorkingSet.FpuMappedTo(i2) == (DWORD)-1) { NeedSync = true; } } for (i2 = 0; !NeedSync && i2 < sizeof(x86_Registers)/ sizeof(x86_Registers[0]); i2++) { if (m_RegWorkingSet.GetX86Mapped(x86_Registers[i2]) == CRegInfo::Stack_Mapped) { if (m_RegWorkingSet.GetX86Mapped(x86_Registers[i2]) != RegSet->GetX86Mapped(x86_Registers[i2])) { NeedSync = true; } break; } } for (i2 = 0; !NeedSync && i2 < 32; i2++) { if (NeedSync == true) { break; } if (m_RegWorkingSet.MipsRegState(i2) != RegSet->MipsRegState(i2)) { NeedSync = true; continue; } switch (m_RegWorkingSet.MipsRegState(i2)) { case CRegInfo::STATE_UNKNOWN: break; case CRegInfo::STATE_MAPPED_64: if (MipsRegMapHi(i2) != RegSet->MipsRegMapHi(i2) || MipsRegMapLo(i2) != RegSet->MipsRegMapLo(i2)) { NeedSync = true; } break; case CRegInfo::STATE_MAPPED_32_ZERO: case CRegInfo::STATE_MAPPED_32_SIGN: if (MipsRegMapLo(i2) != RegSet->MipsRegMapLo(i2)) { //DisplayError("Parent: %d",Parent->SectionID); NeedSync = true; } break; case CRegInfo::STATE_CONST_32: if (MipsRegLo(i2) != RegSet->MipsRegLo(i2)) { _Notify->BreakPoint(__FILE__,__LINE__); NeedSync = true; } break; default: WriteTraceF(TraceError,"Unhandled Reg state %d\nin InheritParentInfo",MipsRegState(i2)); _Notify->BreakPoint(__FILE__,__LINE__); } } if (NeedSync == false) { continue; } Parent = ParentList[CurrentParent].Parent; JumpInfo = ParentList[CurrentParent].JumpInfo; JmpLabel32(Label.c_str(),0); JumpInfo->LinkLocation = (DWORD *)(m_RecompPos - 4); JumpInfo->LinkLocation2 = NULL; CurrentParent = i; Parent = ParentList[CurrentParent].Parent; JumpInfo = ParentList[CurrentParent].JumpInfo; CPU_Message(" Section_%d (from %d):",m_SectionID,Parent->m_SectionID); if (JumpInfo->LinkLocation != NULL) { SetJump32(JumpInfo->LinkLocation,(DWORD *)m_RecompPos); JumpInfo->LinkLocation = NULL; if (JumpInfo->LinkLocation2 != NULL) { SetJump32(JumpInfo->LinkLocation2,(DWORD *)m_RecompPos); JumpInfo->LinkLocation2 = NULL; } } //if (m_EnterPC == 0x8031CE44 && m_SectionID == 6) //{ // _Notify->BreakPoint(__FILE__,__LINE__); //} m_RegWorkingSet = JumpInfo->RegSet; if (m_EnterPC < JumpInfo->JumpPC ) { UpdateCounters(m_RegWorkingSet,true,true); CPU_Message("CompileSystemCheck 11"); CompileSystemCheck(m_EnterPC,m_RegWorkingSet); } else { UpdateCounters(m_RegWorkingSet,false,true); } SyncRegState(m_RegEnter); //Sync m_RegEnter = m_RegWorkingSet; } for (size_t i = 0; i < NoOfCompiledParents;i++) { Parent = ParentList[i].Parent; JumpInfo = ParentList[i].JumpInfo; if (JumpInfo->LinkLocation != NULL) { SetJump32(JumpInfo->LinkLocation,(DWORD *)m_RecompPos); JumpInfo->LinkLocation = NULL; if (JumpInfo->LinkLocation2 != NULL) { SetJump32(JumpInfo->LinkLocation2,(DWORD *)m_RecompPos); JumpInfo->LinkLocation2 = NULL; } } } CPU_Message(" Section_%d:",m_SectionID); m_RegWorkingSet.SetBlockCycleCount(0); return true; } bool CCodeSection::DisplaySectionInformation (DWORD ID, DWORD Test) { if (!bX86Logging) { return false; } if (this == NULL) { return false; } if (m_Test == Test) { return false; } m_Test = Test; if (m_SectionID != ID) { if (m_ContinueSection->DisplaySectionInformation(ID,Test)) { return true; } if (m_JumpSection->DisplaySectionInformation(ID,Test)) { return true; } return false; } DisplaySectionInformation(); return true; } void CCodeSection::DisplaySectionInformation (void) { if (m_SectionID == 0) { return; } CPU_Message("====== Section %d ======",m_SectionID); CPU_Message("Start PC: %X",m_EnterPC); CPU_Message("End PC: %X",m_EndPC); CPU_Message("CompiledLocation: %X",m_CompiledLocation); if (!m_ParentSection.empty()) { stdstr ParentList; for (SECTION_LIST::iterator iter = m_ParentSection.begin(); iter != m_ParentSection.end(); iter++) { CCodeSection * Parent = *iter; if (!ParentList.empty()) { ParentList += ", "; } ParentList += stdstr_f("%d",Parent->m_SectionID); } CPU_Message("Number of parents: %d (%s)",m_ParentSection.size(),ParentList.c_str()); } CPU_Message("Jump Address: 0x%08X",m_Jump.JumpPC); CPU_Message("Jump Target Address: 0x%08X",m_Jump.TargetPC); if (m_JumpSection != NULL) { CPU_Message("Jump Section: %d",m_JumpSection->m_SectionID); } else { CPU_Message("Jump Section: None"); } CPU_Message("Continue Address: 0x%08X",m_Cont.JumpPC); CPU_Message("Continue Target Address: 0x%08X",m_Cont.TargetPC); if (m_ContinueSection != NULL) { CPU_Message("Continue Section: %d",m_ContinueSection->m_SectionID); } else { CPU_Message("Continue Section: None"); } CPU_Message("In Loop: %s",m_InLoop ? "Yes" : "No"); CPU_Message("======================="); }