#include "ARMJIT.h" #include #include #include "Config.h" #include "ARMJIT_Internal.h" #if defined(__x86_64__) #include "ARMJIT_x64/ARMJIT_Compiler.h" #else #include "ARMJIT_A64/ARMJIT_Compiler.h" #endif #include "ARMInterpreter_ALU.h" #include "ARMInterpreter_LoadStore.h" #include "ARMInterpreter_Branch.h" #include "ARMInterpreter.h" #include "GPU3D.h" #include "SPU.h" #include "Wifi.h" #include "NDSCart.h" namespace ARMJIT { #define JIT_DEBUGPRINT(msg, ...) //#define JIT_DEBUGPRINT(msg, ...) printf(msg, ## __VA_ARGS__) Compiler* compiler; const u32 ExeMemRegionSizes[] = { 0x8000, // Unmapped Region (dummy) 0x8000, // ITCM 4*1024*1024, // Main RAM 0x8000, // SWRAM 0xA4000, // LCDC 0x8000, // ARM9 BIOS 0x4000, // ARM7 BIOS 0x10000, // ARM7 WRAM 0x40000 // ARM7 WVRAM }; const u32 ExeMemRegionOffsets[] = { 0, 0x8000, 0x10000, 0x410000, 0x418000, 0x4BC000, 0x4C4000, 0x4C8000, 0x4D8000, 0x518000, }; #define DUP2(x) x, x const static ExeMemKind JIT_MEM[2][32] = { //arm9 { /* 0X*/ DUP2(exeMem_ITCM), /* 1X*/ DUP2(exeMem_ITCM), // mirror /* 2X*/ DUP2(exeMem_MainRAM), /* 3X*/ DUP2(exeMem_SWRAM), /* 4X*/ DUP2(exeMem_Unmapped), /* 5X*/ DUP2(exeMem_Unmapped), /* 6X*/ exeMem_Unmapped, exeMem_LCDC, // Plain ARM9-CPU Access (LCDC mode) (max 656KB) /* 7X*/ DUP2(exeMem_Unmapped), /* 8X*/ DUP2(exeMem_Unmapped), /* 9X*/ DUP2(exeMem_Unmapped), /* AX*/ DUP2(exeMem_Unmapped), /* BX*/ DUP2(exeMem_Unmapped), /* CX*/ DUP2(exeMem_Unmapped), /* DX*/ DUP2(exeMem_Unmapped), /* EX*/ DUP2(exeMem_Unmapped), /* FX*/ DUP2(exeMem_ARM9_BIOS) }, //arm7 { /* 0X*/ DUP2(exeMem_ARM7_BIOS), /* 1X*/ DUP2(exeMem_Unmapped), /* 2X*/ DUP2(exeMem_MainRAM), /* 3X*/ exeMem_SWRAM, exeMem_ARM7_WRAM, /* 4X*/ DUP2(exeMem_Unmapped), /* 5X*/ DUP2(exeMem_Unmapped), /* 6X*/ DUP2(exeMem_ARM7_WVRAM), /* contrary to Gbatek, melonDS and itself, DeSmuME doesn't mirror the 64 MB region at 0x6800000 */ /* 7X*/ DUP2(exeMem_Unmapped), /* 8X*/ DUP2(exeMem_Unmapped), /* 9X*/ DUP2(exeMem_Unmapped), /* AX*/ DUP2(exeMem_Unmapped), /* BX*/ DUP2(exeMem_Unmapped), /* CX*/ DUP2(exeMem_Unmapped), /* DX*/ DUP2(exeMem_Unmapped), /* EX*/ DUP2(exeMem_Unmapped), /* FX*/ DUP2(exeMem_Unmapped) } }; #undef DUP2 /* translates address to pseudo physical address - more compact, eliminates mirroring, everything comes in a row - we only need one translation table */ u32 AddrTranslate9[0x2000]; u32 AddrTranslate7[0x4000]; JitBlockEntry FastBlockAccess[ExeMemSpaceSize / 2]; AddressRange CodeRanges[ExeMemSpaceSize / 512]; TinyVector JitBlocks; JitBlock* RestoreCandidates[0x1000] = {NULL}; u32 HashRestoreCandidate(u32 pseudoPhysicalAddr) { return (u32)(((u64)pseudoPhysicalAddr * 11400714819323198485llu) >> 53); } void Init() { for (int i = 0; i < 0x2000; i++) { ExeMemKind kind = JIT_MEM[0][i >> 8]; u32 size = ExeMemRegionSizes[kind]; AddrTranslate9[i] = ExeMemRegionOffsets[kind] + ((i << 15) & (size - 1)); } for (int i = 0; i < 0x4000; i++) { ExeMemKind kind = JIT_MEM[1][i >> 9]; u32 size = ExeMemRegionSizes[kind]; AddrTranslate7[i] = ExeMemRegionOffsets[kind] + ((i << 14) & (size - 1)); } compiler = new Compiler(); } void DeInit() { delete compiler; } void FloodFillSetFlags(FetchedInstr instrs[], int start, u8 flags) { for (int j = start; j >= 0; j--) { u8 match = instrs[j].Info.WriteFlags & flags; u8 matchMaybe = (instrs[j].Info.WriteFlags >> 4) & flags; if (matchMaybe) // writes flags maybe instrs[j].SetFlags |= matchMaybe; if (match) { instrs[j].SetFlags |= match; flags &= ~match; if (!flags) return; } } } bool DecodeLiteral(const FetchedInstr& instr, u32& addr) { switch (instr.Info.Kind) { case ARMInstrInfo::ak_STR_IMM: case ARMInstrInfo::ak_STRB_IMM: addr = (instr.Addr + 8) + ((instr.Instr & 0xFFF) * (instr.Instr & (1 << 23) ? 1 : -1)); return true; case ARMInstrInfo::ak_STRD_IMM: case ARMInstrInfo::ak_STRH_IMM: addr = (instr.Addr + 8) + (((instr.Instr & 0xF00) >> 4 | (instr.Instr & 0xF)) * (instr.Instr & (1 << 23) ? 1 : -1)); return true; case ARMInstrInfo::ak_STM: // I honestly hope noone was ever crazy enough to do stm pc, {whatever} addr = instr.Addr + 8; return true; default: JIT_DEBUGPRINT("Literal %08x %x not recognised\n", instr.Instr, instr.Addr); return false; } } bool DecodeBranch(bool thumb, const FetchedInstr& instr, u32& cond, bool hasLink, u32 lr, bool& link, u32& linkAddr, u32& targetAddr) { if (thumb) { u32 r15 = instr.Addr + 4; cond = 0xE; link = instr.Info.Kind == ARMInstrInfo::tk_BL_LONG; linkAddr = instr.Addr + 4; if (instr.Info.Kind == ARMInstrInfo::tk_BL_LONG && !(instr.Instr & (1 << 12))) { targetAddr = r15 + ((s32)((instr.Instr & 0x7FF) << 21) >> 9); targetAddr += ((instr.Instr >> 16) & 0x7FF) << 1; return true; } else if (instr.Info.Kind == ARMInstrInfo::tk_B) { s32 offset = (s32)((instr.Instr & 0x7FF) << 21) >> 20; targetAddr = r15 + offset; return true; } else if (instr.Info.Kind == ARMInstrInfo::tk_BCOND) { cond = (instr.Instr >> 8) & 0xF; s32 offset = (s32)(instr.Instr << 24) >> 23; targetAddr = r15 + offset; return true; } else if (hasLink && instr.Info.Kind == ARMInstrInfo::tk_BX && instr.A_Reg(3) == 14) { JIT_DEBUGPRINT("returning!\n"); targetAddr = lr; return true; } } else { link = instr.Info.Kind == ARMInstrInfo::ak_BL; linkAddr = instr.Addr + 4; cond = instr.Cond(); if (instr.Info.Kind == ARMInstrInfo::ak_BL || instr.Info.Kind == ARMInstrInfo::ak_B) { s32 offset = (s32)(instr.Instr << 8) >> 6; u32 r15 = instr.Addr + 8; targetAddr = r15 + offset; return true; } else if (hasLink && instr.Info.Kind == ARMInstrInfo::ak_BX && instr.A_Reg(0) == 14) { JIT_DEBUGPRINT("returning!\n"); targetAddr = lr; return true; } } return false; } bool IsIdleLoop(FetchedInstr* instrs, int instrsCount) { // see https://github.com/dolphin-emu/dolphin/blob/master/Source/Core/Core/PowerPC/PPCAnalyst.cpp#L678 // it basically checks if one iteration of a loop depends on another // the rules are quite simple u16 regsWrittenTo = 0; u16 regsDisallowedToWrite = 0; for (int i = 0; i < instrsCount; i++) { //printf("instr %d %x regs(%x %x) %x %x\n", i, instrs[i].Instr, instrs[i].Info.DstRegs, instrs[i].Info.SrcRegs, regsWrittenTo, regsDisallowedToWrite); if (instrs[i].Info.SpecialKind == ARMInstrInfo::special_WriteMem) return false; if (i < instrsCount - 1 && instrs[i].Info.Branches()) return false; u16 srcRegs = instrs[i].Info.SrcRegs & ~(1 << 15); u16 dstRegs = instrs[i].Info.DstRegs & ~(1 << 15); regsDisallowedToWrite |= srcRegs & ~regsWrittenTo; if (dstRegs & regsDisallowedToWrite) return false; regsWrittenTo |= dstRegs; } return true; } typedef void (*InterpreterFunc)(ARM* cpu); void NOP(ARM* cpu) {} #define F(x) &ARMInterpreter::A_##x #define F_ALU(name, s) \ F(name##_REG_LSL_IMM##s), F(name##_REG_LSR_IMM##s), F(name##_REG_ASR_IMM##s), F(name##_REG_ROR_IMM##s), \ F(name##_REG_LSL_REG##s), F(name##_REG_LSR_REG##s), F(name##_REG_ASR_REG##s), F(name##_REG_ROR_REG##s), F(name##_IMM##s) #define F_MEM_WB(name) \ F(name##_REG_LSL), F(name##_REG_LSR), F(name##_REG_ASR), F(name##_REG_ROR), F(name##_IMM), \ F(name##_POST_REG_LSL), F(name##_POST_REG_LSR), F(name##_POST_REG_ASR), F(name##_POST_REG_ROR), F(name##_POST_IMM) #define F_MEM_HD(name) \ F(name##_REG), F(name##_IMM), F(name##_POST_REG), F(name##_POST_IMM) InterpreterFunc InterpretARM[ARMInstrInfo::ak_Count] = { F_ALU(AND,), F_ALU(AND,_S), F_ALU(EOR,), F_ALU(EOR,_S), F_ALU(SUB,), F_ALU(SUB,_S), F_ALU(RSB,), F_ALU(RSB,_S), F_ALU(ADD,), F_ALU(ADD,_S), F_ALU(ADC,), F_ALU(ADC,_S), F_ALU(SBC,), F_ALU(SBC,_S), F_ALU(RSC,), F_ALU(RSC,_S), F_ALU(ORR,), F_ALU(ORR,_S), F_ALU(MOV,), F_ALU(MOV,_S), F_ALU(BIC,), F_ALU(BIC,_S), F_ALU(MVN,), F_ALU(MVN,_S), F_ALU(TST,), F_ALU(TEQ,), F_ALU(CMP,), F_ALU(CMN,), F(MUL), F(MLA), F(UMULL), F(UMLAL), F(SMULL), F(SMLAL), F(SMLAxy), F(SMLAWy), F(SMULWy), F(SMLALxy), F(SMULxy), F(CLZ), F(QADD), F(QDADD), F(QSUB), F(QDSUB), F_MEM_WB(STR), F_MEM_WB(STRB), F_MEM_WB(LDR), F_MEM_WB(LDRB), F_MEM_HD(STRH), F_MEM_HD(LDRD), F_MEM_HD(STRD), F_MEM_HD(LDRH), F_MEM_HD(LDRSB), F_MEM_HD(LDRSH), F(SWP), F(SWPB), F(LDM), F(STM), F(B), F(BL), F(BLX_IMM), F(BX), F(BLX_REG), F(UNK), F(MSR_IMM), F(MSR_REG), F(MRS), F(MCR), F(MRC), F(SVC), NOP }; #undef F_ALU #undef F_MEM_WB #undef F_MEM_HD #undef F void T_BL_LONG(ARM* cpu) { ARMInterpreter::T_BL_LONG_1(cpu); cpu->R[15] += 2; ARMInterpreter::T_BL_LONG_2(cpu); } #define F(x) ARMInterpreter::T_##x InterpreterFunc InterpretTHUMB[ARMInstrInfo::tk_Count] = { F(LSL_IMM), F(LSR_IMM), F(ASR_IMM), F(ADD_REG_), F(SUB_REG_), F(ADD_IMM_), F(SUB_IMM_), F(MOV_IMM), F(CMP_IMM), F(ADD_IMM), F(SUB_IMM), F(AND_REG), F(EOR_REG), F(LSL_REG), F(LSR_REG), F(ASR_REG), F(ADC_REG), F(SBC_REG), F(ROR_REG), F(TST_REG), F(NEG_REG), F(CMP_REG), F(CMN_REG), F(ORR_REG), F(MUL_REG), F(BIC_REG), F(MVN_REG), F(ADD_HIREG), F(CMP_HIREG), F(MOV_HIREG), F(ADD_PCREL), F(ADD_SPREL), F(ADD_SP), F(LDR_PCREL), F(STR_REG), F(STRB_REG), F(LDR_REG), F(LDRB_REG), F(STRH_REG), F(LDRSB_REG), F(LDRH_REG), F(LDRSH_REG), F(STR_IMM), F(LDR_IMM), F(STRB_IMM), F(LDRB_IMM), F(STRH_IMM), F(LDRH_IMM), F(STR_SPREL), F(LDR_SPREL), F(PUSH), F(POP), F(LDMIA), F(STMIA), F(BCOND), F(BX), F(BLX_REG), F(B), F(BL_LONG_1), F(BL_LONG_2), F(UNK), F(SVC), T_BL_LONG // BL_LONG psudo opcode }; #undef F void CompileBlock(ARM* cpu) { bool thumb = cpu->CPSR & 0x20; if (Config::JIT_MaxBlockSize < 1) Config::JIT_MaxBlockSize = 1; if (Config::JIT_MaxBlockSize > 32) Config::JIT_MaxBlockSize = 32; u32 blockAddr = cpu->R[15] - (thumb ? 2 : 4); if (!(cpu->Num == 0 ? IsMapped<0>(blockAddr) : IsMapped<1>(blockAddr))) { printf("Trying to compile a block in unmapped memory: %x\n", blockAddr); } u32 pseudoPhysicalAddr = cpu->Num == 0 ? TranslateAddr<0>(blockAddr) : TranslateAddr<1>(blockAddr); FetchedInstr instrs[Config::JIT_MaxBlockSize]; int i = 0; u32 r15 = cpu->R[15]; u32 addresseRanges[32] = {}; u32 numAddressRanges = 0; cpu->FillPipeline(); u32 nextInstr[2] = {cpu->NextInstr[0], cpu->NextInstr[1]}; u32 nextInstrAddr[2] = {blockAddr, r15}; JIT_DEBUGPRINT("start block %x %08x (%x) %p %p (region invalidates %dx)\n", blockAddr, cpu->CPSR, pseudoPhysicalAddr, FastBlockAccess[pseudoPhysicalAddr / 2], cpu->Num == 0 ? LookUpBlock<0>(blockAddr) : LookUpBlock<1>(blockAddr), CodeRanges[pseudoPhysicalAddr / 512].TimesInvalidated); u32 lastSegmentStart = blockAddr; u32 lr; bool hasLink = false; do { r15 += thumb ? 2 : 4; instrs[i].BranchFlags = 0; instrs[i].SetFlags = 0; instrs[i].Instr = nextInstr[0]; nextInstr[0] = nextInstr[1]; instrs[i].Addr = nextInstrAddr[0]; nextInstrAddr[0] = nextInstrAddr[1]; nextInstrAddr[1] = r15; JIT_DEBUGPRINT("instr %08x %x\n", instrs[i].Instr & (thumb ? 0xFFFF : ~0), instrs[i].Addr); u32 translatedAddr = (cpu->Num == 0 ? TranslateAddr<0>(instrs[i].Addr) : TranslateAddr<1>(instrs[i].Addr)) & ~0x1FF; if (i == 0 || translatedAddr != addresseRanges[numAddressRanges - 1]) { bool returning = false; for (int j = 0; j < numAddressRanges; j++) { if (addresseRanges[j] == translatedAddr) { returning = true; break; } } if (!returning) addresseRanges[numAddressRanges++] = translatedAddr; } if (cpu->Num == 0) { ARMv5* cpuv5 = (ARMv5*)cpu; if (thumb && r15 & 0x2) { nextInstr[1] >>= 16; instrs[i].CodeCycles = 0; } else { nextInstr[1] = cpuv5->CodeRead32(r15, false); instrs[i].CodeCycles = cpu->CodeCycles; } } else { ARMv4* cpuv4 = (ARMv4*)cpu; if (thumb) nextInstr[1] = cpuv4->CodeRead16(r15); else nextInstr[1] = cpuv4->CodeRead32(r15); instrs[i].CodeCycles = cpu->CodeCycles; } instrs[i].Info = ARMInstrInfo::Decode(thumb, cpu->Num, instrs[i].Instr); cpu->R[15] = r15; cpu->CurInstr = instrs[i].Instr; cpu->CodeCycles = instrs[i].CodeCycles; if (instrs[i].Info.DstRegs & (1 << 14)) hasLink = false; if (thumb) { InterpretTHUMB[instrs[i].Info.Kind](cpu); } else { if (cpu->Num == 0 && instrs[i].Info.Kind == ARMInstrInfo::ak_BLX_IMM) { ARMInterpreter::A_BLX_IMM(cpu); } else { u32 icode = ((instrs[i].Instr >> 4) & 0xF) | ((instrs[i].Instr >> 16) & 0xFF0); assert(InterpretARM[instrs[i].Info.Kind] == ARMInterpreter::ARMInstrTable[icode] || instrs[i].Info.Kind == ARMInstrInfo::ak_MOV_REG_LSL_IMM || instrs[i].Info.Kind == ARMInstrInfo::ak_Nop); if (cpu->CheckCondition(instrs[i].Cond())) InterpretARM[instrs[i].Info.Kind](cpu); else cpu->AddCycles_C(); } } instrs[i].DataCycles = cpu->DataCycles; instrs[i].DataRegion = cpu->DataRegion; if (instrs[i].Info.SpecialKind == ARMInstrInfo::special_WriteMem && instrs[i].Info.SrcRegs == (1 << 15) && instrs[i].Info.DstRegs == 0) { assert (!thumb); u32 addr; if (DecodeLiteral(instrs[i], addr)) { JIT_DEBUGPRINT("pc relative write detected\n"); u32 translatedAddr = cpu->Num == 0 ? TranslateAddr<0>(addr) : TranslateAddr<1>(addr); ARMJIT::InvalidateByAddr(translatedAddr, false); CodeRanges[translatedAddr / 512].InvalidLiterals |= (1 << ((translatedAddr & 0x1FF) / 16)); } } if (thumb && instrs[i].Info.Kind == ARMInstrInfo::tk_BL_LONG_2 && i > 0 && instrs[i - 1].Info.Kind == ARMInstrInfo::tk_BL_LONG_1) { instrs[i - 1].Info.Kind = ARMInstrInfo::tk_BL_LONG; instrs[i - 1].Instr = (instrs[i - 1].Instr & 0xFFFF) | (instrs[i].Instr << 16); instrs[i - 1].Info.DstRegs = 0xC000; instrs[i - 1].Info.SrcRegs = 0; instrs[i - 1].Info.EndBlock = true; i--; } if (instrs[i].Info.Branches() && Config::JIT_BrancheOptimisations) { bool hasBranched = cpu->R[15] != r15; bool link; u32 cond, target, linkAddr; bool staticBranch = DecodeBranch(thumb, instrs[i], cond, hasLink, lr, link, linkAddr, target); JIT_DEBUGPRINT("branch cond %x target %x (%d)\n", cond, target, hasBranched); if (staticBranch) { bool isBackJump = false; if (hasBranched) { for (int j = 0; j < i; j++) { if (instrs[i].Addr == target) { isBackJump = true; break; } } } if (cond < 0xE && target < instrs[i].Addr && target >= lastSegmentStart) { // we might have an idle loop u32 backwardsOffset = (instrs[i].Addr - target) / (thumb ? 2 : 4); if (IsIdleLoop(&instrs[i - backwardsOffset], backwardsOffset + 1)) { instrs[i].BranchFlags |= branch_IdleBranch; JIT_DEBUGPRINT("found %s idle loop %d in block %x\n", thumb ? "thumb" : "arm", cpu->Num, blockAddr); } } else if (hasBranched && !isBackJump && i + 1 < Config::JIT_MaxBlockSize) { u32 targetPseudoPhysical = cpu->Num == 0 ? TranslateAddr<0>(target) : TranslateAddr<1>(target); if (link) { lr = linkAddr; hasLink = true; } r15 = target + (thumb ? 2 : 4); assert(r15 == cpu->R[15]); JIT_DEBUGPRINT("block lengthened by static branch (target %x)\n", target); nextInstr[0] = cpu->NextInstr[0]; nextInstr[1] = cpu->NextInstr[1]; nextInstrAddr[0] = target; nextInstrAddr[1] = r15; lastSegmentStart = target; instrs[i].Info.EndBlock = false; if (cond < 0xE) instrs[i].BranchFlags |= branch_FollowCondTaken; } } if (!hasBranched && cond < 0xE && i + 1 < Config::JIT_MaxBlockSize) { instrs[i].Info.EndBlock = false; instrs[i].BranchFlags |= branch_FollowCondNotTaken; } } i++; bool canCompile = compiler->CanCompile(thumb, instrs[i - 1].Info.Kind); bool secondaryFlagReadCond = !canCompile || (instrs[i - 1].BranchFlags & (branch_FollowCondTaken | branch_FollowCondNotTaken)); if (instrs[i - 1].Info.ReadFlags != 0 || secondaryFlagReadCond) FloodFillSetFlags(instrs, i - 2, !secondaryFlagReadCond ? instrs[i - 1].Info.ReadFlags : 0xF); } while(!instrs[i - 1].Info.EndBlock && i < Config::JIT_MaxBlockSize && !cpu->Halted && (!cpu->IRQ || (cpu->CPSR & 0x80))); u32 restoreSlot = HashRestoreCandidate(pseudoPhysicalAddr); JitBlock* prevBlock = RestoreCandidates[restoreSlot]; bool mayRestore = true; if (prevBlock && prevBlock->PseudoPhysicalAddr == pseudoPhysicalAddr) { RestoreCandidates[restoreSlot] = NULL; if (prevBlock->NumInstrs == i) { for (int j = 0; j < i; j++) { if (prevBlock->Instrs()[j] != instrs[j].Instr) { mayRestore = false; break; } } } else mayRestore = false; if (prevBlock->NumAddresses == numAddressRanges) { for (int j = 0; j < numAddressRanges; j++) { if (prevBlock->AddressRanges()[j] != addresseRanges[j]) { mayRestore = false; break; } } } else mayRestore = false; } else { mayRestore = false; prevBlock = NULL; } JitBlock* block; if (!mayRestore) { if (prevBlock) delete prevBlock; block = new JitBlock(i, numAddressRanges); for (int j = 0; j < i; j++) block->Instrs()[j] = instrs[j].Instr; for (int j = 0; j < numAddressRanges; j++) block->AddressRanges()[j] = addresseRanges[j]; block->StartAddr = blockAddr; block->PseudoPhysicalAddr = pseudoPhysicalAddr; FloodFillSetFlags(instrs, i - 1, 0xF); block->EntryPoint = compiler->CompileBlock(cpu, thumb, instrs, i); } else { JIT_DEBUGPRINT("restored! %p\n", prevBlock); block = prevBlock; } for (int j = 0; j < numAddressRanges; j++) { assert(addresseRanges[j] == block->AddressRanges()[j]); CodeRanges[addresseRanges[j] / 512].Blocks.Add(block); } FastBlockAccess[block->PseudoPhysicalAddr / 2] = block->EntryPoint; JitBlocks.Add(block); } void InvalidateByAddr(u32 pseudoPhysical, bool mayRestore) { JIT_DEBUGPRINT("invalidating by addr %x\n", pseudoPhysical); AddressRange* range = &CodeRanges[pseudoPhysical / 512]; int startLength = range->Blocks.Length; for (int i = 0; i < range->Blocks.Length; i++) { assert(range->Blocks.Length == startLength); JitBlock* block = range->Blocks[i]; for (int j = 0; j < block->NumAddresses; j++) { u32 addr = block->AddressRanges()[j]; if ((addr / 512) != (pseudoPhysical / 512)) { AddressRange* otherRange = &CodeRanges[addr / 512]; assert(otherRange != range); bool removed = otherRange->Blocks.RemoveByValue(block); assert(removed); } } bool removed = JitBlocks.RemoveByValue(block); assert(removed); FastBlockAccess[block->PseudoPhysicalAddr / 2] = NULL; if (mayRestore) { u32 slot = HashRestoreCandidate(block->PseudoPhysicalAddr); if (RestoreCandidates[slot] && RestoreCandidates[slot] != block) delete RestoreCandidates[slot]; RestoreCandidates[slot] = block; } } if ((range->TimesInvalidated + 1) > range->TimesInvalidated) range->TimesInvalidated++; range->Blocks.Clear(); } void InvalidateByAddr7(u32 addr) { u32 pseudoPhysical = TranslateAddr<1>(addr); if (__builtin_expect(CodeRanges[pseudoPhysical / 512].Blocks.Length > 0, false)) InvalidateByAddr(pseudoPhysical); } void InvalidateITCM(u32 addr) { u32 pseudoPhysical = addr + ExeMemRegionOffsets[exeMem_ITCM]; if (CodeRanges[pseudoPhysical / 512].Blocks.Length > 0) InvalidateByAddr(pseudoPhysical); } void InvalidateAll() { JIT_DEBUGPRINT("invalidating all %x\n", JitBlocks.Length); for (int i = 0; i < JitBlocks.Length; i++) { JitBlock* block = JitBlocks[i]; FastBlockAccess[block->PseudoPhysicalAddr / 2] = NULL; for (int j = 0; j < block->NumAddresses; j++) { u32 addr = block->AddressRanges()[j]; AddressRange* range = &CodeRanges[addr / 512]; range->Blocks.Clear(); if (range->TimesInvalidated + 1 > range->TimesInvalidated) range->TimesInvalidated++; } u32 slot = HashRestoreCandidate(block->PseudoPhysicalAddr); if (RestoreCandidates[slot] && RestoreCandidates[slot] != block) delete RestoreCandidates[slot]; RestoreCandidates[slot] = block; } JitBlocks.Clear(); } void ResetBlockCache() { printf("Resetting JIT block cache...\n"); memset(FastBlockAccess, 0, sizeof(FastBlockAccess)); for (int i = 0; i < sizeof(RestoreCandidates)/sizeof(RestoreCandidates[0]); i++) { if (RestoreCandidates[i]) { delete RestoreCandidates[i]; RestoreCandidates[i] = NULL; } } for (int i = 0; i < JitBlocks.Length; i++) { JitBlock* block = JitBlocks[i]; for (int j = 0; j < block->NumAddresses; j++) { u32 addr = block->AddressRanges()[j]; CodeRanges[addr / 512].Blocks.Clear(); CodeRanges[addr / 512].TimesInvalidated = 0; CodeRanges[addr / 512].InvalidLiterals = 0; } delete block; } JitBlocks.Clear(); compiler->Reset(); } void* GetFuncForAddr(ARM* cpu, u32 addr, bool store, int size) { if (cpu->Num == 0) { if ((addr & 0xFF000000) == 0x04000000) { if (!store && size == 32 && addr == 0x04100010 && NDS::ExMemCnt[0] & (1<<11)) return (void*)NDSCart::ReadROMData; /* unfortunately we can't map GPU2D this way since it's hidden inside an object though GPU3D registers are accessed much more intensive */ if (addr >= 0x04000320 && addr < 0x040006A4) { switch (size | store) { case 8: return (void*)GPU3D::Read8; case 9: return (void*)GPU3D::Write8; case 16: return (void*)GPU3D::Read16; case 17: return (void*)GPU3D::Write16; case 32: return (void*)GPU3D::Read32; case 33: return (void*)GPU3D::Write32; } } switch (size | store) { case 8: return (void*)NDS::ARM9IORead8; case 9: return (void*)NDS::ARM9IOWrite8; case 16: return (void*)NDS::ARM9IORead16; case 17: return (void*)NDS::ARM9IOWrite16; case 32: return (void*)NDS::ARM9IORead32; case 33: return (void*)NDS::ARM9IOWrite32; } } } else { switch (addr & 0xFF800000) { case 0x04000000: if (addr >= 0x04000400 && addr < 0x04000520) { switch (size | store) { case 8: return (void*)SPU::Read8; case 9: return (void*)SPU::Write8; case 16: return (void*)SPU::Read16; case 17: return (void*)SPU::Write16; case 32: return (void*)SPU::Read32; case 33: return (void*)SPU::Write32; } } switch (size | store) { case 8: return (void*)NDS::ARM7IORead8; case 9: return (void*)NDS::ARM7IOWrite8; case 16: return (void*)NDS::ARM7IORead16; case 17: return (void*)NDS::ARM7IOWrite16; case 32: return (void*)NDS::ARM7IORead32; case 33: return (void*)NDS::ARM7IOWrite32; } break; case 0x04800000: if (addr < 0x04810000 && size == 16) { if (store) return (void*)Wifi::Write; else return (void*)Wifi::Read; } break; } } return NULL; } }