#include "stdafx.h" #include "Utilities/Log.h" #include "Emu/Cell/PPULLVMRecompiler.h" #include "Emu/Memory/Memory.h" #include "llvm/Support/TargetSelect.h" #include "llvm/Support/Host.h" #include "llvm/Support/ManagedStatic.h" #include "llvm/Support/raw_ostream.h" #include "llvm/ExecutionEngine/GenericValue.h" #include "llvm/IR/Intrinsics.h" using namespace llvm; PPULLVMRecompiler::PPULLVMRecompiler(PPUThread & ppu) : m_ppu(ppu) , m_decoder(this) , m_ir_builder(m_llvm_context) , m_interpreter(ppu) { InitializeNativeTarget(); InitializeNativeTargetAsmPrinter(); InitializeNativeTargetDisassembler(); m_module = new llvm::Module("Module", m_llvm_context); m_pc = new GlobalVariable(*m_module, Type::getInt64Ty(m_llvm_context), false, GlobalValue::ExternalLinkage, nullptr, "pc"); m_gpr = new GlobalVariable(*m_module, ArrayType::get(Type::getInt64Ty(m_llvm_context), 32), false, GlobalValue::ExternalLinkage, nullptr, "gpr"); m_cr = new GlobalVariable(*m_module, Type::getInt32Ty(m_llvm_context), false, GlobalValue::ExternalLinkage, nullptr, "cr"); m_xer = new GlobalVariable(*m_module, Type::getInt64Ty(m_llvm_context), false, GlobalValue::ExternalLinkage, nullptr, "xer"); m_vpr = new GlobalVariable(*m_module, ArrayType::get(Type::getIntNTy(m_llvm_context, 128), 32), false, GlobalValue::ExternalLinkage, nullptr, "vpr"); m_vscr = new GlobalVariable(*m_module, Type::getInt32Ty(m_llvm_context), false, GlobalValue::ExternalLinkage, nullptr, "vscr"); m_execution_engine = EngineBuilder(m_module).create(); m_execution_engine->addGlobalMapping(m_pc, &m_ppu.PC); m_execution_engine->addGlobalMapping(m_gpr, m_ppu.GPR); m_execution_engine->addGlobalMapping(m_cr, &m_ppu.CR); m_execution_engine->addGlobalMapping(m_xer, &m_ppu.XER); m_execution_engine->addGlobalMapping(m_vpr, m_ppu.VPR); m_execution_engine->addGlobalMapping(m_vscr, &m_ppu.VSCR); m_disassembler = LLVMCreateDisasm(sys::getProcessTriple().c_str(), nullptr, 0, nullptr, nullptr); // RunAllTests(); } PPULLVMRecompiler::~PPULLVMRecompiler() { LLVMDisasmDispose(m_disassembler); delete m_execution_engine; llvm_shutdown(); } static std::string module; static std::string registers; static u64 lastAddress; u8 PPULLVMRecompiler::DecodeMemory(const u64 address) { auto function_name = fmt::Format("fn_0x%llx", address); auto function = m_module->getFunction(function_name); if (!function) { u64 offset = 0; function = cast(m_module->getOrInsertFunction(function_name, Type::getVoidTy(m_llvm_context), (Type *)nullptr)); auto block = BasicBlock::Create(m_llvm_context, "start", function); m_ir_builder.SetInsertPoint(block); m_hit_branch_instruction = false; while (!m_hit_branch_instruction) { u32 instr = Memory.Read32(address + offset); m_decoder.Decode(instr); offset += 4; m_ir_builder.CreateStore(m_ir_builder.getInt64(m_ppu.PC + offset), m_pc); } m_ir_builder.CreateRetVoid(); //module = ""; //raw_string_ostream stream(module); //stream << *m_module; } //lastAddress = address; //registers = m_ppu.RegsToString(); std::vector args; m_execution_engine->runFunction(function, args); return 0; } void PPULLVMRecompiler::NULL_OP() { ThisCall0("NULL_OP", &PPUInterpreter::NULL_OP, &m_interpreter); } void PPULLVMRecompiler::NOP() { } void PPULLVMRecompiler::TDI(u32 to, u32 ra, s32 simm16) { ThisCall3("TDI", &PPUInterpreter::TDI, &m_interpreter, to, ra, simm16); } void PPULLVMRecompiler::TWI(u32 to, u32 ra, s32 simm16) { ThisCall3("TWI", &PPUInterpreter::TWI, &m_interpreter, to, ra, simm16); } void PPULLVMRecompiler::MFVSCR(u32 vd) { auto vscr_i32 = m_ir_builder.CreateLoad(m_vscr); auto vscr_i128 = m_ir_builder.CreateZExt(vscr_i32, Type::getIntNTy(m_llvm_context, 128)); SetVr(vd, vscr_i128); } void PPULLVMRecompiler::MTVSCR(u32 vb) { auto vb_v4i32 = GetVrAsIntVec(vb, 32); auto vscr_i32 = m_ir_builder.CreateExtractElement(vb_v4i32, m_ir_builder.getInt32(0)); m_ir_builder.CreateStore(vscr_i32, m_vscr); } void PPULLVMRecompiler::VADDCUW(u32 vd, u32 va, u32 vb) { auto va_v4i32 = GetVrAsIntVec(va, 32); auto vb_v4i32 = GetVrAsIntVec(vb, 32); u32 not_mask_v4i32[4] = {0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF}; va_v4i32 = m_ir_builder.CreateXor(va_v4i32, ConstantDataVector::get(m_llvm_context, not_mask_v4i32)); auto cmpv4i1 = m_ir_builder.CreateICmpULT(va_v4i32, vb_v4i32); auto cmpv4i32 = m_ir_builder.CreateZExt(cmpv4i1, VectorType::get(Type::getInt32Ty(m_llvm_context), 4)); SetVr(vd, cmpv4i32); // TODO: Implement with overflow intrinsics and check if the generated code is better } void PPULLVMRecompiler::VADDFP(u32 vd, u32 va, u32 vb) { auto va_v4f32 = GetVrAsFloatVec(va); auto vb_v4f32 = GetVrAsFloatVec(vb); auto sum_v4f32 = m_ir_builder.CreateFAdd(va_v4f32, vb_v4f32); SetVr(vd, sum_v4f32); } void PPULLVMRecompiler::VADDSBS(u32 vd, u32 va, u32 vb) { auto va_v16i8 = GetVrAsIntVec(va, 8); auto vb_v16i8 = GetVrAsIntVec(vb, 8); auto sum_v16i8 = m_ir_builder.CreateCall2(Intrinsic::getDeclaration(m_module, Intrinsic::x86_sse2_padds_b), va_v16i8, vb_v16i8); SetVr(vd, sum_v16i8); // TODO: Set VSCR.SAT } void PPULLVMRecompiler::VADDSHS(u32 vd, u32 va, u32 vb) { auto va_v8i16 = GetVrAsIntVec(va, 16); auto vb_v8i16 = GetVrAsIntVec(vb, 16); auto sum_v8i16 = m_ir_builder.CreateCall2(Intrinsic::getDeclaration(m_module, Intrinsic::x86_sse2_padds_w), va_v8i16, vb_v8i16); SetVr(vd, sum_v8i16); // TODO: Set VSCR.SAT } void PPULLVMRecompiler::VADDSWS(u32 vd, u32 va, u32 vb) { auto va_v4i32 = GetVrAsIntVec(va, 32); auto vb_v4i32 = GetVrAsIntVec(vb, 32); // It looks like x86 does not have an instruction to add 32 bit intergers with singed/unsiged saturation. // To implement add with saturation, we first determine what the result would be if the operation were to cause // an overflow. If two -ve numbers are being added and cause an overflow, the result would be 0x80000000. // If two +ve numbers are being added and cause an overflow, the result would be 0x7FFFFFFF. Addition of a -ve // number and a +ve number cannot cause overflow. So the result in case of an overflow is 0x7FFFFFFF + sign bit // of any one of the operands. u32 tmp1_v4i32[4] = {0x7FFFFFFF, 0x7FFFFFFF, 0x7FFFFFFF, 0x7FFFFFFF}; auto tmp2_v4i32 = m_ir_builder.CreateLShr(va_v4i32, 31); tmp2_v4i32 = m_ir_builder.CreateAdd(tmp2_v4i32, ConstantDataVector::get(m_llvm_context, tmp1_v4i32)); auto tmp2_v16i8 = m_ir_builder.CreateBitCast(tmp2_v4i32, VectorType::get(Type::getInt8Ty(m_llvm_context), 16)); // Next, we find if the addition can actually result in an overflow. Since an overflow can only happen if the operands // have the same sign, we bitwise XOR both the operands. If the sign bit of the result is 0 then the operands have the // same sign and so may cause an overflow. We invert the result so that the sign bit is 1 when the operands have the // same sign. auto tmp3_v4i32 = m_ir_builder.CreateXor(va_v4i32, vb_v4i32); u32 not_mask_v4i32[4] = {0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF}; tmp3_v4i32 = m_ir_builder.CreateXor(tmp3_v4i32, ConstantDataVector::get(m_llvm_context, not_mask_v4i32)); // Perform the sum. auto sum_v4i32 = m_ir_builder.CreateAdd(va_v4i32, vb_v4i32); auto sum_v16i8 = m_ir_builder.CreateBitCast(sum_v4i32, VectorType::get(Type::getInt8Ty(m_llvm_context), 16)); // If an overflow occurs, then the sign of the sum will be different from the sign of the operands. So, we xor the // result with one of the operands. The sign bit of the result will be 1 if the sign bit of the sum and the sign bit of the // result is different. This result is again ANDed with tmp3 (the sign bit of tmp3 is 1 only if the operands have the same // sign and so can cause an overflow). auto tmp4_v4i32 = m_ir_builder.CreateXor(va_v4i32, sum_v4i32); tmp4_v4i32 = m_ir_builder.CreateAnd(tmp3_v4i32, tmp4_v4i32); tmp4_v4i32 = m_ir_builder.CreateAShr(tmp4_v4i32, 31); auto tmp4_v16i8 = m_ir_builder.CreateBitCast(tmp4_v4i32, VectorType::get(Type::getInt8Ty(m_llvm_context), 16)); // tmp4 is equal to 0xFFFFFFFF if an overflow occured and 0x00000000 otherwise. auto res_v16i8 = m_ir_builder.CreateCall3(Intrinsic::getDeclaration(m_module, Intrinsic::x86_sse41_pblendvb), sum_v16i8, tmp2_v16i8, tmp4_v16i8); SetVr(vd, res_v16i8); // TODO: Set SAT } void PPULLVMRecompiler::VADDUBM(u32 vd, u32 va, u32 vb) { auto va_v16i8 = GetVrAsIntVec(va, 8); auto vb_v16i8 = GetVrAsIntVec(vb, 8); auto sum_v16i8 = m_ir_builder.CreateAdd(va_v16i8, vb_v16i8); SetVr(vd, sum_v16i8); } void PPULLVMRecompiler::VADDUBS(u32 vd, u32 va, u32 vb) { auto va_v16i8 = GetVrAsIntVec(va, 8); auto vb_v16i8 = GetVrAsIntVec(vb, 8); auto sum_v16i8 = m_ir_builder.CreateCall2(Intrinsic::getDeclaration(m_module, Intrinsic::x86_sse2_paddus_b), va_v16i8, vb_v16i8); SetVr(vd, sum_v16i8); // TODO: Set SAT } void PPULLVMRecompiler::VADDUHM(u32 vd, u32 va, u32 vb) { auto va_v8i16 = GetVrAsIntVec(va, 16); auto vb_v8i16 = GetVrAsIntVec(vb, 16); auto sum_v8i16 = m_ir_builder.CreateAdd(va_v8i16, vb_v8i16); SetVr(vd, sum_v8i16); } void PPULLVMRecompiler::VADDUHS(u32 vd, u32 va, u32 vb) { auto va_v8i16 = GetVrAsIntVec(va, 16); auto vb_v8i16 = GetVrAsIntVec(vb, 16); auto sum_v8i16 = m_ir_builder.CreateCall2(Intrinsic::getDeclaration(m_module, Intrinsic::x86_sse2_paddus_w), va_v8i16, vb_v8i16); SetVr(vd, sum_v8i16); // TODO: Set SAT } void PPULLVMRecompiler::VADDUWM(u32 vd, u32 va, u32 vb) { auto va_v4i32 = GetVrAsIntVec(va, 32); auto vb_v4i32 = GetVrAsIntVec(vb, 32); auto sum_v4i32 = m_ir_builder.CreateAdd(va_v4i32, vb_v4i32); SetVr(vd, sum_v4i32); } void PPULLVMRecompiler::VADDUWS(u32 vd, u32 va, u32 vb) { auto va_v4i32 = GetVrAsIntVec(va, 32); auto vb_v4i32 = GetVrAsIntVec(vb, 32); auto sum_v4i32 = m_ir_builder.CreateAdd(va_v4i32, vb_v4i32); auto cmp_v4i1 = m_ir_builder.CreateICmpULT(sum_v4i32, va_v4i32); auto cmp_v4i32 = m_ir_builder.CreateSExt(cmp_v4i1, VectorType::get(Type::getInt32Ty(m_llvm_context), 4)); auto res_v4i32 = m_ir_builder.CreateOr(sum_v4i32, cmp_v4i32); SetVr(vd, res_v4i32); // TODO: Set SAT } void PPULLVMRecompiler::VAND(u32 vd, u32 va, u32 vb) { auto va_v4i32 = GetVrAsIntVec(va, 32); auto vb_v4i32 = GetVrAsIntVec(vb, 32); auto res_v4i32 = m_ir_builder.CreateAnd(va_v4i32, vb_v4i32); SetVr(vd, res_v4i32); } void PPULLVMRecompiler::VANDC(u32 vd, u32 va, u32 vb) { auto va_v4i32 = GetVrAsIntVec(va, 32); auto vb_v4i32 = GetVrAsIntVec(vb, 32); u32 not_mask_v4i32[4] = {0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF, 0xFFFFFFFF}; vb_v4i32 = m_ir_builder.CreateXor(vb_v4i32, ConstantDataVector::get(m_llvm_context, not_mask_v4i32)); auto res_v4i32 = m_ir_builder.CreateAnd(va_v4i32, vb_v4i32); SetVr(vd, res_v4i32); } void PPULLVMRecompiler::VAVGSB(u32 vd, u32 va, u32 vb) { auto va_v16i8 = GetVrAsIntVec(va, 8); auto vb_v16i8 = GetVrAsIntVec(vb, 8); auto va_v16i16 = m_ir_builder.CreateSExt(va_v16i8, VectorType::get(Type::getInt16Ty(m_llvm_context), 16)); auto vb_v16i16 = m_ir_builder.CreateSExt(vb_v16i8, VectorType::get(Type::getInt16Ty(m_llvm_context), 16)); auto sum_v16i16 = m_ir_builder.CreateAdd(va_v16i16, vb_v16i16); u16 one_v16i16[16] = {1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1}; sum_v16i16 = m_ir_builder.CreateAdd(sum_v16i16, ConstantDataVector::get(m_llvm_context, one_v16i16)); auto avg_v16i16 = m_ir_builder.CreateAShr(sum_v16i16, 1); auto avg_v16i8 = m_ir_builder.CreateTrunc(avg_v16i16, VectorType::get(Type::getInt8Ty(m_llvm_context), 16)); SetVr(vd, avg_v16i8); } void PPULLVMRecompiler::VAVGSH(u32 vd, u32 va, u32 vb) { auto va_v8i16 = GetVrAsIntVec(va, 16); auto vb_v8i16 = GetVrAsIntVec(vb, 16); auto va_v8i32 = m_ir_builder.CreateSExt(va_v8i16, VectorType::get(Type::getInt32Ty(m_llvm_context), 8)); auto vb_v8i32 = m_ir_builder.CreateSExt(vb_v8i16, VectorType::get(Type::getInt32Ty(m_llvm_context), 8)); auto sum_v8i32 = m_ir_builder.CreateAdd(va_v8i32, vb_v8i32); u32 one_v8i32[8] = {1, 1, 1, 1, 1, 1, 1, 1}; sum_v8i32 = m_ir_builder.CreateAdd(sum_v8i32, ConstantDataVector::get(m_llvm_context, one_v8i32)); auto avg_v8i32 = m_ir_builder.CreateAShr(sum_v8i32, 1); auto avg_v8i16 = m_ir_builder.CreateTrunc(avg_v8i32, VectorType::get(Type::getInt16Ty(m_llvm_context), 8)); SetVr(vd, avg_v8i16); } void PPULLVMRecompiler::VAVGSW(u32 vd, u32 va, u32 vb) { auto va_v4i32 = GetVrAsIntVec(va, 32); auto vb_v4i32 = GetVrAsIntVec(vb, 32); auto va_v4i64 = m_ir_builder.CreateSExt(va_v4i32, VectorType::get(Type::getInt64Ty(m_llvm_context), 4)); auto vb_v4i64 = m_ir_builder.CreateSExt(vb_v4i32, VectorType::get(Type::getInt64Ty(m_llvm_context), 4)); auto sum_v4i64 = m_ir_builder.CreateAdd(va_v4i64, vb_v4i64); u64 one_v4i64[4] = {1, 1, 1, 1}; sum_v4i64 = m_ir_builder.CreateAdd(sum_v4i64, ConstantDataVector::get(m_llvm_context, one_v4i64)); auto avg_v4i64 = m_ir_builder.CreateAShr(sum_v4i64, 1); auto avg_v4i32 = m_ir_builder.CreateTrunc(avg_v4i64, VectorType::get(Type::getInt32Ty(m_llvm_context), 4)); SetVr(vd, avg_v4i32); } void PPULLVMRecompiler::VAVGUB(u32 vd, u32 va, u32 vb) { auto va_v16i8 = GetVrAsIntVec(va, 8); auto vb_v16i8 = GetVrAsIntVec(vb, 8); auto avg_v16i8 = m_ir_builder.CreateCall2(Intrinsic::getDeclaration(m_module, Intrinsic::x86_sse2_pavg_b), va_v16i8, vb_v16i8); SetVr(vd, avg_v16i8); } void PPULLVMRecompiler::VAVGUH(u32 vd, u32 va, u32 vb) { auto va_v8i16 = GetVrAsIntVec(va, 16); auto vb_v8i16 = GetVrAsIntVec(vb, 16); auto avg_v8i16 = m_ir_builder.CreateCall2(Intrinsic::getDeclaration(m_module, Intrinsic::x86_sse2_pavg_w), va_v8i16, vb_v8i16); SetVr(vd, avg_v8i16); } void PPULLVMRecompiler::VAVGUW(u32 vd, u32 va, u32 vb) { auto va_v4i32 = GetVrAsIntVec(va, 32); auto vb_v4i32 = GetVrAsIntVec(vb, 32); auto va_v4i64 = m_ir_builder.CreateZExt(va_v4i32, VectorType::get(Type::getInt64Ty(m_llvm_context), 4)); auto vb_v4i64 = m_ir_builder.CreateZExt(vb_v4i32, VectorType::get(Type::getInt64Ty(m_llvm_context), 4)); auto sum_v4i64 = m_ir_builder.CreateAdd(va_v4i64, vb_v4i64); u64 one_v4i64[4] = {1, 1, 1, 1}; sum_v4i64 = m_ir_builder.CreateAdd(sum_v4i64, ConstantDataVector::get(m_llvm_context, one_v4i64)); auto avg_v4i64 = m_ir_builder.CreateLShr(sum_v4i64, 1); auto avg_v4i32 = m_ir_builder.CreateTrunc(avg_v4i64, VectorType::get(Type::getInt32Ty(m_llvm_context), 4)); SetVr(vd, avg_v4i32); } void PPULLVMRecompiler::VCFSX(u32 vd, u32 uimm5, u32 vb) { auto vb_v4i32 = GetVrAsIntVec(vb, 32); auto res_v4f32 = m_ir_builder.CreateSIToFP(vb_v4i32, VectorType::get(Type::getFloatTy(m_llvm_context), 4)); if (uimm5) { float scale = (float)(1 << uimm5); float scale_v4f32[4] = {scale, scale, scale, scale}; res_v4f32 = m_ir_builder.CreateFDiv(res_v4f32, ConstantDataVector::get(m_llvm_context, scale_v4f32)); } SetVr(vd, res_v4f32); } void PPULLVMRecompiler::VCFUX(u32 vd, u32 uimm5, u32 vb) { auto vb_v4i32 = GetVrAsIntVec(vb, 32); auto res_v4f32 = m_ir_builder.CreateUIToFP(vb_v4i32, VectorType::get(Type::getFloatTy(m_llvm_context), 4)); if (uimm5) { float scale = (float)(1 << uimm5); float scale_v4f32[4] = {scale, scale, scale, scale}; res_v4f32 = m_ir_builder.CreateFDiv(res_v4f32, ConstantDataVector::get(m_llvm_context, scale_v4f32)); } SetVr(vd, res_v4f32); } void PPULLVMRecompiler::VCMPBFP(u32 vd, u32 va, u32 vb) { auto va_v4f32 = GetVrAsFloatVec(va); auto vb_v4f32 = GetVrAsFloatVec(vb); auto cmp_gt_v4i1 = m_ir_builder.CreateFCmpOGT(va_v4f32, vb_v4f32); vb_v4f32 = m_ir_builder.CreateFNeg(vb_v4f32); auto cmp_lt_v4i1 = m_ir_builder.CreateFCmpOLT(va_v4f32, vb_v4f32); auto cmp_gt_v4i32 = m_ir_builder.CreateZExt(cmp_gt_v4i1, VectorType::get(Type::getInt32Ty(m_llvm_context), 4)); auto cmp_lt_v4i32 = m_ir_builder.CreateZExt(cmp_lt_v4i1, VectorType::get(Type::getInt32Ty(m_llvm_context), 4)); cmp_gt_v4i32 = m_ir_builder.CreateShl(cmp_gt_v4i32, 31); cmp_lt_v4i32 = m_ir_builder.CreateShl(cmp_lt_v4i32, 30); auto res_v4i32 = m_ir_builder.CreateOr(cmp_gt_v4i32, cmp_lt_v4i32); SetVr(vd, res_v4i32); // TODO: Implement NJ mode } void PPULLVMRecompiler::VCMPBFP_(u32 vd, u32 va, u32 vb) { VCMPBFP(vd, va, vb); auto vd_v16i8 = GetVrAsIntVec(vd, 8); u8 mask_v16i8[16] = {3, 7, 11, 15, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0}; vd_v16i8 = m_ir_builder.CreateCall2(Intrinsic::getDeclaration(m_module, Intrinsic::x86_ssse3_pshuf_b_128), vd_v16i8, ConstantDataVector::get(m_llvm_context, mask_v16i8)); auto vd_v4i32 = m_ir_builder.CreateBitCast(vd_v16i8, VectorType::get(Type::getInt32Ty(m_llvm_context), 4)); auto vd_mask_i32 = m_ir_builder.CreateExtractElement(vd_v4i32, m_ir_builder.getInt32(0)); auto cmp_i1 = m_ir_builder.CreateICmpEQ(vd_mask_i32, m_ir_builder.getInt32(0)); SetCrField(6, nullptr, nullptr, cmp_i1, nullptr); } void PPULLVMRecompiler::VCMPEQFP(u32 vd, u32 va, u32 vb) { auto va_v4f32 = GetVrAsFloatVec(va); auto vb_v4f32 = GetVrAsFloatVec(vb); auto cmp_v4i1 = m_ir_builder.CreateFCmpOEQ(va_v4f32, vb_v4f32); auto cmp_v4i32 = m_ir_builder.CreateSExt(cmp_v4i1, VectorType::get(Type::getInt32Ty(m_llvm_context), 4)); SetVr(vd, cmp_v4i32); } void PPULLVMRecompiler::VCMPEQFP_(u32 vd, u32 va, u32 vb) { VCMPEQFP(vd, va, vb); SetCr6AfterVectorCompare(vd); } void PPULLVMRecompiler::VCMPEQUB(u32 vd, u32 va, u32 vb) { auto va_v16i8 = GetVrAsIntVec(va, 8); auto vb_v16i8 = GetVrAsIntVec(vb, 8); auto cmp_v16i1 = m_ir_builder.CreateICmpEQ(va_v16i8, vb_v16i8); auto cmp_v16i8 = m_ir_builder.CreateSExt(cmp_v16i1, VectorType::get(Type::getInt8Ty(m_llvm_context), 16)); SetVr(vd, cmp_v16i8); } void PPULLVMRecompiler::VCMPEQUB_(u32 vd, u32 va, u32 vb) { VCMPEQUB(vd, va, vb); SetCr6AfterVectorCompare(vd); } void PPULLVMRecompiler::VCMPEQUH(u32 vd, u32 va, u32 vb) { auto va_v8i16 = GetVrAsIntVec(va, 16); auto vb_v8i16 = GetVrAsIntVec(vb, 16); auto cmp_v8i1 = m_ir_builder.CreateICmpEQ(va_v8i16, vb_v8i16); auto cmp_v8i16 = m_ir_builder.CreateSExt(cmp_v8i1, VectorType::get(Type::getInt16Ty(m_llvm_context), 8)); SetVr(vd, cmp_v8i16); } void PPULLVMRecompiler::VCMPEQUH_(u32 vd, u32 va, u32 vb) { VCMPEQUH(vd, va, vb); SetCr6AfterVectorCompare(vd); } void PPULLVMRecompiler::VCMPEQUW(u32 vd, u32 va, u32 vb) { auto va_v4i32 = GetVrAsIntVec(va, 32); auto vb_v4i32 = GetVrAsIntVec(vb, 32); auto cmp_v4i1 = m_ir_builder.CreateICmpEQ(va_v4i32, vb_v4i32); auto cmp_v4i32 = m_ir_builder.CreateSExt(cmp_v4i1, VectorType::get(Type::getInt32Ty(m_llvm_context), 4)); SetVr(vd, cmp_v4i32); } void PPULLVMRecompiler::VCMPEQUW_(u32 vd, u32 va, u32 vb) { VCMPEQUW(vd, va, vb); SetCr6AfterVectorCompare(vd); } void PPULLVMRecompiler::VCMPGEFP(u32 vd, u32 va, u32 vb) { auto va_v4f32 = GetVrAsFloatVec(va); auto vb_v4f32 = GetVrAsFloatVec(vb); auto cmp_v4i1 = m_ir_builder.CreateFCmpOGE(va_v4f32, vb_v4f32); auto cmp_v4i32 = m_ir_builder.CreateSExt(cmp_v4i1, VectorType::get(Type::getInt32Ty(m_llvm_context), 4)); SetVr(vd, cmp_v4i32); } void PPULLVMRecompiler::VCMPGEFP_(u32 vd, u32 va, u32 vb) { VCMPGEFP(vd, va, vb); SetCr6AfterVectorCompare(vd); } void PPULLVMRecompiler::VCMPGTFP(u32 vd, u32 va, u32 vb) { auto va_v4f32 = GetVrAsFloatVec(va); auto vb_v4f32 = GetVrAsFloatVec(vb); auto cmp_v4i1 = m_ir_builder.CreateFCmpOGT(va_v4f32, vb_v4f32); auto cmp_v4i32 = m_ir_builder.CreateSExt(cmp_v4i1, VectorType::get(Type::getInt32Ty(m_llvm_context), 4)); SetVr(vd, cmp_v4i32); } void PPULLVMRecompiler::VCMPGTFP_(u32 vd, u32 va, u32 vb) { VCMPGTFP(vd, va, vb); SetCr6AfterVectorCompare(vd); } void PPULLVMRecompiler::VCMPGTSB(u32 vd, u32 va, u32 vb) { auto va_v16i8 = GetVrAsIntVec(va, 8); auto vb_v16i8 = GetVrAsIntVec(vb, 8); auto cmp_v16i1 = m_ir_builder.CreateICmpSGT(va_v16i8, vb_v16i8); auto cmp_v16i8 = m_ir_builder.CreateSExt(cmp_v16i1, VectorType::get(Type::getInt8Ty(m_llvm_context), 16)); SetVr(vd, cmp_v16i8); } void PPULLVMRecompiler::VCMPGTSB_(u32 vd, u32 va, u32 vb) { VCMPGTSB(vd, va, vb); SetCr6AfterVectorCompare(vd); } void PPULLVMRecompiler::VCMPGTSH(u32 vd, u32 va, u32 vb) { auto va_v8i16 = GetVrAsIntVec(va, 16); auto vb_v8i16 = GetVrAsIntVec(vb, 16); auto cmp_v8i1 = m_ir_builder.CreateICmpSGT(va_v8i16, vb_v8i16); auto cmp_v8i16 = m_ir_builder.CreateSExt(cmp_v8i1, VectorType::get(Type::getInt16Ty(m_llvm_context), 8)); SetVr(vd, cmp_v8i16); } void PPULLVMRecompiler::VCMPGTSH_(u32 vd, u32 va, u32 vb) { VCMPGTSH(vd, va, vb); SetCr6AfterVectorCompare(vd); } void PPULLVMRecompiler::VCMPGTSW(u32 vd, u32 va, u32 vb) { auto va_v4i32 = GetVrAsIntVec(va, 32); auto vb_v4i32 = GetVrAsIntVec(vb, 32); auto cmp_v4i1 = m_ir_builder.CreateICmpSGT(va_v4i32, vb_v4i32); auto cmp_v4i32 = m_ir_builder.CreateSExt(cmp_v4i1, VectorType::get(Type::getInt32Ty(m_llvm_context), 4)); SetVr(vd, cmp_v4i32); } void PPULLVMRecompiler::VCMPGTSW_(u32 vd, u32 va, u32 vb) { VCMPGTSW(vd, va, vb); SetCr6AfterVectorCompare(vd); } void PPULLVMRecompiler::VCMPGTUB(u32 vd, u32 va, u32 vb) { auto va_v16i8 = GetVrAsIntVec(va, 8); auto vb_v16i8 = GetVrAsIntVec(vb, 8); auto cmp_v16i1 = m_ir_builder.CreateICmpUGT(va_v16i8, vb_v16i8); auto cmp_v16i8 = m_ir_builder.CreateSExt(cmp_v16i1, VectorType::get(Type::getInt8Ty(m_llvm_context), 16)); SetVr(vd, cmp_v16i8); } void PPULLVMRecompiler::VCMPGTUB_(u32 vd, u32 va, u32 vb) { VCMPGTUB(vd, va, vb); SetCr6AfterVectorCompare(vd); } void PPULLVMRecompiler::VCMPGTUH(u32 vd, u32 va, u32 vb) { auto va_v8i16 = GetVrAsIntVec(va, 16); auto vb_v8i16 = GetVrAsIntVec(vb, 16); auto cmp_v8i1 = m_ir_builder.CreateICmpUGT(va_v8i16, vb_v8i16); auto cmp_v8i16 = m_ir_builder.CreateSExt(cmp_v8i1, VectorType::get(Type::getInt16Ty(m_llvm_context), 8)); SetVr(vd, cmp_v8i16); } void PPULLVMRecompiler::VCMPGTUH_(u32 vd, u32 va, u32 vb) { VCMPGTUH(vd, va, vb); SetCr6AfterVectorCompare(vd); } void PPULLVMRecompiler::VCMPGTUW(u32 vd, u32 va, u32 vb) { auto va_v4i32 = GetVrAsIntVec(va, 32); auto vb_v4i32 = GetVrAsIntVec(vb, 32); auto cmp_v4i1 = m_ir_builder.CreateICmpUGT(va_v4i32, vb_v4i32); auto cmp_v4i32 = m_ir_builder.CreateSExt(cmp_v4i1, VectorType::get(Type::getInt32Ty(m_llvm_context), 4)); SetVr(vd, cmp_v4i32); } void PPULLVMRecompiler::VCMPGTUW_(u32 vd, u32 va, u32 vb) { VCMPGTUW(vd, va, vb); SetCr6AfterVectorCompare(vd); } void PPULLVMRecompiler::VCTSXS(u32 vd, u32 uimm5, u32 vb) { ThisCall3("VCTSXS", &PPUInterpreter::VCTSXS, &m_interpreter, vd, uimm5, vb); } void PPULLVMRecompiler::VCTUXS(u32 vd, u32 uimm5, u32 vb) { ThisCall3("VCTUXS", &PPUInterpreter::VCTUXS, &m_interpreter, vd, uimm5, vb); } void PPULLVMRecompiler::VEXPTEFP(u32 vd, u32 vb) { ThisCall2("VEXPTEFP", &PPUInterpreter::VEXPTEFP, &m_interpreter, vd, vb); } void PPULLVMRecompiler::VLOGEFP(u32 vd, u32 vb) { ThisCall2("VLOGEFP", &PPUInterpreter::VLOGEFP, &m_interpreter, vd, vb); } void PPULLVMRecompiler::VMADDFP(u32 vd, u32 va, u32 vc, u32 vb) { ThisCall4("VMADDFP", &PPUInterpreter::VMADDFP, &m_interpreter, vd, va, vc, vb); } void PPULLVMRecompiler::VMAXFP(u32 vd, u32 va, u32 vb) { ThisCall3("VMAXFP", &PPUInterpreter::VMAXFP, &m_interpreter, vd, va, vb); } void PPULLVMRecompiler::VMAXSB(u32 vd, u32 va, u32 vb) { ThisCall3("VMAXSB", &PPUInterpreter::VMAXSB, &m_interpreter, vd, va, vb); } void PPULLVMRecompiler::VMAXSH(u32 vd, u32 va, u32 vb) { ThisCall3("VMAXSH", &PPUInterpreter::VMAXSH, &m_interpreter, vd, va, vb); } void PPULLVMRecompiler::VMAXSW(u32 vd, u32 va, u32 vb) { ThisCall3("VMAXSW", &PPUInterpreter::VMAXSW, &m_interpreter, vd, va, vb); } void PPULLVMRecompiler::VMAXUB(u32 vd, u32 va, u32 vb) { ThisCall3("VMAXUB", &PPUInterpreter::VMAXUB, &m_interpreter, vd, va, vb); } void PPULLVMRecompiler::VMAXUH(u32 vd, u32 va, u32 vb) { ThisCall3("VMAXUH", &PPUInterpreter::VMAXUH, &m_interpreter, vd, va, vb); } void PPULLVMRecompiler::VMAXUW(u32 vd, u32 va, u32 vb) { ThisCall3("VMAXUW", &PPUInterpreter::VMAXUW, &m_interpreter, vd, va, vb); } void PPULLVMRecompiler::VMHADDSHS(u32 vd, u32 va, u32 vb, u32 vc) { ThisCall4("VMHADDSHS", &PPUInterpreter::VMHADDSHS, &m_interpreter, vd, va, vb, vc); } void PPULLVMRecompiler::VMHRADDSHS(u32 vd, u32 va, u32 vb, u32 vc) { ThisCall4("VMHRADDSHS", &PPUInterpreter::VMHRADDSHS, &m_interpreter, vd, va, vb, vc); } void PPULLVMRecompiler::VMINFP(u32 vd, u32 va, u32 vb) { ThisCall3("VMINFP", &PPUInterpreter::VMINFP, &m_interpreter, vd, va, vb); } void PPULLVMRecompiler::VMINSB(u32 vd, u32 va, u32 vb) { ThisCall3("VMINSB", &PPUInterpreter::VMINSB, &m_interpreter, vd, va, vb); } void PPULLVMRecompiler::VMINSH(u32 vd, u32 va, u32 vb) { ThisCall3("VMINSH", &PPUInterpreter::VMINSH, &m_interpreter, vd, va, vb); } void PPULLVMRecompiler::VMINSW(u32 vd, u32 va, u32 vb) { ThisCall3("VMINSW", &PPUInterpreter::VMINSW, &m_interpreter, vd, va, vb); } void PPULLVMRecompiler::VMINUB(u32 vd, u32 va, u32 vb) { ThisCall3("VMINUB", &PPUInterpreter::VMINUB, &m_interpreter, vd, va, vb); } void PPULLVMRecompiler::VMINUH(u32 vd, u32 va, u32 vb) { ThisCall3("VMINUH", &PPUInterpreter::VMINUH, &m_interpreter, vd, va, vb); } void PPULLVMRecompiler::VMINUW(u32 vd, u32 va, u32 vb) { ThisCall3("VMINUW", &PPUInterpreter::VMINUW, &m_interpreter, vd, va, vb); } void PPULLVMRecompiler::VMLADDUHM(u32 vd, u32 va, u32 vb, u32 vc) { ThisCall4("VMLADDUHM", &PPUInterpreter::VMLADDUHM, &m_interpreter, vd, va, vb, vc); } void PPULLVMRecompiler::VMRGHB(u32 vd, u32 va, u32 vb) { ThisCall3("VMRGHB", &PPUInterpreter::VMRGHB, &m_interpreter, vd, va, vb); } void PPULLVMRecompiler::VMRGHH(u32 vd, u32 va, u32 vb) { ThisCall3("VMRGHH", &PPUInterpreter::VMRGHH, &m_interpreter, vd, va, vb); } void PPULLVMRecompiler::VMRGHW(u32 vd, u32 va, u32 vb) { ThisCall3("VMRGHW", &PPUInterpreter::VMRGHW, &m_interpreter, vd, va, vb); } void PPULLVMRecompiler::VMRGLB(u32 vd, u32 va, u32 vb) { ThisCall3("VMRGLB", &PPUInterpreter::VMRGLB, &m_interpreter, vd, va, vb); } void PPULLVMRecompiler::VMRGLH(u32 vd, u32 va, u32 vb) { ThisCall3("VMRGLH", &PPUInterpreter::VMRGLH, &m_interpreter, vd, va, vb); } void PPULLVMRecompiler::VMRGLW(u32 vd, u32 va, u32 vb) { ThisCall3("VMRGLW", &PPUInterpreter::VMRGLW, &m_interpreter, vd, va, vb); } void PPULLVMRecompiler::VMSUMMBM(u32 vd, u32 va, u32 vb, u32 vc) { ThisCall4("VMSUMMBM", &PPUInterpreter::VMSUMMBM, &m_interpreter, vd, va, vb, vc); } void PPULLVMRecompiler::VMSUMSHM(u32 vd, u32 va, u32 vb, u32 vc) { ThisCall4("VMSUMSHM", &PPUInterpreter::VMSUMSHM, &m_interpreter, vd, va, vb, vc); } void PPULLVMRecompiler::VMSUMSHS(u32 vd, u32 va, u32 vb, u32 vc) { ThisCall4("VMSUMSHS", &PPUInterpreter::VMSUMSHS, &m_interpreter, vd, va, vb, vc); } void PPULLVMRecompiler::VMSUMUBM(u32 vd, u32 va, u32 vb, u32 vc) { ThisCall4("VMSUMUBM", &PPUInterpreter::VMSUMUBM, &m_interpreter, vd, va, vb, vc); } void PPULLVMRecompiler::VMSUMUHM(u32 vd, u32 va, u32 vb, u32 vc) { ThisCall4("VMSUMUHM", &PPUInterpreter::VMSUMUHM, &m_interpreter, vd, va, vb, vc); } void PPULLVMRecompiler::VMSUMUHS(u32 vd, u32 va, u32 vb, u32 vc) { ThisCall4("VMSUMUHS", &PPUInterpreter::VMSUMUHS, &m_interpreter, vd, va, vb, vc); } void PPULLVMRecompiler::VMULESB(u32 vd, u32 va, u32 vb) { ThisCall3("VMULESB", &PPUInterpreter::VMULESB, &m_interpreter, vd, va, vb); } void PPULLVMRecompiler::VMULESH(u32 vd, u32 va, u32 vb) { ThisCall3("VMULESH", &PPUInterpreter::VMULESH, &m_interpreter, vd, va, vb); } void PPULLVMRecompiler::VMULEUB(u32 vd, u32 va, u32 vb) { ThisCall3("VMULEUB", &PPUInterpreter::VMULEUB, &m_interpreter, vd, va, vb); } void PPULLVMRecompiler::VMULEUH(u32 vd, u32 va, u32 vb) { ThisCall3("VMULEUH", &PPUInterpreter::VMULEUH, &m_interpreter, vd, va, vb); } void PPULLVMRecompiler::VMULOSB(u32 vd, u32 va, u32 vb) { ThisCall3("VMULOSB", &PPUInterpreter::VMULOSB, &m_interpreter, vd, va, vb); } void PPULLVMRecompiler::VMULOSH(u32 vd, u32 va, u32 vb) { ThisCall3("VMULOSH", &PPUInterpreter::VMULOSH, &m_interpreter, vd, va, vb); } void PPULLVMRecompiler::VMULOUB(u32 vd, u32 va, u32 vb) { ThisCall3("VMULOUB", &PPUInterpreter::VMULOUB, &m_interpreter, vd, va, vb); } void PPULLVMRecompiler::VMULOUH(u32 vd, u32 va, u32 vb) { ThisCall3("VMULOUH", &PPUInterpreter::VMULOUH, &m_interpreter, vd, va, vb); } void PPULLVMRecompiler::VNMSUBFP(u32 vd, u32 va, u32 vc, u32 vb) { ThisCall4("VNMSUBFP", &PPUInterpreter::VNMSUBFP, &m_interpreter, vd, va, vc, vb); } void PPULLVMRecompiler::VNOR(u32 vd, u32 va, u32 vb) { ThisCall3("VNOR", &PPUInterpreter::VNOR, &m_interpreter, vd, va, vb); } void PPULLVMRecompiler::VOR(u32 vd, u32 va, u32 vb) { ThisCall3("VOR", &PPUInterpreter::VOR, &m_interpreter, vd, va, vb); } void PPULLVMRecompiler::VPERM(u32 vd, u32 va, u32 vb, u32 vc) { ThisCall4("VPERM", &PPUInterpreter::VPERM, &m_interpreter, vd, va, vb, vc); } void PPULLVMRecompiler::VPKPX(u32 vd, u32 va, u32 vb) { ThisCall3("VPKPX", &PPUInterpreter::VPKPX, &m_interpreter, vd, va, vb); } void PPULLVMRecompiler::VPKSHSS(u32 vd, u32 va, u32 vb) { ThisCall3("VPKSHSS", &PPUInterpreter::VPKSHSS, &m_interpreter, vd, va, vb); } void PPULLVMRecompiler::VPKSHUS(u32 vd, u32 va, u32 vb) { ThisCall3("VPKSHUS", &PPUInterpreter::VPKSHUS, &m_interpreter, vd, va, vb); } void PPULLVMRecompiler::VPKSWSS(u32 vd, u32 va, u32 vb) { ThisCall3("VPKSWSS", &PPUInterpreter::VPKSWSS, &m_interpreter, vd, va, vb); } void PPULLVMRecompiler::VPKSWUS(u32 vd, u32 va, u32 vb) { ThisCall3("VPKSWUS", &PPUInterpreter::VPKSWUS, &m_interpreter, vd, va, vb); } void PPULLVMRecompiler::VPKUHUM(u32 vd, u32 va, u32 vb) { ThisCall3("VPKUHUM", &PPUInterpreter::VPKUHUM, &m_interpreter, vd, va, vb); } void PPULLVMRecompiler::VPKUHUS(u32 vd, u32 va, u32 vb) { ThisCall3("VPKUHUS", &PPUInterpreter::VPKUHUS, &m_interpreter, vd, va, vb); } void PPULLVMRecompiler::VPKUWUM(u32 vd, u32 va, u32 vb) { ThisCall3("VPKUWUM", &PPUInterpreter::VPKUWUM, &m_interpreter, vd, va, vb); } void PPULLVMRecompiler::VPKUWUS(u32 vd, u32 va, u32 vb) { ThisCall3("VPKUWUS", &PPUInterpreter::VPKUWUS, &m_interpreter, vd, va, vb); } void PPULLVMRecompiler::VREFP(u32 vd, u32 vb) { ThisCall2("VREFP", &PPUInterpreter::VREFP, &m_interpreter, vd, vb); } void PPULLVMRecompiler::VRFIM(u32 vd, u32 vb) { ThisCall2("VRFIM", &PPUInterpreter::VRFIM, &m_interpreter, vd, vb); } void PPULLVMRecompiler::VRFIN(u32 vd, u32 vb) { ThisCall2("VRFIN", &PPUInterpreter::VRFIN, &m_interpreter, vd, vb); } void PPULLVMRecompiler::VRFIP(u32 vd, u32 vb) { ThisCall2("VRFIP", &PPUInterpreter::VRFIP, &m_interpreter, vd, vb); } void PPULLVMRecompiler::VRFIZ(u32 vd, u32 vb) { ThisCall2("VRFIZ", &PPUInterpreter::VRFIZ, &m_interpreter, vd, vb); } void PPULLVMRecompiler::VRLB(u32 vd, u32 va, u32 vb) { ThisCall3("VRLB", &PPUInterpreter::VRLB, &m_interpreter, vd, va, vb); } void PPULLVMRecompiler::VRLH(u32 vd, u32 va, u32 vb) { ThisCall3("VRLH", &PPUInterpreter::VRLH, &m_interpreter, vd, va, vb); } void PPULLVMRecompiler::VRLW(u32 vd, u32 va, u32 vb) { ThisCall3("VRLW", &PPUInterpreter::VRLW, &m_interpreter, vd, va, vb); } void PPULLVMRecompiler::VRSQRTEFP(u32 vd, u32 vb) { ThisCall2("VRSQRTEFP", &PPUInterpreter::VRSQRTEFP, &m_interpreter, vd, vb); } void PPULLVMRecompiler::VSEL(u32 vd, u32 va, u32 vb, u32 vc) { ThisCall4("VSEL", &PPUInterpreter::VSEL, &m_interpreter, vd, va, vb, vc); } void PPULLVMRecompiler::VSL(u32 vd, u32 va, u32 vb) { ThisCall3("VSL", &PPUInterpreter::VSL, &m_interpreter, vd, va, vb); } void PPULLVMRecompiler::VSLB(u32 vd, u32 va, u32 vb) { ThisCall3("VSLB", &PPUInterpreter::VSLB, &m_interpreter, vd, va, vb); } void PPULLVMRecompiler::VSLDOI(u32 vd, u32 va, u32 vb, u32 sh) { ThisCall4("VSLDOI", &PPUInterpreter::VSLDOI, &m_interpreter, vd, va, vb, sh); } void PPULLVMRecompiler::VSLH(u32 vd, u32 va, u32 vb) { ThisCall3("VSLH", &PPUInterpreter::VSLH, &m_interpreter, vd, va, vb); } void PPULLVMRecompiler::VSLO(u32 vd, u32 va, u32 vb) { ThisCall3("VSLO", &PPUInterpreter::VSLO, &m_interpreter, vd, va, vb); } void PPULLVMRecompiler::VSLW(u32 vd, u32 va, u32 vb) { ThisCall3("VSLW", &PPUInterpreter::VSLW, &m_interpreter, vd, va, vb); } void PPULLVMRecompiler::VSPLTB(u32 vd, u32 uimm5, u32 vb) { ThisCall3("VSPLTB", &PPUInterpreter::VSPLTB, &m_interpreter, vd, uimm5, vb); } void PPULLVMRecompiler::VSPLTH(u32 vd, u32 uimm5, u32 vb) { ThisCall3("VSPLTH", &PPUInterpreter::VSPLTH, &m_interpreter, vd, uimm5, vb); } void PPULLVMRecompiler::VSPLTISB(u32 vd, s32 simm5) { ThisCall2("VSPLTISB", &PPUInterpreter::VSPLTISB, &m_interpreter, vd, simm5); } void PPULLVMRecompiler::VSPLTISH(u32 vd, s32 simm5) { ThisCall2("VSPLTISH", &PPUInterpreter::VSPLTISH, &m_interpreter, vd, simm5); } void PPULLVMRecompiler::VSPLTISW(u32 vd, s32 simm5) { ThisCall2("VSPLTISW", &PPUInterpreter::VSPLTISW, &m_interpreter, vd, simm5); } void PPULLVMRecompiler::VSPLTW(u32 vd, u32 uimm5, u32 vb) { ThisCall3("VSPLTW", &PPUInterpreter::VSPLTW, &m_interpreter, vd, uimm5, vb); } void PPULLVMRecompiler::VSR(u32 vd, u32 va, u32 vb) { ThisCall3("VSR", &PPUInterpreter::VSR, &m_interpreter, vd, va, vb); } void PPULLVMRecompiler::VSRAB(u32 vd, u32 va, u32 vb) { ThisCall3("VSRAB", &PPUInterpreter::VSRAB, &m_interpreter, vd, va, vb); } void PPULLVMRecompiler::VSRAH(u32 vd, u32 va, u32 vb) { ThisCall3("VSRAH", &PPUInterpreter::VSRAH, &m_interpreter, vd, va, vb); } void PPULLVMRecompiler::VSRAW(u32 vd, u32 va, u32 vb) { ThisCall3("VSRAW", &PPUInterpreter::VSRAW, &m_interpreter, vd, va, vb); } void PPULLVMRecompiler::VSRB(u32 vd, u32 va, u32 vb) { ThisCall3("VSRB", &PPUInterpreter::VSRB, &m_interpreter, vd, va, vb); } void PPULLVMRecompiler::VSRH(u32 vd, u32 va, u32 vb) { ThisCall3("VSRH", &PPUInterpreter::VSRH, &m_interpreter, vd, va, vb); } void PPULLVMRecompiler::VSRO(u32 vd, u32 va, u32 vb) { ThisCall3("VSRO", &PPUInterpreter::VSRO, &m_interpreter, vd, va, vb); } void PPULLVMRecompiler::VSRW(u32 vd, u32 va, u32 vb) { ThisCall3("VSRW", &PPUInterpreter::VSRW, &m_interpreter, vd, va, vb); } void PPULLVMRecompiler::VSUBCUW(u32 vd, u32 va, u32 vb) { ThisCall3("VSUBCUW", &PPUInterpreter::VSUBCUW, &m_interpreter, vd, va, vb); } void PPULLVMRecompiler::VSUBFP(u32 vd, u32 va, u32 vb) { ThisCall3("VSUBFP", &PPUInterpreter::VSUBFP, &m_interpreter, vd, va, vb); } void PPULLVMRecompiler::VSUBSBS(u32 vd, u32 va, u32 vb) { ThisCall3("VSUBSBS", &PPUInterpreter::VSUBSBS, &m_interpreter, vd, va, vb); } void PPULLVMRecompiler::VSUBSHS(u32 vd, u32 va, u32 vb) { ThisCall3("VSUBSHS", &PPUInterpreter::VSUBSHS, &m_interpreter, vd, va, vb); } void PPULLVMRecompiler::VSUBSWS(u32 vd, u32 va, u32 vb) { ThisCall3("VSUBSWS", &PPUInterpreter::VSUBSWS, &m_interpreter, vd, va, vb); } void PPULLVMRecompiler::VSUBUBM(u32 vd, u32 va, u32 vb) { ThisCall3("VSUBUBM", &PPUInterpreter::VSUBUBM, &m_interpreter, vd, va, vb); } void PPULLVMRecompiler::VSUBUBS(u32 vd, u32 va, u32 vb) { ThisCall3("VSUBUBS", &PPUInterpreter::VSUBUBS, &m_interpreter, vd, va, vb); } void PPULLVMRecompiler::VSUBUHM(u32 vd, u32 va, u32 vb) { ThisCall3("VSUBUHM", &PPUInterpreter::VSUBUHM, &m_interpreter, vd, va, vb); } void PPULLVMRecompiler::VSUBUHS(u32 vd, u32 va, u32 vb) { ThisCall3("VSUBUHS", &PPUInterpreter::VSUBUHS, &m_interpreter, vd, va, vb); } void PPULLVMRecompiler::VSUBUWM(u32 vd, u32 va, u32 vb) { ThisCall3("VSUBUWM", &PPUInterpreter::VSUBUWM, &m_interpreter, vd, va, vb); } void PPULLVMRecompiler::VSUBUWS(u32 vd, u32 va, u32 vb) { ThisCall3("VSUBUWS", &PPUInterpreter::VSUBUWS, &m_interpreter, vd, va, vb); } void PPULLVMRecompiler::VSUMSWS(u32 vd, u32 va, u32 vb) { ThisCall3("VSUMSWS", &PPUInterpreter::VSUMSWS, &m_interpreter, vd, va, vb); } void PPULLVMRecompiler::VSUM2SWS(u32 vd, u32 va, u32 vb) { ThisCall3("VSUM2SWS", &PPUInterpreter::VSUM2SWS, &m_interpreter, vd, va, vb); } void PPULLVMRecompiler::VSUM4SBS(u32 vd, u32 va, u32 vb) { ThisCall3("VSUM4SBS", &PPUInterpreter::VSUM4SBS, &m_interpreter, vd, va, vb); } void PPULLVMRecompiler::VSUM4SHS(u32 vd, u32 va, u32 vb) { ThisCall3("VSUM4SHS", &PPUInterpreter::VSUM4SHS, &m_interpreter, vd, va, vb); } void PPULLVMRecompiler::VSUM4UBS(u32 vd, u32 va, u32 vb) { ThisCall3("VSUM4UBS", &PPUInterpreter::VSUM4UBS, &m_interpreter, vd, va, vb); } void PPULLVMRecompiler::VUPKHPX(u32 vd, u32 vb) { ThisCall2("VUPKHPX", &PPUInterpreter::VUPKHPX, &m_interpreter, vd, vb); } void PPULLVMRecompiler::VUPKHSB(u32 vd, u32 vb) { ThisCall2("VUPKHSB", &PPUInterpreter::VUPKHSB, &m_interpreter, vd, vb); } void PPULLVMRecompiler::VUPKHSH(u32 vd, u32 vb) { ThisCall2("VUPKHSH", &PPUInterpreter::VUPKHSH, &m_interpreter, vd, vb); } void PPULLVMRecompiler::VUPKLPX(u32 vd, u32 vb) { ThisCall2("VUPKLPX", &PPUInterpreter::VUPKLPX, &m_interpreter, vd, vb); } void PPULLVMRecompiler::VUPKLSB(u32 vd, u32 vb) { ThisCall2("VUPKLSB", &PPUInterpreter::VUPKLSB, &m_interpreter, vd, vb); } void PPULLVMRecompiler::VUPKLSH(u32 vd, u32 vb) { ThisCall2("VUPKLSH", &PPUInterpreter::VUPKLSH, &m_interpreter, vd, vb); } void PPULLVMRecompiler::VXOR(u32 vd, u32 va, u32 vb) { ThisCall3("VXOR", &PPUInterpreter::VXOR, &m_interpreter, vd, va, vb); } void PPULLVMRecompiler::MULLI(u32 rd, u32 ra, s32 simm16) { //auto ra_i64 = GetGpr(ra); //auto res_i64 = m_ir_builder.CreateMul(ra_i64, m_ir_builder.getInt64((s64)simm16)); //SetGpr(rd, res_i64); ThisCall3("MULLI", &PPUInterpreter::MULLI, &m_interpreter, rd, ra, simm16); } void PPULLVMRecompiler::SUBFIC(u32 rd, u32 ra, s32 simm16) { //auto ra_i64 = GetGpr(ra); //auto res_s = m_ir_builder.CreateCall2(Intrinsic::getDeclaration(m_module, Intrinsic::ssub_with_overflow), m_ir_builder.getInt64((s64)simm16), ra_i64); //auto diff_i64 = m_ir_builder.CreateExtractValue(res_s, {0}); //auto carry_i1 = m_ir_builder.CreateExtractValue(res_s, {1}); //SetGpr(rd, diff_i64); //SetXerCa(carry_i1); ThisCall3("SUBFIC", &PPUInterpreter::SUBFIC, &m_interpreter, rd, ra, simm16); } void PPULLVMRecompiler::CMPLI(u32 crfd, u32 l, u32 ra, u32 uimm16) { //auto ra_i64 = GetGpr(ra); //if (l == 0) { // ra_i64 = m_ir_builder.CreateAnd(ra_i64, 0xFFFFFFFF); //} //SetCrFieldUnsignedCmp(crfd, ra_i64, m_ir_builder.getInt64(uimm16)); ThisCall4("CMPLI", &PPUInterpreter::CMPLI, &m_interpreter, crfd, l, ra, uimm16); } void PPULLVMRecompiler::CMPI(u32 crfd, u32 l, u32 ra, s32 simm16) { //auto ra_i64 = GetGpr(ra); //if (l == 0) { // auto ra_i32 = m_ir_builder.CreateTrunc(ra_i64, Type::getInt32Ty(m_llvm_context)); // ra_i64 = m_ir_builder.CreateSExt(ra_i64, Type::getInt64Ty(m_llvm_context)); //} //SetCrFieldSignedCmp(crfd, ra_i64, m_ir_builder.getInt64((s64)simm16)); ThisCall4("CMPI", &PPUInterpreter::CMPI, &m_interpreter, crfd, l, ra, simm16); } void PPULLVMRecompiler::ADDIC(u32 rd, u32 ra, s32 simm16) { //auto ra_i64 = GetGpr(ra); //auto res_s = m_ir_builder.CreateCall2(Intrinsic::getDeclaration(m_module, Intrinsic::sadd_with_overflow), m_ir_builder.getInt64((s64)simm16), ra_i64); //auto sum_i64 = m_ir_builder.CreateExtractValue(res_s, {0}); //auto carry_i1 = m_ir_builder.CreateExtractValue(res_s, {1}); //SetGpr(rd, sum_i64); //SetXerCa(carry_i1); ThisCall3("ADDIC", &PPUInterpreter::ADDIC, &m_interpreter, rd, ra, simm16); } void PPULLVMRecompiler::ADDIC_(u32 rd, u32 ra, s32 simm16) { //ADDIC(rd, ra, simm16); //SetCrFieldSignedCmp(0, GetGpr(rd), m_ir_builder.getInt64(0)); ThisCall3("ADDIC_", &PPUInterpreter::ADDIC_, &m_interpreter, rd, ra, simm16); } void PPULLVMRecompiler::ADDI(u32 rd, u32 ra, s32 simm16) { //if (ra == 0) { // SetGpr(rd, m_ir_builder.getInt64((s64)simm16)); //} else { // auto ra_i64 = GetGpr(ra); // auto sum_i64 = m_ir_builder.CreateAdd(ra_i64, m_ir_builder.getInt64((s64)simm16)); // SetGpr(rd, sum_i64); //} ThisCall3("ADDI", &PPUInterpreter::ADDI, &m_interpreter, rd, ra, simm16); } void PPULLVMRecompiler::ADDIS(u32 rd, u32 ra, s32 simm16) { //if (ra == 0) { // SetGpr(rd, m_ir_builder.getInt64((s64)(simm16 << 16))); //} else { // auto ra_i64 = GetGpr(ra); // auto sum_i64 = m_ir_builder.CreateAdd(ra_i64, m_ir_builder.getInt64((s64)(simm16 << 16))); // SetGpr(rd, sum_i64); //} ThisCall3("ADDIS", &PPUInterpreter::ADDIS, &m_interpreter, rd, ra, simm16); } void PPULLVMRecompiler::BC(u32 bo, u32 bi, s32 bd, u32 aa, u32 lk) { ThisCall5("BC", &PPUInterpreter::BC, &m_interpreter, bo, bi, bd, aa, lk); m_hit_branch_instruction = true; } void PPULLVMRecompiler::SC(u32 sc_code) { ThisCall1("SC", &PPUInterpreter::SC, &m_interpreter, sc_code); } void PPULLVMRecompiler::B(s32 ll, u32 aa, u32 lk) { ThisCall3("B", &PPUInterpreter::B, &m_interpreter, ll, aa, lk); m_hit_branch_instruction = true; } void PPULLVMRecompiler::MCRF(u32 crfd, u32 crfs) { //if (crfd != crfs) { // auto cr_i32 = GetCr(); // auto crf_i32 = GetNibble(cr_i32, crfs); // cr_i32 = SetNibble(cr_i32, crfd, crf_i32); // SetCr(cr_i32); //} ThisCall2("MCRF", &PPUInterpreter::MCRF, &m_interpreter, crfd, crfs); } void PPULLVMRecompiler::BCLR(u32 bo, u32 bi, u32 bh, u32 lk) { ThisCall4("BCLR", &PPUInterpreter::BCLR, &m_interpreter, bo, bi, bh, lk); m_hit_branch_instruction = true; } void PPULLVMRecompiler::CRNOR(u32 crbd, u32 crba, u32 crbb) { //auto cr_i32 = GetCr(); //auto ba_i32 = GetBit(cr_i32, crba); //auto bb_i32 = GetBit(cr_i32, crbb); //auto res_i32 = m_ir_builder.CreateOr(ba_i32, bb_i32); //res_i32 = m_ir_builder.CreateXor(res_i32, 1); //cr_i32 = SetBit(cr_i32, crbd, res_i32); //SetCr(cr_i32); ThisCall3("CRNOR", &PPUInterpreter::CRNOR, &m_interpreter, crbd, crba, crbb); } void PPULLVMRecompiler::CRANDC(u32 crbd, u32 crba, u32 crbb) { //auto cr_i32 = GetCr(); //auto ba_i32 = GetBit(cr_i32, crba); //auto bb_i32 = GetBit(cr_i32, crbb); //auto res_i32 = m_ir_builder.CreateXor(bb_i32, 1); //res_i32 = m_ir_builder.CreateAnd(ba_i32, res_i32); //cr_i32 = SetBit(cr_i32, crbd, res_i32); //SetCr(cr_i32); ThisCall3("CRANDC", &PPUInterpreter::CRANDC, &m_interpreter, crbd, crba, crbb); } void PPULLVMRecompiler::ISYNC() { m_ir_builder.CreateCall(Intrinsic::getDeclaration(m_module, Intrinsic::x86_sse2_mfence)); } void PPULLVMRecompiler::CRXOR(u32 crbd, u32 crba, u32 crbb) { //auto cr_i32 = GetCr(); //auto ba_i32 = GetBit(cr_i32, crba); //auto bb_i32 = GetBit(cr_i32, crbb); //auto res_i32 = m_ir_builder.CreateXor(ba_i32, bb_i32); //cr_i32 = SetBit(cr_i32, crbd, res_i32); //SetCr(cr_i32); ThisCall3("CRXOR", &PPUInterpreter::CRXOR, &m_interpreter, crbd, crba, crbb); } void PPULLVMRecompiler::CRNAND(u32 crbd, u32 crba, u32 crbb) { //auto cr_i32 = GetCr(); //auto ba_i32 = GetBit(cr_i32, crba); //auto bb_i32 = GetBit(cr_i32, crbb); //auto res_i32 = m_ir_builder.CreateAnd(ba_i32, bb_i32); //res_i32 = m_ir_builder.CreateXor(res_i32, 1); //cr_i32 = SetBit(cr_i32, crbd, res_i32); //SetCr(cr_i32); ThisCall3("CRNAND", &PPUInterpreter::CRNAND, &m_interpreter, crbd, crba, crbb); } void PPULLVMRecompiler::CRAND(u32 crbd, u32 crba, u32 crbb) { //auto cr_i32 = GetCr(); //auto ba_i32 = GetBit(cr_i32, crba); //auto bb_i32 = GetBit(cr_i32, crbb); //auto res_i32 = m_ir_builder.CreateAnd(ba_i32, bb_i32); //cr_i32 = SetBit(cr_i32, crbd, res_i32); //SetCr(cr_i32); ThisCall3("CRAND", &PPUInterpreter::CRAND, &m_interpreter, crbd, crba, crbb); } void PPULLVMRecompiler::CREQV(u32 crbd, u32 crba, u32 crbb) { //auto cr_i32 = GetCr(); //auto ba_i32 = GetBit(cr_i32, crba); //auto bb_i32 = GetBit(cr_i32, crbb); //auto res_i32 = m_ir_builder.CreateXor(ba_i32, bb_i32); //res_i32 = m_ir_builder.CreateXor(res_i32, 1); //cr_i32 = SetBit(cr_i32, crbd, res_i32); //SetCr(cr_i32); ThisCall3("CREQV", &PPUInterpreter::CREQV, &m_interpreter, crbd, crba, crbb); } void PPULLVMRecompiler::CRORC(u32 crbd, u32 crba, u32 crbb) { //auto cr_i32 = GetCr(); //auto ba_i32 = GetBit(cr_i32, crba); //auto bb_i32 = GetBit(cr_i32, crbb); //auto res_i32 = m_ir_builder.CreateXor(bb_i32, 1); //res_i32 = m_ir_builder.CreateOr(ba_i32, res_i32); //cr_i32 = SetBit(cr_i32, crbd, res_i32); //SetCr(cr_i32); ThisCall3("CRORC", &PPUInterpreter::CRORC, &m_interpreter, crbd, crba, crbb); } void PPULLVMRecompiler::CROR(u32 crbd, u32 crba, u32 crbb) { //auto cr_i32 = GetCr(); //auto ba_i32 = GetBit(cr_i32, crba); //auto bb_i32 = GetBit(cr_i32, crbb); //auto res_i32 = m_ir_builder.CreateOr(ba_i32, bb_i32); //cr_i32 = SetBit(cr_i32, crbd, res_i32); //SetCr(cr_i32); ThisCall3("CROR", &PPUInterpreter::CROR, &m_interpreter, crbd, crba, crbb); } void PPULLVMRecompiler::BCCTR(u32 bo, u32 bi, u32 bh, u32 lk) { ThisCall4("BCCTR", &PPUInterpreter::BCCTR, &m_interpreter, bo, bi, bh, lk); m_hit_branch_instruction = true; } void PPULLVMRecompiler::RLWIMI(u32 ra, u32 rs, u32 sh, u32 mb, u32 me, bool rc) { ThisCall6("RLWIMI", &PPUInterpreter::RLWIMI, &m_interpreter, ra, rs, sh, mb, me, rc); } void PPULLVMRecompiler::RLWINM(u32 ra, u32 rs, u32 sh, u32 mb, u32 me, bool rc) { ThisCall6("RLWINM", &PPUInterpreter::RLWINM, &m_interpreter, ra, rs, sh, mb, me, rc); } void PPULLVMRecompiler::RLWNM(u32 ra, u32 rs, u32 rb, u32 mb, u32 me, bool rc) { ThisCall6("RLWNM", &PPUInterpreter::RLWNM, &m_interpreter, ra, rs, rb, mb, me, rc); } void PPULLVMRecompiler::ORI(u32 ra, u32 rs, u32 uimm16) { //auto rs_i64 = GetGpr(rs); //auto res_i64 = m_ir_builder.CreateOr(rs_i64, uimm16); //SetGpr(ra, res_i64); ThisCall3("ORI", &PPUInterpreter::ORI, &m_interpreter, ra, rs, uimm16); } void PPULLVMRecompiler::ORIS(u32 ra, u32 rs, u32 uimm16) { //auto rs_i64 = GetGpr(rs); //auto res_i64 = m_ir_builder.CreateOr(rs_i64, uimm16 << 16); //SetGpr(ra, res_i64); ThisCall3("ORIS", &PPUInterpreter::ORIS, &m_interpreter, ra, rs, uimm16); } void PPULLVMRecompiler::XORI(u32 ra, u32 rs, u32 uimm16) { //auto rs_i64 = GetGpr(rs); //auto res_i64 = m_ir_builder.CreateXor(rs_i64, uimm16); //SetGpr(ra, res_i64); ThisCall3("XORI", &PPUInterpreter::XORI, &m_interpreter, ra, rs, uimm16); } void PPULLVMRecompiler::XORIS(u32 ra, u32 rs, u32 uimm16) { //auto rs_i64 = GetGpr(rs); //auto res_i64 = m_ir_builder.CreateXor(rs_i64, uimm16 << 16); //SetGpr(ra, res_i64); ThisCall3("XORIS", &PPUInterpreter::XORIS, &m_interpreter, ra, rs, uimm16); } void PPULLVMRecompiler::ANDI_(u32 ra, u32 rs, u32 uimm16) { //auto rs_i64 = GetGpr(rs); //auto res_i64 = m_ir_builder.CreateAnd(rs_i64, uimm16); //SetGpr(ra, res_i64); //SetCrFieldSignedCmp(0, res_i64, m_ir_builder.getInt64(0)); ThisCall3("ANDI_", &PPUInterpreter::ANDI_, &m_interpreter, ra, rs, uimm16); } void PPULLVMRecompiler::ANDIS_(u32 ra, u32 rs, u32 uimm16) { //auto rs_i64 = GetGpr(rs); //auto res_i64 = m_ir_builder.CreateAnd(rs_i64, uimm16 << 16); //SetGpr(ra, res_i64); //SetCrFieldSignedCmp(0, res_i64, m_ir_builder.getInt64(0)); ThisCall3("ANDIS_", &PPUInterpreter::ANDIS_, &m_interpreter, ra, rs, uimm16); } void PPULLVMRecompiler::RLDICL(u32 ra, u32 rs, u32 sh, u32 mb, bool rc) { ThisCall5("RLDICL", &PPUInterpreter::RLDICL, &m_interpreter, ra, rs, sh, mb, rc); } void PPULLVMRecompiler::RLDICR(u32 ra, u32 rs, u32 sh, u32 me, bool rc) { ThisCall5("RLDICR", &PPUInterpreter::RLDICR, &m_interpreter, ra, rs, sh, me, rc); } void PPULLVMRecompiler::RLDIC(u32 ra, u32 rs, u32 sh, u32 mb, bool rc) { ThisCall5("RLDIC", &PPUInterpreter::RLDIC, &m_interpreter, ra, rs, sh, mb, rc); } void PPULLVMRecompiler::RLDIMI(u32 ra, u32 rs, u32 sh, u32 mb, bool rc) { ThisCall5("RLDIMI", &PPUInterpreter::RLDIMI, &m_interpreter, ra, rs, sh, mb, rc); } void PPULLVMRecompiler::RLDC_LR(u32 ra, u32 rs, u32 rb, u32 m_eb, bool is_r, bool rc) { ThisCall6("RLDC_LR", &PPUInterpreter::RLDC_LR, &m_interpreter, ra, rs, rb, m_eb, is_r, rc); } void PPULLVMRecompiler::CMP(u32 crfd, u32 l, u32 ra, u32 rb) { //m_ppu.UpdateCRnS(l, crfd, m_ppu.GPR[ra], m_ppu.GPR[rb]); ThisCall4("CMP", &PPUInterpreter::CMP, &m_interpreter, crfd, l, ra, rb); } void PPULLVMRecompiler::TW(u32 to, u32 ra, u32 rb) { ThisCall3("TW", &PPUInterpreter::TW, &m_interpreter, to, ra, rb); } void PPULLVMRecompiler::LVSL(u32 vd, u32 ra, u32 rb) { ThisCall3("LVSL", &PPUInterpreter::LVSL, &m_interpreter, vd, ra, rb); } void PPULLVMRecompiler::LVEBX(u32 vd, u32 ra, u32 rb) { ThisCall3("LVEBX", &PPUInterpreter::LVEBX, &m_interpreter, vd, ra, rb); } void PPULLVMRecompiler::SUBFC(u32 rd, u32 ra, u32 rb, u32 oe, bool rc) { ThisCall5("SUBFC", &PPUInterpreter::SUBFC, &m_interpreter, rd, ra, rb, oe, rc); } void PPULLVMRecompiler::ADDC(u32 rd, u32 ra, u32 rb, u32 oe, bool rc) { ThisCall5("ADDC", &PPUInterpreter::ADDC, &m_interpreter, rd, ra, rb, oe, rc); } void PPULLVMRecompiler::MULHDU(u32 rd, u32 ra, u32 rb, bool rc) { ThisCall4("MULHDU", &PPUInterpreter::MULHDU, &m_interpreter, rd, ra, rb, rc); } void PPULLVMRecompiler::MULHWU(u32 rd, u32 ra, u32 rb, bool rc) { ThisCall4("MULHWU", &PPUInterpreter::MULHWU, &m_interpreter, rd, ra, rb, rc); } void PPULLVMRecompiler::MFOCRF(u32 a, u32 rd, u32 crm) { ThisCall3("MFOCRF", &PPUInterpreter::MFOCRF, &m_interpreter, a, rd, crm); } void PPULLVMRecompiler::LWARX(u32 rd, u32 ra, u32 rb) { ThisCall3("LWARX", &PPUInterpreter::LWARX, &m_interpreter, rd, ra, rb); } void PPULLVMRecompiler::LDX(u32 rd, u32 ra, u32 rb) { ThisCall3("LDX", &PPUInterpreter::LDX, &m_interpreter, rd, ra, rb); } void PPULLVMRecompiler::LWZX(u32 rd, u32 ra, u32 rb) { ThisCall3("LWZX", &PPUInterpreter::LWZX, &m_interpreter, rd, ra, rb); } void PPULLVMRecompiler::SLW(u32 ra, u32 rs, u32 rb, bool rc) { ThisCall4("SLW", &PPUInterpreter::SLW, &m_interpreter, ra, rs, rb, rc); } void PPULLVMRecompiler::CNTLZW(u32 ra, u32 rs, bool rc) { ThisCall3("CNTLZW", &PPUInterpreter::CNTLZW, &m_interpreter, ra, rs, rc); } void PPULLVMRecompiler::SLD(u32 ra, u32 rs, u32 rb, bool rc) { ThisCall4("SLD", &PPUInterpreter::SLD, &m_interpreter, ra, rs, rb, rc); } void PPULLVMRecompiler::AND(u32 ra, u32 rs, u32 rb, bool rc) { ThisCall4("AND", &PPUInterpreter::AND, &m_interpreter, ra, rs, rb, rc); } void PPULLVMRecompiler::CMPL(u32 crfd, u32 l, u32 ra, u32 rb) { ThisCall4("CMPL", &PPUInterpreter::CMPL, &m_interpreter, crfd, l, ra, rb); } void PPULLVMRecompiler::LVSR(u32 vd, u32 ra, u32 rb) { ThisCall3("LVSR", &PPUInterpreter::LVSR, &m_interpreter, vd, ra, rb); } void PPULLVMRecompiler::LVEHX(u32 vd, u32 ra, u32 rb) { ThisCall3("LVEHX", &PPUInterpreter::LVEHX, &m_interpreter, vd, ra, rb); } void PPULLVMRecompiler::SUBF(u32 rd, u32 ra, u32 rb, u32 oe, bool rc) { ThisCall5("SUBF", &PPUInterpreter::SUBF, &m_interpreter, rd, ra, rb, oe, rc); } void PPULLVMRecompiler::LDUX(u32 rd, u32 ra, u32 rb) { ThisCall3("LDUX", &PPUInterpreter::LDUX, &m_interpreter, rd, ra, rb); } void PPULLVMRecompiler::DCBST(u32 ra, u32 rb) { ThisCall2("DCBST", &PPUInterpreter::DCBST, &m_interpreter, ra, rb); } void PPULLVMRecompiler::LWZUX(u32 rd, u32 ra, u32 rb) { ThisCall3("LWZUX", &PPUInterpreter::LWZUX, &m_interpreter, rd, ra, rb); } void PPULLVMRecompiler::CNTLZD(u32 ra, u32 rs, bool rc) { ThisCall3("CNTLZD", &PPUInterpreter::CNTLZD, &m_interpreter, ra, rs, rc); } void PPULLVMRecompiler::ANDC(u32 ra, u32 rs, u32 rb, bool rc) { ThisCall4("ANDC", &PPUInterpreter::ANDC, &m_interpreter, ra, rs, rb, rc); } void PPULLVMRecompiler::TD(u32 to, u32 ra, u32 rb) { ThisCall3("TD", &PPUInterpreter::TD, &m_interpreter, to, ra, rb); } void PPULLVMRecompiler::LVEWX(u32 vd, u32 ra, u32 rb) { ThisCall3("LVEWX", &PPUInterpreter::LVEWX, &m_interpreter, vd, ra, rb); } void PPULLVMRecompiler::MULHD(u32 rd, u32 ra, u32 rb, bool rc) { ThisCall4("MULHD", &PPUInterpreter::MULHD, &m_interpreter, rd, ra, rb, rc); } void PPULLVMRecompiler::MULHW(u32 rd, u32 ra, u32 rb, bool rc) { ThisCall4("MULHW", &PPUInterpreter::MULHW, &m_interpreter, rd, ra, rb, rc); } void PPULLVMRecompiler::LDARX(u32 rd, u32 ra, u32 rb) { ThisCall3("LDARX", &PPUInterpreter::LDARX, &m_interpreter, rd, ra, rb); } void PPULLVMRecompiler::DCBF(u32 ra, u32 rb) { ThisCall2("DCBF", &PPUInterpreter::DCBF, &m_interpreter, ra, rb); } void PPULLVMRecompiler::LBZX(u32 rd, u32 ra, u32 rb) { ThisCall3("LBZX", &PPUInterpreter::LBZX, &m_interpreter, rd, ra, rb); } void PPULLVMRecompiler::LVX(u32 vd, u32 ra, u32 rb) { ThisCall3("LVX", &PPUInterpreter::LVX, &m_interpreter, vd, ra, rb); } void PPULLVMRecompiler::NEG(u32 rd, u32 ra, u32 oe, bool rc) { ThisCall4("NEG", &PPUInterpreter::NEG, &m_interpreter, rd, ra, oe, rc); } void PPULLVMRecompiler::LBZUX(u32 rd, u32 ra, u32 rb) { ThisCall3("LBZUX", &PPUInterpreter::LBZUX, &m_interpreter, rd, ra, rb); } void PPULLVMRecompiler::NOR(u32 ra, u32 rs, u32 rb, bool rc) { ThisCall4("NOR", &PPUInterpreter::NOR, &m_interpreter, ra, rs, rb, rc); } void PPULLVMRecompiler::STVEBX(u32 vs, u32 ra, u32 rb) { ThisCall3("STVEBX", &PPUInterpreter::STVEBX, &m_interpreter, vs, ra, rb); } void PPULLVMRecompiler::SUBFE(u32 rd, u32 ra, u32 rb, u32 oe, bool rc) { ThisCall5("SUBFE", &PPUInterpreter::SUBFE, &m_interpreter, rd, ra, rb, oe, rc); } void PPULLVMRecompiler::ADDE(u32 rd, u32 ra, u32 rb, u32 oe, bool rc) { ThisCall5("ADDE", &PPUInterpreter::ADDE, &m_interpreter, rd, ra, rb, oe, rc); } void PPULLVMRecompiler::MTOCRF(u32 l, u32 crm, u32 rs) { ThisCall3("MTOCRF", &PPUInterpreter::MTOCRF, &m_interpreter, l, crm, rs); } void PPULLVMRecompiler::STDX(u32 rs, u32 ra, u32 rb) { ThisCall3("STDX", &PPUInterpreter::STDX, &m_interpreter, rs, ra, rb); } void PPULLVMRecompiler::STWCX_(u32 rs, u32 ra, u32 rb) { ThisCall3("STWCX_", &PPUInterpreter::STWCX_, &m_interpreter, rs, ra, rb); } void PPULLVMRecompiler::STWX(u32 rs, u32 ra, u32 rb) { ThisCall3("STWX", &PPUInterpreter::STWX, &m_interpreter, rs, ra, rb); } void PPULLVMRecompiler::STVEHX(u32 vs, u32 ra, u32 rb) { ThisCall3("STVEHX", &PPUInterpreter::STVEHX, &m_interpreter, vs, ra, rb); } void PPULLVMRecompiler::STDUX(u32 rs, u32 ra, u32 rb) { ThisCall3("STDUX", &PPUInterpreter::STDUX, &m_interpreter, rs, ra, rb); } void PPULLVMRecompiler::STWUX(u32 rs, u32 ra, u32 rb) { ThisCall3("STWUX", &PPUInterpreter::STWUX, &m_interpreter, rs, ra, rb); } void PPULLVMRecompiler::STVEWX(u32 vs, u32 ra, u32 rb) { ThisCall3("STVEWX", &PPUInterpreter::STVEWX, &m_interpreter, vs, ra, rb); } void PPULLVMRecompiler::ADDZE(u32 rd, u32 ra, u32 oe, bool rc) { ThisCall4("ADDZE", &PPUInterpreter::ADDZE, &m_interpreter, rd, ra, oe, rc); } void PPULLVMRecompiler::SUBFZE(u32 rd, u32 ra, u32 oe, bool rc) { ThisCall4("SUBFZE", &PPUInterpreter::SUBFZE, &m_interpreter, rd, ra, oe, rc); } void PPULLVMRecompiler::STDCX_(u32 rs, u32 ra, u32 rb) { ThisCall3("STDCX_", &PPUInterpreter::STDCX_, &m_interpreter, rs, ra, rb); } void PPULLVMRecompiler::STBX(u32 rs, u32 ra, u32 rb) { ThisCall3("STBX", &PPUInterpreter::STBX, &m_interpreter, rs, ra, rb); } void PPULLVMRecompiler::STVX(u32 vs, u32 ra, u32 rb) { ThisCall3("STVX", &PPUInterpreter::STVX, &m_interpreter, vs, ra, rb); } void PPULLVMRecompiler::SUBFME(u32 rd, u32 ra, u32 oe, bool rc) { ThisCall4("SUBFME", &PPUInterpreter::SUBFME, &m_interpreter, rd, ra, oe, rc); } void PPULLVMRecompiler::MULLD(u32 rd, u32 ra, u32 rb, u32 oe, bool rc) { ThisCall5("MULLD", &PPUInterpreter::MULLD, &m_interpreter, rd, ra, rb, oe, rc); } void PPULLVMRecompiler::ADDME(u32 rd, u32 ra, u32 oe, bool rc) { ThisCall4("ADDME", &PPUInterpreter::ADDME, &m_interpreter, rd, ra, oe, rc); } void PPULLVMRecompiler::MULLW(u32 rd, u32 ra, u32 rb, u32 oe, bool rc) { ThisCall5("MULLW", &PPUInterpreter::MULLW, &m_interpreter, rd, ra, rb, oe, rc); } void PPULLVMRecompiler::DCBTST(u32 ra, u32 rb, u32 th) { ThisCall3("DCBTST", &PPUInterpreter::DCBTST, &m_interpreter, ra, rb, th); } void PPULLVMRecompiler::STBUX(u32 rs, u32 ra, u32 rb) { ThisCall3("STBUX", &PPUInterpreter::STBUX, &m_interpreter, rs, ra, rb); } void PPULLVMRecompiler::ADD(u32 rd, u32 ra, u32 rb, u32 oe, bool rc) { ThisCall5("ADD", &PPUInterpreter::ADD, &m_interpreter, rd, ra, rb, oe, rc); } void PPULLVMRecompiler::DCBT(u32 ra, u32 rb, u32 th) { ThisCall3("DCBT", &PPUInterpreter::DCBT, &m_interpreter, ra, rb, th); } void PPULLVMRecompiler::LHZX(u32 rd, u32 ra, u32 rb) { ThisCall3("LHZX", &PPUInterpreter::LHZX, &m_interpreter, rd, ra, rb); } void PPULLVMRecompiler::EQV(u32 ra, u32 rs, u32 rb, bool rc) { ThisCall4("EQV", &PPUInterpreter::EQV, &m_interpreter, ra, rs, rb, rc); } void PPULLVMRecompiler::ECIWX(u32 rd, u32 ra, u32 rb) { ThisCall3("ECIWX", &PPUInterpreter::ECIWX, &m_interpreter, rd, ra, rb); } void PPULLVMRecompiler::LHZUX(u32 rd, u32 ra, u32 rb) { ThisCall3("LHZUX", &PPUInterpreter::LHZUX, &m_interpreter, rd, ra, rb); } void PPULLVMRecompiler::XOR(u32 ra, u32 rs, u32 rb, bool rc) { ThisCall4("XOR", &PPUInterpreter::XOR, &m_interpreter, ra, rs, rb, rc); } void PPULLVMRecompiler::MFSPR(u32 rd, u32 spr) { ThisCall2("MFSPR", &PPUInterpreter::MFSPR, &m_interpreter, rd, spr); } void PPULLVMRecompiler::LWAX(u32 rd, u32 ra, u32 rb) { ThisCall3("LWAX", &PPUInterpreter::LWAX, &m_interpreter, rd, ra, rb); } void PPULLVMRecompiler::DST(u32 ra, u32 rb, u32 strm, u32 t) { ThisCall4("DST", &PPUInterpreter::DST, &m_interpreter, ra, rb, strm, t); } void PPULLVMRecompiler::LHAX(u32 rd, u32 ra, u32 rb) { ThisCall3("LHAX", &PPUInterpreter::LHAX, &m_interpreter, rd, ra, rb); } void PPULLVMRecompiler::LVXL(u32 vd, u32 ra, u32 rb) { ThisCall3("LVXL", &PPUInterpreter::LVXL, &m_interpreter, vd, ra, rb); } void PPULLVMRecompiler::MFTB(u32 rd, u32 spr) { ThisCall2("MFTB", &PPUInterpreter::MFTB, &m_interpreter, rd, spr); } void PPULLVMRecompiler::LWAUX(u32 rd, u32 ra, u32 rb) { ThisCall3("LWAUX", &PPUInterpreter::LWAUX, &m_interpreter, rd, ra, rb); } void PPULLVMRecompiler::DSTST(u32 ra, u32 rb, u32 strm, u32 t) { ThisCall4("DSTST", &PPUInterpreter::DSTST, &m_interpreter, ra, rb, strm, t); } void PPULLVMRecompiler::LHAUX(u32 rd, u32 ra, u32 rb) { ThisCall3("LHAUX", &PPUInterpreter::LHAUX, &m_interpreter, rd, ra, rb); } void PPULLVMRecompiler::STHX(u32 rs, u32 ra, u32 rb) { ThisCall3("STHX", &PPUInterpreter::STHX, &m_interpreter, rs, ra, rb); } void PPULLVMRecompiler::ORC(u32 ra, u32 rs, u32 rb, bool rc) { ThisCall4("ORC", &PPUInterpreter::ORC, &m_interpreter, ra, rs, rb, rc); } void PPULLVMRecompiler::ECOWX(u32 rs, u32 ra, u32 rb) { ThisCall3("ECOWX", &PPUInterpreter::ECOWX, &m_interpreter, rs, ra, rb); } void PPULLVMRecompiler::STHUX(u32 rs, u32 ra, u32 rb) { ThisCall3("STHUX", &PPUInterpreter::STHUX, &m_interpreter, rs, ra, rb); } void PPULLVMRecompiler::OR(u32 ra, u32 rs, u32 rb, bool rc) { ThisCall4("OR", &PPUInterpreter::OR, &m_interpreter, ra, rs, rb, rc); } void PPULLVMRecompiler::DIVDU(u32 rd, u32 ra, u32 rb, u32 oe, bool rc) { ThisCall5("DIVDU", &PPUInterpreter::DIVDU, &m_interpreter, rd, ra, rb, oe, rc); } void PPULLVMRecompiler::DIVWU(u32 rd, u32 ra, u32 rb, u32 oe, bool rc) { ThisCall5("DIVWU", &PPUInterpreter::DIVWU, &m_interpreter, rd, ra, rb, oe, rc); } void PPULLVMRecompiler::MTSPR(u32 spr, u32 rs) { ThisCall2("MTSPR", &PPUInterpreter::MTSPR, &m_interpreter, spr, rs); } void PPULLVMRecompiler::NAND(u32 ra, u32 rs, u32 rb, bool rc) { ThisCall4("NAND", &PPUInterpreter::NAND, &m_interpreter, ra, rs, rb, rc); } void PPULLVMRecompiler::STVXL(u32 vs, u32 ra, u32 rb) { ThisCall3("STVXL", &PPUInterpreter::STVXL, &m_interpreter, vs, ra, rb); } void PPULLVMRecompiler::DIVD(u32 rd, u32 ra, u32 rb, u32 oe, bool rc) { ThisCall5("DIVD", &PPUInterpreter::DIVD, &m_interpreter, rd, ra, rb, oe, rc); } void PPULLVMRecompiler::DIVW(u32 rd, u32 ra, u32 rb, u32 oe, bool rc) { ThisCall5("DIVW", &PPUInterpreter::DIVW, &m_interpreter, rd, ra, rb, oe, rc); } void PPULLVMRecompiler::LVLX(u32 vd, u32 ra, u32 rb) { ThisCall3("LVLX", &PPUInterpreter::LVLX, &m_interpreter, vd, ra, rb); } void PPULLVMRecompiler::LDBRX(u32 rd, u32 ra, u32 rb) { ThisCall3("LDBRX", &PPUInterpreter::LDBRX, &m_interpreter, rd, ra, rb); } void PPULLVMRecompiler::LSWX(u32 rd, u32 ra, u32 rb) { ThisCall3("LSWX", &PPUInterpreter::LSWX, &m_interpreter, rd, ra, rb); } void PPULLVMRecompiler::LWBRX(u32 rd, u32 ra, u32 rb) { ThisCall3("LWBRX", &PPUInterpreter::LWBRX, &m_interpreter, rd, ra, rb); } void PPULLVMRecompiler::LFSX(u32 frd, u32 ra, u32 rb) { ThisCall3("LFSX", &PPUInterpreter::LFSX, &m_interpreter, frd, ra, rb); } void PPULLVMRecompiler::SRW(u32 ra, u32 rs, u32 rb, bool rc) { ThisCall4("SRW", &PPUInterpreter::SRW, &m_interpreter, ra, rs, rb, rc); } void PPULLVMRecompiler::SRD(u32 ra, u32 rs, u32 rb, bool rc) { ThisCall4("SRD", &PPUInterpreter::SRD, &m_interpreter, ra, rs, rb, rc); } void PPULLVMRecompiler::LVRX(u32 vd, u32 ra, u32 rb) { ThisCall3("LVRX", &PPUInterpreter::LVRX, &m_interpreter, vd, ra, rb); } void PPULLVMRecompiler::LSWI(u32 rd, u32 ra, u32 nb) { ThisCall3("LSWI", &PPUInterpreter::LSWI, &m_interpreter, rd, ra, nb); } void PPULLVMRecompiler::LFSUX(u32 frd, u32 ra, u32 rb) { ThisCall3("LFSUX", &PPUInterpreter::LFSUX, &m_interpreter, frd, ra, rb); } void PPULLVMRecompiler::SYNC(u32 l) { ThisCall1("SYNC", &PPUInterpreter::SYNC, &m_interpreter, l); } void PPULLVMRecompiler::LFDX(u32 frd, u32 ra, u32 rb) { ThisCall3("LFDX", &PPUInterpreter::LFDX, &m_interpreter, frd, ra, rb); } void PPULLVMRecompiler::LFDUX(u32 frd, u32 ra, u32 rb) { ThisCall3("LFDUX", &PPUInterpreter::LFDUX, &m_interpreter, frd, ra, rb); } void PPULLVMRecompiler::STVLX(u32 vs, u32 ra, u32 rb) { ThisCall3("STVLX", &PPUInterpreter::STVLX, &m_interpreter, vs, ra, rb); } void PPULLVMRecompiler::STSWX(u32 rs, u32 ra, u32 rb) { ThisCall3("STSWX", &PPUInterpreter::STSWX, &m_interpreter, rs, ra, rb); } void PPULLVMRecompiler::STWBRX(u32 rs, u32 ra, u32 rb) { ThisCall3("STWBRX", &PPUInterpreter::STWBRX, &m_interpreter, rs, ra, rb); } void PPULLVMRecompiler::STFSX(u32 frs, u32 ra, u32 rb) { ThisCall3("STFSX", &PPUInterpreter::STFSX, &m_interpreter, frs, ra, rb); } void PPULLVMRecompiler::STVRX(u32 vs, u32 ra, u32 rb) { ThisCall3("STVRX", &PPUInterpreter::STVRX, &m_interpreter, vs, ra, rb); } void PPULLVMRecompiler::STFSUX(u32 frs, u32 ra, u32 rb) { ThisCall3("STFSUX", &PPUInterpreter::STFSUX, &m_interpreter, frs, ra, rb); } void PPULLVMRecompiler::STSWI(u32 rd, u32 ra, u32 nb) { ThisCall3("STSWI", &PPUInterpreter::STSWI, &m_interpreter, rd, ra, nb); } void PPULLVMRecompiler::STFDX(u32 frs, u32 ra, u32 rb) { ThisCall3("STFDX", &PPUInterpreter::STFDX, &m_interpreter, frs, ra, rb); } void PPULLVMRecompiler::STFDUX(u32 frs, u32 ra, u32 rb) { ThisCall3("STFDUX", &PPUInterpreter::STFDUX, &m_interpreter, frs, ra, rb); } void PPULLVMRecompiler::LVLXL(u32 vd, u32 ra, u32 rb) { ThisCall3("LVLXL", &PPUInterpreter::LVLXL, &m_interpreter, vd, ra, rb); } void PPULLVMRecompiler::LHBRX(u32 rd, u32 ra, u32 rb) { ThisCall3("LHBRX", &PPUInterpreter::LHBRX, &m_interpreter, rd, ra, rb); } void PPULLVMRecompiler::SRAW(u32 ra, u32 rs, u32 rb, bool rc) { ThisCall4("SRAW", &PPUInterpreter::SRAW, &m_interpreter, ra, rs, rb, rc); } void PPULLVMRecompiler::SRAD(u32 ra, u32 rs, u32 rb, bool rc) { ThisCall4("SRAD", &PPUInterpreter::SRAD, &m_interpreter, ra, rs, rb, rc); } void PPULLVMRecompiler::LVRXL(u32 vd, u32 ra, u32 rb) { ThisCall3("LVRXL", &PPUInterpreter::LVRXL, &m_interpreter, vd, ra, rb); } void PPULLVMRecompiler::DSS(u32 strm, u32 a) { ThisCall2("DSS", &PPUInterpreter::DSS, &m_interpreter, strm, a); } void PPULLVMRecompiler::SRAWI(u32 ra, u32 rs, u32 sh, bool rc) { ThisCall4("SRAWI", &PPUInterpreter::SRAWI, &m_interpreter, ra, rs, sh, rc); } void PPULLVMRecompiler::SRADI1(u32 ra, u32 rs, u32 sh, bool rc) { ThisCall4("SRADI1", &PPUInterpreter::SRADI1, &m_interpreter, ra, rs, sh, rc); } void PPULLVMRecompiler::SRADI2(u32 ra, u32 rs, u32 sh, bool rc) { ThisCall4("SRADI2", &PPUInterpreter::SRADI2, &m_interpreter, ra, rs, sh, rc); } void PPULLVMRecompiler::EIEIO() { ThisCall0("EIEIO", &PPUInterpreter::EIEIO, &m_interpreter); } void PPULLVMRecompiler::STVLXL(u32 vs, u32 ra, u32 rb) { ThisCall3("STVLXL", &PPUInterpreter::STVLXL, &m_interpreter, vs, ra, rb); } void PPULLVMRecompiler::STHBRX(u32 rs, u32 ra, u32 rb) { ThisCall3("STHBRX", &PPUInterpreter::STHBRX, &m_interpreter, rs, ra, rb); } void PPULLVMRecompiler::EXTSH(u32 ra, u32 rs, bool rc) { ThisCall3("EXTSH", &PPUInterpreter::EXTSH, &m_interpreter, ra, rs, rc); } void PPULLVMRecompiler::STVRXL(u32 vs, u32 ra, u32 rb) { ThisCall3("STVRXL", &PPUInterpreter::STVRXL, &m_interpreter, vs, ra, rb); } void PPULLVMRecompiler::EXTSB(u32 ra, u32 rs, bool rc) { ThisCall3("EXTSB", &PPUInterpreter::EXTSB, &m_interpreter, ra, rs, rc); } void PPULLVMRecompiler::STFIWX(u32 frs, u32 ra, u32 rb) { ThisCall3("STFIWX", &PPUInterpreter::STFIWX, &m_interpreter, frs, ra, rb); } void PPULLVMRecompiler::EXTSW(u32 ra, u32 rs, bool rc) { ThisCall3("EXTSW", &PPUInterpreter::EXTSW, &m_interpreter, ra, rs, rc); } void PPULLVMRecompiler::ICBI(u32 ra, u32 rs) { ThisCall2("ICBI", &PPUInterpreter::ICBI, &m_interpreter, ra, rs); } void PPULLVMRecompiler::DCBZ(u32 ra, u32 rb) { ThisCall2("DCBZ", &PPUInterpreter::DCBZ, &m_interpreter, ra, rb); } void PPULLVMRecompiler::LWZ(u32 rd, u32 ra, s32 d) { ThisCall3("LWZ", &PPUInterpreter::LWZ, &m_interpreter, rd, ra, d); } void PPULLVMRecompiler::LWZU(u32 rd, u32 ra, s32 d) { ThisCall3("LWZU", &PPUInterpreter::LWZU, &m_interpreter, rd, ra, d); } void PPULLVMRecompiler::LBZ(u32 rd, u32 ra, s32 d) { ThisCall3("LBZ", &PPUInterpreter::LBZ, &m_interpreter, rd, ra, d); } void PPULLVMRecompiler::LBZU(u32 rd, u32 ra, s32 d) { ThisCall3("LBZU", &PPUInterpreter::LBZU, &m_interpreter, rd, ra, d); } void PPULLVMRecompiler::STW(u32 rs, u32 ra, s32 d) { ThisCall3("STW", &PPUInterpreter::STW, &m_interpreter, rs, ra, d); } void PPULLVMRecompiler::STWU(u32 rs, u32 ra, s32 d) { ThisCall3("STWU", &PPUInterpreter::STWU, &m_interpreter, rs, ra, d); } void PPULLVMRecompiler::STB(u32 rs, u32 ra, s32 d) { ThisCall3("STB", &PPUInterpreter::STB, &m_interpreter, rs, ra, d); } void PPULLVMRecompiler::STBU(u32 rs, u32 ra, s32 d) { ThisCall3("STBU", &PPUInterpreter::STBU, &m_interpreter, rs, ra, d); } void PPULLVMRecompiler::LHZ(u32 rd, u32 ra, s32 d) { ThisCall3("LHZ", &PPUInterpreter::LHZ, &m_interpreter, rd, ra, d); } void PPULLVMRecompiler::LHZU(u32 rd, u32 ra, s32 d) { ThisCall3("LHZU", &PPUInterpreter::LHZU, &m_interpreter, rd, ra, d); } void PPULLVMRecompiler::LHA(u32 rd, u32 ra, s32 d) { ThisCall3("LHA", &PPUInterpreter::LHA, &m_interpreter, rd, ra, d); } void PPULLVMRecompiler::LHAU(u32 rd, u32 ra, s32 d) { ThisCall3("LHAU", &PPUInterpreter::LHAU, &m_interpreter, rd, ra, d); } void PPULLVMRecompiler::STH(u32 rs, u32 ra, s32 d) { ThisCall3("STH", &PPUInterpreter::STH, &m_interpreter, rs, ra, d); } void PPULLVMRecompiler::STHU(u32 rs, u32 ra, s32 d) { ThisCall3("STHU", &PPUInterpreter::STHU, &m_interpreter, rs, ra, d); } void PPULLVMRecompiler::LMW(u32 rd, u32 ra, s32 d) { ThisCall3("LMW", &PPUInterpreter::LMW, &m_interpreter, rd, ra, d); } void PPULLVMRecompiler::STMW(u32 rs, u32 ra, s32 d) { ThisCall3("STMW", &PPUInterpreter::STMW, &m_interpreter, rs, ra, d); } void PPULLVMRecompiler::LFS(u32 frd, u32 ra, s32 d) { ThisCall3("LFS", &PPUInterpreter::LFS, &m_interpreter, frd, ra, d); } void PPULLVMRecompiler::LFSU(u32 frd, u32 ra, s32 ds) { ThisCall3("LFSU", &PPUInterpreter::LFSU, &m_interpreter, frd, ra, ds); } void PPULLVMRecompiler::LFD(u32 frd, u32 ra, s32 d) { ThisCall3("LFD", &PPUInterpreter::LFD, &m_interpreter, frd, ra, d); } void PPULLVMRecompiler::LFDU(u32 frd, u32 ra, s32 ds) { ThisCall3("LFDU", &PPUInterpreter::LFDU, &m_interpreter, frd, ra, ds); } void PPULLVMRecompiler::STFS(u32 frs, u32 ra, s32 d) { ThisCall3("STFS", &PPUInterpreter::STFS, &m_interpreter, frs, ra, d); } void PPULLVMRecompiler::STFSU(u32 frs, u32 ra, s32 d) { ThisCall3("STFSU", &PPUInterpreter::STFSU, &m_interpreter, frs, ra, d); } void PPULLVMRecompiler::STFD(u32 frs, u32 ra, s32 d) { ThisCall3("STFD", &PPUInterpreter::STFD, &m_interpreter, frs, ra, d); } void PPULLVMRecompiler::STFDU(u32 frs, u32 ra, s32 d) { ThisCall3("STFDU", &PPUInterpreter::STFDU, &m_interpreter, frs, ra, d); } void PPULLVMRecompiler::LD(u32 rd, u32 ra, s32 ds) { ThisCall3("LD", &PPUInterpreter::LD, &m_interpreter, rd, ra, ds); } void PPULLVMRecompiler::LDU(u32 rd, u32 ra, s32 ds) { ThisCall3("LDU", &PPUInterpreter::LDU, &m_interpreter, rd, ra, ds); } void PPULLVMRecompiler::LWA(u32 rd, u32 ra, s32 ds) { ThisCall3("LWA", &PPUInterpreter::LWA, &m_interpreter, rd, ra, ds); } void PPULLVMRecompiler::FDIVS(u32 frd, u32 fra, u32 frb, bool rc) { ThisCall4("FDIVS", &PPUInterpreter::FDIVS, &m_interpreter, frd, fra, frb, rc); } void PPULLVMRecompiler::FSUBS(u32 frd, u32 fra, u32 frb, bool rc) { ThisCall4("FSUBS", &PPUInterpreter::FSUBS, &m_interpreter, frd, fra, frb, rc); } void PPULLVMRecompiler::FADDS(u32 frd, u32 fra, u32 frb, bool rc) { ThisCall4("FADDS", &PPUInterpreter::FADDS, &m_interpreter, frd, fra, frb, rc); } void PPULLVMRecompiler::FSQRTS(u32 frd, u32 frb, bool rc) { ThisCall3("FSQRTS", &PPUInterpreter::FSQRTS, &m_interpreter, frd, frb, rc); } void PPULLVMRecompiler::FRES(u32 frd, u32 frb, bool rc) { ThisCall3("FRES", &PPUInterpreter::FRES, &m_interpreter, frd, frb, rc); } void PPULLVMRecompiler::FMULS(u32 frd, u32 fra, u32 frc, bool rc) { ThisCall4("FMULS", &PPUInterpreter::FMULS, &m_interpreter, frd, fra, frc, rc); } void PPULLVMRecompiler::FMADDS(u32 frd, u32 fra, u32 frc, u32 frb, bool rc) { ThisCall5("FMADDS", &PPUInterpreter::FMADDS, &m_interpreter, frd, fra, frc, frb, rc); } void PPULLVMRecompiler::FMSUBS(u32 frd, u32 fra, u32 frc, u32 frb, bool rc) { ThisCall5("FMSUBS", &PPUInterpreter::FMSUBS, &m_interpreter, frd, fra, frc, frb, rc); } void PPULLVMRecompiler::FNMSUBS(u32 frd, u32 fra, u32 frc, u32 frb, bool rc) { ThisCall5("FNMSUBS", &PPUInterpreter::FNMSUBS, &m_interpreter, frd, fra, frc, frb, rc); } void PPULLVMRecompiler::FNMADDS(u32 frd, u32 fra, u32 frc, u32 frb, bool rc) { ThisCall5("FNMADDS", &PPUInterpreter::FNMADDS, &m_interpreter, frd, fra, frc, frb, rc); } void PPULLVMRecompiler::STD(u32 rs, u32 ra, s32 d) { ThisCall3("STD", &PPUInterpreter::STD, &m_interpreter, rs, ra, d); } void PPULLVMRecompiler::STDU(u32 rs, u32 ra, s32 ds) { ThisCall3("STDU", &PPUInterpreter::STDU, &m_interpreter, rs, ra, ds); } void PPULLVMRecompiler::MTFSB1(u32 crbd, bool rc) { ThisCall2("MTFSB1", &PPUInterpreter::MTFSB1, &m_interpreter, crbd, rc); } void PPULLVMRecompiler::MCRFS(u32 crbd, u32 crbs) { ThisCall2("MCRFS", &PPUInterpreter::MCRFS, &m_interpreter, crbd, crbs); } void PPULLVMRecompiler::MTFSB0(u32 crbd, bool rc) { ThisCall2("MTFSB0", &PPUInterpreter::MTFSB0, &m_interpreter, crbd, rc); } void PPULLVMRecompiler::MTFSFI(u32 crfd, u32 i, bool rc) { ThisCall3("MTFSFI", &PPUInterpreter::MTFSFI, &m_interpreter, crfd, i, rc); } void PPULLVMRecompiler::MFFS(u32 frd, bool rc) { ThisCall2("MFFS", &PPUInterpreter::MFFS, &m_interpreter, frd, rc); } void PPULLVMRecompiler::MTFSF(u32 flm, u32 frb, bool rc) { ThisCall3("MTFSF", &PPUInterpreter::MTFSF, &m_interpreter, flm, frb, rc); } void PPULLVMRecompiler::FCMPU(u32 crfd, u32 fra, u32 frb) { ThisCall3("FCMPU", &PPUInterpreter::FCMPU, &m_interpreter, crfd, fra, frb); } void PPULLVMRecompiler::FRSP(u32 frd, u32 frb, bool rc) { ThisCall3("FRSP", &PPUInterpreter::FRSP, &m_interpreter, frd, frb, rc); } void PPULLVMRecompiler::FCTIW(u32 frd, u32 frb, bool rc) { ThisCall3("FCTIW", &PPUInterpreter::FCTIW, &m_interpreter, frd, frb, rc); } void PPULLVMRecompiler::FCTIWZ(u32 frd, u32 frb, bool rc) { ThisCall3("FCTIWZ", &PPUInterpreter::FCTIWZ, &m_interpreter, frd, frb, rc); } void PPULLVMRecompiler::FDIV(u32 frd, u32 fra, u32 frb, bool rc) { ThisCall4("FDIV", &PPUInterpreter::FDIV, &m_interpreter, frd, fra, frb, rc); } void PPULLVMRecompiler::FSUB(u32 frd, u32 fra, u32 frb, bool rc) { ThisCall4("FSUB", &PPUInterpreter::FSUB, &m_interpreter, frd, fra, frb, rc); } void PPULLVMRecompiler::FADD(u32 frd, u32 fra, u32 frb, bool rc) { ThisCall4("FADD", &PPUInterpreter::FADD, &m_interpreter, frd, fra, frb, rc); } void PPULLVMRecompiler::FSQRT(u32 frd, u32 frb, bool rc) { ThisCall3("FSQRT", &PPUInterpreter::FSQRT, &m_interpreter, frd, frb, rc); } void PPULLVMRecompiler::FSEL(u32 frd, u32 fra, u32 frc, u32 frb, bool rc) { ThisCall5("FSEL", &PPUInterpreter::FSEL, &m_interpreter, frd, fra, frc, frb, rc); } void PPULLVMRecompiler::FMUL(u32 frd, u32 fra, u32 frc, bool rc) { ThisCall4("FMUL", &PPUInterpreter::FMUL, &m_interpreter, frd, fra, frc, rc); } void PPULLVMRecompiler::FRSQRTE(u32 frd, u32 frb, bool rc) { ThisCall3("FRSQRTE", &PPUInterpreter::FRSQRTE, &m_interpreter, frd, frb, rc); } void PPULLVMRecompiler::FMSUB(u32 frd, u32 fra, u32 frc, u32 frb, bool rc) { ThisCall5("FMSUB", &PPUInterpreter::FMSUB, &m_interpreter, frd, fra, frc, frb, rc); } void PPULLVMRecompiler::FMADD(u32 frd, u32 fra, u32 frc, u32 frb, bool rc) { ThisCall5("FMADD", &PPUInterpreter::FMADD, &m_interpreter, frd, fra, frc, frb, rc); } void PPULLVMRecompiler::FNMSUB(u32 frd, u32 fra, u32 frc, u32 frb, bool rc) { ThisCall5("FNMSUB", &PPUInterpreter::FNMSUB, &m_interpreter, frd, fra, frc, frb, rc); } void PPULLVMRecompiler::FNMADD(u32 frd, u32 fra, u32 frc, u32 frb, bool rc) { ThisCall5("FNMADD", &PPUInterpreter::FNMADD, &m_interpreter, frd, fra, frc, frb, rc); } void PPULLVMRecompiler::FCMPO(u32 crfd, u32 fra, u32 frb) { ThisCall3("FCMPO", &PPUInterpreter::FCMPO, &m_interpreter, crfd, fra, frb); } void PPULLVMRecompiler::FNEG(u32 frd, u32 frb, bool rc) { ThisCall3("FNEG", &PPUInterpreter::FNEG, &m_interpreter, frd, frb, rc); } void PPULLVMRecompiler::FMR(u32 frd, u32 frb, bool rc) { ThisCall3("FMR", &PPUInterpreter::FMR, &m_interpreter, frd, frb, rc); } void PPULLVMRecompiler::FNABS(u32 frd, u32 frb, bool rc) { ThisCall3("FNABS", &PPUInterpreter::FNABS, &m_interpreter, frd, frb, rc); } void PPULLVMRecompiler::FABS(u32 frd, u32 frb, bool rc) { ThisCall3("FABS", &PPUInterpreter::FABS, &m_interpreter, frd, frb, rc); } void PPULLVMRecompiler::FCTID(u32 frd, u32 frb, bool rc) { ThisCall3("FCTID", &PPUInterpreter::FCTID, &m_interpreter, frd, frb, rc); } void PPULLVMRecompiler::FCTIDZ(u32 frd, u32 frb, bool rc) { ThisCall3("FCTIDZ", &PPUInterpreter::FCTIDZ, &m_interpreter, frd, frb, rc); } void PPULLVMRecompiler::FCFID(u32 frd, u32 frb, bool rc) { ThisCall3("FCFID", &PPUInterpreter::FCFID, &m_interpreter, frd, frb, rc); } void PPULLVMRecompiler::UNK(const u32 code, const u32 opcode, const u32 gcode) { //ThisCall3("UNK", &PPUInterpreter::UNK, &m_interpreter, code, opcode, gcode); } Value * PPULLVMRecompiler::GetBit(Value * val, u32 n) { Value * bit; if (val->getType()->isIntegerTy(32)) { bit = m_ir_builder.CreateCall2(Intrinsic::getDeclaration(m_module, Intrinsic::x86_bmi_pext_32), val, m_ir_builder.getInt32(1 << (31- n))); } else if (val->getType()->isIntegerTy(64)) { bit = m_ir_builder.CreateCall2(Intrinsic::getDeclaration(m_module, Intrinsic::x86_bmi_pext_64), val, m_ir_builder.getInt64(1 << (63 - n))); } else { if (val->getType()->getIntegerBitWidth() != (n + 1)) { bit = m_ir_builder.CreateLShr(val, val->getType()->getIntegerBitWidth() - n - 1); } bit = m_ir_builder.CreateAnd(val, 1); } return bit; } Value * PPULLVMRecompiler::ClrBit(Value * val, u32 n) { return m_ir_builder.CreateAnd(val, ~(1 << (val->getType()->getIntegerBitWidth() - n - 1))); } Value * PPULLVMRecompiler::SetBit(Value * val, u32 n, Value * bit, bool doClear) { if (doClear) { val = ClrBit(val, n); } if (bit->getType()->getIntegerBitWidth() < val->getType()->getIntegerBitWidth()) { bit = m_ir_builder.CreateZExt(bit, val->getType()); } else if (bit->getType()->getIntegerBitWidth() > val->getType()->getIntegerBitWidth()) { bit = m_ir_builder.CreateTrunc(bit, val->getType()); } if (val->getType()->getIntegerBitWidth() != (n + 1)) { bit = m_ir_builder.CreateShl(bit, bit->getType()->getIntegerBitWidth() - n - 1); } return m_ir_builder.CreateOr(val, bit); } Value * PPULLVMRecompiler::GetNibble(Value * val, u32 n) { Value * nibble; if (val->getType()->isIntegerTy(32)) { nibble = m_ir_builder.CreateCall2(Intrinsic::getDeclaration(m_module, Intrinsic::x86_bmi_pext_32), val, m_ir_builder.getInt32(0xF << ((7 - n) * 4))); } else if (val->getType()->isIntegerTy(64)) { nibble = m_ir_builder.CreateCall2(Intrinsic::getDeclaration(m_module, Intrinsic::x86_bmi_pext_64), val, m_ir_builder.getInt64(0xF << ((15 - n) * 4))); } else { if ((val->getType()->getIntegerBitWidth() >> 2) != (n + 1)) { nibble = m_ir_builder.CreateLShr(val, (((val->getType()->getIntegerBitWidth() >> 2) - 1) - n) * 4); } nibble = m_ir_builder.CreateAnd(val, 0xF); } return nibble; } Value * PPULLVMRecompiler::ClrNibble(Value * val, u32 n) { return m_ir_builder.CreateAnd(val, ~(0xF << ((((val->getType()->getIntegerBitWidth() >> 2) - 1) - n) * 4))); } Value * PPULLVMRecompiler::SetNibble(Value * val, u32 n, Value * nibble, bool doClear) { if (doClear) { val = ClrNibble(val, n); } if (nibble->getType()->getIntegerBitWidth() < val->getType()->getIntegerBitWidth()) { nibble = m_ir_builder.CreateZExt(nibble, val->getType()); } else if (nibble->getType()->getIntegerBitWidth() > val->getType()->getIntegerBitWidth()) { nibble = m_ir_builder.CreateTrunc(nibble, val->getType()); } if ((val->getType()->getIntegerBitWidth() >> 2) != (n + 1)) { nibble = m_ir_builder.CreateShl(nibble, (((val->getType()->getIntegerBitWidth() >> 2) - 1) - n) * 4); } return m_ir_builder.CreateOr(val, nibble); } Value * PPULLVMRecompiler::SetNibble(Value * val, u32 n, Value * b0, Value * b1, Value * b2, Value * b3, bool doClear) { if (doClear) { val = ClrNibble(val, n); } if (b0) { val = SetBit(val, n * 4, b0, false); } if (b1) { val = SetBit(val, (n * 4) + 1, b1, false); } if (b2) { val = SetBit(val, (n * 4) + 2, b2, false); } if (b3) { val = SetBit(val, (n * 4) + 3, b3, false); } return val; } Value * PPULLVMRecompiler::GetGpr(u32 r) { auto r_i64_ptr = m_ir_builder.CreateConstGEP2_32(m_gpr, 0, r); return m_ir_builder.CreateLoad(r_i64_ptr); } void PPULLVMRecompiler::SetGpr(u32 r, Value * val_x64) { auto r_i64_ptr = m_ir_builder.CreateConstGEP2_32(m_gpr, 0, r); auto val_i64 = m_ir_builder.CreateBitCast(val_x64, Type::getInt64Ty(m_llvm_context)); m_ir_builder.CreateStore(val_i64, r_i64_ptr); } Value * PPULLVMRecompiler::GetCr() { return m_ir_builder.CreateLoad(m_cr); } Value * PPULLVMRecompiler::GetCrField(u32 n) { return GetNibble(GetCr(), n); } void PPULLVMRecompiler::SetCr(Value * val_x32) { auto val_i32 = m_ir_builder.CreateBitCast(val_x32, Type::getInt32Ty(m_llvm_context)); m_ir_builder.CreateStore(val_i32, m_cr); } void PPULLVMRecompiler::SetCrField(u32 n, Value * field) { SetCr(SetNibble(GetCr(), n, field)); } void PPULLVMRecompiler::SetCrField(u32 n, Value * b0, Value * b1, Value * b2, Value * b3) { SetCr(SetNibble(GetCr(), n, b0, b1, b2, b3)); } void PPULLVMRecompiler::SetCrFieldSignedCmp(u32 n, llvm::Value * a, llvm::Value * b) { auto lt_i1 = m_ir_builder.CreateICmpSLT(a, b); auto gt_i1 = m_ir_builder.CreateICmpSGT(a, b); auto eq_i1 = m_ir_builder.CreateICmpEQ(a, b); auto cr_i32 = GetCr(); cr_i32 = SetNibble(cr_i32, n, lt_i1, gt_i1, eq_i1, GetXerSo()); SetCr(cr_i32); } void PPULLVMRecompiler::SetCrFieldUnsignedCmp(u32 n, llvm::Value * a, llvm::Value * b) { auto lt_i1 = m_ir_builder.CreateICmpULT(a, b); auto gt_i1 = m_ir_builder.CreateICmpUGT(a, b); auto eq_i1 = m_ir_builder.CreateICmpEQ(a, b); auto cr_i32 = GetCr(); cr_i32 = SetNibble(cr_i32, n, lt_i1, gt_i1, eq_i1, GetXerSo()); SetCr(cr_i32); } void PPULLVMRecompiler::SetCr6AfterVectorCompare(u32 vr) { auto vr_v16i8 = GetVrAsIntVec(vr, 8); auto vr_mask_i32 = m_ir_builder.CreateCall(Intrinsic::getDeclaration(m_module, Intrinsic::x86_sse2_pmovmskb_128), vr_v16i8); auto cmp0_i1 = m_ir_builder.CreateICmpEQ(vr_mask_i32, m_ir_builder.getInt32(0)); auto cmp1_i1 = m_ir_builder.CreateICmpEQ(vr_mask_i32, m_ir_builder.getInt32(0xFFFF)); auto cr_i32 = GetCr(); cr_i32 = SetNibble(cr_i32, 6, cmp1_i1, nullptr, cmp0_i1, nullptr); SetCr(cr_i32); } Value * PPULLVMRecompiler::GetXer() { return m_ir_builder.CreateLoad(m_xer); } Value * PPULLVMRecompiler::GetXerCa() { return GetBit(GetXer(), 34); } Value * PPULLVMRecompiler::GetXerSo() { return GetBit(GetXer(), 32); } void PPULLVMRecompiler::SetXer(Value * val_x64) { auto val_i64 = m_ir_builder.CreateBitCast(val_x64, Type::getInt64Ty(m_llvm_context)); m_ir_builder.CreateStore(val_i64, m_xer); } void PPULLVMRecompiler::SetXerCa(Value * ca) { auto xer_i64 = GetXer(); xer_i64 = SetBit(xer_i64, 34, ca); SetXer(xer_i64); } void PPULLVMRecompiler::SetXerSo(Value * so) { auto xer_i64 = GetXer(); xer_i64 = SetBit(xer_i64, 32, so); SetXer(xer_i64); } Value * PPULLVMRecompiler::GetVrAsIntVec(u32 vr, u32 vec_elt_num_bits) { auto vr_i128_ptr = m_ir_builder.CreateConstGEP2_32(m_vpr, 0, vr); auto vr_vec_ptr = m_ir_builder.CreateBitCast(vr_i128_ptr, VectorType::get(Type::getIntNTy(m_llvm_context, vec_elt_num_bits), 128 / vec_elt_num_bits)->getPointerTo()); return m_ir_builder.CreateLoad(vr_vec_ptr); } Value * PPULLVMRecompiler::GetVrAsFloatVec(u32 vr) { auto vr_i128_ptr = m_ir_builder.CreateConstGEP2_32(m_vpr, 0, vr); auto vr_v4f32_ptr = m_ir_builder.CreateBitCast(vr_i128_ptr, VectorType::get(Type::getFloatTy(m_llvm_context), 4)->getPointerTo()); return m_ir_builder.CreateLoad(vr_v4f32_ptr); } Value * PPULLVMRecompiler::GetVrAsDoubleVec(u32 vr) { auto vr_i128_ptr = m_ir_builder.CreateConstGEP2_32(m_vpr, 0, vr); auto vr_v2f64_ptr = m_ir_builder.CreateBitCast(vr_i128_ptr, VectorType::get(Type::getDoubleTy(m_llvm_context), 2)->getPointerTo()); return m_ir_builder.CreateLoad(vr_v2f64_ptr); } void PPULLVMRecompiler::SetVr(u32 vr, Value * val_x128) { auto vr_i128_ptr = m_ir_builder.CreateConstGEP2_32(m_vpr, 0, vr); auto val_i128 = m_ir_builder.CreateBitCast(val_x128, Type::getIntNTy(m_llvm_context, 128)); m_ir_builder.CreateStore(val_i128, vr_i128_ptr); } template void PPULLVMRecompiler::ThisCall0(const char * name, F function, C * this_p) { static FunctionType * fn_type = nullptr; if (fn_type == nullptr) { static std::vector fn_args; fn_args.push_back(Type::getInt64PtrTy(m_llvm_context)); fn_type = FunctionType::get(Type::getVoidTy(m_llvm_context), fn_args, false); } auto fn_ptr = m_module->getFunction(name); if (!fn_ptr) { fn_ptr = Function::Create(fn_type, GlobalValue::ExternalLinkage, name, m_module); fn_ptr->setCallingConv(CallingConv::C); m_execution_engine->addGlobalMapping(fn_ptr, (void *&)function); } auto this_i64 = m_ir_builder.getInt64((uint64_t)this_p); auto this_ptr = m_ir_builder.CreateIntToPtr(this_i64, Type::getInt64PtrTy(m_llvm_context)); m_ir_builder.CreateCall(fn_ptr, this_ptr); } template void PPULLVMRecompiler::ThisCall1(const char * name, F function, C * this_p, T1 arg1) { static FunctionType * fn_type = nullptr; if (fn_type == nullptr) { static std::vector fn_args; fn_args.push_back(Type::getInt64PtrTy(m_llvm_context)); fn_args.push_back(Type::getInt32Ty(m_llvm_context)); fn_type = FunctionType::get(Type::getVoidTy(m_llvm_context), fn_args, false); } auto fn_ptr = m_module->getFunction(name); if (!fn_ptr) { fn_ptr = Function::Create(fn_type, GlobalValue::ExternalLinkage, name, m_module); fn_ptr->setCallingConv(CallingConv::C); m_execution_engine->addGlobalMapping(fn_ptr, (void *&)function); } auto this_i64 = m_ir_builder.getInt64((uint64_t)this_p); auto this_ptr = m_ir_builder.CreateIntToPtr(this_i64, Type::getInt64PtrTy(m_llvm_context)); m_ir_builder.CreateCall2(fn_ptr, this_ptr, m_ir_builder.getInt32(arg1)); } template void PPULLVMRecompiler::ThisCall2(const char * name, F function, C * this_p, T1 arg1, T2 arg2) { static FunctionType * fn_type = nullptr; if (fn_type == nullptr) { static std::vector fn_args; fn_args.push_back(Type::getInt64PtrTy(m_llvm_context)); fn_args.push_back(Type::getInt32Ty(m_llvm_context)); fn_args.push_back(Type::getInt32Ty(m_llvm_context)); fn_type = FunctionType::get(Type::getVoidTy(m_llvm_context), fn_args, false); } auto fn_ptr = m_module->getFunction(name); if (!fn_ptr) { fn_ptr = Function::Create(fn_type, GlobalValue::ExternalLinkage, name, m_module); fn_ptr->setCallingConv(CallingConv::C); m_execution_engine->addGlobalMapping(fn_ptr, (void *&)function); } auto this_i64 = m_ir_builder.getInt64((uint64_t)this_p); auto this_ptr = m_ir_builder.CreateIntToPtr(this_i64, Type::getInt64PtrTy(m_llvm_context)); m_ir_builder.CreateCall3(fn_ptr, this_ptr, m_ir_builder.getInt32(arg1), m_ir_builder.getInt32(arg2)); } template void PPULLVMRecompiler::ThisCall3(const char * name, F function, C * this_p, T1 arg1, T2 arg2, T3 arg3) { static FunctionType * fn_type = nullptr; if (fn_type == nullptr) { static std::vector fn_args; fn_args.push_back(Type::getInt64PtrTy(m_llvm_context)); fn_args.push_back(Type::getInt32Ty(m_llvm_context)); fn_args.push_back(Type::getInt32Ty(m_llvm_context)); fn_args.push_back(Type::getInt32Ty(m_llvm_context)); fn_type = FunctionType::get(Type::getVoidTy(m_llvm_context), fn_args, false); } auto fn_ptr = m_module->getFunction(name); if (!fn_ptr) { fn_ptr = Function::Create(fn_type, GlobalValue::ExternalLinkage, name, m_module); fn_ptr->setCallingConv(CallingConv::C); m_execution_engine->addGlobalMapping(fn_ptr, (void *&)function); } auto this_i64 = m_ir_builder.getInt64((uint64_t)this_p); auto this_ptr = m_ir_builder.CreateIntToPtr(this_i64, Type::getInt64PtrTy(m_llvm_context)); m_ir_builder.CreateCall4(fn_ptr, this_ptr, m_ir_builder.getInt32(arg1), m_ir_builder.getInt32(arg2), m_ir_builder.getInt32(arg3)); } template void PPULLVMRecompiler::ThisCall4(const char * name, F function, C * this_p, T1 arg1, T2 arg2, T3 arg3, T4 arg4) { static FunctionType * fn_type = nullptr; if (fn_type == nullptr) { static std::vector fn_args; fn_args.push_back(Type::getInt64PtrTy(m_llvm_context)); fn_args.push_back(Type::getInt32Ty(m_llvm_context)); fn_args.push_back(Type::getInt32Ty(m_llvm_context)); fn_args.push_back(Type::getInt32Ty(m_llvm_context)); fn_args.push_back(Type::getInt32Ty(m_llvm_context)); fn_type = FunctionType::get(Type::getVoidTy(m_llvm_context), fn_args, false); } auto fn_ptr = m_module->getFunction(name); if (!fn_ptr) { fn_ptr = Function::Create(fn_type, GlobalValue::ExternalLinkage, name, m_module); fn_ptr->setCallingConv(CallingConv::C); m_execution_engine->addGlobalMapping(fn_ptr, (void *&)function); } auto this_i64 = m_ir_builder.getInt64((uint64_t)this_p); auto this_ptr = m_ir_builder.CreateIntToPtr(this_i64, Type::getInt64PtrTy(m_llvm_context)); m_ir_builder.CreateCall5(fn_ptr, this_ptr, m_ir_builder.getInt32(arg1), m_ir_builder.getInt32(arg2), m_ir_builder.getInt32(arg3), m_ir_builder.getInt32(arg4)); } template void PPULLVMRecompiler::ThisCall5(const char * name, F function, C * this_p, T1 arg1, T2 arg2, T3 arg3, T4 arg4, T5 arg5) { static FunctionType * fn_type = nullptr; if (fn_type == nullptr) { static std::vector fn_args; fn_args.push_back(Type::getInt64PtrTy(m_llvm_context)); fn_args.push_back(Type::getInt32Ty(m_llvm_context)); fn_args.push_back(Type::getInt32Ty(m_llvm_context)); fn_args.push_back(Type::getInt32Ty(m_llvm_context)); fn_args.push_back(Type::getInt32Ty(m_llvm_context)); fn_args.push_back(Type::getInt32Ty(m_llvm_context)); fn_type = FunctionType::get(Type::getVoidTy(m_llvm_context), fn_args, false); } auto fn_ptr = m_module->getFunction(name); if (!fn_ptr) { fn_ptr = Function::Create(fn_type, GlobalValue::ExternalLinkage, name, m_module); fn_ptr->setCallingConv(CallingConv::C); m_execution_engine->addGlobalMapping(fn_ptr, (void *&)function); } auto this_i64 = m_ir_builder.getInt64((uint64_t)this_p); auto this_ptr = m_ir_builder.CreateIntToPtr(this_i64, Type::getInt64PtrTy(m_llvm_context)); std::vector args; args.push_back(this_ptr); args.push_back(m_ir_builder.getInt32(arg1)); args.push_back(m_ir_builder.getInt32(arg2)); args.push_back(m_ir_builder.getInt32(arg3)); args.push_back(m_ir_builder.getInt32(arg4)); args.push_back(m_ir_builder.getInt32(arg5)); m_ir_builder.CreateCall(fn_ptr, args); } template void PPULLVMRecompiler::ThisCall6(const char * name, F function, C * this_p, T1 arg1, T2 arg2, T3 arg3, T4 arg4, T5 arg5, T6 arg6) { static FunctionType * fn_type = nullptr; if (fn_type == nullptr) { static std::vector fn_args; fn_args.push_back(Type::getInt64PtrTy(m_llvm_context)); fn_args.push_back(Type::getInt32Ty(m_llvm_context)); fn_args.push_back(Type::getInt32Ty(m_llvm_context)); fn_args.push_back(Type::getInt32Ty(m_llvm_context)); fn_args.push_back(Type::getInt32Ty(m_llvm_context)); fn_args.push_back(Type::getInt32Ty(m_llvm_context)); fn_args.push_back(Type::getInt32Ty(m_llvm_context)); fn_type = FunctionType::get(Type::getVoidTy(m_llvm_context), fn_args, false); } auto fn_ptr = m_module->getFunction(name); if (!fn_ptr) { fn_ptr = Function::Create(fn_type, GlobalValue::ExternalLinkage, name, m_module); fn_ptr->setCallingConv(CallingConv::C); m_execution_engine->addGlobalMapping(fn_ptr, (void *&)function); } auto this_i64 = m_ir_builder.getInt64((uint64_t)this_p); auto this_ptr = m_ir_builder.CreateIntToPtr(this_i64, Type::getInt64PtrTy(m_llvm_context)); std::vector args; args.push_back(this_ptr); args.push_back(m_ir_builder.getInt32(arg1)); args.push_back(m_ir_builder.getInt32(arg2)); args.push_back(m_ir_builder.getInt32(arg3)); args.push_back(m_ir_builder.getInt32(arg4)); args.push_back(m_ir_builder.getInt32(arg5)); args.push_back(m_ir_builder.getInt32(arg6)); m_ir_builder.CreateCall(fn_ptr, args); }