#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/CodeGen/MachineCodeInfo.h" #include "llvm/ExecutionEngine/GenericValue.h" #include "llvm/IR/Intrinsics.h" #include "llvm/Support/FileSystem.h" #include "llvm/Analysis/Passes.h" #include "llvm/Analysis/TargetTransformInfo.h" #include "llvm/Analysis/MemoryDependenceAnalysis.h" #include "llvm/Analysis/LoopInfo.h" #include "llvm/Analysis/ScalarEvolution.h" #include "llvm/IR/Dominators.h" #include "llvm/Transforms/Scalar.h" #include "llvm/Transforms/Vectorize.h" #include "llvm/MC/MCDisassembler.h" #include "llvm/IR/Verifier.h" using namespace llvm; using namespace ppu_recompiler_llvm; u64 Compiler::s_rotate_mask[64][64]; bool Compiler::s_rotate_mask_inited = false; Compiler::Compiler(RecompilationEngine & recompilation_engine, const Executable execute_unknown_function, const Executable execute_unknown_block) : m_recompilation_engine(recompilation_engine) { InitializeNativeTarget(); InitializeNativeTargetAsmPrinter(); InitializeNativeTargetDisassembler(); m_llvm_context = new LLVMContext(); m_ir_builder = new IRBuilder<>(*m_llvm_context); m_module = new llvm::Module("Module", *m_llvm_context); m_fpm = new FunctionPassManager(m_module); EngineBuilder engine_builder(m_module); engine_builder.setMCPU(sys::getHostCPUName()); engine_builder.setEngineKind(EngineKind::JIT); engine_builder.setOptLevel(CodeGenOpt::Default); m_execution_engine = engine_builder.create(); m_fpm->add(new DataLayoutPass(m_module)); m_fpm->add(createNoAAPass()); m_fpm->add(createBasicAliasAnalysisPass()); m_fpm->add(createNoTargetTransformInfoPass()); m_fpm->add(createEarlyCSEPass()); m_fpm->add(createTailCallEliminationPass()); m_fpm->add(createReassociatePass()); m_fpm->add(createInstructionCombiningPass()); m_fpm->add(new DominatorTreeWrapperPass()); m_fpm->add(new MemoryDependenceAnalysis()); m_fpm->add(createGVNPass()); m_fpm->add(createInstructionCombiningPass()); m_fpm->add(new MemoryDependenceAnalysis()); m_fpm->add(createDeadStoreEliminationPass()); m_fpm->add(new LoopInfo()); m_fpm->add(new ScalarEvolution()); m_fpm->add(createSLPVectorizerPass()); m_fpm->add(createInstructionCombiningPass()); m_fpm->add(createCFGSimplificationPass()); m_fpm->doInitialization(); std::vector arg_types; arg_types.push_back(m_ir_builder->getInt8PtrTy()); arg_types.push_back(m_ir_builder->getInt8PtrTy()); arg_types.push_back(m_ir_builder->getInt64Ty()); m_compiled_function_type = FunctionType::get(m_ir_builder->getInt32Ty(), arg_types, false); m_execute_unknown_function = (Function *)m_module->getOrInsertFunction("execute_unknown_function", m_compiled_function_type); m_execute_unknown_function->setCallingConv(CallingConv::X86_64_Win64); m_execution_engine->addGlobalMapping(m_execute_unknown_function, (void *)execute_unknown_function); m_execute_unknown_block = (Function *)m_module->getOrInsertFunction("execute_unknown_block", m_compiled_function_type); m_execute_unknown_block->setCallingConv(CallingConv::X86_64_Win64); m_execution_engine->addGlobalMapping(m_execute_unknown_block, (void *)execute_unknown_block); if (!s_rotate_mask_inited) { InitRotateMask(); s_rotate_mask_inited = true; } } Compiler::~Compiler() { delete m_execution_engine; delete m_fpm; delete m_ir_builder; delete m_llvm_context; } Executable Compiler::Compile(const std::string & name, const ControlFlowGraph & cfg, bool inline_all, bool generate_linkable_exits) { auto compilation_start = std::chrono::high_resolution_clock::now(); m_state.cfg = &cfg; m_state.inline_all = inline_all; m_state.generate_linkable_exits = generate_linkable_exits; // Create the function m_state.function = (Function *)m_module->getOrInsertFunction(name, m_compiled_function_type); m_state.function->setCallingConv(CallingConv::X86_64_Win64); auto arg_i = m_state.function->arg_begin(); arg_i->setName("ppu_state"); m_state.args[CompileTaskState::Args::State] = arg_i; (++arg_i)->setName("interpreter"); m_state.args[CompileTaskState::Args::Interpreter] = arg_i; (++arg_i)->setName("context"); m_state.args[CompileTaskState::Args::Context] = arg_i; // Create the entry block and add code to branch to the first instruction m_ir_builder->SetInsertPoint(GetBasicBlockFromAddress(0)); m_ir_builder->CreateBr(GetBasicBlockFromAddress(cfg.start_address)); // Convert each instruction in the CFG to LLVM IR std::vector exit_instr_list; for (auto instr_i = cfg.instruction_addresses.begin(); instr_i != cfg.instruction_addresses.end(); instr_i++) { m_state.hit_branch_instruction = false; m_state.current_instruction_address = *instr_i; auto instr_bb = GetBasicBlockFromAddress(m_state.current_instruction_address); m_ir_builder->SetInsertPoint(instr_bb); if (!inline_all && *instr_i != cfg.start_address) { // Use an already compiled implementation of this block if available auto ordinal = m_recompilation_engine.GetOrdinal(*instr_i); if (ordinal != 0xFFFFFFFF) { auto exit_instr_i32 = m_ir_builder->CreatePHI(m_ir_builder->getInt32Ty(), 0); exit_instr_list.push_back(exit_instr_i32); auto context_i64 = m_ir_builder->CreateZExt(exit_instr_i32, m_ir_builder->getInt64Ty()); context_i64 = m_ir_builder->CreateOr(context_i64, (u64)cfg.function_address << 32); auto ret_i32 = IndirectCall(*instr_i, context_i64, false); auto switch_instr = m_ir_builder->CreateSwitch(ret_i32, GetBasicBlockFromAddress(0xFFFFFFFF)); auto branch_i = cfg.branches.find(*instr_i); if (branch_i != cfg.branches.end()) { for (auto next_instr_i = branch_i->second.begin(); next_instr_i != branch_i->second.end(); next_instr_i++) { switch_instr->addCase(m_ir_builder->getInt32(*next_instr_i), GetBasicBlockFromAddress(*next_instr_i)); } } } } if (instr_bb->empty()) { u32 instr = re32(vm::get_ref(m_state.current_instruction_address)); Decode(instr); if (!m_state.hit_branch_instruction) { m_ir_builder->CreateBr(GetBasicBlockFromAddress(m_state.current_instruction_address + 4)); } } } // Generate exit logic for all empty blocks auto default_exit_block_name = GetBasicBlockNameFromAddress(0xFFFFFFFF); for (auto block_i = m_state.function->begin(); block_i != m_state.function->end(); block_i++) { if (!block_i->getInstList().empty() || block_i->getName() == default_exit_block_name) { continue; } // Found an empty block m_ir_builder->SetInsertPoint(block_i); auto exit_instr_i32 = m_ir_builder->CreatePHI(m_ir_builder->getInt32Ty(), 0); exit_instr_list.push_back(exit_instr_i32); auto instr_address = GetAddressFromBasicBlockName(block_i->getName()); SetPc(m_ir_builder->getInt32(instr_address)); if (generate_linkable_exits) { auto context_i64 = m_ir_builder->CreateZExt(exit_instr_i32, m_ir_builder->getInt64Ty()); context_i64 = m_ir_builder->CreateOr(context_i64, (u64)cfg.function_address << 32); auto ret_i32 = IndirectCall(instr_address, context_i64, false); auto cmp_i1 = m_ir_builder->CreateICmpNE(ret_i32, m_ir_builder->getInt32(0)); auto then_bb = GetBasicBlockFromAddress(instr_address, "then"); auto merge_bb = GetBasicBlockFromAddress(instr_address, "merge"); m_ir_builder->CreateCondBr(cmp_i1, then_bb, merge_bb); m_ir_builder->SetInsertPoint(then_bb); context_i64 = m_ir_builder->CreateZExt(ret_i32, m_ir_builder->getInt64Ty()); context_i64 = m_ir_builder->CreateOr(context_i64, (u64)cfg.function_address << 32); m_ir_builder->CreateCall3(m_execute_unknown_block, m_state.args[CompileTaskState::Args::State], m_state.args[CompileTaskState::Args::Interpreter], context_i64); m_ir_builder->CreateBr(merge_bb); m_ir_builder->SetInsertPoint(merge_bb); m_ir_builder->CreateRet(m_ir_builder->getInt32(0)); } else { m_ir_builder->CreateRet(exit_instr_i32); } } // If the function has a default exit block then generate code for it auto default_exit_bb = GetBasicBlockFromAddress(0xFFFFFFFF, "", false); if (default_exit_bb) { m_ir_builder->SetInsertPoint(default_exit_bb); auto exit_instr_i32 = m_ir_builder->CreatePHI(m_ir_builder->getInt32Ty(), 0); exit_instr_list.push_back(exit_instr_i32); if (generate_linkable_exits) { auto cmp_i1 = m_ir_builder->CreateICmpNE(exit_instr_i32, m_ir_builder->getInt32(0)); auto then_bb = GetBasicBlockFromAddress(0xFFFFFFFF, "then"); auto merge_bb = GetBasicBlockFromAddress(0xFFFFFFFF, "merge"); m_ir_builder->CreateCondBr(cmp_i1, then_bb, merge_bb); m_ir_builder->SetInsertPoint(then_bb); auto context_i64 = m_ir_builder->CreateZExt(exit_instr_i32, m_ir_builder->getInt64Ty()); context_i64 = m_ir_builder->CreateOr(context_i64, (u64)cfg.function_address << 32); m_ir_builder->CreateCall3(m_execute_unknown_block, m_state.args[CompileTaskState::Args::State], m_state.args[CompileTaskState::Args::Interpreter], context_i64); m_ir_builder->CreateBr(merge_bb); m_ir_builder->SetInsertPoint(merge_bb); m_ir_builder->CreateRet(m_ir_builder->getInt32(0)); } else { m_ir_builder->CreateRet(exit_instr_i32); } } // Add incoming values for all exit instr PHI nodes for (auto exit_instr_i = exit_instr_list.begin(); exit_instr_i != exit_instr_list.end(); exit_instr_i++) { auto block = (*exit_instr_i)->getParent(); for (auto pred_i = pred_begin(block); pred_i != pred_end(block); pred_i++) { auto pred_address = GetAddressFromBasicBlockName((*pred_i)->getName()); (*exit_instr_i)->addIncoming(m_ir_builder->getInt32(pred_address), *pred_i); } } #ifdef _DEBUG m_recompilation_engine.Log() << *m_state.function; std::string verify; raw_string_ostream verify_ostream(verify); if (verifyFunction(*m_state.function, &verify_ostream)) { m_recompilation_engine.Log() << "Verification failed: " << verify << "\n"; } #endif auto ir_build_end = std::chrono::high_resolution_clock::now(); m_stats.ir_build_time += std::chrono::duration_cast(ir_build_end - compilation_start); // Optimize this function m_fpm->run(*m_state.function); auto optimize_end = std::chrono::high_resolution_clock::now(); m_stats.optimization_time += std::chrono::duration_cast(optimize_end - ir_build_end); // Translate to machine code MachineCodeInfo mci; m_execution_engine->runJITOnFunction(m_state.function, &mci); auto translate_end = std::chrono::high_resolution_clock::now(); m_stats.translation_time += std::chrono::duration_cast(translate_end - optimize_end); #ifdef _DEBUG m_recompilation_engine.Log() << "\nDisassembly:\n"; auto disassembler = LLVMCreateDisasm(sys::getProcessTriple().c_str(), nullptr, 0, nullptr, nullptr); for (size_t pc = 0; pc < mci.size();) { char str[1024]; auto size = LLVMDisasmInstruction(disassembler, ((u8 *)mci.address()) + pc, mci.size() - pc, (uint64_t)(((u8 *)mci.address()) + pc), str, sizeof(str)); m_recompilation_engine.Log() << fmt::Format("0x%08X: ", (u64)(((u8 *)mci.address()) + pc)) << str << '\n'; pc += size; } LLVMDisasmDispose(disassembler); #endif auto compilation_end = std::chrono::high_resolution_clock::now(); m_stats.total_time += std::chrono::duration_cast(compilation_end - compilation_start); return (Executable)mci.address(); } void Compiler::FreeExecutable(const std::string & name) { auto function = m_module->getFunction(name); if (function) { m_execution_engine->freeMachineCodeForFunction(function); function->eraseFromParent(); } } Compiler::Stats Compiler::GetStats() { return m_stats; } void Compiler::Decode(const u32 code) { (*PPU_instr::main_list)(this, code); } void Compiler::NULL_OP() { InterpreterCall("NULL_OP", &PPUInterpreter::NULL_OP); } void Compiler::NOP() { InterpreterCall("NOP", &PPUInterpreter::NOP); } void Compiler::TDI(u32 to, u32 ra, s32 simm16) { InterpreterCall("TDI", &PPUInterpreter::TDI, to, ra, simm16); } void Compiler::TWI(u32 to, u32 ra, s32 simm16) { InterpreterCall("TWI", &PPUInterpreter::TWI, to, ra, simm16); } void Compiler::MFVSCR(u32 vd) { auto vscr_i32 = GetVscr(); auto vscr_i128 = m_ir_builder->CreateZExt(vscr_i32, m_ir_builder->getIntNTy(128)); SetVr(vd, vscr_i128); } void Compiler::MTVSCR(u32 vb) { auto vb_v4i32 = GetVrAsIntVec(vb, 32); auto vscr_i32 = m_ir_builder->CreateExtractElement(vb_v4i32, m_ir_builder->getInt32(0)); vscr_i32 = m_ir_builder->CreateAnd(vscr_i32, 0x00010001); SetVscr(vscr_i32); } void Compiler::VADDCUW(u32 vd, u32 va, u32 vb) { auto va_v4i32 = GetVrAsIntVec(va, 32); auto vb_v4i32 = GetVrAsIntVec(vb, 32); va_v4i32 = m_ir_builder->CreateNot(va_v4i32); auto cmpv4i1 = m_ir_builder->CreateICmpULT(va_v4i32, vb_v4i32); auto cmpv4i32 = m_ir_builder->CreateZExt(cmpv4i1, VectorType::get(m_ir_builder->getInt32Ty(), 4)); SetVr(vd, cmpv4i32); } void Compiler::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 Compiler::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 Compiler::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 Compiler::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 signed/unsigned 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. auto tmp1_v4i32 = m_ir_builder->CreateLShr(va_v4i32, 31); tmp1_v4i32 = m_ir_builder->CreateAdd(tmp1_v4i32, m_ir_builder->CreateVectorSplat(4, m_ir_builder->getInt32(0x7FFFFFFF))); auto tmp1_v16i8 = m_ir_builder->CreateBitCast(tmp1_v4i32, VectorType::get(m_ir_builder->getInt8Ty(), 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 tmp2_v4i32 = m_ir_builder->CreateXor(va_v4i32, vb_v4i32); tmp2_v4i32 = m_ir_builder->CreateNot(tmp2_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(m_ir_builder->getInt8Ty(), 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 tmp3_v4i32 = m_ir_builder->CreateXor(va_v4i32, sum_v4i32); tmp3_v4i32 = m_ir_builder->CreateAnd(tmp2_v4i32, tmp3_v4i32); tmp3_v4i32 = m_ir_builder->CreateAShr(tmp3_v4i32, 31); auto tmp3_v16i8 = m_ir_builder->CreateBitCast(tmp3_v4i32, VectorType::get(m_ir_builder->getInt8Ty(), 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, tmp1_v16i8, tmp3_v16i8); SetVr(vd, res_v16i8); // TODO: Set SAT } void Compiler::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 Compiler::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 Compiler::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 Compiler::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 Compiler::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 Compiler::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(m_ir_builder->getInt32Ty(), 4)); auto res_v4i32 = m_ir_builder->CreateOr(sum_v4i32, cmp_v4i32); SetVr(vd, res_v4i32); // TODO: Set SAT } void Compiler::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 Compiler::VANDC(u32 vd, u32 va, u32 vb) { auto va_v4i32 = GetVrAsIntVec(va, 32); auto vb_v4i32 = GetVrAsIntVec(vb, 32); vb_v4i32 = m_ir_builder->CreateNot(vb_v4i32); auto res_v4i32 = m_ir_builder->CreateAnd(va_v4i32, vb_v4i32); SetVr(vd, res_v4i32); } void Compiler::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(m_ir_builder->getInt16Ty(), 16)); auto vb_v16i16 = m_ir_builder->CreateSExt(vb_v16i8, VectorType::get(m_ir_builder->getInt16Ty(), 16)); auto sum_v16i16 = m_ir_builder->CreateAdd(va_v16i16, vb_v16i16); sum_v16i16 = m_ir_builder->CreateAdd(sum_v16i16, m_ir_builder->CreateVectorSplat(16, m_ir_builder->getInt16(1))); auto avg_v16i16 = m_ir_builder->CreateAShr(sum_v16i16, 1); auto avg_v16i8 = m_ir_builder->CreateTrunc(avg_v16i16, VectorType::get(m_ir_builder->getInt8Ty(), 16)); SetVr(vd, avg_v16i8); } void Compiler::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(m_ir_builder->getInt32Ty(), 8)); auto vb_v8i32 = m_ir_builder->CreateSExt(vb_v8i16, VectorType::get(m_ir_builder->getInt32Ty(), 8)); auto sum_v8i32 = m_ir_builder->CreateAdd(va_v8i32, vb_v8i32); sum_v8i32 = m_ir_builder->CreateAdd(sum_v8i32, m_ir_builder->CreateVectorSplat(8, m_ir_builder->getInt32(1))); auto avg_v8i32 = m_ir_builder->CreateAShr(sum_v8i32, 1); auto avg_v8i16 = m_ir_builder->CreateTrunc(avg_v8i32, VectorType::get(m_ir_builder->getInt16Ty(), 8)); SetVr(vd, avg_v8i16); } void Compiler::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(m_ir_builder->getInt64Ty(), 4)); auto vb_v4i64 = m_ir_builder->CreateSExt(vb_v4i32, VectorType::get(m_ir_builder->getInt64Ty(), 4)); auto sum_v4i64 = m_ir_builder->CreateAdd(va_v4i64, vb_v4i64); sum_v4i64 = m_ir_builder->CreateAdd(sum_v4i64, m_ir_builder->CreateVectorSplat(4, m_ir_builder->getInt64(1))); auto avg_v4i64 = m_ir_builder->CreateAShr(sum_v4i64, 1); auto avg_v4i32 = m_ir_builder->CreateTrunc(avg_v4i64, VectorType::get(m_ir_builder->getInt32Ty(), 4)); SetVr(vd, avg_v4i32); } void Compiler::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 Compiler::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 Compiler::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(m_ir_builder->getInt64Ty(), 4)); auto vb_v4i64 = m_ir_builder->CreateZExt(vb_v4i32, VectorType::get(m_ir_builder->getInt64Ty(), 4)); auto sum_v4i64 = m_ir_builder->CreateAdd(va_v4i64, vb_v4i64); sum_v4i64 = m_ir_builder->CreateAdd(sum_v4i64, m_ir_builder->CreateVectorSplat(4, m_ir_builder->getInt64(1))); auto avg_v4i64 = m_ir_builder->CreateLShr(sum_v4i64, 1); auto avg_v4i32 = m_ir_builder->CreateTrunc(avg_v4i64, VectorType::get(m_ir_builder->getInt32Ty(), 4)); SetVr(vd, avg_v4i32); } void Compiler::VCFSX(u32 vd, u32 uimm5, u32 vb) { auto vb_v4i32 = GetVrAsIntVec(vb, 32); auto res_v4f32 = m_ir_builder->CreateSIToFP(vb_v4i32, VectorType::get(m_ir_builder->getFloatTy(), 4)); if (uimm5) { float scale = (float)((u64)1 << uimm5); res_v4f32 = m_ir_builder->CreateFDiv(res_v4f32, m_ir_builder->CreateVectorSplat(4, ConstantFP::get(m_ir_builder->getFloatTy(), scale))); } SetVr(vd, res_v4f32); } void Compiler::VCFUX(u32 vd, u32 uimm5, u32 vb) { auto vb_v4i32 = GetVrAsIntVec(vb, 32); auto res_v4f32 = m_ir_builder->CreateUIToFP(vb_v4i32, VectorType::get(m_ir_builder->getFloatTy(), 4)); if (uimm5) { float scale = (float)((u64)1 << uimm5); res_v4f32 = m_ir_builder->CreateFDiv(res_v4f32, m_ir_builder->CreateVectorSplat(4, ConstantFP::get(m_ir_builder->getFloatTy(), scale))); } SetVr(vd, res_v4f32); } void Compiler::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(m_ir_builder->getInt32Ty(), 4)); auto cmp_lt_v4i32 = m_ir_builder->CreateZExt(cmp_lt_v4i1, VectorType::get(m_ir_builder->getInt32Ty(), 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 Compiler::VCMPBFP_(u32 vd, u32 va, u32 vb) { VCMPBFP(vd, va, vb); auto vd_v16i8 = GetVrAsIntVec(vd, 8); u32 mask_v16i32[16] = {3, 7, 11, 15, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0}; vd_v16i8 = m_ir_builder->CreateShuffleVector(vd_v16i8, UndefValue::get(VectorType::get(m_ir_builder->getInt8Ty(), 16)), ConstantDataVector::get(m_ir_builder->getContext(), mask_v16i32)); auto vd_v4i32 = m_ir_builder->CreateBitCast(vd_v16i8, VectorType::get(m_ir_builder->getInt32Ty(), 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 Compiler::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(m_ir_builder->getInt32Ty(), 4)); SetVr(vd, cmp_v4i32); } void Compiler::VCMPEQFP_(u32 vd, u32 va, u32 vb) { VCMPEQFP(vd, va, vb); SetCr6AfterVectorCompare(vd); } void Compiler::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(m_ir_builder->getInt8Ty(), 16)); SetVr(vd, cmp_v16i8); } void Compiler::VCMPEQUB_(u32 vd, u32 va, u32 vb) { VCMPEQUB(vd, va, vb); SetCr6AfterVectorCompare(vd); } void Compiler::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(m_ir_builder->getInt16Ty(), 8)); SetVr(vd, cmp_v8i16); } void Compiler::VCMPEQUH_(u32 vd, u32 va, u32 vb) { VCMPEQUH(vd, va, vb); SetCr6AfterVectorCompare(vd); } void Compiler::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(m_ir_builder->getInt32Ty(), 4)); SetVr(vd, cmp_v4i32); } void Compiler::VCMPEQUW_(u32 vd, u32 va, u32 vb) { VCMPEQUW(vd, va, vb); SetCr6AfterVectorCompare(vd); } void Compiler::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(m_ir_builder->getInt32Ty(), 4)); SetVr(vd, cmp_v4i32); } void Compiler::VCMPGEFP_(u32 vd, u32 va, u32 vb) { VCMPGEFP(vd, va, vb); SetCr6AfterVectorCompare(vd); } void Compiler::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(m_ir_builder->getInt32Ty(), 4)); SetVr(vd, cmp_v4i32); } void Compiler::VCMPGTFP_(u32 vd, u32 va, u32 vb) { VCMPGTFP(vd, va, vb); SetCr6AfterVectorCompare(vd); } void Compiler::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(m_ir_builder->getInt8Ty(), 16)); SetVr(vd, cmp_v16i8); } void Compiler::VCMPGTSB_(u32 vd, u32 va, u32 vb) { VCMPGTSB(vd, va, vb); SetCr6AfterVectorCompare(vd); } void Compiler::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(m_ir_builder->getInt16Ty(), 8)); SetVr(vd, cmp_v8i16); } void Compiler::VCMPGTSH_(u32 vd, u32 va, u32 vb) { VCMPGTSH(vd, va, vb); SetCr6AfterVectorCompare(vd); } void Compiler::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(m_ir_builder->getInt32Ty(), 4)); SetVr(vd, cmp_v4i32); } void Compiler::VCMPGTSW_(u32 vd, u32 va, u32 vb) { VCMPGTSW(vd, va, vb); SetCr6AfterVectorCompare(vd); } void Compiler::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(m_ir_builder->getInt8Ty(), 16)); SetVr(vd, cmp_v16i8); } void Compiler::VCMPGTUB_(u32 vd, u32 va, u32 vb) { VCMPGTUB(vd, va, vb); SetCr6AfterVectorCompare(vd); } void Compiler::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(m_ir_builder->getInt16Ty(), 8)); SetVr(vd, cmp_v8i16); } void Compiler::VCMPGTUH_(u32 vd, u32 va, u32 vb) { VCMPGTUH(vd, va, vb); SetCr6AfterVectorCompare(vd); } void Compiler::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(m_ir_builder->getInt32Ty(), 4)); SetVr(vd, cmp_v4i32); } void Compiler::VCMPGTUW_(u32 vd, u32 va, u32 vb) { VCMPGTUW(vd, va, vb); SetCr6AfterVectorCompare(vd); } void Compiler::VCTSXS(u32 vd, u32 uimm5, u32 vb) { InterpreterCall("VCTSXS", &PPUInterpreter::VCTSXS, vd, uimm5, vb); } void Compiler::VCTUXS(u32 vd, u32 uimm5, u32 vb) { InterpreterCall("VCTUXS", &PPUInterpreter::VCTUXS, vd, uimm5, vb); } void Compiler::VEXPTEFP(u32 vd, u32 vb) { InterpreterCall("VEXPTEFP", &PPUInterpreter::VEXPTEFP, vd, vb); } void Compiler::VLOGEFP(u32 vd, u32 vb) { InterpreterCall("VLOGEFP", &PPUInterpreter::VLOGEFP, vd, vb); } void Compiler::VMADDFP(u32 vd, u32 va, u32 vc, u32 vb) { auto va_v4f32 = GetVrAsFloatVec(va); auto vb_v4f32 = GetVrAsFloatVec(vb); auto vc_v4f32 = GetVrAsFloatVec(vc); auto res_v4f32 = m_ir_builder->CreateCall3(Intrinsic::getDeclaration(m_module, Intrinsic::fmuladd, VectorType::get(m_ir_builder->getFloatTy(), 4)), va_v4f32, vc_v4f32, vb_v4f32); SetVr(vd, res_v4f32); } void Compiler::VMAXFP(u32 vd, u32 va, u32 vb) { auto va_v4f32 = GetVrAsFloatVec(va); auto vb_v4f32 = GetVrAsFloatVec(vb); auto res_v4f32 = m_ir_builder->CreateCall2(Intrinsic::getDeclaration(m_module, Intrinsic::x86_sse_max_ps), va_v4f32, vb_v4f32); SetVr(vd, res_v4f32); } void Compiler::VMAXSB(u32 vd, u32 va, u32 vb) { auto va_v16i8 = GetVrAsIntVec(va, 8); auto vb_v16i8 = GetVrAsIntVec(vb, 8); auto res_v16i8 = m_ir_builder->CreateCall2(Intrinsic::getDeclaration(m_module, Intrinsic::x86_sse41_pmaxsb), va_v16i8, vb_v16i8); SetVr(vd, res_v16i8); } void Compiler::VMAXSH(u32 vd, u32 va, u32 vb) { auto va_v8i16 = GetVrAsIntVec(va, 16); auto vb_v8i16 = GetVrAsIntVec(vb, 16); auto res_v8i16 = m_ir_builder->CreateCall2(Intrinsic::getDeclaration(m_module, Intrinsic::x86_sse2_pmaxs_w), va_v8i16, vb_v8i16); SetVr(vd, res_v8i16); } void Compiler::VMAXSW(u32 vd, u32 va, u32 vb) { auto va_v4i32 = GetVrAsIntVec(va, 32); auto vb_v4i32 = GetVrAsIntVec(vb, 32); auto res_v4i32 = m_ir_builder->CreateCall2(Intrinsic::getDeclaration(m_module, Intrinsic::x86_sse41_pmaxsd), va_v4i32, vb_v4i32); SetVr(vd, res_v4i32); } void Compiler::VMAXUB(u32 vd, u32 va, u32 vb) { auto va_v16i8 = GetVrAsIntVec(va, 8); auto vb_v16i8 = GetVrAsIntVec(vb, 8); auto res_v16i8 = m_ir_builder->CreateCall2(Intrinsic::getDeclaration(m_module, Intrinsic::x86_sse2_pmaxu_b), va_v16i8, vb_v16i8); SetVr(vd, res_v16i8); } void Compiler::VMAXUH(u32 vd, u32 va, u32 vb) { auto va_v8i16 = GetVrAsIntVec(va, 16); auto vb_v8i16 = GetVrAsIntVec(vb, 16); auto res_v8i16 = m_ir_builder->CreateCall2(Intrinsic::getDeclaration(m_module, Intrinsic::x86_sse41_pmaxuw), va_v8i16, vb_v8i16); SetVr(vd, res_v8i16); } void Compiler::VMAXUW(u32 vd, u32 va, u32 vb) { auto va_v4i32 = GetVrAsIntVec(va, 32); auto vb_v4i32 = GetVrAsIntVec(vb, 32); auto res_v4i32 = m_ir_builder->CreateCall2(Intrinsic::getDeclaration(m_module, Intrinsic::x86_sse41_pmaxud), va_v4i32, vb_v4i32); SetVr(vd, res_v4i32); } void Compiler::VMHADDSHS(u32 vd, u32 va, u32 vb, u32 vc) { InterpreterCall("VMHADDSHS", &PPUInterpreter::VMHADDSHS, vd, va, vb, vc); } void Compiler::VMHRADDSHS(u32 vd, u32 va, u32 vb, u32 vc) { InterpreterCall("VMHRADDSHS", &PPUInterpreter::VMHRADDSHS, vd, va, vb, vc); } void Compiler::VMINFP(u32 vd, u32 va, u32 vb) { auto va_v4f32 = GetVrAsFloatVec(va); auto vb_v4f32 = GetVrAsFloatVec(vb); auto res_v4f32 = m_ir_builder->CreateCall2(Intrinsic::getDeclaration(m_module, Intrinsic::x86_sse_min_ps), va_v4f32, vb_v4f32); SetVr(vd, res_v4f32); } void Compiler::VMINSB(u32 vd, u32 va, u32 vb) { auto va_v16i8 = GetVrAsIntVec(va, 8); auto vb_v16i8 = GetVrAsIntVec(vb, 8); auto res_v16i8 = m_ir_builder->CreateCall2(Intrinsic::getDeclaration(m_module, Intrinsic::x86_sse41_pminsb), va_v16i8, vb_v16i8); SetVr(vd, res_v16i8); } void Compiler::VMINSH(u32 vd, u32 va, u32 vb) { auto va_v8i16 = GetVrAsIntVec(va, 16); auto vb_v8i16 = GetVrAsIntVec(vb, 16); auto res_v8i16 = m_ir_builder->CreateCall2(Intrinsic::getDeclaration(m_module, Intrinsic::x86_sse2_pmins_w), va_v8i16, vb_v8i16); SetVr(vd, res_v8i16); } void Compiler::VMINSW(u32 vd, u32 va, u32 vb) { auto va_v4i32 = GetVrAsIntVec(va, 32); auto vb_v4i32 = GetVrAsIntVec(vb, 32); auto res_v4i32 = m_ir_builder->CreateCall2(Intrinsic::getDeclaration(m_module, Intrinsic::x86_sse41_pminsd), va_v4i32, vb_v4i32); SetVr(vd, res_v4i32); } void Compiler::VMINUB(u32 vd, u32 va, u32 vb) { auto va_v16i8 = GetVrAsIntVec(va, 8); auto vb_v16i8 = GetVrAsIntVec(vb, 8); auto res_v16i8 = m_ir_builder->CreateCall2(Intrinsic::getDeclaration(m_module, Intrinsic::x86_sse2_pminu_b), va_v16i8, vb_v16i8); SetVr(vd, res_v16i8); } void Compiler::VMINUH(u32 vd, u32 va, u32 vb) { auto va_v8i16 = GetVrAsIntVec(va, 16); auto vb_v8i16 = GetVrAsIntVec(vb, 16); auto res_v8i16 = m_ir_builder->CreateCall2(Intrinsic::getDeclaration(m_module, Intrinsic::x86_sse41_pminuw), va_v8i16, vb_v8i16); SetVr(vd, res_v8i16); } void Compiler::VMINUW(u32 vd, u32 va, u32 vb) { auto va_v4i32 = GetVrAsIntVec(va, 32); auto vb_v4i32 = GetVrAsIntVec(vb, 32); auto res_v4i32 = m_ir_builder->CreateCall2(Intrinsic::getDeclaration(m_module, Intrinsic::x86_sse41_pminud), va_v4i32, vb_v4i32); SetVr(vd, res_v4i32); } void Compiler::VMLADDUHM(u32 vd, u32 va, u32 vb, u32 vc) { InterpreterCall("VMLADDUHM", &PPUInterpreter::VMLADDUHM, vd, va, vb, vc); } void Compiler::VMRGHB(u32 vd, u32 va, u32 vb) { auto va_v16i8 = GetVrAsIntVec(va, 8); auto vb_v16i8 = GetVrAsIntVec(vb, 8); u32 mask_v16i32[16] = {24, 8, 25, 9, 26, 10, 27, 11, 28, 12, 29, 13, 30, 14, 31, 15}; auto vd_v16i8 = m_ir_builder->CreateShuffleVector(va_v16i8, vb_v16i8, ConstantDataVector::get(m_ir_builder->getContext(), mask_v16i32)); SetVr(vd, vd_v16i8); } void Compiler::VMRGHH(u32 vd, u32 va, u32 vb) { auto va_v8i16 = GetVrAsIntVec(va, 16); auto vb_v8i16 = GetVrAsIntVec(vb, 16); u32 mask_v8i32[8] = {12, 4, 13, 5, 14, 6, 15, 7}; auto vd_v8i16 = m_ir_builder->CreateShuffleVector(va_v8i16, vb_v8i16, ConstantDataVector::get(m_ir_builder->getContext(), mask_v8i32)); SetVr(vd, vd_v8i16); } void Compiler::VMRGHW(u32 vd, u32 va, u32 vb) { auto va_v4i32 = GetVrAsIntVec(va, 32); auto vb_v4i32 = GetVrAsIntVec(vb, 32); u32 mask_v4i32[4] = {6, 2, 7, 3}; auto vd_v4i32 = m_ir_builder->CreateShuffleVector(va_v4i32, vb_v4i32, ConstantDataVector::get(m_ir_builder->getContext(), mask_v4i32)); SetVr(vd, vd_v4i32); } void Compiler::VMRGLB(u32 vd, u32 va, u32 vb) { auto va_v16i8 = GetVrAsIntVec(va, 8); auto vb_v16i8 = GetVrAsIntVec(vb, 8); u32 mask_v16i32[16] = {16, 0, 17, 1, 18, 2, 19, 3, 20, 4, 21, 5, 22, 6, 23, 7}; auto vd_v16i8 = m_ir_builder->CreateShuffleVector(va_v16i8, vb_v16i8, ConstantDataVector::get(m_ir_builder->getContext(), mask_v16i32)); SetVr(vd, vd_v16i8); } void Compiler::VMRGLH(u32 vd, u32 va, u32 vb) { auto va_v8i16 = GetVrAsIntVec(va, 16); auto vb_v8i16 = GetVrAsIntVec(vb, 16); u32 mask_v8i32[8] = {8, 0, 9, 1, 10, 2, 11, 3}; auto vd_v8i16 = m_ir_builder->CreateShuffleVector(va_v8i16, vb_v8i16, ConstantDataVector::get(m_ir_builder->getContext(), mask_v8i32)); SetVr(vd, vd_v8i16); } void Compiler::VMRGLW(u32 vd, u32 va, u32 vb) { auto va_v4i32 = GetVrAsIntVec(va, 32); auto vb_v4i32 = GetVrAsIntVec(vb, 32); u32 mask_v4i32[4] = {4, 0, 5, 1}; auto vd_v4i32 = m_ir_builder->CreateShuffleVector(va_v4i32, vb_v4i32, ConstantDataVector::get(m_ir_builder->getContext(), mask_v4i32)); SetVr(vd, vd_v4i32); } void Compiler::VMSUMMBM(u32 vd, u32 va, u32 vb, u32 vc) { auto va_v16i8 = GetVrAsIntVec(va, 8); auto vb_v16i8 = GetVrAsIntVec(vb, 8); auto va_v16i16 = m_ir_builder->CreateSExt(va_v16i8, VectorType::get(m_ir_builder->getInt16Ty(), 16)); auto vb_v16i16 = m_ir_builder->CreateZExt(vb_v16i8, VectorType::get(m_ir_builder->getInt16Ty(), 16)); auto tmp_v16i16 = m_ir_builder->CreateMul(va_v16i16, vb_v16i16); auto undef_v16i16 = UndefValue::get(VectorType::get(m_ir_builder->getInt16Ty(), 16)); u32 mask1_v4i32[4] = {0, 4, 8, 12}; auto tmp1_v4i16 = m_ir_builder->CreateShuffleVector(tmp_v16i16, undef_v16i16, ConstantDataVector::get(m_ir_builder->getContext(), mask1_v4i32)); auto tmp1_v4i32 = m_ir_builder->CreateSExt(tmp1_v4i16, VectorType::get(m_ir_builder->getInt32Ty(), 4)); u32 mask2_v4i32[4] = {1, 5, 9, 13}; auto tmp2_v4i16 = m_ir_builder->CreateShuffleVector(tmp_v16i16, undef_v16i16, ConstantDataVector::get(m_ir_builder->getContext(), mask2_v4i32)); auto tmp2_v4i32 = m_ir_builder->CreateSExt(tmp2_v4i16, VectorType::get(m_ir_builder->getInt32Ty(), 4)); u32 mask3_v4i32[4] = {2, 6, 10, 14}; auto tmp3_v4i16 = m_ir_builder->CreateShuffleVector(tmp_v16i16, undef_v16i16, ConstantDataVector::get(m_ir_builder->getContext(), mask3_v4i32)); auto tmp3_v4i32 = m_ir_builder->CreateSExt(tmp3_v4i16, VectorType::get(m_ir_builder->getInt32Ty(), 4)); u32 mask4_v4i32[4] = {3, 7, 11, 15}; auto tmp4_v4i16 = m_ir_builder->CreateShuffleVector(tmp_v16i16, undef_v16i16, ConstantDataVector::get(m_ir_builder->getContext(), mask4_v4i32)); auto tmp4_v4i32 = m_ir_builder->CreateSExt(tmp4_v4i16, VectorType::get(m_ir_builder->getInt32Ty(), 4)); auto vc_v4i32 = GetVrAsIntVec(vc, 32); auto res_v4i32 = m_ir_builder->CreateAdd(tmp1_v4i32, tmp2_v4i32); res_v4i32 = m_ir_builder->CreateAdd(res_v4i32, tmp3_v4i32); res_v4i32 = m_ir_builder->CreateAdd(res_v4i32, tmp4_v4i32); res_v4i32 = m_ir_builder->CreateAdd(res_v4i32, vc_v4i32); SetVr(vd, res_v4i32); // TODO: Try to optimize with horizontal add } void Compiler::VMSUMSHM(u32 vd, u32 va, u32 vb, u32 vc) { auto va_v8i16 = GetVrAsIntVec(va, 16); auto vb_v8i16 = GetVrAsIntVec(vb, 16); auto vc_v4i32 = GetVrAsIntVec(vc, 32); auto res_v4i32 = (Value *)m_ir_builder->CreateCall2(Intrinsic::getDeclaration(m_module, Intrinsic::x86_sse2_pmadd_wd), va_v8i16, vb_v8i16); res_v4i32 = m_ir_builder->CreateAdd(res_v4i32, vc_v4i32); SetVr(vd, res_v4i32); } void Compiler::VMSUMSHS(u32 vd, u32 va, u32 vb, u32 vc) { InterpreterCall("VMSUMSHS", &PPUInterpreter::VMSUMSHS, vd, va, vb, vc); } void Compiler::VMSUMUBM(u32 vd, u32 va, u32 vb, u32 vc) { auto va_v16i8 = GetVrAsIntVec(va, 8); auto vb_v16i8 = GetVrAsIntVec(vb, 8); auto va_v16i16 = m_ir_builder->CreateZExt(va_v16i8, VectorType::get(m_ir_builder->getInt16Ty(), 16)); auto vb_v16i16 = m_ir_builder->CreateZExt(vb_v16i8, VectorType::get(m_ir_builder->getInt16Ty(), 16)); auto tmp_v16i16 = m_ir_builder->CreateMul(va_v16i16, vb_v16i16); auto undef_v16i16 = UndefValue::get(VectorType::get(m_ir_builder->getInt16Ty(), 16)); u32 mask1_v4i32[4] = {0, 4, 8, 12}; auto tmp1_v4i16 = m_ir_builder->CreateShuffleVector(tmp_v16i16, undef_v16i16, ConstantDataVector::get(m_ir_builder->getContext(), mask1_v4i32)); auto tmp1_v4i32 = m_ir_builder->CreateZExt(tmp1_v4i16, VectorType::get(m_ir_builder->getInt32Ty(), 4)); u32 mask2_v4i32[4] = {1, 5, 9, 13}; auto tmp2_v4i16 = m_ir_builder->CreateShuffleVector(tmp_v16i16, undef_v16i16, ConstantDataVector::get(m_ir_builder->getContext(), mask2_v4i32)); auto tmp2_v4i32 = m_ir_builder->CreateZExt(tmp2_v4i16, VectorType::get(m_ir_builder->getInt32Ty(), 4)); u32 mask3_v4i32[4] = {2, 6, 10, 14}; auto tmp3_v4i16 = m_ir_builder->CreateShuffleVector(tmp_v16i16, undef_v16i16, ConstantDataVector::get(m_ir_builder->getContext(), mask3_v4i32)); auto tmp3_v4i32 = m_ir_builder->CreateZExt(tmp3_v4i16, VectorType::get(m_ir_builder->getInt32Ty(), 4)); u32 mask4_v4i32[4] = {3, 7, 11, 15}; auto tmp4_v4i16 = m_ir_builder->CreateShuffleVector(tmp_v16i16, undef_v16i16, ConstantDataVector::get(m_ir_builder->getContext(), mask4_v4i32)); auto tmp4_v4i32 = m_ir_builder->CreateZExt(tmp4_v4i16, VectorType::get(m_ir_builder->getInt32Ty(), 4)); auto vc_v4i32 = GetVrAsIntVec(vc, 32); auto res_v4i32 = m_ir_builder->CreateAdd(tmp1_v4i32, tmp2_v4i32); res_v4i32 = m_ir_builder->CreateAdd(res_v4i32, tmp3_v4i32); res_v4i32 = m_ir_builder->CreateAdd(res_v4i32, tmp4_v4i32); res_v4i32 = m_ir_builder->CreateAdd(res_v4i32, vc_v4i32); SetVr(vd, res_v4i32); // TODO: Try to optimize with horizontal add } void Compiler::VMSUMUHM(u32 vd, u32 va, u32 vb, u32 vc) { auto va_v8i16 = GetVrAsIntVec(va, 16); auto vb_v8i16 = GetVrAsIntVec(vb, 16); auto va_v8i32 = m_ir_builder->CreateZExt(va_v8i16, VectorType::get(m_ir_builder->getInt32Ty(), 8)); auto vb_v8i32 = m_ir_builder->CreateZExt(vb_v8i16, VectorType::get(m_ir_builder->getInt32Ty(), 8)); auto tmp_v8i32 = m_ir_builder->CreateMul(va_v8i32, vb_v8i32); auto undef_v8i32 = UndefValue::get(VectorType::get(m_ir_builder->getInt32Ty(), 8)); u32 mask1_v4i32[4] = {0, 2, 4, 6}; auto tmp1_v4i32 = m_ir_builder->CreateShuffleVector(tmp_v8i32, undef_v8i32, ConstantDataVector::get(m_ir_builder->getContext(), mask1_v4i32)); u32 mask2_v4i32[4] = {1, 3, 5, 7}; auto tmp2_v4i32 = m_ir_builder->CreateShuffleVector(tmp_v8i32, undef_v8i32, ConstantDataVector::get(m_ir_builder->getContext(), mask2_v4i32)); auto vc_v4i32 = GetVrAsIntVec(vc, 32); auto res_v4i32 = m_ir_builder->CreateAdd(tmp1_v4i32, tmp2_v4i32); res_v4i32 = m_ir_builder->CreateAdd(res_v4i32, vc_v4i32); SetVr(vd, res_v4i32); // TODO: Try to optimize with horizontal add } void Compiler::VMSUMUHS(u32 vd, u32 va, u32 vb, u32 vc) { InterpreterCall("VMSUMUHS", &PPUInterpreter::VMSUMUHS, vd, va, vb, vc); } void Compiler::VMULESB(u32 vd, u32 va, u32 vb) { InterpreterCall("VMULESB", &PPUInterpreter::VMULESB, vd, va, vb); } void Compiler::VMULESH(u32 vd, u32 va, u32 vb) { InterpreterCall("VMULESH", &PPUInterpreter::VMULESH, vd, va, vb); } void Compiler::VMULEUB(u32 vd, u32 va, u32 vb) { InterpreterCall("VMULEUB", &PPUInterpreter::VMULEUB, vd, va, vb); } void Compiler::VMULEUH(u32 vd, u32 va, u32 vb) { InterpreterCall("VMULEUH", &PPUInterpreter::VMULEUH, vd, va, vb); } void Compiler::VMULOSB(u32 vd, u32 va, u32 vb) { InterpreterCall("VMULOSB", &PPUInterpreter::VMULOSB, vd, va, vb); } void Compiler::VMULOSH(u32 vd, u32 va, u32 vb) { InterpreterCall("VMULOSH", &PPUInterpreter::VMULOSH, vd, va, vb); } void Compiler::VMULOUB(u32 vd, u32 va, u32 vb) { InterpreterCall("VMULOUB", &PPUInterpreter::VMULOUB, vd, va, vb); } void Compiler::VMULOUH(u32 vd, u32 va, u32 vb) { InterpreterCall("VMULOUH", &PPUInterpreter::VMULOUH, vd, va, vb); } void Compiler::VNMSUBFP(u32 vd, u32 va, u32 vc, u32 vb) { auto va_v4f32 = GetVrAsFloatVec(va); auto vb_v4f32 = GetVrAsFloatVec(vb); auto vc_v4f32 = GetVrAsFloatVec(vc); vc_v4f32 = m_ir_builder->CreateFNeg(vc_v4f32); auto res_v4f32 = (Value *)m_ir_builder->CreateCall3(Intrinsic::getDeclaration(m_module, Intrinsic::fmuladd, VectorType::get(m_ir_builder->getFloatTy(), 4)), va_v4f32, vc_v4f32, vb_v4f32); SetVr(vd, res_v4f32); } void Compiler::VNOR(u32 vd, u32 va, u32 vb) { auto va_v8i16 = GetVrAsIntVec(va, 16); auto vb_v8i16 = GetVrAsIntVec(vb, 16); auto res_v8i16 = m_ir_builder->CreateOr(va_v8i16, vb_v8i16); res_v8i16 = m_ir_builder->CreateNot(res_v8i16); SetVr(vd, res_v8i16); } void Compiler::VOR(u32 vd, u32 va, u32 vb) { auto va_v8i16 = GetVrAsIntVec(va, 16); auto vb_v8i16 = GetVrAsIntVec(vb, 16); auto res_v8i16 = m_ir_builder->CreateOr(va_v8i16, vb_v8i16); SetVr(vd, res_v8i16); } void Compiler::VPERM(u32 vd, u32 va, u32 vb, u32 vc) { auto va_v16i8 = GetVrAsIntVec(va, 8); auto vb_v16i8 = GetVrAsIntVec(vb, 8); auto vc_v16i8 = GetVrAsIntVec(vc, 8); auto thrity_one_v16i8 = m_ir_builder->CreateVectorSplat(16, m_ir_builder->getInt8(31)); vc_v16i8 = m_ir_builder->CreateAnd(vc_v16i8, thrity_one_v16i8); auto fifteen_v16i8 = m_ir_builder->CreateVectorSplat(16, m_ir_builder->getInt8(15)); auto vc_le15_v16i8 = m_ir_builder->CreateSub(fifteen_v16i8, vc_v16i8); auto res_va_v16i8 = m_ir_builder->CreateCall2(Intrinsic::getDeclaration(m_module, Intrinsic::x86_ssse3_pshuf_b_128), va_v16i8, vc_le15_v16i8); auto vc_gt15_v16i8 = m_ir_builder->CreateSub(thrity_one_v16i8, vc_v16i8); auto cmp_i1 = m_ir_builder->CreateICmpUGT(vc_gt15_v16i8, fifteen_v16i8); auto cmp_i8 = m_ir_builder->CreateSExt(cmp_i1, VectorType::get(m_ir_builder->getInt8Ty(), 16)); vc_gt15_v16i8 = m_ir_builder->CreateOr(cmp_i8, vc_gt15_v16i8); auto res_vb_v16i8 = m_ir_builder->CreateCall2(Intrinsic::getDeclaration(m_module, Intrinsic::x86_ssse3_pshuf_b_128), vb_v16i8, vc_gt15_v16i8); auto res_v16i8 = m_ir_builder->CreateOr(res_vb_v16i8, res_va_v16i8); SetVr(vd, res_v16i8); } void Compiler::VPKPX(u32 vd, u32 va, u32 vb) { InterpreterCall("VPKPX", &PPUInterpreter::VPKPX, vd, va, vb); } void Compiler::VPKSHSS(u32 vd, u32 va, u32 vb) { InterpreterCall("VPKSHSS", &PPUInterpreter::VPKSHSS, vd, va, vb); } void Compiler::VPKSHUS(u32 vd, u32 va, u32 vb) { InterpreterCall("VPKSHUS", &PPUInterpreter::VPKSHUS, vd, va, vb); } void Compiler::VPKSWSS(u32 vd, u32 va, u32 vb) { InterpreterCall("VPKSWSS", &PPUInterpreter::VPKSWSS, vd, va, vb); } void Compiler::VPKSWUS(u32 vd, u32 va, u32 vb) { InterpreterCall("VPKSWUS", &PPUInterpreter::VPKSWUS, vd, va, vb); } void Compiler::VPKUHUM(u32 vd, u32 va, u32 vb) { InterpreterCall("VPKUHUM", &PPUInterpreter::VPKUHUM, vd, va, vb); } void Compiler::VPKUHUS(u32 vd, u32 va, u32 vb) { InterpreterCall("VPKUHUS", &PPUInterpreter::VPKUHUS, vd, va, vb); } void Compiler::VPKUWUM(u32 vd, u32 va, u32 vb) { InterpreterCall("VPKUWUM", &PPUInterpreter::VPKUWUM, vd, va, vb); } void Compiler::VPKUWUS(u32 vd, u32 va, u32 vb) { InterpreterCall("VPKUWUS", &PPUInterpreter::VPKUWUS, vd, va, vb); } void Compiler::VREFP(u32 vd, u32 vb) { auto vb_v4f32 = GetVrAsFloatVec(vb); auto res_v4f32 = m_ir_builder->CreateCall(Intrinsic::getDeclaration(m_module, Intrinsic::x86_sse_rcp_ps), vb_v4f32); SetVr(vd, res_v4f32); } void Compiler::VRFIM(u32 vd, u32 vb) { InterpreterCall("VRFIM", &PPUInterpreter::VRFIM, vd, vb); } void Compiler::VRFIN(u32 vd, u32 vb) { InterpreterCall("VRFIN", &PPUInterpreter::VRFIN, vd, vb); } void Compiler::VRFIP(u32 vd, u32 vb) { InterpreterCall("VRFIP", &PPUInterpreter::VRFIP, vd, vb); } void Compiler::VRFIZ(u32 vd, u32 vb) { InterpreterCall("VRFIZ", &PPUInterpreter::VRFIZ, vd, vb); } void Compiler::VRLB(u32 vd, u32 va, u32 vb) { InterpreterCall("VRLB", &PPUInterpreter::VRLB, vd, va, vb); } void Compiler::VRLH(u32 vd, u32 va, u32 vb) { InterpreterCall("VRLH", &PPUInterpreter::VRLH, vd, va, vb); } void Compiler::VRLW(u32 vd, u32 va, u32 vb) { InterpreterCall("VRLW", &PPUInterpreter::VRLW, vd, va, vb); } void Compiler::VRSQRTEFP(u32 vd, u32 vb) { InterpreterCall("VRSQRTEFP", &PPUInterpreter::VRSQRTEFP, vd, vb); } void Compiler::VSEL(u32 vd, u32 va, u32 vb, u32 vc) { auto va_v4i32 = GetVrAsIntVec(va, 32); auto vb_v4i32 = GetVrAsIntVec(vb, 32); auto vc_v4i32 = GetVrAsIntVec(vc, 32); vb_v4i32 = m_ir_builder->CreateAnd(vb_v4i32, vc_v4i32); vc_v4i32 = m_ir_builder->CreateNot(vc_v4i32); va_v4i32 = m_ir_builder->CreateAnd(va_v4i32, vc_v4i32); auto vd_v4i32 = m_ir_builder->CreateOr(va_v4i32, vb_v4i32); SetVr(vd, vd_v4i32); } void Compiler::VSL(u32 vd, u32 va, u32 vb) { auto va_i128 = GetVr(va); auto vb_v16i8 = GetVrAsIntVec(vb, 8); auto sh_i8 = m_ir_builder->CreateExtractElement(vb_v16i8, m_ir_builder->getInt8(0)); sh_i8 = m_ir_builder->CreateAnd(sh_i8, 0x7); auto sh_i128 = m_ir_builder->CreateZExt(sh_i8, m_ir_builder->getIntNTy(128)); va_i128 = m_ir_builder->CreateShl(va_i128, sh_i128); SetVr(vd, va_i128); } void Compiler::VSLB(u32 vd, u32 va, u32 vb) { auto va_v16i8 = GetVrAsIntVec(va, 8); auto vb_v16i8 = GetVrAsIntVec(vb, 8); vb_v16i8 = m_ir_builder->CreateAnd(vb_v16i8, m_ir_builder->CreateVectorSplat(16, m_ir_builder->getInt8(0x7))); auto res_v16i8 = m_ir_builder->CreateShl(va_v16i8, vb_v16i8); SetVr(vd, res_v16i8); } void Compiler::VSLDOI(u32 vd, u32 va, u32 vb, u32 sh) { auto va_v16i8 = GetVrAsIntVec(va, 8); auto vb_v16i8 = GetVrAsIntVec(vb, 8); sh = 16 - sh; u32 mask_v16i32[16] = {sh, sh + 1, sh + 2, sh + 3, sh + 4, sh + 5, sh + 6, sh + 7, sh + 8, sh + 9, sh + 10, sh + 11, sh + 12, sh + 13, sh + 14, sh + 15}; auto vd_v16i8 = m_ir_builder->CreateShuffleVector(vb_v16i8, va_v16i8, ConstantDataVector::get(m_ir_builder->getContext(), mask_v16i32)); SetVr(vd, vd_v16i8); } void Compiler::VSLH(u32 vd, u32 va, u32 vb) { auto va_v8i16 = GetVrAsIntVec(va, 16); auto vb_v8i16 = GetVrAsIntVec(vb, 16); vb_v8i16 = m_ir_builder->CreateAnd(vb_v8i16, m_ir_builder->CreateVectorSplat(8, m_ir_builder->getInt16(0xF))); auto res_v8i16 = m_ir_builder->CreateShl(va_v8i16, vb_v8i16); SetVr(vd, res_v8i16); } void Compiler::VSLO(u32 vd, u32 va, u32 vb) { auto va_i128 = GetVr(va); auto vb_v16i8 = GetVrAsIntVec(vb, 8); auto sh_i8 = m_ir_builder->CreateExtractElement(vb_v16i8, m_ir_builder->getInt8(0)); sh_i8 = m_ir_builder->CreateAnd(sh_i8, 0x78); auto sh_i128 = m_ir_builder->CreateZExt(sh_i8, m_ir_builder->getIntNTy(128)); va_i128 = m_ir_builder->CreateShl(va_i128, sh_i128); SetVr(vd, va_i128); } void Compiler::VSLW(u32 vd, u32 va, u32 vb) { auto va_v4i32 = GetVrAsIntVec(va, 32); auto vb_v4i32 = GetVrAsIntVec(vb, 32); vb_v4i32 = m_ir_builder->CreateAnd(vb_v4i32, m_ir_builder->CreateVectorSplat(4, m_ir_builder->getInt32(0x1F))); auto res_v4i32 = m_ir_builder->CreateShl(va_v4i32, vb_v4i32); SetVr(vd, res_v4i32); } void Compiler::VSPLTB(u32 vd, u32 uimm5, u32 vb) { auto vb_v16i8 = GetVrAsIntVec(vb, 8); auto undef_v16i8 = UndefValue::get(VectorType::get(m_ir_builder->getInt8Ty(), 16)); auto mask_v16i32 = m_ir_builder->CreateVectorSplat(16, m_ir_builder->getInt32(15 - uimm5)); auto res_v16i8 = m_ir_builder->CreateShuffleVector(vb_v16i8, undef_v16i8, mask_v16i32); SetVr(vd, res_v16i8); } void Compiler::VSPLTH(u32 vd, u32 uimm5, u32 vb) { auto vb_v8i16 = GetVrAsIntVec(vb, 16); auto undef_v8i16 = UndefValue::get(VectorType::get(m_ir_builder->getInt16Ty(), 8)); auto mask_v8i32 = m_ir_builder->CreateVectorSplat(8, m_ir_builder->getInt32(7 - uimm5)); auto res_v8i16 = m_ir_builder->CreateShuffleVector(vb_v8i16, undef_v8i16, mask_v8i32); SetVr(vd, res_v8i16); } void Compiler::VSPLTISB(u32 vd, s32 simm5) { auto vd_v16i8 = m_ir_builder->CreateVectorSplat(16, m_ir_builder->getInt8((s8)simm5)); SetVr(vd, vd_v16i8); } void Compiler::VSPLTISH(u32 vd, s32 simm5) { auto vd_v8i16 = m_ir_builder->CreateVectorSplat(8, m_ir_builder->getInt16((s16)simm5)); SetVr(vd, vd_v8i16); } void Compiler::VSPLTISW(u32 vd, s32 simm5) { auto vd_v4i32 = m_ir_builder->CreateVectorSplat(4, m_ir_builder->getInt32((s32)simm5)); SetVr(vd, vd_v4i32); } void Compiler::VSPLTW(u32 vd, u32 uimm5, u32 vb) { auto vb_v4i32 = GetVrAsIntVec(vb, 32); auto undef_v4i32 = UndefValue::get(VectorType::get(m_ir_builder->getInt32Ty(), 4)); auto mask_v4i32 = m_ir_builder->CreateVectorSplat(4, m_ir_builder->getInt32(3 - uimm5)); auto res_v4i32 = m_ir_builder->CreateShuffleVector(vb_v4i32, undef_v4i32, mask_v4i32); SetVr(vd, res_v4i32); } void Compiler::VSR(u32 vd, u32 va, u32 vb) { auto va_i128 = GetVr(va); auto vb_v16i8 = GetVrAsIntVec(vb, 8); auto sh_i8 = m_ir_builder->CreateExtractElement(vb_v16i8, m_ir_builder->getInt8(0)); sh_i8 = m_ir_builder->CreateAnd(sh_i8, 0x7); auto sh_i128 = m_ir_builder->CreateZExt(sh_i8, m_ir_builder->getIntNTy(128)); va_i128 = m_ir_builder->CreateLShr(va_i128, sh_i128); SetVr(vd, va_i128); } void Compiler::VSRAB(u32 vd, u32 va, u32 vb) { auto va_v16i8 = GetVrAsIntVec(va, 8); auto vb_v16i8 = GetVrAsIntVec(vb, 8); vb_v16i8 = m_ir_builder->CreateAnd(vb_v16i8, m_ir_builder->CreateVectorSplat(16, m_ir_builder->getInt8(0x7))); auto res_v16i8 = m_ir_builder->CreateAShr(va_v16i8, vb_v16i8); SetVr(vd, res_v16i8); } void Compiler::VSRAH(u32 vd, u32 va, u32 vb) { auto va_v8i16 = GetVrAsIntVec(va, 16); auto vb_v8i16 = GetVrAsIntVec(vb, 16); vb_v8i16 = m_ir_builder->CreateAnd(vb_v8i16, m_ir_builder->CreateVectorSplat(8, m_ir_builder->getInt16(0xF))); auto res_v8i16 = m_ir_builder->CreateAShr(va_v8i16, vb_v8i16); SetVr(vd, res_v8i16); } void Compiler::VSRAW(u32 vd, u32 va, u32 vb) { auto va_v4i32 = GetVrAsIntVec(va, 32); auto vb_v4i32 = GetVrAsIntVec(vb, 32); vb_v4i32 = m_ir_builder->CreateAnd(vb_v4i32, m_ir_builder->CreateVectorSplat(4, m_ir_builder->getInt32(0x1F))); auto res_v4i32 = m_ir_builder->CreateAShr(va_v4i32, vb_v4i32); SetVr(vd, res_v4i32); } void Compiler::VSRB(u32 vd, u32 va, u32 vb) { auto va_v16i8 = GetVrAsIntVec(va, 8); auto vb_v16i8 = GetVrAsIntVec(vb, 8); vb_v16i8 = m_ir_builder->CreateAnd(vb_v16i8, m_ir_builder->CreateVectorSplat(16, m_ir_builder->getInt8(0x7))); auto res_v16i8 = m_ir_builder->CreateLShr(va_v16i8, vb_v16i8); SetVr(vd, res_v16i8); } void Compiler::VSRH(u32 vd, u32 va, u32 vb) { auto va_v8i16 = GetVrAsIntVec(va, 16); auto vb_v8i16 = GetVrAsIntVec(vb, 16); vb_v8i16 = m_ir_builder->CreateAnd(vb_v8i16, m_ir_builder->CreateVectorSplat(8, m_ir_builder->getInt16(0xF))); auto res_v8i16 = m_ir_builder->CreateLShr(va_v8i16, vb_v8i16); SetVr(vd, res_v8i16); } void Compiler::VSRO(u32 vd, u32 va, u32 vb) { auto va_i128 = GetVr(va); auto vb_v16i8 = GetVrAsIntVec(vb, 8); auto sh_i8 = m_ir_builder->CreateExtractElement(vb_v16i8, m_ir_builder->getInt8(0)); sh_i8 = m_ir_builder->CreateAnd(sh_i8, 0x78); auto sh_i128 = m_ir_builder->CreateZExt(sh_i8, m_ir_builder->getIntNTy(128)); va_i128 = m_ir_builder->CreateLShr(va_i128, sh_i128); SetVr(vd, va_i128); } void Compiler::VSRW(u32 vd, u32 va, u32 vb) { auto va_v4i32 = GetVrAsIntVec(va, 32); auto vb_v4i32 = GetVrAsIntVec(vb, 32); vb_v4i32 = m_ir_builder->CreateAnd(vb_v4i32, m_ir_builder->CreateVectorSplat(4, m_ir_builder->getInt32(0x1F))); auto res_v4i32 = m_ir_builder->CreateLShr(va_v4i32, vb_v4i32); SetVr(vd, res_v4i32); } void Compiler::VSUBCUW(u32 vd, u32 va, u32 vb) { auto va_v4i32 = GetVrAsIntVec(va, 32); auto vb_v4i32 = GetVrAsIntVec(vb, 32); auto cmpv4i1 = m_ir_builder->CreateICmpUGE(va_v4i32, vb_v4i32); auto cmpv4i32 = m_ir_builder->CreateZExt(cmpv4i1, VectorType::get(m_ir_builder->getInt32Ty(), 4)); SetVr(vd, cmpv4i32); } void Compiler::VSUBFP(u32 vd, u32 va, u32 vb) { auto va_v4f32 = GetVrAsFloatVec(va); auto vb_v4f32 = GetVrAsFloatVec(vb); auto diff_v4f32 = m_ir_builder->CreateFSub(va_v4f32, vb_v4f32); SetVr(vd, diff_v4f32); } void Compiler::VSUBSBS(u32 vd, u32 va, u32 vb) { auto va_v16i8 = GetVrAsIntVec(va, 8); auto vb_v16i8 = GetVrAsIntVec(vb, 8); auto diff_v16i8 = m_ir_builder->CreateCall2(Intrinsic::getDeclaration(m_module, Intrinsic::x86_sse2_psubs_b), va_v16i8, vb_v16i8); SetVr(vd, diff_v16i8); // TODO: Set VSCR.SAT } void Compiler::VSUBSHS(u32 vd, u32 va, u32 vb) { auto va_v8i16 = GetVrAsIntVec(va, 16); auto vb_v8i16 = GetVrAsIntVec(vb, 16); auto diff_v8i16 = m_ir_builder->CreateCall2(Intrinsic::getDeclaration(m_module, Intrinsic::x86_sse2_psubs_w), va_v8i16, vb_v8i16); SetVr(vd, diff_v8i16); // TODO: Set VSCR.SAT } void Compiler::VSUBSWS(u32 vd, u32 va, u32 vb) { auto va_v4i32 = GetVrAsIntVec(va, 32); auto vb_v4i32 = GetVrAsIntVec(vb, 32); // See the comments for VADDSWS for a detailed description of how this works // Find the result in case of an overflow auto tmp1_v4i32 = m_ir_builder->CreateLShr(va_v4i32, 31); tmp1_v4i32 = m_ir_builder->CreateAdd(tmp1_v4i32, m_ir_builder->CreateVectorSplat(4, m_ir_builder->getInt32(0x7FFFFFFF))); auto tmp1_v16i8 = m_ir_builder->CreateBitCast(tmp1_v4i32, VectorType::get(m_ir_builder->getInt8Ty(), 16)); // Find the elements that can overflow (elements with opposite sign bits) auto tmp2_v4i32 = m_ir_builder->CreateXor(va_v4i32, vb_v4i32); // Perform the sub auto diff_v4i32 = m_ir_builder->CreateSub(va_v4i32, vb_v4i32); auto diff_v16i8 = m_ir_builder->CreateBitCast(diff_v4i32, VectorType::get(m_ir_builder->getInt8Ty(), 16)); // Find the elements that overflowed auto tmp3_v4i32 = m_ir_builder->CreateXor(va_v4i32, diff_v4i32); tmp3_v4i32 = m_ir_builder->CreateAnd(tmp2_v4i32, tmp3_v4i32); tmp3_v4i32 = m_ir_builder->CreateAShr(tmp3_v4i32, 31); auto tmp3_v16i8 = m_ir_builder->CreateBitCast(tmp3_v4i32, VectorType::get(m_ir_builder->getInt8Ty(), 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), diff_v16i8, tmp1_v16i8, tmp3_v16i8); SetVr(vd, res_v16i8); // TODO: Set SAT } void Compiler::VSUBUBM(u32 vd, u32 va, u32 vb) { auto va_v16i8 = GetVrAsIntVec(va, 8); auto vb_v16i8 = GetVrAsIntVec(vb, 8); auto diff_v16i8 = m_ir_builder->CreateSub(va_v16i8, vb_v16i8); SetVr(vd, diff_v16i8); } void Compiler::VSUBUBS(u32 vd, u32 va, u32 vb) { auto va_v16i8 = GetVrAsIntVec(va, 8); auto vb_v16i8 = GetVrAsIntVec(vb, 8); auto diff_v16i8 = m_ir_builder->CreateCall2(Intrinsic::getDeclaration(m_module, Intrinsic::x86_sse2_psubus_b), va_v16i8, vb_v16i8); SetVr(vd, diff_v16i8); // TODO: Set SAT } void Compiler::VSUBUHM(u32 vd, u32 va, u32 vb) { auto va_v8i16 = GetVrAsIntVec(va, 16); auto vb_v8i16 = GetVrAsIntVec(vb, 16); auto diff_v8i16 = m_ir_builder->CreateSub(va_v8i16, vb_v8i16); SetVr(vd, diff_v8i16); } void Compiler::VSUBUHS(u32 vd, u32 va, u32 vb) { auto va_v8i16 = GetVrAsIntVec(va, 16); auto vb_v8i16 = GetVrAsIntVec(vb, 16); auto diff_v8i16 = m_ir_builder->CreateCall2(Intrinsic::getDeclaration(m_module, Intrinsic::x86_sse2_psubus_w), va_v8i16, vb_v8i16); SetVr(vd, diff_v8i16); // TODO: Set SAT } void Compiler::VSUBUWM(u32 vd, u32 va, u32 vb) { auto va_v4i32 = GetVrAsIntVec(va, 32); auto vb_v4i32 = GetVrAsIntVec(vb, 32); auto diff_v4i32 = m_ir_builder->CreateSub(va_v4i32, vb_v4i32); SetVr(vd, diff_v4i32); } void Compiler::VSUBUWS(u32 vd, u32 va, u32 vb) { auto va_v4i32 = GetVrAsIntVec(va, 32); auto vb_v4i32 = GetVrAsIntVec(vb, 32); auto diff_v4i32 = m_ir_builder->CreateSub(va_v4i32, vb_v4i32); auto cmp_v4i1 = m_ir_builder->CreateICmpULE(diff_v4i32, va_v4i32); auto cmp_v4i32 = m_ir_builder->CreateSExt(cmp_v4i1, VectorType::get(m_ir_builder->getInt32Ty(), 4)); auto res_v4i32 = m_ir_builder->CreateAnd(diff_v4i32, cmp_v4i32); SetVr(vd, res_v4i32); // TODO: Set SAT } void Compiler::VSUMSWS(u32 vd, u32 va, u32 vb) { InterpreterCall("VSUMSWS", &PPUInterpreter::VSUMSWS, vd, va, vb); } void Compiler::VSUM2SWS(u32 vd, u32 va, u32 vb) { InterpreterCall("VSUM2SWS", &PPUInterpreter::VSUM2SWS, vd, va, vb); } void Compiler::VSUM4SBS(u32 vd, u32 va, u32 vb) { InterpreterCall("VSUM4SBS", &PPUInterpreter::VSUM4SBS, vd, va, vb); } void Compiler::VSUM4SHS(u32 vd, u32 va, u32 vb) { InterpreterCall("VSUM4SHS", &PPUInterpreter::VSUM4SHS, vd, va, vb); } void Compiler::VSUM4UBS(u32 vd, u32 va, u32 vb) { InterpreterCall("VSUM4UBS", &PPUInterpreter::VSUM4UBS, vd, va, vb); } void Compiler::VUPKHPX(u32 vd, u32 vb) { InterpreterCall("VUPKHPX", &PPUInterpreter::VUPKHPX, vd, vb); } void Compiler::VUPKHSB(u32 vd, u32 vb) { InterpreterCall("VUPKHSB", &PPUInterpreter::VUPKHSB, vd, vb); } void Compiler::VUPKHSH(u32 vd, u32 vb) { InterpreterCall("VUPKHSH", &PPUInterpreter::VUPKHSH, vd, vb); } void Compiler::VUPKLPX(u32 vd, u32 vb) { InterpreterCall("VUPKLPX", &PPUInterpreter::VUPKLPX, vd, vb); } void Compiler::VUPKLSB(u32 vd, u32 vb) { InterpreterCall("VUPKLSB", &PPUInterpreter::VUPKLSB, vd, vb); } void Compiler::VUPKLSH(u32 vd, u32 vb) { InterpreterCall("VUPKLSH", &PPUInterpreter::VUPKLSH, vd, vb); } void Compiler::VXOR(u32 vd, u32 va, u32 vb) { auto va_v8i16 = GetVrAsIntVec(va, 16); auto vb_v8i16 = GetVrAsIntVec(vb, 16); auto res_v8i16 = m_ir_builder->CreateXor(va_v8i16, vb_v8i16); SetVr(vd, res_v8i16); } void Compiler::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); //InterpreterCall("MULLI", &PPUInterpreter::MULLI, rd, ra, simm16); } void Compiler::SUBFIC(u32 rd, u32 ra, s32 simm16) { auto ra_i64 = GetGpr(ra); ra_i64 = m_ir_builder->CreateNeg(ra_i64); auto res_s = m_ir_builder->CreateCall2(Intrinsic::getDeclaration(m_module, Intrinsic::uadd_with_overflow, m_ir_builder->getInt64Ty()), ra_i64, m_ir_builder->getInt64((s64)simm16)); 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); //InterpreterCall("SUBFIC", &PPUInterpreter::SUBFIC, rd, ra, simm16); } void Compiler::CMPLI(u32 crfd, u32 l, u32 ra, u32 uimm16) { Value * ra_i64; if (l == 0) { ra_i64 = m_ir_builder->CreateZExt(GetGpr(ra, 32), m_ir_builder->getInt64Ty()); } else { ra_i64 = GetGpr(ra); } SetCrFieldUnsignedCmp(crfd, ra_i64, m_ir_builder->getInt64(uimm16)); //InterpreterCall("CMPLI", &PPUInterpreter::CMPLI, crfd, l, ra, uimm16); } void Compiler::CMPI(u32 crfd, u32 l, u32 ra, s32 simm16) { Value * ra_i64; if (l == 0) { ra_i64 = m_ir_builder->CreateSExt(GetGpr(ra, 32), m_ir_builder->getInt64Ty()); } else { ra_i64 = GetGpr(ra); } SetCrFieldSignedCmp(crfd, ra_i64, m_ir_builder->getInt64((s64)simm16)); //InterpreterCall("CMPI", &PPUInterpreter::CMPI, crfd, l, ra, simm16); } void Compiler::ADDIC(u32 rd, u32 ra, s32 simm16) { auto ra_i64 = GetGpr(ra); auto res_s = m_ir_builder->CreateCall2(Intrinsic::getDeclaration(m_module, Intrinsic::uadd_with_overflow, m_ir_builder->getInt64Ty()), 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); //InterpreterCall("ADDIC", &PPUInterpreter::ADDIC, rd, ra, simm16); } void Compiler::ADDIC_(u32 rd, u32 ra, s32 simm16) { ADDIC(rd, ra, simm16); SetCrFieldSignedCmp(0, GetGpr(rd), m_ir_builder->getInt64(0)); //InterpreterCall("ADDIC_", &PPUInterpreter::ADDIC_, rd, ra, simm16); } void Compiler::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); } //InterpreterCall("ADDI", &PPUInterpreter::ADDI, rd, ra, simm16); } void Compiler::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); } //InterpreterCall("ADDIS", &PPUInterpreter::ADDIS, rd, ra, simm16); } void Compiler::BC(u32 bo, u32 bi, s32 bd, u32 aa, u32 lk) { auto target_i64 = m_ir_builder->getInt64(branchTarget(aa ? 0 : m_state.current_instruction_address, bd)); auto target_i32 = m_ir_builder->CreateTrunc(target_i64, m_ir_builder->getInt32Ty()); CreateBranch(CheckBranchCondition(bo, bi), target_i32, lk ? true : false); //m_hit_branch_instruction = true; //SetPc(m_ir_builder->getInt32(m_current_instruction_address)); //InterpreterCall("BC", &PPUInterpreter::BC, bo, bi, bd, aa, lk); //SetPc(m_ir_builder->getInt32(m_current_instruction_address + 4)); //m_ir_builder->CreateRetVoid(); } void Compiler::SC(u32 sc_code) { InterpreterCall("SC", &PPUInterpreter::SC, sc_code); } void Compiler::B(s32 ll, u32 aa, u32 lk) { auto target_i64 = m_ir_builder->getInt64(branchTarget(aa ? 0 : m_state.current_instruction_address, ll)); auto target_i32 = m_ir_builder->CreateTrunc(target_i64, m_ir_builder->getInt32Ty()); CreateBranch(nullptr, target_i32, lk ? true : false); //m_hit_branch_instruction = true; //SetPc(m_ir_builder->getInt32(m_current_instruction_address)); //InterpreterCall("B", &PPUInterpreter::B, ll, aa, lk); //m_ir_builder->CreateRetVoid(); } void Compiler::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); } //InterpreterCall("MCRF", &PPUInterpreter::MCRF, crfd, crfs); } void Compiler::BCLR(u32 bo, u32 bi, u32 bh, u32 lk) { auto lr_i64 = GetLr(); lr_i64 = m_ir_builder->CreateAnd(lr_i64, ~0x3ULL); auto lr_i32 = m_ir_builder->CreateTrunc(lr_i64, m_ir_builder->getInt32Ty()); CreateBranch(CheckBranchCondition(bo, bi), lr_i32, lk ? true : false, true); //m_hit_branch_instruction = true; //SetPc(m_ir_builder->getInt32(m_current_instruction_address)); //InterpreterCall("BCLR", &PPUInterpreter::BCLR, bo, bi, bh, lk); //SetPc(m_ir_builder->getInt32(m_current_instruction_address + 4)); //m_ir_builder->CreateRetVoid(); } void Compiler::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); //InterpreterCall("CRNOR", &PPUInterpreter::CRNOR, crbd, crba, crbb); } void Compiler::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); //InterpreterCall("CRANDC", &PPUInterpreter::CRANDC, crbd, crba, crbb); } void Compiler::ISYNC() { m_ir_builder->CreateCall(Intrinsic::getDeclaration(m_module, Intrinsic::x86_sse2_mfence)); //InterpreterCall("ISYNC", &PPUInterpreter::ISYNC); } void Compiler::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); //InterpreterCall("CRXOR", &PPUInterpreter::CRXOR, crbd, crba, crbb); } void Compiler::DCBI(u32 ra, u32 rb) { InterpreterCall("DCBI", &PPUInterpreter::DCBI, ra, rb); } void Compiler::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); //InterpreterCall("CRNAND", &PPUInterpreter::CRNAND, crbd, crba, crbb); } void Compiler::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); //InterpreterCall("CRAND", &PPUInterpreter::CRAND, crbd, crba, crbb); } void Compiler::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); //InterpreterCall("CREQV", &PPUInterpreter::CREQV, crbd, crba, crbb); } void Compiler::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); //InterpreterCall("CRORC", &PPUInterpreter::CRORC, crbd, crba, crbb); } void Compiler::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); //InterpreterCall("CROR", &PPUInterpreter::CROR, crbd, crba, crbb); } void Compiler::BCCTR(u32 bo, u32 bi, u32 bh, u32 lk) { auto ctr_i64 = GetCtr(); ctr_i64 = m_ir_builder->CreateAnd(ctr_i64, ~0x3ULL); auto ctr_i32 = m_ir_builder->CreateTrunc(ctr_i64, m_ir_builder->getInt32Ty()); CreateBranch(CheckBranchCondition(bo, bi), ctr_i32, lk ? true : false); //m_hit_branch_instruction = true; //SetPc(m_ir_builder->getInt32(m_current_instruction_address)); //InterpreterCall("BCCTR", &PPUInterpreter::BCCTR, bo, bi, bh, lk); //SetPc(m_ir_builder->getInt32(m_current_instruction_address + 4)); //m_ir_builder->CreateRetVoid(); } void Compiler::RLWIMI(u32 ra, u32 rs, u32 sh, u32 mb, u32 me, bool rc) { auto rs_i32 = GetGpr(rs, 32); auto rs_i64 = m_ir_builder->CreateZExt(rs_i32, m_ir_builder->getInt64Ty()); auto rsh_i64 = m_ir_builder->CreateShl(rs_i64, 32); rs_i64 = m_ir_builder->CreateOr(rs_i64, rsh_i64); auto ra_i64 = GetGpr(ra); auto res_i64 = rs_i64; if (sh) { auto resl_i64 = m_ir_builder->CreateLShr(rs_i64, 64 - sh); auto resh_i64 = m_ir_builder->CreateShl(rs_i64, sh); res_i64 = m_ir_builder->CreateOr(resh_i64, resl_i64); } u64 mask = s_rotate_mask[32 + mb][32 + me]; res_i64 = m_ir_builder->CreateAnd(res_i64, mask); ra_i64 = m_ir_builder->CreateAnd(ra_i64, ~mask); res_i64 = m_ir_builder->CreateOr(res_i64, ra_i64); SetGpr(ra, res_i64); if (rc) { SetCrFieldSignedCmp(0, res_i64, m_ir_builder->getInt64(0)); } //InterpreterCall("RLWIMI", &PPUInterpreter::RLWIMI, ra, rs, sh, mb, me, rc); } void Compiler::RLWINM(u32 ra, u32 rs, u32 sh, u32 mb, u32 me, bool rc) { auto rs_i32 = GetGpr(rs, 32); auto rs_i64 = m_ir_builder->CreateZExt(rs_i32, m_ir_builder->getInt64Ty()); auto rsh_i64 = m_ir_builder->CreateShl(rs_i64, 32); rs_i64 = m_ir_builder->CreateOr(rs_i64, rsh_i64); auto res_i64 = rs_i64; if (sh) { auto resl_i64 = m_ir_builder->CreateLShr(rs_i64, 64 - sh); auto resh_i64 = m_ir_builder->CreateShl(rs_i64, sh); res_i64 = m_ir_builder->CreateOr(resh_i64, resl_i64); } res_i64 = m_ir_builder->CreateAnd(res_i64, s_rotate_mask[32 + mb][32 + me]); SetGpr(ra, res_i64); if (rc) { SetCrFieldSignedCmp(0, res_i64, m_ir_builder->getInt64(0)); } //InterpreterCall("RLWINM", &PPUInterpreter::RLWINM, ra, rs, sh, mb, me, rc); } void Compiler::RLWNM(u32 ra, u32 rs, u32 rb, u32 mb, u32 me, bool rc) { auto rs_i32 = GetGpr(rs, 32); auto rs_i64 = m_ir_builder->CreateZExt(rs_i32, m_ir_builder->getInt64Ty()); auto rsh_i64 = m_ir_builder->CreateShl(rs_i64, 32); rs_i64 = m_ir_builder->CreateOr(rs_i64, rsh_i64); auto rb_i64 = GetGpr(rb); auto shl_i64 = m_ir_builder->CreateAnd(rb_i64, 0x1F); auto shr_i64 = m_ir_builder->CreateSub(m_ir_builder->getInt64(32), shl_i64); auto resl_i64 = m_ir_builder->CreateLShr(rs_i64, shr_i64); auto resh_i64 = m_ir_builder->CreateShl(rs_i64, shl_i64); auto res_i64 = m_ir_builder->CreateOr(resh_i64, resl_i64); res_i64 = m_ir_builder->CreateAnd(res_i64, s_rotate_mask[32 + mb][32 + me]); SetGpr(ra, res_i64); if (rc) { SetCrFieldSignedCmp(0, res_i64, m_ir_builder->getInt64(0)); } //InterpreterCall("RLWNM", &PPUInterpreter::RLWNM, ra, rs, rb, mb, me, rc); } void Compiler::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); //InterpreterCall("ORI", &PPUInterpreter::ORI, ra, rs, uimm16); } void Compiler::ORIS(u32 ra, u32 rs, u32 uimm16) { auto rs_i64 = GetGpr(rs); auto res_i64 = m_ir_builder->CreateOr(rs_i64, (u64)uimm16 << 16); SetGpr(ra, res_i64); //InterpreterCall("ORIS", &PPUInterpreter::ORIS, ra, rs, uimm16); } void Compiler::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); //InterpreterCall("XORI", &PPUInterpreter::XORI, ra, rs, uimm16); } void Compiler::XORIS(u32 ra, u32 rs, u32 uimm16) { auto rs_i64 = GetGpr(rs); auto res_i64 = m_ir_builder->CreateXor(rs_i64, (u64)uimm16 << 16); SetGpr(ra, res_i64); //InterpreterCall("XORIS", &PPUInterpreter::XORIS, ra, rs, uimm16); } void Compiler::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)); //InterpreterCall("ANDI_", &PPUInterpreter::ANDI_, ra, rs, uimm16); } void Compiler::ANDIS_(u32 ra, u32 rs, u32 uimm16) { auto rs_i64 = GetGpr(rs); auto res_i64 = m_ir_builder->CreateAnd(rs_i64, (u64)uimm16 << 16); SetGpr(ra, res_i64); SetCrFieldSignedCmp(0, res_i64, m_ir_builder->getInt64(0)); //InterpreterCall("ANDIS_", &PPUInterpreter::ANDIS_, ra, rs, uimm16); } void Compiler::RLDICL(u32 ra, u32 rs, u32 sh, u32 mb, bool rc) { auto rs_i64 = GetGpr(rs); auto res_i64 = rs_i64; if (sh) { auto resl_i64 = m_ir_builder->CreateLShr(rs_i64, 64 - sh); auto resh_i64 = m_ir_builder->CreateShl(rs_i64, sh); res_i64 = m_ir_builder->CreateOr(resh_i64, resl_i64); } res_i64 = m_ir_builder->CreateAnd(res_i64, s_rotate_mask[mb][63]); SetGpr(ra, res_i64); if (rc) { SetCrFieldSignedCmp(0, res_i64, m_ir_builder->getInt64(0)); } //InterpreterCall("RLDICL", &PPUInterpreter::RLDICL, ra, rs, sh, mb, rc); } void Compiler::RLDICR(u32 ra, u32 rs, u32 sh, u32 me, bool rc) { auto rs_i64 = GetGpr(rs); auto res_i64 = rs_i64; if (sh) { auto resl_i64 = m_ir_builder->CreateLShr(rs_i64, 64 - sh); auto resh_i64 = m_ir_builder->CreateShl(rs_i64, sh); res_i64 = m_ir_builder->CreateOr(resh_i64, resl_i64); } res_i64 = m_ir_builder->CreateAnd(res_i64, s_rotate_mask[0][me]); SetGpr(ra, res_i64); if (rc) { SetCrFieldSignedCmp(0, res_i64, m_ir_builder->getInt64(0)); } //InterpreterCall("RLDICR", &PPUInterpreter::RLDICR, ra, rs, sh, me, rc); } void Compiler::RLDIC(u32 ra, u32 rs, u32 sh, u32 mb, bool rc) { auto rs_i64 = GetGpr(rs); auto res_i64 = rs_i64; if (sh) { auto resl_i64 = m_ir_builder->CreateLShr(rs_i64, 64 - sh); auto resh_i64 = m_ir_builder->CreateShl(rs_i64, sh); res_i64 = m_ir_builder->CreateOr(resh_i64, resl_i64); } res_i64 = m_ir_builder->CreateAnd(res_i64, s_rotate_mask[mb][63 - sh]); SetGpr(ra, res_i64); if (rc) { SetCrFieldSignedCmp(0, res_i64, m_ir_builder->getInt64(0)); } //InterpreterCall("RLDIC", &PPUInterpreter::RLDIC, ra, rs, sh, mb, rc); } void Compiler::RLDIMI(u32 ra, u32 rs, u32 sh, u32 mb, bool rc) { auto rs_i64 = GetGpr(rs); auto ra_i64 = GetGpr(ra); auto res_i64 = rs_i64; if (sh) { auto resl_i64 = m_ir_builder->CreateLShr(rs_i64, 64 - sh); auto resh_i64 = m_ir_builder->CreateShl(rs_i64, sh); res_i64 = m_ir_builder->CreateOr(resh_i64, resl_i64); } u64 mask = s_rotate_mask[mb][63 - sh]; res_i64 = m_ir_builder->CreateAnd(res_i64, mask); ra_i64 = m_ir_builder->CreateAnd(ra_i64, ~mask); res_i64 = m_ir_builder->CreateOr(res_i64, ra_i64); SetGpr(ra, res_i64); if (rc) { SetCrFieldSignedCmp(0, res_i64, m_ir_builder->getInt64(0)); } //InterpreterCall("RLDIMI", &PPUInterpreter::RLDIMI, ra, rs, sh, mb, rc); } void Compiler::RLDC_LR(u32 ra, u32 rs, u32 rb, u32 m_eb, bool is_r, bool rc) { auto rs_i64 = GetGpr(rs); auto rb_i64 = GetGpr(rb); auto shl_i64 = m_ir_builder->CreateAnd(rb_i64, 0x3F); auto shr_i64 = m_ir_builder->CreateSub(m_ir_builder->getInt64(64), shl_i64); auto resl_i64 = m_ir_builder->CreateLShr(rs_i64, shr_i64); auto resh_i64 = m_ir_builder->CreateShl(rs_i64, shl_i64); auto res_i64 = m_ir_builder->CreateOr(resh_i64, resl_i64); if (is_r) { res_i64 = m_ir_builder->CreateAnd(res_i64, s_rotate_mask[0][m_eb]); } else { res_i64 = m_ir_builder->CreateAnd(res_i64, s_rotate_mask[m_eb][63]); } SetGpr(ra, res_i64); if (rc) { SetCrFieldSignedCmp(0, res_i64, m_ir_builder->getInt64(0)); } //InterpreterCall("RLDC_LR", &PPUInterpreter::RLDC_LR, ra, rs, rb, m_eb, is_r, rc); } void Compiler::CMP(u32 crfd, u32 l, u32 ra, u32 rb) { Value * ra_i64; Value * rb_i64; if (l == 0) { ra_i64 = m_ir_builder->CreateSExt(GetGpr(ra, 32), m_ir_builder->getInt64Ty()); rb_i64 = m_ir_builder->CreateSExt(GetGpr(rb, 32), m_ir_builder->getInt64Ty()); } else { ra_i64 = GetGpr(ra); rb_i64 = GetGpr(rb); } SetCrFieldSignedCmp(crfd, ra_i64, rb_i64); //InterpreterCall("CMP", &PPUInterpreter::CMP, crfd, l, ra, rb); } void Compiler::TW(u32 to, u32 ra, u32 rb) { InterpreterCall("TW", &PPUInterpreter::TW, to, ra, rb); } void Compiler::LVSL(u32 vd, u32 ra, u32 rb) { static const u128 s_lvsl_values[] = { {0x08090A0B0C0D0E0F, 0x0001020304050607}, {0x090A0B0C0D0E0F10, 0x0102030405060708}, {0x0A0B0C0D0E0F1011, 0x0203040506070809}, {0x0B0C0D0E0F101112, 0x030405060708090A}, {0x0C0D0E0F10111213, 0x0405060708090A0B}, {0x0D0E0F1011121314, 0x05060708090A0B0C}, {0x0E0F101112131415, 0x060708090A0B0C0D}, {0x0F10111213141516, 0x0708090A0B0C0D0E}, {0x1011121314151617, 0x08090A0B0C0D0E0F}, {0x1112131415161718, 0x090A0B0C0D0E0F10}, {0x1213141516171819, 0x0A0B0C0D0E0F1011}, {0x131415161718191A, 0x0B0C0D0E0F101112}, {0x1415161718191A1B, 0x0C0D0E0F10111213}, {0x15161718191A1B1C, 0x0D0E0F1011121314}, {0x161718191A1B1C1D, 0x0E0F101112131415}, {0x1718191A1B1C1D1E, 0x0F10111213141516}, }; auto addr_i64 = GetGpr(rb); if (ra) { auto ra_i64 = GetGpr(ra); addr_i64 = m_ir_builder->CreateAdd(ra_i64, addr_i64); } auto index_i64 = m_ir_builder->CreateAnd(addr_i64, 0xF); auto lvsl_values_v16i8_ptr = m_ir_builder->CreateIntToPtr(m_ir_builder->getInt64((u64)s_lvsl_values), VectorType::get(m_ir_builder->getInt8Ty(), 16)->getPointerTo()); lvsl_values_v16i8_ptr = m_ir_builder->CreateGEP(lvsl_values_v16i8_ptr, index_i64); auto val_v16i8 = m_ir_builder->CreateAlignedLoad(lvsl_values_v16i8_ptr, 16); SetVr(vd, val_v16i8); //InterpreterCall("LVSL", &PPUInterpreter::LVSL, vd, ra, rb); } void Compiler::LVEBX(u32 vd, u32 ra, u32 rb) { auto addr_i64 = GetGpr(rb); if (ra) { auto ra_i64 = GetGpr(ra); addr_i64 = m_ir_builder->CreateAdd(ra_i64, addr_i64); } auto val_i8 = ReadMemory(addr_i64, 8); auto index_i64 = m_ir_builder->CreateAnd(addr_i64, 0xf); index_i64 = m_ir_builder->CreateSub(m_ir_builder->getInt64(15), index_i64); auto vd_v16i8 = GetVrAsIntVec(vd, 8); vd_v16i8 = m_ir_builder->CreateInsertElement(vd_v16i8, val_i8, index_i64); SetVr(vd, vd_v16i8); //InterpreterCall("LVEBX", &PPUInterpreter::LVEBX, vd, ra, rb); } void Compiler::SUBFC(u32 rd, u32 ra, u32 rb, u32 oe, bool rc) { auto ra_i64 = GetGpr(ra); ra_i64 = m_ir_builder->CreateNeg(ra_i64); auto rb_i64 = GetGpr(rb); auto res_s = m_ir_builder->CreateCall2(Intrinsic::getDeclaration(m_module, Intrinsic::uadd_with_overflow, m_ir_builder->getInt64Ty()), ra_i64, rb_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); if (rc) { SetCrFieldSignedCmp(0, diff_i64, m_ir_builder->getInt64(0)); } if (oe) { // TODO: Implement this } //InterpreterCall("SUBFC", &PPUInterpreter::SUBFC, rd, ra, rb, oe, rc); } void Compiler::ADDC(u32 rd, u32 ra, u32 rb, u32 oe, bool rc) { auto ra_i64 = GetGpr(ra); auto rb_i64 = GetGpr(rb); auto res_s = m_ir_builder->CreateCall2(Intrinsic::getDeclaration(m_module, Intrinsic::uadd_with_overflow, m_ir_builder->getInt64Ty()), ra_i64, rb_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); if (rc) { SetCrFieldSignedCmp(0, sum_i64, m_ir_builder->getInt64(0)); } if (oe) { // TODO: Implement this } //InterpreterCall("ADDC", &PPUInterpreter::ADDC, rd, ra, rb, oe, rc); } void Compiler::MULHDU(u32 rd, u32 ra, u32 rb, bool rc) { auto ra_i64 = GetGpr(ra); auto rb_i64 = GetGpr(rb); auto ra_i128 = m_ir_builder->CreateZExt(ra_i64, m_ir_builder->getIntNTy(128)); auto rb_i128 = m_ir_builder->CreateZExt(rb_i64, m_ir_builder->getIntNTy(128)); auto prod_i128 = m_ir_builder->CreateMul(ra_i128, rb_i128); prod_i128 = m_ir_builder->CreateLShr(prod_i128, 64); auto prod_i64 = m_ir_builder->CreateTrunc(prod_i128, m_ir_builder->getInt64Ty()); SetGpr(rd, prod_i64); if (rc) { SetCrFieldSignedCmp(0, prod_i64, m_ir_builder->getInt64(0)); } //InterpreterCall("MULHDU", &PPUInterpreter::MULHDU, rd, ra, rb, rc); } void Compiler::MULHWU(u32 rd, u32 ra, u32 rb, bool rc) { auto ra_i32 = GetGpr(ra, 32); auto rb_i32 = GetGpr(rb, 32); auto ra_i64 = m_ir_builder->CreateZExt(ra_i32, m_ir_builder->getInt64Ty()); auto rb_i64 = m_ir_builder->CreateZExt(rb_i32, m_ir_builder->getInt64Ty()); auto prod_i64 = m_ir_builder->CreateMul(ra_i64, rb_i64); prod_i64 = m_ir_builder->CreateLShr(prod_i64, 32); SetGpr(rd, prod_i64); if (rc) { SetCrFieldSignedCmp(0, prod_i64, m_ir_builder->getInt64(0)); } //InterpreterCall("MULHWU", &PPUInterpreter::MULHWU, rd, ra, rb, rc); } void Compiler::MFOCRF(u32 a, u32 rd, u32 crm) { auto cr_i32 = GetCr(); auto cr_i64 = m_ir_builder->CreateZExt(cr_i32, m_ir_builder->getInt64Ty()); SetGpr(rd, cr_i64); //InterpreterCall("MFOCRF", &PPUInterpreter::MFOCRF, a, rd, crm); } void Compiler::LWARX(u32 rd, u32 ra, u32 rb) { auto addr_i64 = GetGpr(rb); if (ra) { auto ra_i64 = GetGpr(ra); addr_i64 = m_ir_builder->CreateAdd(ra_i64, addr_i64); } auto resv_addr_i8_ptr = m_ir_builder->CreateConstGEP1_32(m_state.args[CompileTaskState::Args::State], (unsigned int)offsetof(PPUThread, R_ADDR)); auto resv_addr_i64_ptr = m_ir_builder->CreateBitCast(resv_addr_i8_ptr, m_ir_builder->getInt64Ty()->getPointerTo()); m_ir_builder->CreateAlignedStore(addr_i64, resv_addr_i64_ptr, 8); auto resv_val_i32 = ReadMemory(addr_i64, 32, 4, false, false); auto resv_val_i64 = m_ir_builder->CreateZExt(resv_val_i32, m_ir_builder->getInt64Ty()); auto resv_val_i8_ptr = m_ir_builder->CreateConstGEP1_32(m_state.args[CompileTaskState::Args::State], (unsigned int)offsetof(PPUThread, R_VALUE)); auto resv_val_i64_ptr = m_ir_builder->CreateBitCast(resv_val_i8_ptr, m_ir_builder->getInt64Ty()->getPointerTo()); m_ir_builder->CreateAlignedStore(resv_val_i64, resv_val_i64_ptr, 8); resv_val_i32 = m_ir_builder->CreateCall(Intrinsic::getDeclaration(m_module, Intrinsic::bswap, m_ir_builder->getInt32Ty()), resv_val_i32); resv_val_i64 = m_ir_builder->CreateZExt(resv_val_i32, m_ir_builder->getInt64Ty()); SetGpr(rd, resv_val_i64); //InterpreterCall("LWARX", &PPUInterpreter::LWARX, rd, ra, rb); } void Compiler::LDX(u32 rd, u32 ra, u32 rb) { auto addr_i64 = GetGpr(rb); if (ra) { auto ra_i64 = GetGpr(ra); addr_i64 = m_ir_builder->CreateAdd(ra_i64, addr_i64); } auto mem_i64 = ReadMemory(addr_i64, 64); SetGpr(rd, mem_i64); //InterpreterCall("LDX", &PPUInterpreter::LDX, rd, ra, rb); } void Compiler::LWZX(u32 rd, u32 ra, u32 rb) { auto addr_i64 = GetGpr(rb); if (ra) { auto ra_i64 = GetGpr(ra); addr_i64 = m_ir_builder->CreateAdd(ra_i64, addr_i64); } auto mem_i32 = ReadMemory(addr_i64, 32); auto mem_i64 = m_ir_builder->CreateZExt(mem_i32, m_ir_builder->getInt64Ty()); SetGpr(rd, mem_i64); //InterpreterCall("LWZX", &PPUInterpreter::LWZX, rd, ra, rb); } void Compiler::SLW(u32 ra, u32 rs, u32 rb, bool rc) { auto rs_i32 = GetGpr(rs, 32); auto rs_i64 = m_ir_builder->CreateZExt(rs_i32, m_ir_builder->getInt64Ty()); auto rb_i8 = GetGpr(rb, 8); rb_i8 = m_ir_builder->CreateAnd(rb_i8, 0x3F); auto rb_i64 = m_ir_builder->CreateZExt(rb_i8, m_ir_builder->getInt64Ty()); auto res_i64 = m_ir_builder->CreateShl(rs_i64, rb_i64); auto res_i32 = m_ir_builder->CreateTrunc(res_i64, m_ir_builder->getInt32Ty()); res_i64 = m_ir_builder->CreateZExt(res_i32, m_ir_builder->getInt64Ty()); SetGpr(ra, res_i64); if (rc) { SetCrFieldSignedCmp(0, res_i64, m_ir_builder->getInt64(0)); } //InterpreterCall("SLW", &PPUInterpreter::SLW, ra, rs, rb, rc); } void Compiler::CNTLZW(u32 ra, u32 rs, bool rc) { auto rs_i32 = GetGpr(rs, 32); auto res_i32 = m_ir_builder->CreateCall2(Intrinsic::getDeclaration(m_module, Intrinsic::ctlz, m_ir_builder->getInt32Ty()), rs_i32, m_ir_builder->getInt1(false)); auto res_i64 = m_ir_builder->CreateZExt(res_i32, m_ir_builder->getInt64Ty()); SetGpr(ra, res_i64); if (rc) { SetCrFieldSignedCmp(0, res_i64, m_ir_builder->getInt64(0)); } //InterpreterCall("CNTLZW", &PPUInterpreter::CNTLZW, ra, rs, rc); } void Compiler::SLD(u32 ra, u32 rs, u32 rb, bool rc) { auto rs_i64 = GetGpr(rs); auto rs_i128 = m_ir_builder->CreateZExt(rs_i64, m_ir_builder->getIntNTy(128)); auto rb_i8 = GetGpr(rb, 8); rb_i8 = m_ir_builder->CreateAnd(rb_i8, 0x7F); auto rb_i128 = m_ir_builder->CreateZExt(rb_i8, m_ir_builder->getIntNTy(128)); auto res_i128 = m_ir_builder->CreateShl(rs_i128, rb_i128); auto res_i64 = m_ir_builder->CreateTrunc(res_i128, m_ir_builder->getInt64Ty()); SetGpr(ra, res_i64); if (rc) { SetCrFieldSignedCmp(0, res_i64, m_ir_builder->getInt64(0)); } //InterpreterCall("SLD", &PPUInterpreter::SLD, ra, rs, rb, rc); } void Compiler::AND(u32 ra, u32 rs, u32 rb, bool rc) { auto rs_i64 = GetGpr(rs); auto rb_i64 = GetGpr(rb); auto res_i64 = m_ir_builder->CreateAnd(rs_i64, rb_i64); SetGpr(ra, res_i64); if (rc) { SetCrFieldSignedCmp(0, res_i64, m_ir_builder->getInt64(0)); } //InterpreterCall("AND", &PPUInterpreter::AND, ra, rs, rb, rc); } void Compiler::CMPL(u32 crfd, u32 l, u32 ra, u32 rb) { Value * ra_i64; Value * rb_i64; if (l == 0) { ra_i64 = m_ir_builder->CreateZExt(GetGpr(ra, 32), m_ir_builder->getInt64Ty()); rb_i64 = m_ir_builder->CreateZExt(GetGpr(rb, 32), m_ir_builder->getInt64Ty()); } else { ra_i64 = GetGpr(ra); rb_i64 = GetGpr(rb); } SetCrFieldUnsignedCmp(crfd, ra_i64, rb_i64); //InterpreterCall("CMPL", &PPUInterpreter::CMPL, crfd, l, ra, rb); } void Compiler::LVSR(u32 vd, u32 ra, u32 rb) { static const u128 s_lvsr_values[] = { {0x18191A1B1C1D1E1F, 0x1011121314151617}, {0x1718191A1B1C1D1E, 0x0F10111213141516}, {0x161718191A1B1C1D, 0x0E0F101112131415}, {0x15161718191A1B1C, 0x0D0E0F1011121314}, {0x1415161718191A1B, 0x0C0D0E0F10111213}, {0x131415161718191A, 0x0B0C0D0E0F101112}, {0x1213141516171819, 0x0A0B0C0D0E0F1011}, {0x1112131415161718, 0x090A0B0C0D0E0F10}, {0x1011121314151617, 0x08090A0B0C0D0E0F}, {0x0F10111213141516, 0x0708090A0B0C0D0E}, {0x0E0F101112131415, 0x060708090A0B0C0D}, {0x0D0E0F1011121314, 0x05060708090A0B0C}, {0x0C0D0E0F10111213, 0x0405060708090A0B}, {0x0B0C0D0E0F101112, 0x030405060708090A}, {0x0A0B0C0D0E0F1011, 0x0203040506070809}, {0x090A0B0C0D0E0F10, 0x0102030405060708}, }; auto addr_i64 = GetGpr(rb); if (ra) { auto ra_i64 = GetGpr(ra); addr_i64 = m_ir_builder->CreateAdd(ra_i64, addr_i64); } auto index_i64 = m_ir_builder->CreateAnd(addr_i64, 0xF); auto lvsr_values_v16i8_ptr = m_ir_builder->CreateIntToPtr(m_ir_builder->getInt64((u64)s_lvsr_values), VectorType::get(m_ir_builder->getInt8Ty(), 16)->getPointerTo()); lvsr_values_v16i8_ptr = m_ir_builder->CreateGEP(lvsr_values_v16i8_ptr, index_i64); auto val_v16i8 = m_ir_builder->CreateAlignedLoad(lvsr_values_v16i8_ptr, 16); SetVr(vd, val_v16i8); //InterpreterCall("LVSR", &PPUInterpreter::LVSR, vd, ra, rb); } void Compiler::LVEHX(u32 vd, u32 ra, u32 rb) { auto addr_i64 = GetGpr(rb); if (ra) { auto ra_i64 = GetGpr(ra); addr_i64 = m_ir_builder->CreateAdd(ra_i64, addr_i64); } addr_i64 = m_ir_builder->CreateAnd(addr_i64, 0xFFFFFFFFFFFFFFFEULL); auto val_i16 = ReadMemory(addr_i64, 16, 2); auto index_i64 = m_ir_builder->CreateAnd(addr_i64, 0xf); index_i64 = m_ir_builder->CreateLShr(index_i64, 1); index_i64 = m_ir_builder->CreateSub(m_ir_builder->getInt64(7), index_i64); auto vd_v8i16 = GetVrAsIntVec(vd, 16); vd_v8i16 = m_ir_builder->CreateInsertElement(vd_v8i16, val_i16, index_i64); SetVr(vd, vd_v8i16); //InterpreterCall("LVEHX", &PPUInterpreter::LVEHX, vd, ra, rb); } void Compiler::SUBF(u32 rd, u32 ra, u32 rb, u32 oe, bool rc) { auto ra_i64 = GetGpr(ra); auto rb_i64 = GetGpr(rb); auto diff_i64 = m_ir_builder->CreateSub(rb_i64, ra_i64); SetGpr(rd, diff_i64); if (rc) { SetCrFieldSignedCmp(0, diff_i64, m_ir_builder->getInt64(0)); } if (oe) { // TODO: Implement this } //InterpreterCall("SUBF", &PPUInterpreter::SUBF, rd, ra, rb, oe, rc); } void Compiler::LDUX(u32 rd, u32 ra, u32 rb) { auto addr_i64 = GetGpr(rb); auto ra_i64 = GetGpr(ra); addr_i64 = m_ir_builder->CreateAdd(ra_i64, addr_i64); auto mem_i64 = ReadMemory(addr_i64, 64); SetGpr(rd, mem_i64); SetGpr(ra, addr_i64); //InterpreterCall("LDUX", &PPUInterpreter::LDUX, rd, ra, rb); } void Compiler::DCBST(u32 ra, u32 rb) { // TODO: Implement this m_ir_builder->CreateCall(Intrinsic::getDeclaration(m_module, Intrinsic::donothing)); //InterpreterCall("DCBST", &PPUInterpreter::DCBST, ra, rb); } void Compiler::LWZUX(u32 rd, u32 ra, u32 rb) { auto addr_i64 = GetGpr(rb); auto ra_i64 = GetGpr(ra); addr_i64 = m_ir_builder->CreateAdd(ra_i64, addr_i64); auto mem_i32 = ReadMemory(addr_i64, 32); auto mem_i64 = m_ir_builder->CreateZExt(mem_i32, m_ir_builder->getInt64Ty()); SetGpr(rd, mem_i64); SetGpr(ra, addr_i64); //InterpreterCall("LWZUX", &PPUInterpreter::LWZUX, rd, ra, rb); } void Compiler::CNTLZD(u32 ra, u32 rs, bool rc) { auto rs_i64 = GetGpr(rs); auto res_i64 = m_ir_builder->CreateCall2(Intrinsic::getDeclaration(m_module, Intrinsic::ctlz, m_ir_builder->getInt64Ty()), rs_i64, m_ir_builder->getInt1(false)); SetGpr(ra, res_i64); if (rc) { SetCrFieldSignedCmp(0, res_i64, m_ir_builder->getInt64(0)); } //InterpreterCall("CNTLZD", &PPUInterpreter::CNTLZD, ra, rs, rc); } void Compiler::ANDC(u32 ra, u32 rs, u32 rb, bool rc) { auto rs_i64 = GetGpr(rs); auto rb_i64 = GetGpr(rb); rb_i64 = m_ir_builder->CreateNot(rb_i64); auto res_i64 = m_ir_builder->CreateAnd(rs_i64, rb_i64); SetGpr(ra, res_i64); if (rc) { SetCrFieldSignedCmp(0, res_i64, m_ir_builder->getInt64(0)); } //InterpreterCall("ANDC", &PPUInterpreter::ANDC, ra, rs, rb, rc); } void Compiler::TD(u32 to, u32 ra, u32 rb) { InterpreterCall("TD", &PPUInterpreter::TD, to, ra, rb); } void Compiler::LVEWX(u32 vd, u32 ra, u32 rb) { auto addr_i64 = GetGpr(rb); if (ra) { auto ra_i64 = GetGpr(ra); addr_i64 = m_ir_builder->CreateAdd(ra_i64, addr_i64); } addr_i64 = m_ir_builder->CreateAnd(addr_i64, 0xFFFFFFFFFFFFFFFCULL); auto val_i32 = ReadMemory(addr_i64, 32, 4); auto index_i64 = m_ir_builder->CreateAnd(addr_i64, 0xf); index_i64 = m_ir_builder->CreateLShr(index_i64, 2); index_i64 = m_ir_builder->CreateSub(m_ir_builder->getInt64(3), index_i64); auto vd_v4i32 = GetVrAsIntVec(vd, 32); vd_v4i32 = m_ir_builder->CreateInsertElement(vd_v4i32, val_i32, index_i64); SetVr(vd, vd_v4i32); //InterpreterCall("LVEWX", &PPUInterpreter::LVEWX, vd, ra, rb); } void Compiler::MULHD(u32 rd, u32 ra, u32 rb, bool rc) { auto ra_i64 = GetGpr(ra); auto rb_i64 = GetGpr(rb); auto ra_i128 = m_ir_builder->CreateSExt(ra_i64, m_ir_builder->getIntNTy(128)); auto rb_i128 = m_ir_builder->CreateSExt(rb_i64, m_ir_builder->getIntNTy(128)); auto prod_i128 = m_ir_builder->CreateMul(ra_i128, rb_i128); prod_i128 = m_ir_builder->CreateLShr(prod_i128, 64); auto prod_i64 = m_ir_builder->CreateTrunc(prod_i128, m_ir_builder->getInt64Ty()); SetGpr(rd, prod_i64); if (rc) { SetCrFieldSignedCmp(0, prod_i64, m_ir_builder->getInt64(0)); } //InterpreterCall("MULHD", &PPUInterpreter::MULHD, rd, ra, rb, rc); } void Compiler::MULHW(u32 rd, u32 ra, u32 rb, bool rc) { auto ra_i32 = GetGpr(ra, 32); auto rb_i32 = GetGpr(rb, 32); auto ra_i64 = m_ir_builder->CreateSExt(ra_i32, m_ir_builder->getInt64Ty()); auto rb_i64 = m_ir_builder->CreateSExt(rb_i32, m_ir_builder->getInt64Ty()); auto prod_i64 = m_ir_builder->CreateMul(ra_i64, rb_i64); prod_i64 = m_ir_builder->CreateAShr(prod_i64, 32); SetGpr(rd, prod_i64); if (rc) { SetCrFieldSignedCmp(0, prod_i64, m_ir_builder->getInt64(0)); } //InterpreterCall("MULHW", &PPUInterpreter::MULHW, rd, ra, rb, rc); } void Compiler::LDARX(u32 rd, u32 ra, u32 rb) { auto addr_i64 = GetGpr(rb); if (ra) { auto ra_i64 = GetGpr(ra); addr_i64 = m_ir_builder->CreateAdd(ra_i64, addr_i64); } auto resv_addr_i8_ptr = m_ir_builder->CreateConstGEP1_32(m_state.args[CompileTaskState::Args::State], (unsigned int)offsetof(PPUThread, R_ADDR)); auto resv_addr_i64_ptr = m_ir_builder->CreateBitCast(resv_addr_i8_ptr, m_ir_builder->getInt64Ty()->getPointerTo()); m_ir_builder->CreateAlignedStore(addr_i64, resv_addr_i64_ptr, 8); auto resv_val_i64 = ReadMemory(addr_i64, 64, 8, false); auto resv_val_i8_ptr = m_ir_builder->CreateConstGEP1_32(m_state.args[CompileTaskState::Args::State], (unsigned int)offsetof(PPUThread, R_VALUE)); auto resv_val_i64_ptr = m_ir_builder->CreateBitCast(resv_val_i8_ptr, m_ir_builder->getInt64Ty()->getPointerTo()); m_ir_builder->CreateAlignedStore(resv_val_i64, resv_val_i64_ptr, 8); resv_val_i64 = m_ir_builder->CreateCall(Intrinsic::getDeclaration(m_module, Intrinsic::bswap, m_ir_builder->getInt64Ty()), resv_val_i64); SetGpr(rd, resv_val_i64); //InterpreterCall("LDARX", &PPUInterpreter::LDARX, rd, ra, rb); } void Compiler::DCBF(u32 ra, u32 rb) { // TODO: Implement this m_ir_builder->CreateCall(Intrinsic::getDeclaration(m_module, Intrinsic::donothing)); //InterpreterCall("DCBF", &PPUInterpreter::DCBF, ra, rb); } void Compiler::LBZX(u32 rd, u32 ra, u32 rb) { auto addr_i64 = GetGpr(rb); if (ra) { auto ra_i64 = GetGpr(ra); addr_i64 = m_ir_builder->CreateAdd(ra_i64, addr_i64); } auto mem_i8 = ReadMemory(addr_i64, 8); auto mem_i64 = m_ir_builder->CreateZExt(mem_i8, m_ir_builder->getInt64Ty()); SetGpr(rd, mem_i64); //InterpreterCall("LBZX", &PPUInterpreter::LBZX, rd, ra, rb); } void Compiler::LVX(u32 vd, u32 ra, u32 rb) { auto addr_i64 = GetGpr(rb); if (ra) { auto ra_i64 = GetGpr(ra); addr_i64 = m_ir_builder->CreateAdd(ra_i64, addr_i64); } addr_i64 = m_ir_builder->CreateAnd(addr_i64, 0xFFFFFFFFFFFFFFF0ULL); auto mem_i128 = ReadMemory(addr_i64, 128, 16); SetVr(vd, mem_i128); //InterpreterCall("LVX", &PPUInterpreter::LVX, vd, ra, rb); } void Compiler::NEG(u32 rd, u32 ra, u32 oe, bool rc) { auto ra_i64 = GetGpr(ra); auto diff_i64 = m_ir_builder->CreateSub(m_ir_builder->getInt64(0), ra_i64); SetGpr(rd, diff_i64); if (rc) { SetCrFieldSignedCmp(0, diff_i64, m_ir_builder->getInt64(0)); } if (oe) { // TODO: Implement this } //InterpreterCall("NEG", &PPUInterpreter::NEG, rd, ra, oe, rc); } void Compiler::LBZUX(u32 rd, u32 ra, u32 rb) { auto addr_i64 = GetGpr(rb); auto ra_i64 = GetGpr(ra); addr_i64 = m_ir_builder->CreateAdd(ra_i64, addr_i64); auto mem_i8 = ReadMemory(addr_i64, 8); auto mem_i64 = m_ir_builder->CreateZExt(mem_i8, m_ir_builder->getInt64Ty()); SetGpr(rd, mem_i64); SetGpr(ra, addr_i64); //InterpreterCall("LBZUX", &PPUInterpreter::LBZUX, rd, ra, rb); } void Compiler::NOR(u32 ra, u32 rs, u32 rb, bool rc) { auto rs_i64 = GetGpr(rs); auto rb_i64 = GetGpr(rb); auto res_i64 = m_ir_builder->CreateOr(rs_i64, rb_i64); res_i64 = m_ir_builder->CreateXor(res_i64, (s64)-1); SetGpr(ra, res_i64); if (rc) { SetCrFieldSignedCmp(0, res_i64, m_ir_builder->getInt64(0)); } //InterpreterCall("NOR", &PPUInterpreter::NOR, ra, rs, rb, rc); } void Compiler::STVEBX(u32 vs, u32 ra, u32 rb) { auto addr_i64 = GetGpr(rb); if (ra) { auto ra_i64 = GetGpr(ra); addr_i64 = m_ir_builder->CreateAdd(ra_i64, addr_i64); } auto index_i64 = m_ir_builder->CreateAnd(addr_i64, 0xf); index_i64 = m_ir_builder->CreateSub(m_ir_builder->getInt64(15), index_i64); auto vs_v16i8 = GetVrAsIntVec(vs, 8); auto val_i8 = m_ir_builder->CreateExtractElement(vs_v16i8, index_i64); WriteMemory(addr_i64, val_i8); //InterpreterCall("STVEBX", &PPUInterpreter::STVEBX, vs, ra, rb); } void Compiler::SUBFE(u32 rd, u32 ra, u32 rb, u32 oe, bool rc) { InterpreterCall("SUBFE", &PPUInterpreter::SUBFE, rd, ra, rb, oe, rc); } void Compiler::ADDE(u32 rd, u32 ra, u32 rb, u32 oe, bool rc) { InterpreterCall("ADDE", &PPUInterpreter::ADDE, rd, ra, rb, oe, rc); } void Compiler::MTOCRF(u32 l, u32 crm, u32 rs) { auto rs_i32 = GetGpr(rs, 32); auto cr_i32 = GetCr(); u32 mask = 0; for (u32 i = 0; i < 8; i++) { if (crm & (1 << i)) { mask |= 0xF << ((7 - i) * 4); if (l) { break; } } } cr_i32 = m_ir_builder->CreateAnd(cr_i32, ~mask); rs_i32 = m_ir_builder->CreateAnd(rs_i32, ~mask); cr_i32 = m_ir_builder->CreateOr(cr_i32, rs_i32); SetCr(cr_i32); //InterpreterCall("MTOCRF", &PPUInterpreter::MTOCRF, l, crm, rs); } void Compiler::STDX(u32 rs, u32 ra, u32 rb) { auto addr_i64 = GetGpr(rb); if (ra) { auto ra_i64 = GetGpr(ra); addr_i64 = m_ir_builder->CreateAdd(ra_i64, addr_i64); } WriteMemory(addr_i64, GetGpr(rs, 64)); //InterpreterCall("STDX", &PPUInterpreter::STDX, rs, ra, rb); } void Compiler::STWCX_(u32 rs, u32 ra, u32 rb) { InterpreterCall("STWCX_", &PPUInterpreter::STWCX_, rs, ra, rb); } void Compiler::STWX(u32 rs, u32 ra, u32 rb) { auto addr_i64 = GetGpr(rb); if (ra) { auto ra_i64 = GetGpr(ra); addr_i64 = m_ir_builder->CreateAdd(ra_i64, addr_i64); } WriteMemory(addr_i64, GetGpr(rs, 32)); //InterpreterCall("STWX", &PPUInterpreter::STWX, rs, ra, rb); } void Compiler::STVEHX(u32 vs, u32 ra, u32 rb) { auto addr_i64 = GetGpr(rb); if (ra) { auto ra_i64 = GetGpr(ra); addr_i64 = m_ir_builder->CreateAdd(ra_i64, addr_i64); } addr_i64 = m_ir_builder->CreateAnd(addr_i64, 0xFFFFFFFFFFFFFFFEULL); auto index_i64 = m_ir_builder->CreateAnd(addr_i64, 0xf); index_i64 = m_ir_builder->CreateLShr(index_i64, 1); index_i64 = m_ir_builder->CreateSub(m_ir_builder->getInt64(7), index_i64); auto vs_v8i16 = GetVrAsIntVec(vs, 16); auto val_i16 = m_ir_builder->CreateExtractElement(vs_v8i16, index_i64); WriteMemory(addr_i64, val_i16, 2); //InterpreterCall("STVEHX", &PPUInterpreter::STVEHX, vs, ra, rb); } void Compiler::STDUX(u32 rs, u32 ra, u32 rb) { auto addr_i64 = GetGpr(rb); auto ra_i64 = GetGpr(ra); addr_i64 = m_ir_builder->CreateAdd(ra_i64, addr_i64); WriteMemory(addr_i64, GetGpr(rs, 64)); SetGpr(ra, addr_i64); //InterpreterCall("STDUX", &PPUInterpreter::STDUX, rs, ra, rb); } void Compiler::STWUX(u32 rs, u32 ra, u32 rb) { auto addr_i64 = GetGpr(rb); auto ra_i64 = GetGpr(ra); addr_i64 = m_ir_builder->CreateAdd(ra_i64, addr_i64); WriteMemory(addr_i64, GetGpr(rs, 32)); SetGpr(ra, addr_i64); //InterpreterCall("STWUX", &PPUInterpreter::STWUX, rs, ra, rb); } void Compiler::STVEWX(u32 vs, u32 ra, u32 rb) { auto addr_i64 = GetGpr(rb); if (ra) { auto ra_i64 = GetGpr(ra); addr_i64 = m_ir_builder->CreateAdd(ra_i64, addr_i64); } addr_i64 = m_ir_builder->CreateAnd(addr_i64, 0xFFFFFFFFFFFFFFFCULL); auto index_i64 = m_ir_builder->CreateAnd(addr_i64, 0xf); index_i64 = m_ir_builder->CreateLShr(index_i64, 2); index_i64 = m_ir_builder->CreateSub(m_ir_builder->getInt64(3), index_i64); auto vs_v4i32 = GetVrAsIntVec(vs, 32); auto val_i32 = m_ir_builder->CreateExtractElement(vs_v4i32, index_i64); WriteMemory(addr_i64, val_i32, 4); //InterpreterCall("STVEWX", &PPUInterpreter::STVEWX, vs, ra, rb); } void Compiler::ADDZE(u32 rd, u32 ra, u32 oe, bool rc) { auto ra_i64 = GetGpr(ra); auto ca_i64 = GetXerCa(); auto res_s = m_ir_builder->CreateCall2(Intrinsic::getDeclaration(m_module, Intrinsic::uadd_with_overflow, m_ir_builder->getInt64Ty()), ra_i64, ca_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); if (rc) { SetCrFieldSignedCmp(0, sum_i64, m_ir_builder->getInt64(0)); } //InterpreterCall("ADDZE", &PPUInterpreter::ADDZE, rd, ra, oe, rc); } void Compiler::SUBFZE(u32 rd, u32 ra, u32 oe, bool rc) { InterpreterCall("SUBFZE", &PPUInterpreter::SUBFZE, rd, ra, oe, rc); } void Compiler::STDCX_(u32 rs, u32 ra, u32 rb) { InterpreterCall("STDCX_", &PPUInterpreter::STDCX_, rs, ra, rb); } void Compiler::STBX(u32 rs, u32 ra, u32 rb) { auto addr_i64 = GetGpr(rb); if (ra) { auto ra_i64 = GetGpr(ra); addr_i64 = m_ir_builder->CreateAdd(ra_i64, addr_i64); } WriteMemory(addr_i64, GetGpr(rs, 8)); //InterpreterCall("STBX", &PPUInterpreter::STBX, rs, ra, rb); } void Compiler::STVX(u32 vs, u32 ra, u32 rb) { auto addr_i64 = GetGpr(rb); if (ra) { auto ra_i64 = GetGpr(ra); addr_i64 = m_ir_builder->CreateAdd(ra_i64, addr_i64); } addr_i64 = m_ir_builder->CreateAnd(addr_i64, 0xFFFFFFFFFFFFFFF0ULL); WriteMemory(addr_i64, GetVr(vs), 16); //InterpreterCall("STVX", &PPUInterpreter::STVX, vs, ra, rb); } void Compiler::SUBFME(u32 rd, u32 ra, u32 oe, bool rc) { InterpreterCall("SUBFME", &PPUInterpreter::SUBFME, rd, ra, oe, rc); } void Compiler::MULLD(u32 rd, u32 ra, u32 rb, u32 oe, bool rc) { auto ra_i64 = GetGpr(ra); auto rb_i64 = GetGpr(rb); auto prod_i64 = m_ir_builder->CreateMul(ra_i64, rb_i64); SetGpr(rd, prod_i64); if (rc) { SetCrFieldSignedCmp(0, prod_i64, m_ir_builder->getInt64(0)); } // TODO implement oe //InterpreterCall("MULLD", &PPUInterpreter::MULLD, rd, ra, rb, oe, rc); } void Compiler::ADDME(u32 rd, u32 ra, u32 oe, bool rc) { InterpreterCall("ADDME", &PPUInterpreter::ADDME, rd, ra, oe, rc); } void Compiler::MULLW(u32 rd, u32 ra, u32 rb, u32 oe, bool rc) { auto ra_i32 = GetGpr(ra, 32); auto rb_i32 = GetGpr(rb, 32); auto ra_i64 = m_ir_builder->CreateSExt(ra_i32, m_ir_builder->getInt64Ty()); auto rb_i64 = m_ir_builder->CreateSExt(rb_i32, m_ir_builder->getInt64Ty()); auto prod_i64 = m_ir_builder->CreateMul(ra_i64, rb_i64); SetGpr(rd, prod_i64); if (rc) { SetCrFieldSignedCmp(0, prod_i64, m_ir_builder->getInt64(0)); } // TODO implement oe //InterpreterCall("MULLW", &PPUInterpreter::MULLW, rd, ra, rb, oe, rc); } void Compiler::DCBTST(u32 ra, u32 rb, u32 th) { // TODO: Implement this m_ir_builder->CreateCall(Intrinsic::getDeclaration(m_module, Intrinsic::donothing)); //InterpreterCall("DCBTST", &PPUInterpreter::DCBTST, ra, rb, th); } void Compiler::STBUX(u32 rs, u32 ra, u32 rb) { auto addr_i64 = GetGpr(rb); auto ra_i64 = GetGpr(ra); addr_i64 = m_ir_builder->CreateAdd(ra_i64, addr_i64); WriteMemory(addr_i64, GetGpr(rs, 8)); SetGpr(ra, addr_i64); //InterpreterCall("STBUX", &PPUInterpreter::STBUX, rs, ra, rb); } void Compiler::ADD(u32 rd, u32 ra, u32 rb, u32 oe, bool rc) { auto ra_i64 = GetGpr(ra); auto rb_i64 = GetGpr(rb); auto sum_i64 = m_ir_builder->CreateAdd(ra_i64, rb_i64); SetGpr(rd, sum_i64); if (rc) { SetCrFieldSignedCmp(0, sum_i64, m_ir_builder->getInt64(0)); } if (oe) { // TODO: Implement this } //InterpreterCall("ADD", &PPUInterpreter::ADD, rd, ra, rb, oe, rc); } void Compiler::DCBT(u32 ra, u32 rb, u32 th) { // TODO: Implement this using prefetch m_ir_builder->CreateCall(Intrinsic::getDeclaration(m_module, Intrinsic::donothing)); //InterpreterCall("DCBT", &PPUInterpreter::DCBT, ra, rb, th); } void Compiler::LHZX(u32 rd, u32 ra, u32 rb) { auto addr_i64 = GetGpr(rb); if (ra) { auto ra_i64 = GetGpr(ra); addr_i64 = m_ir_builder->CreateAdd(ra_i64, addr_i64); } auto mem_i16 = ReadMemory(addr_i64, 16); auto mem_i64 = m_ir_builder->CreateZExt(mem_i16, m_ir_builder->getInt64Ty()); SetGpr(rd, mem_i64); //InterpreterCall("LHZX", &PPUInterpreter::LHZX, rd, ra, rb); } void Compiler::EQV(u32 ra, u32 rs, u32 rb, bool rc) { InterpreterCall("EQV", &PPUInterpreter::EQV, ra, rs, rb, rc); } void Compiler::ECIWX(u32 rd, u32 ra, u32 rb) { InterpreterCall("ECIWX", &PPUInterpreter::ECIWX, rd, ra, rb); } void Compiler::LHZUX(u32 rd, u32 ra, u32 rb) { auto addr_i64 = GetGpr(rb); auto ra_i64 = GetGpr(ra); addr_i64 = m_ir_builder->CreateAdd(ra_i64, addr_i64); auto mem_i16 = ReadMemory(addr_i64, 16); auto mem_i64 = m_ir_builder->CreateZExt(mem_i16, m_ir_builder->getInt64Ty()); SetGpr(rd, mem_i64); SetGpr(ra, addr_i64); //InterpreterCall("LHZUX", &PPUInterpreter::LHZUX, rd, ra, rb); } void Compiler::XOR(u32 ra, u32 rs, u32 rb, bool rc) { auto rs_i64 = GetGpr(rs); auto rb_i64 = GetGpr(rb); auto res_i64 = m_ir_builder->CreateXor(rs_i64, rb_i64); SetGpr(ra, res_i64); if (rc) { SetCrFieldSignedCmp(0, res_i64, m_ir_builder->getInt64(0)); } //InterpreterCall("XOR", &PPUInterpreter::XOR, ra, rs, rb, rc); } void Compiler::MFSPR(u32 rd, u32 spr) { Value * rd_i64; auto n = (spr >> 5) | ((spr & 0x1f) << 5); switch (n) { case 0x001: rd_i64 = GetXer(); break; case 0x008: rd_i64 = GetLr(); break; case 0x009: rd_i64 = GetCtr(); break; case 0x100: rd_i64 = GetUsprg0(); break; case 0x10C: rd_i64 = Call("get_time", get_time); break; case 0x10D: rd_i64 = Call("get_time", get_time); rd_i64 = m_ir_builder->CreateLShr(rd_i64, 32); break; default: assert(0); break; } SetGpr(rd, rd_i64); //InterpreterCall("MFSPR", &PPUInterpreter::MFSPR, rd, spr); } void Compiler::LWAX(u32 rd, u32 ra, u32 rb) { auto addr_i64 = GetGpr(rb); if (ra) { auto ra_i64 = GetGpr(ra); addr_i64 = m_ir_builder->CreateAdd(ra_i64, addr_i64); } auto mem_i32 = ReadMemory(addr_i64, 32); auto mem_i64 = m_ir_builder->CreateSExt(mem_i32, m_ir_builder->getInt64Ty()); SetGpr(rd, mem_i64); //InterpreterCall("LWAX", &PPUInterpreter::LWAX, rd, ra, rb); } void Compiler::DST(u32 ra, u32 rb, u32 strm, u32 t) { InterpreterCall("DST", &PPUInterpreter::DST, ra, rb, strm, t); } void Compiler::LHAX(u32 rd, u32 ra, u32 rb) { auto addr_i64 = GetGpr(rb); if (ra) { auto ra_i64 = GetGpr(ra); addr_i64 = m_ir_builder->CreateAdd(ra_i64, addr_i64); } auto mem_i16 = ReadMemory(addr_i64, 16); auto mem_i64 = m_ir_builder->CreateSExt(mem_i16, m_ir_builder->getInt64Ty()); SetGpr(rd, mem_i64); //InterpreterCall("LHAX", &PPUInterpreter::LHAX, rd, ra, rb); } void Compiler::LVXL(u32 vd, u32 ra, u32 rb) { LVX(vd, ra, rb); //InterpreterCall("LVXL", &PPUInterpreter::LVXL, vd, ra, rb); } void Compiler::MFTB(u32 rd, u32 spr) { auto tb_i64 = Call("get_time", get_time); u32 n = (spr >> 5) | ((spr & 0x1f) << 5); if (n == 0x10D) { tb_i64 = m_ir_builder->CreateLShr(tb_i64, 32); } SetGpr(rd, tb_i64); } void Compiler::LWAUX(u32 rd, u32 ra, u32 rb) { auto addr_i64 = GetGpr(rb); auto ra_i64 = GetGpr(ra); addr_i64 = m_ir_builder->CreateAdd(ra_i64, addr_i64); auto mem_i32 = ReadMemory(addr_i64, 32); auto mem_i64 = m_ir_builder->CreateSExt(mem_i32, m_ir_builder->getInt64Ty()); SetGpr(rd, mem_i64); SetGpr(ra, addr_i64); //InterpreterCall("LWAUX", &PPUInterpreter::LWAUX, rd, ra, rb); } void Compiler::DSTST(u32 ra, u32 rb, u32 strm, u32 t) { InterpreterCall("DSTST", &PPUInterpreter::DSTST, ra, rb, strm, t); } void Compiler::LHAUX(u32 rd, u32 ra, u32 rb) { auto addr_i64 = GetGpr(rb); auto ra_i64 = GetGpr(ra); addr_i64 = m_ir_builder->CreateAdd(ra_i64, addr_i64); auto mem_i16 = ReadMemory(addr_i64, 16); auto mem_i64 = m_ir_builder->CreateSExt(mem_i16, m_ir_builder->getInt64Ty()); SetGpr(rd, mem_i64); SetGpr(ra, addr_i64); //InterpreterCall("LHAUX", &PPUInterpreter::LHAUX, rd, ra, rb); } void Compiler::STHX(u32 rs, u32 ra, u32 rb) { auto addr_i64 = GetGpr(rb); if (ra) { auto ra_i64 = GetGpr(ra); addr_i64 = m_ir_builder->CreateAdd(ra_i64, addr_i64); } WriteMemory(addr_i64, GetGpr(rs, 16)); //InterpreterCall("STHX", &PPUInterpreter::STHX, rs, ra, rb); } void Compiler::ORC(u32 ra, u32 rs, u32 rb, bool rc) { InterpreterCall("ORC", &PPUInterpreter::ORC, ra, rs, rb, rc); } void Compiler::ECOWX(u32 rs, u32 ra, u32 rb) { InterpreterCall("ECOWX", &PPUInterpreter::ECOWX, rs, ra, rb); } void Compiler::STHUX(u32 rs, u32 ra, u32 rb) { auto addr_i64 = GetGpr(rb); auto ra_i64 = GetGpr(ra); addr_i64 = m_ir_builder->CreateAdd(ra_i64, addr_i64); WriteMemory(addr_i64, GetGpr(rs, 16)); SetGpr(ra, addr_i64); //InterpreterCall("STHUX", &PPUInterpreter::STHUX, rs, ra, rb); } void Compiler::OR(u32 ra, u32 rs, u32 rb, bool rc) { auto rs_i64 = GetGpr(rs); auto rb_i64 = GetGpr(rb); auto res_i64 = m_ir_builder->CreateOr(rs_i64, rb_i64); SetGpr(ra, res_i64); if (rc) { SetCrFieldSignedCmp(0, res_i64, m_ir_builder->getInt64(0)); } //InterpreterCall("OR", &PPUInterpreter::OR, ra, rs, rb, rc); } void Compiler::DIVDU(u32 rd, u32 ra, u32 rb, u32 oe, bool rc) { auto ra_i64 = GetGpr(ra); auto rb_i64 = GetGpr(rb); auto res_i64 = m_ir_builder->CreateUDiv(ra_i64, rb_i64); SetGpr(rd, res_i64); if (rc) { SetCrFieldSignedCmp(0, res_i64, m_ir_builder->getInt64(0)); } // TODO implement oe // TODO make sure an exception does not occur on divide by 0 and overflow //InterpreterCall("DIVDU", &PPUInterpreter::DIVDU, rd, ra, rb, oe, rc); } void Compiler::DIVWU(u32 rd, u32 ra, u32 rb, u32 oe, bool rc) { auto ra_i32 = GetGpr(ra, 32); auto rb_i32 = GetGpr(rb, 32); auto res_i32 = m_ir_builder->CreateUDiv(ra_i32, rb_i32); auto res_i64 = m_ir_builder->CreateZExt(res_i32, m_ir_builder->getInt64Ty()); SetGpr(rd, res_i64); if (rc) { SetCrFieldSignedCmp(0, res_i64, m_ir_builder->getInt64(0)); } // TODO implement oe // TODO make sure an exception does not occur on divide by 0 and overflow //InterpreterCall("DIVWU", &PPUInterpreter::DIVWU, rd, ra, rb, oe, rc); } void Compiler::MTSPR(u32 spr, u32 rs) { auto rs_i64 = GetGpr(rs); auto n = (spr >> 5) | ((spr & 0x1f) << 5); switch (n) { case 0x001: SetXer(rs_i64); break; case 0x008: SetLr(rs_i64); break; case 0x009: SetCtr(rs_i64); break; case 0x100: SetUsprg0(rs_i64); break; default: assert(0); break; } //InterpreterCall("MTSPR", &PPUInterpreter::MTSPR, spr, rs); } void Compiler::NAND(u32 ra, u32 rs, u32 rb, bool rc) { InterpreterCall("NAND", &PPUInterpreter::NAND, ra, rs, rb, rc); } void Compiler::STVXL(u32 vs, u32 ra, u32 rb) { STVX(vs, ra, rb); //InterpreterCall("STVXL", &PPUInterpreter::STVXL, vs, ra, rb); } void Compiler::DIVD(u32 rd, u32 ra, u32 rb, u32 oe, bool rc) { auto ra_i64 = GetGpr(ra); auto rb_i64 = GetGpr(rb); auto res_i64 = m_ir_builder->CreateSDiv(ra_i64, rb_i64); SetGpr(rd, res_i64); if (rc) { SetCrFieldSignedCmp(0, res_i64, m_ir_builder->getInt64(0)); } // TODO implement oe // TODO make sure an exception does not occur on divide by 0 and overflow //InterpreterCall("DIVD", &PPUInterpreter::DIVD, rd, ra, rb, oe, rc); } void Compiler::DIVW(u32 rd, u32 ra, u32 rb, u32 oe, bool rc) { auto ra_i32 = GetGpr(ra, 32); auto rb_i32 = GetGpr(rb, 32); auto res_i32 = m_ir_builder->CreateSDiv(ra_i32, rb_i32); auto res_i64 = m_ir_builder->CreateZExt(res_i32, m_ir_builder->getInt64Ty()); SetGpr(rd, res_i64); if (rc) { SetCrFieldSignedCmp(0, res_i64, m_ir_builder->getInt64(0)); } // TODO implement oe // TODO make sure an exception does not occur on divide by 0 and overflow //InterpreterCall("DIVW", &PPUInterpreter::DIVW, rd, ra, rb, oe, rc); } void Compiler::LVLX(u32 vd, u32 ra, u32 rb) { auto addr_i64 = GetGpr(rb); if (ra) { auto ra_i64 = GetGpr(ra); addr_i64 = m_ir_builder->CreateAdd(ra_i64, addr_i64); } auto eb_i64 = m_ir_builder->CreateAnd(addr_i64, 0xF); eb_i64 = m_ir_builder->CreateShl(eb_i64, 3); auto eb_i128 = m_ir_builder->CreateZExt(eb_i64, m_ir_builder->getIntNTy(128)); addr_i64 = m_ir_builder->CreateAnd(addr_i64, 0xFFFFFFFFFFFFFFF0ULL); auto mem_i128 = ReadMemory(addr_i64, 128, 16); mem_i128 = m_ir_builder->CreateShl(mem_i128, eb_i128); SetVr(vd, mem_i128); //InterpreterCall("LVLX", &PPUInterpreter::LVLX, vd, ra, rb); } void Compiler::LDBRX(u32 rd, u32 ra, u32 rb) { auto addr_i64 = GetGpr(rb); if (ra) { auto ra_i64 = GetGpr(ra); addr_i64 = m_ir_builder->CreateAdd(ra_i64, addr_i64); } auto mem_i64 = ReadMemory(addr_i64, 64, 0, false); SetGpr(rd, mem_i64); //InterpreterCall("LDBRX", &PPUInterpreter::LDBRX, rd, ra, rb); } void Compiler::LSWX(u32 rd, u32 ra, u32 rb) { InterpreterCall("LSWX", &PPUInterpreter::LSWX, rd, ra, rb); } void Compiler::LWBRX(u32 rd, u32 ra, u32 rb) { auto addr_i64 = GetGpr(rb); if (ra) { auto ra_i64 = GetGpr(ra); addr_i64 = m_ir_builder->CreateAdd(ra_i64, addr_i64); } auto mem_i32 = ReadMemory(addr_i64, 32, 0, false); auto mem_i64 = m_ir_builder->CreateZExt(mem_i32, m_ir_builder->getInt64Ty()); SetGpr(rd, mem_i64); //InterpreterCall("LWBRX", &PPUInterpreter::LWBRX, rd, ra, rb); } void Compiler::LFSX(u32 frd, u32 ra, u32 rb) { auto addr_i64 = GetGpr(rb); if (ra) { auto ra_i64 = GetGpr(ra); addr_i64 = m_ir_builder->CreateAdd(ra_i64, addr_i64); } auto mem_i32 = ReadMemory(addr_i64, 32); SetFpr(frd, mem_i32); //InterpreterCall("LFSX", &PPUInterpreter::LFSX, frd, ra, rb); } void Compiler::SRW(u32 ra, u32 rs, u32 rb, bool rc) { auto rs_i32 = GetGpr(rs, 32); auto rs_i64 = m_ir_builder->CreateZExt(rs_i32, m_ir_builder->getInt64Ty()); auto rb_i8 = GetGpr(rb, 8); rb_i8 = m_ir_builder->CreateAnd(rb_i8, 0x3F); auto rb_i64 = m_ir_builder->CreateZExt(rb_i8, m_ir_builder->getInt64Ty()); auto res_i64 = m_ir_builder->CreateLShr(rs_i64, rb_i64); SetGpr(ra, res_i64); if (rc) { SetCrFieldSignedCmp(0, res_i64, m_ir_builder->getInt64(0)); } //InterpreterCall("SRW", &PPUInterpreter::SRW, ra, rs, rb, rc); } void Compiler::SRD(u32 ra, u32 rs, u32 rb, bool rc) { auto rs_i64 = GetGpr(rs); auto rs_i128 = m_ir_builder->CreateZExt(rs_i64, m_ir_builder->getIntNTy(128)); auto rb_i8 = GetGpr(rb, 8); rb_i8 = m_ir_builder->CreateAnd(rb_i8, 0x7F); auto rb_i128 = m_ir_builder->CreateZExt(rb_i8, m_ir_builder->getIntNTy(128)); auto res_i128 = m_ir_builder->CreateLShr(rs_i128, rb_i128); auto res_i64 = m_ir_builder->CreateTrunc(res_i128, m_ir_builder->getInt64Ty()); SetGpr(ra, res_i64); if (rc) { SetCrFieldSignedCmp(0, res_i64, m_ir_builder->getInt64(0)); } //InterpreterCall("SRD", &PPUInterpreter::SRD, ra, rs, rb, rc); } void Compiler::LVRX(u32 vd, u32 ra, u32 rb) { auto addr_i64 = GetGpr(rb); if (ra) { auto ra_i64 = GetGpr(ra); addr_i64 = m_ir_builder->CreateAdd(ra_i64, addr_i64); } auto eb_i64 = m_ir_builder->CreateSub(m_ir_builder->getInt64(16), addr_i64); eb_i64 = m_ir_builder->CreateAnd(eb_i64, 0xF); eb_i64 = m_ir_builder->CreateShl(eb_i64, 3); auto eb_i128 = m_ir_builder->CreateZExt(eb_i64, m_ir_builder->getIntNTy(128)); addr_i64 = m_ir_builder->CreateAnd(addr_i64, 0xFFFFFFFFFFFFFFF0ULL); auto mem_i128 = ReadMemory(addr_i64, 128, 16); mem_i128 = m_ir_builder->CreateLShr(mem_i128, eb_i128); auto cmp_i1 = m_ir_builder->CreateICmpNE(eb_i64, m_ir_builder->getInt64(0)); auto cmp_i128 = m_ir_builder->CreateSExt(cmp_i1, m_ir_builder->getIntNTy(128)); mem_i128 = m_ir_builder->CreateAnd(mem_i128, cmp_i128); SetVr(vd, mem_i128); //InterpreterCall("LVRX", &PPUInterpreter::LVRX, vd, ra, rb); } void Compiler::LSWI(u32 rd, u32 ra, u32 nb) { auto addr_i64 = ra ? GetGpr(ra) : m_ir_builder->getInt64(0); nb = nb ? nb : 32; for (u32 i = 0; i < nb; i += 4) { auto val_i32 = ReadMemory(addr_i64, 32, 0, true, false); if (i + 4 <= nb) { addr_i64 = m_ir_builder->CreateAdd(addr_i64, m_ir_builder->getInt64(4)); } else { u32 mask = 0xFFFFFFFF << ((4 - (nb - i)) * 8); val_i32 = m_ir_builder->CreateAnd(val_i32, mask); } auto val_i64 = m_ir_builder->CreateZExt(val_i32, m_ir_builder->getInt64Ty()); SetGpr(rd, val_i64); rd = (rd + 1) % 32; } //InterpreterCall("LSWI", &PPUInterpreter::LSWI, rd, ra, nb); } void Compiler::LFSUX(u32 frd, u32 ra, u32 rb) { auto addr_i64 = GetGpr(rb); auto ra_i64 = GetGpr(ra); addr_i64 = m_ir_builder->CreateAdd(ra_i64, addr_i64); auto mem_i32 = ReadMemory(addr_i64, 32); SetFpr(frd, mem_i32); SetGpr(ra, addr_i64); //InterpreterCall("LFSUX", &PPUInterpreter::LFSUX, frd, ra, rb); } void Compiler::SYNC(u32 l) { m_ir_builder->CreateCall(Intrinsic::getDeclaration(m_module, Intrinsic::x86_sse2_mfence)); //InterpreterCall("SYNC", &PPUInterpreter::SYNC, l); } void Compiler::LFDX(u32 frd, u32 ra, u32 rb) { auto addr_i64 = GetGpr(rb); if (ra) { auto ra_i64 = GetGpr(ra); addr_i64 = m_ir_builder->CreateAdd(ra_i64, addr_i64); } auto mem_i64 = ReadMemory(addr_i64, 64); SetFpr(frd, mem_i64); //InterpreterCall("LFDX", &PPUInterpreter::LFDX, frd, ra, rb); } void Compiler::LFDUX(u32 frd, u32 ra, u32 rb) { auto addr_i64 = GetGpr(rb); auto ra_i64 = GetGpr(ra); addr_i64 = m_ir_builder->CreateAdd(ra_i64, addr_i64); auto mem_i64 = ReadMemory(addr_i64, 64); SetFpr(frd, mem_i64); SetGpr(ra, addr_i64); //InterpreterCall("LFDUX", &PPUInterpreter::LFDUX, frd, ra, rb); } void Compiler::STVLX(u32 vs, u32 ra, u32 rb) { InterpreterCall("STVLX", &PPUInterpreter::STVLX, vs, ra, rb); } void Compiler::STSWX(u32 rs, u32 ra, u32 rb) { InterpreterCall("STSWX", &PPUInterpreter::STSWX, rs, ra, rb); } void Compiler::STWBRX(u32 rs, u32 ra, u32 rb) { auto addr_i64 = GetGpr(rb); if (ra) { auto ra_i64 = GetGpr(ra); addr_i64 = m_ir_builder->CreateAdd(ra_i64, addr_i64); } WriteMemory(addr_i64, GetGpr(rs, 32), 0, false); //InterpreterCall("STWBRX", &PPUInterpreter::STWBRX, rs, ra, rb); } void Compiler::STFSX(u32 frs, u32 ra, u32 rb) { auto addr_i64 = GetGpr(rb); if (ra) { auto ra_i64 = GetGpr(ra); addr_i64 = m_ir_builder->CreateAdd(ra_i64, addr_i64); } auto frs_i32 = m_ir_builder->CreateBitCast(GetFpr(frs, 32), m_ir_builder->getInt32Ty()); WriteMemory(addr_i64, frs_i32); //InterpreterCall("STFSX", &PPUInterpreter::STFSX, frs, ra, rb); } void Compiler::STVRX(u32 vs, u32 ra, u32 rb) { InterpreterCall("STVRX", &PPUInterpreter::STVRX, vs, ra, rb); } void Compiler::STFSUX(u32 frs, u32 ra, u32 rb) { auto addr_i64 = GetGpr(rb); auto ra_i64 = GetGpr(ra); addr_i64 = m_ir_builder->CreateAdd(ra_i64, addr_i64); auto frs_i32 = m_ir_builder->CreateBitCast(GetFpr(frs, 32), m_ir_builder->getInt32Ty()); WriteMemory(addr_i64, frs_i32); SetGpr(ra, addr_i64); //InterpreterCall("STFSUX", &PPUInterpreter::STFSUX, frs, ra, rb); } void Compiler::STSWI(u32 rd, u32 ra, u32 nb) { auto addr_i64 = ra ? GetGpr(ra) : m_ir_builder->getInt64(0); nb = nb ? nb : 32; for (u32 i = 0; i < nb; i += 4) { auto val_i32 = GetGpr(rd, 32); if (i + 4 <= nb) { WriteMemory(addr_i64, val_i32, 0, true, false); addr_i64 = m_ir_builder->CreateAdd(addr_i64, m_ir_builder->getInt64(4)); rd = (rd + 1) % 32; } else { u32 n = nb - i; if (n >= 2) { auto val_i16 = m_ir_builder->CreateLShr(val_i32, 16); val_i16 = m_ir_builder->CreateTrunc(val_i16, m_ir_builder->getInt16Ty()); WriteMemory(addr_i64, val_i16); if (n == 3) { auto val_i8 = m_ir_builder->CreateLShr(val_i32, 8); val_i8 = m_ir_builder->CreateTrunc(val_i8, m_ir_builder->getInt8Ty()); addr_i64 = m_ir_builder->CreateAdd(addr_i64, m_ir_builder->getInt64(2)); WriteMemory(addr_i64, val_i8); } } else { auto val_i8 = m_ir_builder->CreateLShr(val_i32, 24); val_i8 = m_ir_builder->CreateTrunc(val_i8, m_ir_builder->getInt8Ty()); WriteMemory(addr_i64, val_i8); } } } //InterpreterCall("STSWI", &PPUInterpreter::STSWI, rd, ra, nb); } void Compiler::STFDX(u32 frs, u32 ra, u32 rb) { auto addr_i64 = GetGpr(rb); if (ra) { auto ra_i64 = GetGpr(ra); addr_i64 = m_ir_builder->CreateAdd(ra_i64, addr_i64); } auto frs_i64 = m_ir_builder->CreateBitCast(GetFpr(frs), m_ir_builder->getInt64Ty()); WriteMemory(addr_i64, frs_i64); //InterpreterCall("STFDX", &PPUInterpreter::STFDX, frs, ra, rb); } void Compiler::STFDUX(u32 frs, u32 ra, u32 rb) { auto addr_i64 = GetGpr(rb); auto ra_i64 = GetGpr(ra); addr_i64 = m_ir_builder->CreateAdd(ra_i64, addr_i64); auto frs_i64 = m_ir_builder->CreateBitCast(GetFpr(frs), m_ir_builder->getInt64Ty()); WriteMemory(addr_i64, frs_i64); SetGpr(ra, addr_i64); //InterpreterCall("STFDUX", &PPUInterpreter::STFDUX, frs, ra, rb); } void Compiler::LVLXL(u32 vd, u32 ra, u32 rb) { LVLX(vd, ra, rb); //InterpreterCall("LVLXL", &PPUInterpreter::LVLXL, vd, ra, rb); } void Compiler::LHBRX(u32 rd, u32 ra, u32 rb) { auto addr_i64 = GetGpr(rb); if (ra) { auto ra_i64 = GetGpr(ra); addr_i64 = m_ir_builder->CreateAdd(ra_i64, addr_i64); } auto mem_i16 = ReadMemory(addr_i64, 16, 0, false); auto mem_i64 = m_ir_builder->CreateZExt(mem_i16, m_ir_builder->getInt64Ty()); SetGpr(rd, mem_i64); //InterpreterCall("LHBRX", &PPUInterpreter::LHBRX, rd, ra, rb); } void Compiler::SRAW(u32 ra, u32 rs, u32 rb, bool rc) { auto rs_i32 = GetGpr(rs, 32); auto rs_i64 = m_ir_builder->CreateZExt(rs_i32, m_ir_builder->getInt64Ty()); rs_i64 = m_ir_builder->CreateShl(rs_i64, 32); auto rb_i8 = GetGpr(rb, 8); rb_i8 = m_ir_builder->CreateAnd(rb_i8, 0x3F); auto rb_i64 = m_ir_builder->CreateZExt(rb_i8, m_ir_builder->getInt64Ty()); auto res_i64 = m_ir_builder->CreateAShr(rs_i64, rb_i64); auto ra_i64 = m_ir_builder->CreateAShr(res_i64, 32); SetGpr(ra, ra_i64); auto res_i32 = m_ir_builder->CreateTrunc(res_i64, m_ir_builder->getInt32Ty()); auto ca1_i1 = m_ir_builder->CreateICmpSLT(ra_i64, m_ir_builder->getInt64(0)); auto ca2_i1 = m_ir_builder->CreateICmpNE(res_i32, m_ir_builder->getInt32(0)); auto ca_i1 = m_ir_builder->CreateAnd(ca1_i1, ca2_i1); SetXerCa(ca_i1); if (rc) { SetCrFieldSignedCmp(0, ra_i64, m_ir_builder->getInt64(0)); } //InterpreterCall("SRAW", &PPUInterpreter::SRAW, ra, rs, rb, rc); } void Compiler::SRAD(u32 ra, u32 rs, u32 rb, bool rc) { auto rs_i64 = GetGpr(rs); auto rs_i128 = m_ir_builder->CreateZExt(rs_i64, m_ir_builder->getIntNTy(128)); rs_i128 = m_ir_builder->CreateShl(rs_i128, 64); auto rb_i8 = GetGpr(rb, 8); rb_i8 = m_ir_builder->CreateAnd(rb_i8, 0x7F); auto rb_i128 = m_ir_builder->CreateZExt(rb_i8, m_ir_builder->getIntNTy(128)); auto res_i128 = m_ir_builder->CreateAShr(rs_i128, rb_i128); auto ra_i128 = m_ir_builder->CreateAShr(res_i128, 64); auto ra_i64 = m_ir_builder->CreateTrunc(ra_i128, m_ir_builder->getInt64Ty()); SetGpr(ra, ra_i64); auto res_i64 = m_ir_builder->CreateTrunc(res_i128, m_ir_builder->getInt64Ty()); auto ca1_i1 = m_ir_builder->CreateICmpSLT(ra_i64, m_ir_builder->getInt64(0)); auto ca2_i1 = m_ir_builder->CreateICmpNE(res_i64, m_ir_builder->getInt64(0)); auto ca_i1 = m_ir_builder->CreateAnd(ca1_i1, ca2_i1); SetXerCa(ca_i1); if (rc) { SetCrFieldSignedCmp(0, ra_i64, m_ir_builder->getInt64(0)); } //InterpreterCall("SRAD", &PPUInterpreter::SRAD, ra, rs, rb, rc); } void Compiler::LVRXL(u32 vd, u32 ra, u32 rb) { LVRX(vd, ra, rb); //InterpreterCall("LVRXL", &PPUInterpreter::LVRXL, vd, ra, rb); } void Compiler::DSS(u32 strm, u32 a) { InterpreterCall("DSS", &PPUInterpreter::DSS, strm, a); } void Compiler::SRAWI(u32 ra, u32 rs, u32 sh, bool rc) { auto rs_i32 = GetGpr(rs, 32); auto rs_i64 = m_ir_builder->CreateZExt(rs_i32, m_ir_builder->getInt64Ty()); rs_i64 = m_ir_builder->CreateShl(rs_i64, 32); auto res_i64 = m_ir_builder->CreateAShr(rs_i64, sh); auto ra_i64 = m_ir_builder->CreateAShr(res_i64, 32); SetGpr(ra, ra_i64); auto res_i32 = m_ir_builder->CreateTrunc(res_i64, m_ir_builder->getInt32Ty()); auto ca1_i1 = m_ir_builder->CreateICmpSLT(ra_i64, m_ir_builder->getInt64(0)); auto ca2_i1 = m_ir_builder->CreateICmpNE(res_i32, m_ir_builder->getInt32(0)); auto ca_i1 = m_ir_builder->CreateAnd(ca1_i1, ca2_i1); SetXerCa(ca_i1); if (rc) { SetCrFieldSignedCmp(0, ra_i64, m_ir_builder->getInt64(0)); } //InterpreterCall("SRAWI", &PPUInterpreter::SRAWI, ra, rs, sh, rc); } void Compiler::SRADI1(u32 ra, u32 rs, u32 sh, bool rc) { auto rs_i64 = GetGpr(rs); auto rs_i128 = m_ir_builder->CreateZExt(rs_i64, m_ir_builder->getIntNTy(128)); rs_i128 = m_ir_builder->CreateShl(rs_i128, 64); auto res_i128 = m_ir_builder->CreateAShr(rs_i128, sh); auto ra_i128 = m_ir_builder->CreateAShr(res_i128, 64); auto ra_i64 = m_ir_builder->CreateTrunc(ra_i128, m_ir_builder->getInt64Ty()); SetGpr(ra, ra_i64); auto res_i64 = m_ir_builder->CreateTrunc(res_i128, m_ir_builder->getInt64Ty()); auto ca1_i1 = m_ir_builder->CreateICmpSLT(ra_i64, m_ir_builder->getInt64(0)); auto ca2_i1 = m_ir_builder->CreateICmpNE(res_i64, m_ir_builder->getInt64(0)); auto ca_i1 = m_ir_builder->CreateAnd(ca1_i1, ca2_i1); SetXerCa(ca_i1); if (rc) { SetCrFieldSignedCmp(0, ra_i64, m_ir_builder->getInt64(0)); } //InterpreterCall("SRADI1", &PPUInterpreter::SRADI1, ra, rs, sh, rc); } void Compiler::SRADI2(u32 ra, u32 rs, u32 sh, bool rc) { SRADI1(ra, rs, sh, rc); //InterpreterCall("SRADI2", &PPUInterpreter::SRADI2, ra, rs, sh, rc); } void Compiler::EIEIO() { m_ir_builder->CreateCall(Intrinsic::getDeclaration(m_module, Intrinsic::x86_sse2_mfence)); //InterpreterCall("EIEIO", &PPUInterpreter::EIEIO); } void Compiler::STVLXL(u32 vs, u32 ra, u32 rb) { STVLX(vs, ra, rb); //InterpreterCall("STVLXL", &PPUInterpreter::STVLXL, vs, ra, rb); } void Compiler::STHBRX(u32 rs, u32 ra, u32 rb) { auto addr_i64 = GetGpr(rb); if (ra) { auto ra_i64 = GetGpr(ra); addr_i64 = m_ir_builder->CreateAdd(ra_i64, addr_i64); } WriteMemory(addr_i64, GetGpr(rs, 16), 0, false); //InterpreterCall("STHBRX", &PPUInterpreter::STHBRX, rs, ra, rb); } void Compiler::EXTSH(u32 ra, u32 rs, bool rc) { auto rs_i16 = GetGpr(rs, 16); auto rs_i64 = m_ir_builder->CreateSExt(rs_i16, m_ir_builder->getInt64Ty()); SetGpr(ra, rs_i64); if (rc) { SetCrFieldSignedCmp(0, rs_i64, m_ir_builder->getInt64(0)); } //InterpreterCall("EXTSH", &PPUInterpreter::EXTSH, ra, rs, rc); } void Compiler::STVRXL(u32 vs, u32 ra, u32 rb) { STVRX(vs, ra, rb); //InterpreterCall("STVRXL", &PPUInterpreter::STVRXL, vs, ra, rb); } void Compiler::EXTSB(u32 ra, u32 rs, bool rc) { auto rs_i8 = GetGpr(rs, 8); auto rs_i64 = m_ir_builder->CreateSExt(rs_i8, m_ir_builder->getInt64Ty()); SetGpr(ra, rs_i64); if (rc) { SetCrFieldSignedCmp(0, rs_i64, m_ir_builder->getInt64(0)); } //InterpreterCall("EXTSB", &PPUInterpreter::EXTSB, ra, rs, rc); } void Compiler::STFIWX(u32 frs, u32 ra, u32 rb) { auto addr_i64 = GetGpr(rb); if (ra) { auto ra_i64 = GetGpr(ra); addr_i64 = m_ir_builder->CreateAdd(ra_i64, addr_i64); } auto frs_i64 = m_ir_builder->CreateBitCast(GetFpr(frs), m_ir_builder->getInt64Ty()); auto frs_i32 = m_ir_builder->CreateTrunc(frs_i64, m_ir_builder->getInt32Ty()); WriteMemory(addr_i64, frs_i32); //InterpreterCall("STFIWX", &PPUInterpreter::STFIWX, frs, ra, rb); } void Compiler::EXTSW(u32 ra, u32 rs, bool rc) { auto rs_i32 = GetGpr(rs, 32); auto rs_i64 = m_ir_builder->CreateSExt(rs_i32, m_ir_builder->getInt64Ty()); SetGpr(ra, rs_i64); if (rc) { SetCrFieldSignedCmp(0, rs_i64, m_ir_builder->getInt64(0)); } //InterpreterCall("EXTSW", &PPUInterpreter::EXTSW, ra, rs, rc); } void Compiler::ICBI(u32 ra, u32 rs) { InterpreterCall("ICBI", &PPUInterpreter::ICBI, ra, rs); } void Compiler::DCBZ(u32 ra, u32 rb) { auto addr_i64 = GetGpr(rb); if (ra) { auto ra_i64 = GetGpr(ra); addr_i64 = m_ir_builder->CreateAdd(ra_i64, addr_i64); } addr_i64 = m_ir_builder->CreateAnd(addr_i64, ~(127ULL)); addr_i64 = m_ir_builder->CreateAdd(addr_i64, m_ir_builder->getInt64((u64)vm::get_ptr(0))); auto addr_i8_ptr = m_ir_builder->CreateIntToPtr(addr_i64, m_ir_builder->getInt8PtrTy()); std::vector types = {(Type *)m_ir_builder->getInt8PtrTy(), (Type *)m_ir_builder->getInt32Ty()}; m_ir_builder->CreateCall5(Intrinsic::getDeclaration(m_module, Intrinsic::memset, types), addr_i8_ptr, m_ir_builder->getInt8(0), m_ir_builder->getInt32(128), m_ir_builder->getInt32(128), m_ir_builder->getInt1(true)); //InterpreterCall("DCBZ", &PPUInterpreter::DCBZ, ra, rb);L } void Compiler::LWZ(u32 rd, u32 ra, s32 d) { auto addr_i64 = (Value *)m_ir_builder->getInt64((s64)d); if (ra) { auto ra_i64 = GetGpr(ra); addr_i64 = m_ir_builder->CreateAdd(ra_i64, addr_i64); } auto mem_i32 = ReadMemory(addr_i64, 32); auto mem_i64 = m_ir_builder->CreateZExt(mem_i32, m_ir_builder->getInt64Ty()); SetGpr(rd, mem_i64); //InterpreterCall("LWZ", &PPUInterpreter::LWZ, rd, ra, d); } void Compiler::LWZU(u32 rd, u32 ra, s32 d) { auto addr_i64 = (Value *)m_ir_builder->getInt64((s64)d); auto ra_i64 = GetGpr(ra); addr_i64 = m_ir_builder->CreateAdd(ra_i64, addr_i64); auto mem_i32 = ReadMemory(addr_i64, 32); auto mem_i64 = m_ir_builder->CreateZExt(mem_i32, m_ir_builder->getInt64Ty()); SetGpr(rd, mem_i64); SetGpr(ra, addr_i64); //InterpreterCall("LWZU", &PPUInterpreter::LWZU, rd, ra, d); } void Compiler::LBZ(u32 rd, u32 ra, s32 d) { auto addr_i64 = (Value *)m_ir_builder->getInt64((s64)d); if (ra) { auto ra_i64 = GetGpr(ra); addr_i64 = m_ir_builder->CreateAdd(ra_i64, addr_i64); } auto mem_i8 = ReadMemory(addr_i64, 8); auto mem_i64 = m_ir_builder->CreateZExt(mem_i8, m_ir_builder->getInt64Ty()); SetGpr(rd, mem_i64); //InterpreterCall("LBZ", &PPUInterpreter::LBZ, rd, ra, d); } void Compiler::LBZU(u32 rd, u32 ra, s32 d) { auto addr_i64 = (Value *)m_ir_builder->getInt64((s64)d); auto ra_i64 = GetGpr(ra); addr_i64 = m_ir_builder->CreateAdd(ra_i64, addr_i64); auto mem_i8 = ReadMemory(addr_i64, 8); auto mem_i64 = m_ir_builder->CreateZExt(mem_i8, m_ir_builder->getInt64Ty()); SetGpr(rd, mem_i64); SetGpr(ra, addr_i64); //InterpreterCall("LBZU", &PPUInterpreter::LBZU, rd, ra, d); } void Compiler::STW(u32 rs, u32 ra, s32 d) { auto addr_i64 = (Value *)m_ir_builder->getInt64((s64)d); if (ra) { auto ra_i64 = GetGpr(ra); addr_i64 = m_ir_builder->CreateAdd(ra_i64, addr_i64); } WriteMemory(addr_i64, GetGpr(rs, 32)); //InterpreterCall("STW", &PPUInterpreter::STW, rs, ra, d); } void Compiler::STWU(u32 rs, u32 ra, s32 d) { auto addr_i64 = (Value *)m_ir_builder->getInt64((s64)d); auto ra_i64 = GetGpr(ra); addr_i64 = m_ir_builder->CreateAdd(ra_i64, addr_i64); WriteMemory(addr_i64, GetGpr(rs, 32)); SetGpr(ra, addr_i64); //InterpreterCall("STWU", &PPUInterpreter::STWU, rs, ra, d); } void Compiler::STB(u32 rs, u32 ra, s32 d) { auto addr_i64 = (Value *)m_ir_builder->getInt64((s64)d); if (ra) { auto ra_i64 = GetGpr(ra); addr_i64 = m_ir_builder->CreateAdd(ra_i64, addr_i64); } WriteMemory(addr_i64, GetGpr(rs, 8)); //InterpreterCall("STB", &PPUInterpreter::STB, rs, ra, d); } void Compiler::STBU(u32 rs, u32 ra, s32 d) { auto addr_i64 = (Value *)m_ir_builder->getInt64((s64)d); auto ra_i64 = GetGpr(ra); addr_i64 = m_ir_builder->CreateAdd(ra_i64, addr_i64); WriteMemory(addr_i64, GetGpr(rs, 8)); SetGpr(ra, addr_i64); //InterpreterCall("STBU", &PPUInterpreter::STBU, rs, ra, d); } void Compiler::LHZ(u32 rd, u32 ra, s32 d) { auto addr_i64 = (Value *)m_ir_builder->getInt64((s64)d); if (ra) { auto ra_i64 = GetGpr(ra); addr_i64 = m_ir_builder->CreateAdd(ra_i64, addr_i64); } auto mem_i16 = ReadMemory(addr_i64, 16); auto mem_i64 = m_ir_builder->CreateZExt(mem_i16, m_ir_builder->getInt64Ty()); SetGpr(rd, mem_i64); //InterpreterCall("LHZ", &PPUInterpreter::LHZ, rd, ra, d); } void Compiler::LHZU(u32 rd, u32 ra, s32 d) { auto addr_i64 = (Value *)m_ir_builder->getInt64((s64)d); auto ra_i64 = GetGpr(ra); addr_i64 = m_ir_builder->CreateAdd(ra_i64, addr_i64); auto mem_i16 = ReadMemory(addr_i64, 16); auto mem_i64 = m_ir_builder->CreateZExt(mem_i16, m_ir_builder->getInt64Ty()); SetGpr(rd, mem_i64); SetGpr(ra, addr_i64); //InterpreterCall("LHZU", &PPUInterpreter::LHZU, rd, ra, d); } void Compiler::LHA(u32 rd, u32 ra, s32 d) { auto addr_i64 = (Value *)m_ir_builder->getInt64((s64)d); if (ra) { auto ra_i64 = GetGpr(ra); addr_i64 = m_ir_builder->CreateAdd(ra_i64, addr_i64); } auto mem_i16 = ReadMemory(addr_i64, 16); auto mem_i64 = m_ir_builder->CreateSExt(mem_i16, m_ir_builder->getInt64Ty()); SetGpr(rd, mem_i64); //InterpreterCall("LHA", &PPUInterpreter::LHA, rd, ra, d); } void Compiler::LHAU(u32 rd, u32 ra, s32 d) { auto addr_i64 = (Value *)m_ir_builder->getInt64((s64)d); auto ra_i64 = GetGpr(ra); addr_i64 = m_ir_builder->CreateAdd(ra_i64, addr_i64); auto mem_i16 = ReadMemory(addr_i64, 16); auto mem_i64 = m_ir_builder->CreateSExt(mem_i16, m_ir_builder->getInt64Ty()); SetGpr(rd, mem_i64); SetGpr(ra, addr_i64); //InterpreterCall("LHAU", &PPUInterpreter::LHAU, rd, ra, d); } void Compiler::STH(u32 rs, u32 ra, s32 d) { auto addr_i64 = (Value *)m_ir_builder->getInt64((s64)d); if (ra) { auto ra_i64 = GetGpr(ra); addr_i64 = m_ir_builder->CreateAdd(ra_i64, addr_i64); } WriteMemory(addr_i64, GetGpr(rs, 16)); //InterpreterCall("STH", &PPUInterpreter::STH, rs, ra, d); } void Compiler::STHU(u32 rs, u32 ra, s32 d) { auto addr_i64 = (Value *)m_ir_builder->getInt64((s64)d); auto ra_i64 = GetGpr(ra); addr_i64 = m_ir_builder->CreateAdd(ra_i64, addr_i64); WriteMemory(addr_i64, GetGpr(rs, 16)); SetGpr(ra, addr_i64); //InterpreterCall("STHU", &PPUInterpreter::STHU, rs, ra, d); } void Compiler::LMW(u32 rd, u32 ra, s32 d) { auto addr_i64 = (Value *)m_ir_builder->getInt64((s64)d); if (ra) { addr_i64 = m_ir_builder->CreateAdd(addr_i64, GetGpr(ra)); } for (u32 i = rd; i < 32; i++) { auto val_i32 = ReadMemory(addr_i64, 32); auto val_i64 = m_ir_builder->CreateZExt(val_i32, m_ir_builder->getInt64Ty()); SetGpr(i, val_i64); addr_i64 = m_ir_builder->CreateAdd(addr_i64, m_ir_builder->getInt64(4)); } //InterpreterCall("LMW", &PPUInterpreter::LMW, rd, ra, d); } void Compiler::STMW(u32 rs, u32 ra, s32 d) { auto addr_i64 = (Value *)m_ir_builder->getInt64((s64)d); if (ra) { addr_i64 = m_ir_builder->CreateAdd(addr_i64, GetGpr(ra)); } for (u32 i = rs; i < 32; i++) { auto val_i32 = GetGpr(i, 32); WriteMemory(addr_i64, val_i32); addr_i64 = m_ir_builder->CreateAdd(addr_i64, m_ir_builder->getInt64(4)); } //InterpreterCall("STMW", &PPUInterpreter::STMW, rs, ra, d); } void Compiler::LFS(u32 frd, u32 ra, s32 d) { auto addr_i64 = (Value *)m_ir_builder->getInt64((s64)d); if (ra) { auto ra_i64 = GetGpr(ra); addr_i64 = m_ir_builder->CreateAdd(ra_i64, addr_i64); } auto mem_i32 = ReadMemory(addr_i64, 32); SetFpr(frd, mem_i32); //InterpreterCall("LFS", &PPUInterpreter::LFS, frd, ra, d); } void Compiler::LFSU(u32 frd, u32 ra, s32 ds) { auto addr_i64 = (Value *)m_ir_builder->getInt64((s64)ds); auto ra_i64 = GetGpr(ra); addr_i64 = m_ir_builder->CreateAdd(ra_i64, addr_i64); auto mem_i32 = ReadMemory(addr_i64, 32); SetFpr(frd, mem_i32); SetGpr(ra, addr_i64); //InterpreterCall("LFSU", &PPUInterpreter::LFSU, frd, ra, ds); } void Compiler::LFD(u32 frd, u32 ra, s32 d) { auto addr_i64 = (Value *)m_ir_builder->getInt64((s64)d); if (ra) { auto ra_i64 = GetGpr(ra); addr_i64 = m_ir_builder->CreateAdd(ra_i64, addr_i64); } auto mem_i64 = ReadMemory(addr_i64, 64); SetFpr(frd, mem_i64); //InterpreterCall("LFD", &PPUInterpreter::LFD, frd, ra, d); } void Compiler::LFDU(u32 frd, u32 ra, s32 ds) { auto addr_i64 = (Value *)m_ir_builder->getInt64((s64)ds); auto ra_i64 = GetGpr(ra); addr_i64 = m_ir_builder->CreateAdd(ra_i64, addr_i64); auto mem_i64 = ReadMemory(addr_i64, 64); SetFpr(frd, mem_i64); SetGpr(ra, addr_i64); //InterpreterCall("LFDU", &PPUInterpreter::LFDU, frd, ra, ds); } void Compiler::STFS(u32 frs, u32 ra, s32 d) { auto addr_i64 = (Value *)m_ir_builder->getInt64((s64)d); if (ra) { auto ra_i64 = GetGpr(ra); addr_i64 = m_ir_builder->CreateAdd(ra_i64, addr_i64); } auto frs_i32 = m_ir_builder->CreateBitCast(GetFpr(frs, 32), m_ir_builder->getInt32Ty()); WriteMemory(addr_i64, frs_i32); //InterpreterCall("STFS", &PPUInterpreter::STFS, frs, ra, d); } void Compiler::STFSU(u32 frs, u32 ra, s32 d) { auto addr_i64 = (Value *)m_ir_builder->getInt64((s64)d); auto ra_i64 = GetGpr(ra); addr_i64 = m_ir_builder->CreateAdd(ra_i64, addr_i64); auto frs_i32 = m_ir_builder->CreateBitCast(GetFpr(frs, 32), m_ir_builder->getInt32Ty()); WriteMemory(addr_i64, frs_i32); SetGpr(ra, addr_i64); //InterpreterCall("STFSU", &PPUInterpreter::STFSU, frs, ra, d); } void Compiler::STFD(u32 frs, u32 ra, s32 d) { auto addr_i64 = (Value *)m_ir_builder->getInt64((s64)d); if (ra) { auto ra_i64 = GetGpr(ra); addr_i64 = m_ir_builder->CreateAdd(ra_i64, addr_i64); } auto frs_i64 = m_ir_builder->CreateBitCast(GetFpr(frs), m_ir_builder->getInt64Ty()); WriteMemory(addr_i64, frs_i64); //InterpreterCall("STFD", &PPUInterpreter::STFD, frs, ra, d); } void Compiler::STFDU(u32 frs, u32 ra, s32 d) { auto addr_i64 = (Value *)m_ir_builder->getInt64((s64)d); auto ra_i64 = GetGpr(ra); addr_i64 = m_ir_builder->CreateAdd(ra_i64, addr_i64); auto frs_i64 = m_ir_builder->CreateBitCast(GetFpr(frs), m_ir_builder->getInt64Ty()); WriteMemory(addr_i64, frs_i64); SetGpr(ra, addr_i64); //InterpreterCall("STFDU", &PPUInterpreter::STFDU, frs, ra, d); } void Compiler::LD(u32 rd, u32 ra, s32 ds) { auto addr_i64 = (Value *)m_ir_builder->getInt64((s64)ds); if (ra) { auto ra_i64 = GetGpr(ra); addr_i64 = m_ir_builder->CreateAdd(ra_i64, addr_i64); } auto mem_i64 = ReadMemory(addr_i64, 64); SetGpr(rd, mem_i64); //InterpreterCall("LD", &PPUInterpreter::LD, rd, ra, ds); } void Compiler::LDU(u32 rd, u32 ra, s32 ds) { auto addr_i64 = (Value *)m_ir_builder->getInt64((s64)ds); auto ra_i64 = GetGpr(ra); addr_i64 = m_ir_builder->CreateAdd(ra_i64, addr_i64); auto mem_i64 = ReadMemory(addr_i64, 64); SetGpr(rd, mem_i64); SetGpr(ra, addr_i64); //InterpreterCall("LDU", &PPUInterpreter::LDU, rd, ra, ds); } void Compiler::LWA(u32 rd, u32 ra, s32 ds) { auto addr_i64 = (Value *)m_ir_builder->getInt64((s64)ds); if (ra) { auto ra_i64 = GetGpr(ra); addr_i64 = m_ir_builder->CreateAdd(ra_i64, addr_i64); } auto mem_i32 = ReadMemory(addr_i64, 32); auto mem_i64 = m_ir_builder->CreateSExt(mem_i32, m_ir_builder->getInt64Ty()); SetGpr(rd, mem_i64); //InterpreterCall("LWA", &PPUInterpreter::LWA, rd, ra, ds); } void Compiler::FDIVS(u32 frd, u32 fra, u32 frb, bool rc) { auto ra_f64 = GetFpr(fra); auto rb_f64 = GetFpr(frb); auto res_f64 = m_ir_builder->CreateFDiv(ra_f64, rb_f64); auto res_f32 = m_ir_builder->CreateFPTrunc(res_f64, m_ir_builder->getFloatTy()); res_f64 = m_ir_builder->CreateFPExt(res_f32, m_ir_builder->getDoubleTy()); SetFpr(frd, res_f64); // TODO: Set flags //InterpreterCall("FDIVS", &PPUInterpreter::FDIVS, frd, fra, frb, rc); } void Compiler::FSUBS(u32 frd, u32 fra, u32 frb, bool rc) { auto ra_f64 = GetFpr(fra); auto rb_f64 = GetFpr(frb); auto res_f64 = m_ir_builder->CreateFSub(ra_f64, rb_f64); auto res_f32 = m_ir_builder->CreateFPTrunc(res_f64, m_ir_builder->getFloatTy()); res_f64 = m_ir_builder->CreateFPExt(res_f32, m_ir_builder->getDoubleTy()); SetFpr(frd, res_f64); // TODO: Set flags //InterpreterCall("FSUBS", &PPUInterpreter::FSUBS, frd, fra, frb, rc); } void Compiler::FADDS(u32 frd, u32 fra, u32 frb, bool rc) { auto ra_f64 = GetFpr(fra); auto rb_f64 = GetFpr(frb); auto res_f64 = m_ir_builder->CreateFAdd(ra_f64, rb_f64); auto res_f32 = m_ir_builder->CreateFPTrunc(res_f64, m_ir_builder->getFloatTy()); res_f64 = m_ir_builder->CreateFPExt(res_f32, m_ir_builder->getDoubleTy()); SetFpr(frd, res_f64); // TODO: Set flags //InterpreterCall("FADDS", &PPUInterpreter::FADDS, frd, fra, frb, rc); } void Compiler::FSQRTS(u32 frd, u32 frb, bool rc) { auto rb_f64 = GetFpr(frb); auto res_f64 = (Value *)m_ir_builder->CreateCall(Intrinsic::getDeclaration(m_module, Intrinsic::sqrt, m_ir_builder->getDoubleTy()), rb_f64); auto res_f32 = m_ir_builder->CreateFPTrunc(res_f64, m_ir_builder->getFloatTy()); res_f64 = m_ir_builder->CreateFPExt(res_f32, m_ir_builder->getDoubleTy()); SetFpr(frd, res_f64); // TODO: Set flags //InterpreterCall("FSQRTS", &PPUInterpreter::FSQRTS, frd, frb, rc); } void Compiler::FRES(u32 frd, u32 frb, bool rc) { InterpreterCall("FRES", &PPUInterpreter::FRES, frd, frb, rc); } void Compiler::FMULS(u32 frd, u32 fra, u32 frc, bool rc) { auto ra_f64 = GetFpr(fra); auto rc_f64 = GetFpr(frc); auto res_f64 = m_ir_builder->CreateFMul(ra_f64, rc_f64); auto res_f32 = m_ir_builder->CreateFPTrunc(res_f64, m_ir_builder->getFloatTy()); res_f64 = m_ir_builder->CreateFPExt(res_f32, m_ir_builder->getDoubleTy()); SetFpr(frd, res_f64); // TODO: Set flags //InterpreterCall("FMULS", &PPUInterpreter::FMULS, frd, fra, frc, rc); } void Compiler::FMADDS(u32 frd, u32 fra, u32 frc, u32 frb, bool rc) { auto ra_f64 = GetFpr(fra); auto rb_f64 = GetFpr(frb); auto rc_f64 = GetFpr(frc); auto res_f64 = (Value *)m_ir_builder->CreateCall3(Intrinsic::getDeclaration(m_module, Intrinsic::fmuladd, m_ir_builder->getDoubleTy()), ra_f64, rc_f64, rb_f64); auto res_f32 = m_ir_builder->CreateFPTrunc(res_f64, m_ir_builder->getFloatTy()); res_f64 = m_ir_builder->CreateFPExt(res_f32, m_ir_builder->getDoubleTy()); SetFpr(frd, res_f64); // TODO: Set flags //InterpreterCall("FMADDS", &PPUInterpreter::FMADDS, frd, fra, frc, frb, rc); } void Compiler::FMSUBS(u32 frd, u32 fra, u32 frc, u32 frb, bool rc) { auto ra_f64 = GetFpr(fra); auto rb_f64 = GetFpr(frb); auto rc_f64 = GetFpr(frc); rb_f64 = m_ir_builder->CreateFNeg(rb_f64); auto res_f64 = (Value *)m_ir_builder->CreateCall3(Intrinsic::getDeclaration(m_module, Intrinsic::fmuladd, m_ir_builder->getDoubleTy()), ra_f64, rc_f64, rb_f64); auto res_f32 = m_ir_builder->CreateFPTrunc(res_f64, m_ir_builder->getFloatTy()); res_f64 = m_ir_builder->CreateFPExt(res_f32, m_ir_builder->getDoubleTy()); SetFpr(frd, res_f64); // TODO: Set flags //InterpreterCall("FMSUBS", &PPUInterpreter::FMSUBS, frd, fra, frc, frb, rc); } void Compiler::FNMSUBS(u32 frd, u32 fra, u32 frc, u32 frb, bool rc) { auto ra_f64 = GetFpr(fra); auto rb_f64 = GetFpr(frb); auto rc_f64 = GetFpr(frc); rb_f64 = m_ir_builder->CreateFNeg(rb_f64); auto res_f64 = (Value *)m_ir_builder->CreateCall3(Intrinsic::getDeclaration(m_module, Intrinsic::fmuladd, m_ir_builder->getDoubleTy()), ra_f64, rc_f64, rb_f64); res_f64 = m_ir_builder->CreateFNeg(res_f64); auto res_f32 = m_ir_builder->CreateFPTrunc(res_f64, m_ir_builder->getFloatTy()); res_f64 = m_ir_builder->CreateFPExt(res_f32, m_ir_builder->getDoubleTy()); SetFpr(frd, res_f64); // TODO: Set flags //InterpreterCall("FNMSUBS", &PPUInterpreter::FNMSUBS, frd, fra, frc, frb, rc); } void Compiler::FNMADDS(u32 frd, u32 fra, u32 frc, u32 frb, bool rc) { auto ra_f64 = GetFpr(fra); auto rb_f64 = GetFpr(frb); auto rc_f64 = GetFpr(frc); auto res_f64 = (Value *)m_ir_builder->CreateCall3(Intrinsic::getDeclaration(m_module, Intrinsic::fmuladd, m_ir_builder->getDoubleTy()), ra_f64, rc_f64, rb_f64); res_f64 = m_ir_builder->CreateFNeg(res_f64); auto res_f32 = m_ir_builder->CreateFPTrunc(res_f64, m_ir_builder->getFloatTy()); res_f64 = m_ir_builder->CreateFPExt(res_f32, m_ir_builder->getDoubleTy()); SetFpr(frd, res_f64); // TODO: Set flags //InterpreterCall("FNMADDS", &PPUInterpreter::FNMADDS, frd, fra, frc, frb, rc); } void Compiler::STD(u32 rs, u32 ra, s32 d) { auto addr_i64 = (Value *)m_ir_builder->getInt64((s64)d); if (ra) { auto ra_i64 = GetGpr(ra); addr_i64 = m_ir_builder->CreateAdd(ra_i64, addr_i64); } WriteMemory(addr_i64, GetGpr(rs, 64)); //InterpreterCall("STD", &PPUInterpreter::STD, rs, ra, d); } void Compiler::STDU(u32 rs, u32 ra, s32 ds) { auto addr_i64 = (Value *)m_ir_builder->getInt64((s64)ds); auto ra_i64 = GetGpr(ra); addr_i64 = m_ir_builder->CreateAdd(ra_i64, addr_i64); WriteMemory(addr_i64, GetGpr(rs, 64)); SetGpr(ra, addr_i64); //InterpreterCall("STDU", &PPUInterpreter::STDU, rs, ra, ds); } void Compiler::MTFSB1(u32 crbd, bool rc) { InterpreterCall("MTFSB1", &PPUInterpreter::MTFSB1, crbd, rc); } void Compiler::MCRFS(u32 crbd, u32 crbs) { InterpreterCall("MCRFS", &PPUInterpreter::MCRFS, crbd, crbs); } void Compiler::MTFSB0(u32 crbd, bool rc) { InterpreterCall("MTFSB0", &PPUInterpreter::MTFSB0, crbd, rc); } void Compiler::MTFSFI(u32 crfd, u32 i, bool rc) { InterpreterCall("MTFSFI", &PPUInterpreter::MTFSFI, crfd, i, rc); } void Compiler::MFFS(u32 frd, bool rc) { InterpreterCall("MFFS", &PPUInterpreter::MFFS, frd, rc); } void Compiler::MTFSF(u32 flm, u32 frb, bool rc) { InterpreterCall("MTFSF", &PPUInterpreter::MTFSF, flm, frb, rc); } void Compiler::FCMPU(u32 crfd, u32 fra, u32 frb) { InterpreterCall("FCMPU", &PPUInterpreter::FCMPU, crfd, fra, frb); } void Compiler::FRSP(u32 frd, u32 frb, bool rc) { InterpreterCall("FRSP", &PPUInterpreter::FRSP, frd, frb, rc); } void Compiler::FCTIW(u32 frd, u32 frb, bool rc) { auto rb_f64 = GetFpr(frb); auto res_i32 = m_ir_builder->CreateFPToSI(rb_f64, m_ir_builder->getInt32Ty()); SetFpr(frd, res_i32); // TODO: Set flags / Handle NaN / Implement Saturation //InterpreterCall("FCTIW", &PPUInterpreter::FCTIW, frd, frb, rc); } void Compiler::FCTIWZ(u32 frd, u32 frb, bool rc) { InterpreterCall("FCTIWZ", &PPUInterpreter::FCTIWZ, frd, frb, rc); } void Compiler::FDIV(u32 frd, u32 fra, u32 frb, bool rc) { auto ra_f64 = GetFpr(fra); auto rb_f64 = GetFpr(frb); auto res_f64 = m_ir_builder->CreateFDiv(ra_f64, rb_f64); SetFpr(frd, res_f64); // TODO: Set flags //InterpreterCall("FDIV", &PPUInterpreter::FDIV, frd, fra, frb, rc); } void Compiler::FSUB(u32 frd, u32 fra, u32 frb, bool rc) { auto ra_f64 = GetFpr(fra); auto rb_f64 = GetFpr(frb); auto res_f64 = m_ir_builder->CreateFSub(ra_f64, rb_f64); SetFpr(frd, res_f64); // TODO: Set flags //InterpreterCall("FSUB", &PPUInterpreter::FSUB, frd, fra, frb, rc); } void Compiler::FADD(u32 frd, u32 fra, u32 frb, bool rc) { auto ra_f64 = GetFpr(fra); auto rb_f64 = GetFpr(frb); auto res_f64 = m_ir_builder->CreateFAdd(ra_f64, rb_f64); SetFpr(frd, res_f64); // TODO: Set flags //InterpreterCall("FADD", &PPUInterpreter::FADD, frd, fra, frb, rc); } void Compiler::FSQRT(u32 frd, u32 frb, bool rc) { auto rb_f64 = GetFpr(frb); auto res_f64 = (Value *)m_ir_builder->CreateCall(Intrinsic::getDeclaration(m_module, Intrinsic::sqrt, m_ir_builder->getDoubleTy()), rb_f64); SetFpr(frd, res_f64); // TODO: Set flags //InterpreterCall("FSQRT", &PPUInterpreter::FSQRT, frd, frb, rc); } void Compiler::FSEL(u32 frd, u32 fra, u32 frc, u32 frb, bool rc) { InterpreterCall("FSEL", &PPUInterpreter::FSEL, frd, fra, frc, frb, rc); } void Compiler::FMUL(u32 frd, u32 fra, u32 frc, bool rc) { auto ra_f64 = GetFpr(fra); auto rc_f64 = GetFpr(frc); auto res_f64 = m_ir_builder->CreateFMul(ra_f64, rc_f64); SetFpr(frd, res_f64); // TODO: Set flags //InterpreterCall("FMUL", &PPUInterpreter::FMUL, frd, fra, frc, rc); } void Compiler::FRSQRTE(u32 frd, u32 frb, bool rc) { InterpreterCall("FRSQRTE", &PPUInterpreter::FRSQRTE, frd, frb, rc); } void Compiler::FMSUB(u32 frd, u32 fra, u32 frc, u32 frb, bool rc) { auto ra_f64 = GetFpr(fra); auto rb_f64 = GetFpr(frb); auto rc_f64 = GetFpr(frc); rb_f64 = m_ir_builder->CreateFNeg(rb_f64); auto res_f64 = m_ir_builder->CreateCall3(Intrinsic::getDeclaration(m_module, Intrinsic::fmuladd, m_ir_builder->getDoubleTy()), ra_f64, rc_f64, rb_f64); SetFpr(frd, res_f64); // TODO: Set flags //InterpreterCall("FMSUB", &PPUInterpreter::FMSUB, frd, fra, frc, frb, rc); } void Compiler::FMADD(u32 frd, u32 fra, u32 frc, u32 frb, bool rc) { auto ra_f64 = GetFpr(fra); auto rb_f64 = GetFpr(frb); auto rc_f64 = GetFpr(frc); auto res_f64 = m_ir_builder->CreateCall3(Intrinsic::getDeclaration(m_module, Intrinsic::fmuladd, m_ir_builder->getDoubleTy()), ra_f64, rc_f64, rb_f64); SetFpr(frd, res_f64); // TODO: Set flags //InterpreterCall("FMADD", &PPUInterpreter::FMADD, frd, fra, frc, frb, rc); } void Compiler::FNMSUB(u32 frd, u32 fra, u32 frc, u32 frb, bool rc) { auto ra_f64 = GetFpr(fra); auto rb_f64 = GetFpr(frb); auto rc_f64 = GetFpr(frc); rc_f64 = m_ir_builder->CreateFNeg(rc_f64); auto res_f64 = (Value *)m_ir_builder->CreateCall3(Intrinsic::getDeclaration(m_module, Intrinsic::fmuladd, m_ir_builder->getDoubleTy()), ra_f64, rc_f64, rb_f64); SetFpr(frd, res_f64); // TODO: Set flags //InterpreterCall("FNMSUB", &PPUInterpreter::FNMSUB, frd, fra, frc, frb, rc); } void Compiler::FNMADD(u32 frd, u32 fra, u32 frc, u32 frb, bool rc) { auto ra_f64 = GetFpr(fra); auto rb_f64 = GetFpr(frb); auto rc_f64 = GetFpr(frc); rb_f64 = m_ir_builder->CreateFNeg(rb_f64); rc_f64 = m_ir_builder->CreateFNeg(rc_f64); auto res_f64 = (Value *)m_ir_builder->CreateCall3(Intrinsic::getDeclaration(m_module, Intrinsic::fmuladd, m_ir_builder->getDoubleTy()), ra_f64, rc_f64, rb_f64); SetFpr(frd, res_f64); // TODO: Set flags //InterpreterCall("FNMADD", &PPUInterpreter::FNMADD, frd, fra, frc, frb, rc); } void Compiler::FCMPO(u32 crfd, u32 fra, u32 frb) { InterpreterCall("FCMPO", &PPUInterpreter::FCMPO, crfd, fra, frb); } void Compiler::FNEG(u32 frd, u32 frb, bool rc) { auto rb_f64 = GetFpr(frb); rb_f64 = m_ir_builder->CreateFNeg(rb_f64); SetFpr(frd, rb_f64); // TODO: Set flags //InterpreterCall("FNEG", &PPUInterpreter::FNEG, frd, frb, rc); } void Compiler::FMR(u32 frd, u32 frb, bool rc) { SetFpr(frd, GetFpr(frb)); // TODO: Set flags //InterpreterCall("FMR", &PPUInterpreter::FMR, frd, frb, rc); } void Compiler::FNABS(u32 frd, u32 frb, bool rc) { auto rb_f64 = GetFpr(frb); auto res_f64 = (Value *)m_ir_builder->CreateCall(Intrinsic::getDeclaration(m_module, Intrinsic::fabs, m_ir_builder->getDoubleTy()), rb_f64); res_f64 = m_ir_builder->CreateFNeg(res_f64); SetFpr(frd, res_f64); // TODO: Set flags //InterpreterCall("FNABS", &PPUInterpreter::FNABS, frd, frb, rc); } void Compiler::FABS(u32 frd, u32 frb, bool rc) { auto rb_f64 = GetFpr(frb); auto res_f64 = (Value *)m_ir_builder->CreateCall(Intrinsic::getDeclaration(m_module, Intrinsic::fabs, m_ir_builder->getDoubleTy()), rb_f64); SetFpr(frd, res_f64); // TODO: Set flags //InterpreterCall("FABS", &PPUInterpreter::FABS, frd, frb, rc); } void Compiler::FCTID(u32 frd, u32 frb, bool rc) { auto rb_f64 = GetFpr(frb); auto res_i64 = m_ir_builder->CreateFPToSI(rb_f64, m_ir_builder->getInt64Ty()); SetFpr(frd, res_i64); // TODO: Set flags / Handle NaN / Implement Saturation //InterpreterCall("FCTID", &PPUInterpreter::FCTID, frd, frb, rc); } void Compiler::FCTIDZ(u32 frd, u32 frb, bool rc) { InterpreterCall("FCTIDZ", &PPUInterpreter::FCTIDZ, frd, frb, rc); } void Compiler::FCFID(u32 frd, u32 frb, bool rc) { auto rb_i64 = GetFpr(frb, 64, true); auto res_f64 = m_ir_builder->CreateSIToFP(rb_i64, m_ir_builder->getDoubleTy()); SetFpr(frd, res_f64); // TODO: Set flags //InterpreterCall("FCFID", &PPUInterpreter::FCFID, frd, frb, rc); } void Compiler::UNK(const u32 code, const u32 opcode, const u32 gcode) { //InterpreterCall("UNK", &PPUInterpreter::UNK, code, opcode, gcode); } std::string Compiler::GetBasicBlockNameFromAddress(u32 address, const std::string & suffix) const { std::string name; if (address == 0) { name = "entry"; } else if (address == 0xFFFFFFFF) { name = "default_exit"; } else { name = fmt::Format("instr_0x%08X", address); } if (suffix != "") { name += "_" + suffix; } return name; } u32 Compiler::GetAddressFromBasicBlockName(const std::string & name) const { if (name.compare(0, 6, "instr_") == 0) { return strtoul(name.c_str() + 6, nullptr, 0); } else if (name == GetBasicBlockNameFromAddress(0)) { return 0; } else if (name == GetBasicBlockNameFromAddress(0xFFFFFFFF)) { return 0xFFFFFFFF; } return 0; } BasicBlock * Compiler::GetBasicBlockFromAddress(u32 address, const std::string & suffix, bool create_if_not_exist) { auto block_name = GetBasicBlockNameFromAddress(address, suffix); BasicBlock * block = nullptr; BasicBlock * next_block = nullptr; for (auto i = m_state.function->begin(); i != m_state.function->end(); i++) { if (i->getName() == block_name) { block = &(*i); break; } #ifdef _DEBUG auto block_address = GetAddressFromBasicBlockName(i->getName()); if (block_address > address) { next_block = &(*i); break; } #endif } if (!block && create_if_not_exist) { block = BasicBlock::Create(m_ir_builder->getContext(), block_name, m_state.function, next_block); } return block; } Value * Compiler::GetBit(Value * val, u32 n) { Value * bit; #ifdef PPU_LLVM_RECOMPILER_USE_BMI 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((u64)1 << (63 - n))); } else { #endif if (val->getType()->getIntegerBitWidth() != (n + 1)) { bit = m_ir_builder->CreateLShr(val, val->getType()->getIntegerBitWidth() - n - 1); } bit = m_ir_builder->CreateAnd(bit, 1); #ifdef PPU_LLVM_RECOMPILER_USE_BMI } #endif return bit; } Value * Compiler::ClrBit(Value * val, u32 n) { return m_ir_builder->CreateAnd(val, ~((u64)1 << (val->getType()->getIntegerBitWidth() - n - 1))); } Value * Compiler::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 * Compiler::GetNibble(Value * val, u32 n) { Value * nibble; #ifdef PPU_LLVM_RECOMPILER_USE_BMI if (val->getType()->isIntegerTy(32)) { nibble = m_ir_builder->CreateCall2(Intrinsic::getDeclaration(m_module, Intrinsic::x86_bmi_pext_32), val, m_ir_builder->getInt32((u64)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((u64)0xF << ((15 - n) * 4))); } else { #endif if ((val->getType()->getIntegerBitWidth() >> 2) != (n + 1)) { val = m_ir_builder->CreateLShr(val, (((val->getType()->getIntegerBitWidth() >> 2) - 1) - n) * 4); } nibble = m_ir_builder->CreateAnd(val, 0xF); #ifdef PPU_LLVM_RECOMPILER_USE_BMI } #endif return nibble; } Value * Compiler::ClrNibble(Value * val, u32 n) { return m_ir_builder->CreateAnd(val, ~((u64)0xF << ((((val->getType()->getIntegerBitWidth() >> 2) - 1) - n) * 4))); } Value * Compiler::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 * Compiler::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 * Compiler::GetPc() { auto pc_i8_ptr = m_ir_builder->CreateConstGEP1_32(m_state.args[CompileTaskState::Args::State], (unsigned int)offsetof(PPUThread, PC)); auto pc_i32_ptr = m_ir_builder->CreateBitCast(pc_i8_ptr, m_ir_builder->getInt32Ty()->getPointerTo()); return m_ir_builder->CreateAlignedLoad(pc_i32_ptr, 4); } void Compiler::SetPc(Value * val_ix) { auto pc_i8_ptr = m_ir_builder->CreateConstGEP1_32(m_state.args[CompileTaskState::Args::State], (unsigned int)offsetof(PPUThread, PC)); auto pc_i32_ptr = m_ir_builder->CreateBitCast(pc_i8_ptr, m_ir_builder->getInt32Ty()->getPointerTo()); auto val_i32 = m_ir_builder->CreateZExtOrTrunc(val_ix, m_ir_builder->getInt32Ty()); m_ir_builder->CreateAlignedStore(val_i32, pc_i32_ptr, 4); } Value * Compiler::GetGpr(u32 r, u32 num_bits) { auto r_i8_ptr = m_ir_builder->CreateConstGEP1_32(m_state.args[CompileTaskState::Args::State], (unsigned int)offsetof(PPUThread, GPR[r])); auto r_ix_ptr = m_ir_builder->CreateBitCast(r_i8_ptr, m_ir_builder->getIntNTy(num_bits)->getPointerTo()); return m_ir_builder->CreateAlignedLoad(r_ix_ptr, 8); } void Compiler::SetGpr(u32 r, Value * val_x64) { auto r_i8_ptr = m_ir_builder->CreateConstGEP1_32(m_state.args[CompileTaskState::Args::State], (unsigned int)offsetof(PPUThread, GPR[r])); auto r_i64_ptr = m_ir_builder->CreateBitCast(r_i8_ptr, m_ir_builder->getInt64Ty()->getPointerTo()); auto val_i64 = m_ir_builder->CreateBitCast(val_x64, m_ir_builder->getInt64Ty()); m_ir_builder->CreateAlignedStore(val_i64, r_i64_ptr, 8); } Value * Compiler::GetCr() { auto cr_i8_ptr = m_ir_builder->CreateConstGEP1_32(m_state.args[CompileTaskState::Args::State], (unsigned int)offsetof(PPUThread, CR)); auto cr_i32_ptr = m_ir_builder->CreateBitCast(cr_i8_ptr, m_ir_builder->getInt32Ty()->getPointerTo()); return m_ir_builder->CreateAlignedLoad(cr_i32_ptr, 4); } Value * Compiler::GetCrField(u32 n) { return GetNibble(GetCr(), n); } void Compiler::SetCr(Value * val_x32) { auto val_i32 = m_ir_builder->CreateBitCast(val_x32, m_ir_builder->getInt32Ty()); auto cr_i8_ptr = m_ir_builder->CreateConstGEP1_32(m_state.args[CompileTaskState::Args::State], (unsigned int)offsetof(PPUThread, CR)); auto cr_i32_ptr = m_ir_builder->CreateBitCast(cr_i8_ptr, m_ir_builder->getInt32Ty()->getPointerTo()); m_ir_builder->CreateAlignedStore(val_i32, cr_i32_ptr, 4); } void Compiler::SetCrField(u32 n, Value * field) { SetCr(SetNibble(GetCr(), n, field)); } void Compiler::SetCrField(u32 n, Value * b0, Value * b1, Value * b2, Value * b3) { SetCr(SetNibble(GetCr(), n, b0, b1, b2, b3)); } void Compiler::SetCrFieldSignedCmp(u32 n, Value * a, 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 Compiler::SetCrFieldUnsignedCmp(u32 n, Value * a, 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 Compiler::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 * Compiler::GetLr() { auto lr_i8_ptr = m_ir_builder->CreateConstGEP1_32(m_state.args[CompileTaskState::Args::State], (unsigned int)offsetof(PPUThread, LR)); auto lr_i64_ptr = m_ir_builder->CreateBitCast(lr_i8_ptr, m_ir_builder->getInt64Ty()->getPointerTo()); return m_ir_builder->CreateAlignedLoad(lr_i64_ptr, 8); } void Compiler::SetLr(Value * val_x64) { auto val_i64 = m_ir_builder->CreateBitCast(val_x64, m_ir_builder->getInt64Ty()); auto lr_i8_ptr = m_ir_builder->CreateConstGEP1_32(m_state.args[CompileTaskState::Args::State], (unsigned int)offsetof(PPUThread, LR)); auto lr_i64_ptr = m_ir_builder->CreateBitCast(lr_i8_ptr, m_ir_builder->getInt64Ty()->getPointerTo()); m_ir_builder->CreateAlignedStore(val_i64, lr_i64_ptr, 8); } Value * Compiler::GetCtr() { auto ctr_i8_ptr = m_ir_builder->CreateConstGEP1_32(m_state.args[CompileTaskState::Args::State], (unsigned int)offsetof(PPUThread, CTR)); auto ctr_i64_ptr = m_ir_builder->CreateBitCast(ctr_i8_ptr, m_ir_builder->getInt64Ty()->getPointerTo()); return m_ir_builder->CreateAlignedLoad(ctr_i64_ptr, 8); } void Compiler::SetCtr(Value * val_x64) { auto val_i64 = m_ir_builder->CreateBitCast(val_x64, m_ir_builder->getInt64Ty()); auto ctr_i8_ptr = m_ir_builder->CreateConstGEP1_32(m_state.args[CompileTaskState::Args::State], (unsigned int)offsetof(PPUThread, CTR)); auto ctr_i64_ptr = m_ir_builder->CreateBitCast(ctr_i8_ptr, m_ir_builder->getInt64Ty()->getPointerTo()); m_ir_builder->CreateAlignedStore(val_i64, ctr_i64_ptr, 8); } Value * Compiler::GetXer() { auto xer_i8_ptr = m_ir_builder->CreateConstGEP1_32(m_state.args[CompileTaskState::Args::State], (unsigned int)offsetof(PPUThread, XER)); auto xer_i64_ptr = m_ir_builder->CreateBitCast(xer_i8_ptr, m_ir_builder->getInt64Ty()->getPointerTo()); return m_ir_builder->CreateAlignedLoad(xer_i64_ptr, 8); } Value * Compiler::GetXerCa() { return GetBit(GetXer(), 34); } Value * Compiler::GetXerSo() { return GetBit(GetXer(), 32); } void Compiler::SetXer(Value * val_x64) { auto val_i64 = m_ir_builder->CreateBitCast(val_x64, m_ir_builder->getInt64Ty()); auto xer_i8_ptr = m_ir_builder->CreateConstGEP1_32(m_state.args[CompileTaskState::Args::State], (unsigned int)offsetof(PPUThread, XER)); auto xer_i64_ptr = m_ir_builder->CreateBitCast(xer_i8_ptr, m_ir_builder->getInt64Ty()->getPointerTo()); m_ir_builder->CreateAlignedStore(val_i64, xer_i64_ptr, 8); } void Compiler::SetXerCa(Value * ca) { auto xer_i64 = GetXer(); xer_i64 = SetBit(xer_i64, 34, ca); SetXer(xer_i64); } void Compiler::SetXerSo(Value * so) { auto xer_i64 = GetXer(); xer_i64 = SetBit(xer_i64, 32, so); SetXer(xer_i64); } Value * Compiler::GetUsprg0() { auto usrpg0_i8_ptr = m_ir_builder->CreateConstGEP1_32(m_state.args[CompileTaskState::Args::State], (unsigned int)offsetof(PPUThread, USPRG0)); auto usprg0_i64_ptr = m_ir_builder->CreateBitCast(usrpg0_i8_ptr, m_ir_builder->getInt64Ty()->getPointerTo()); return m_ir_builder->CreateAlignedLoad(usprg0_i64_ptr, 8); } void Compiler::SetUsprg0(Value * val_x64) { auto val_i64 = m_ir_builder->CreateBitCast(val_x64, m_ir_builder->getInt64Ty()); auto usprg0_i8_ptr = m_ir_builder->CreateConstGEP1_32(m_state.args[CompileTaskState::Args::State], (unsigned int)offsetof(PPUThread, USPRG0)); auto usprg0_i64_ptr = m_ir_builder->CreateBitCast(usprg0_i8_ptr, m_ir_builder->getInt64Ty()->getPointerTo()); m_ir_builder->CreateAlignedStore(val_i64, usprg0_i64_ptr, 8); } Value * Compiler::GetFpr(u32 r, u32 bits, bool as_int) { auto r_i8_ptr = m_ir_builder->CreateConstGEP1_32(m_state.args[CompileTaskState::Args::State], (unsigned int)offsetof(PPUThread, FPR[r])); if (!as_int) { auto r_f64_ptr = m_ir_builder->CreateBitCast(r_i8_ptr, m_ir_builder->getDoubleTy()->getPointerTo()); auto r_f64 = m_ir_builder->CreateAlignedLoad(r_f64_ptr, 8); if (bits == 32) { return m_ir_builder->CreateFPTrunc(r_f64, m_ir_builder->getFloatTy()); } else { return r_f64; } } else { auto r_i64_ptr = m_ir_builder->CreateBitCast(r_i8_ptr, m_ir_builder->getInt64Ty()->getPointerTo()); auto r_i64 = m_ir_builder->CreateAlignedLoad(r_i64_ptr, 8); if (bits == 32) { return m_ir_builder->CreateTrunc(r_i64, m_ir_builder->getInt32Ty()); } else { return r_i64; } } } void Compiler::SetFpr(u32 r, Value * val) { auto r_i8_ptr = m_ir_builder->CreateConstGEP1_32(m_state.args[CompileTaskState::Args::State], (unsigned int)offsetof(PPUThread, FPR[r])); auto r_f64_ptr = m_ir_builder->CreateBitCast(r_i8_ptr, m_ir_builder->getDoubleTy()->getPointerTo()); Value* val_f64; if (val->getType()->isDoubleTy() || val->getType()->isIntegerTy(64)) { val_f64 = m_ir_builder->CreateBitCast(val, m_ir_builder->getDoubleTy()); } else if (val->getType()->isFloatTy() || val->getType()->isIntegerTy(32)) { auto val_f32 = m_ir_builder->CreateBitCast(val, m_ir_builder->getFloatTy()); val_f64 = m_ir_builder->CreateFPExt(val_f32, m_ir_builder->getDoubleTy()); } else { assert(0); } m_ir_builder->CreateAlignedStore(val_f64, r_f64_ptr, 8); } Value * Compiler::GetVscr() { auto vscr_i8_ptr = m_ir_builder->CreateConstGEP1_32(m_state.args[CompileTaskState::Args::State], (unsigned int)offsetof(PPUThread, VSCR)); auto vscr_i32_ptr = m_ir_builder->CreateBitCast(vscr_i8_ptr, m_ir_builder->getInt32Ty()->getPointerTo()); return m_ir_builder->CreateAlignedLoad(vscr_i32_ptr, 4); } void Compiler::SetVscr(Value * val_x32) { auto val_i32 = m_ir_builder->CreateBitCast(val_x32, m_ir_builder->getInt32Ty()); auto vscr_i8_ptr = m_ir_builder->CreateConstGEP1_32(m_state.args[CompileTaskState::Args::State], (unsigned int)offsetof(PPUThread, VSCR)); auto vscr_i32_ptr = m_ir_builder->CreateBitCast(vscr_i8_ptr, m_ir_builder->getInt32Ty()->getPointerTo()); m_ir_builder->CreateAlignedStore(val_i32, vscr_i32_ptr, 4); } Value * Compiler::GetVr(u32 vr) { auto vr_i8_ptr = m_ir_builder->CreateConstGEP1_32(m_state.args[CompileTaskState::Args::State], (unsigned int)offsetof(PPUThread, VPR[vr])); auto vr_i128_ptr = m_ir_builder->CreateBitCast(vr_i8_ptr, m_ir_builder->getIntNTy(128)->getPointerTo()); return m_ir_builder->CreateAlignedLoad(vr_i128_ptr, 16); } Value * Compiler::GetVrAsIntVec(u32 vr, u32 vec_elt_num_bits) { auto vr_i8_ptr = m_ir_builder->CreateConstGEP1_32(m_state.args[CompileTaskState::Args::State], (unsigned int)offsetof(PPUThread, VPR[vr])); auto vr_i128_ptr = m_ir_builder->CreateBitCast(vr_i8_ptr, m_ir_builder->getIntNTy(128)->getPointerTo()); auto vr_vec_ptr = m_ir_builder->CreateBitCast(vr_i128_ptr, VectorType::get(m_ir_builder->getIntNTy(vec_elt_num_bits), 128 / vec_elt_num_bits)->getPointerTo()); return m_ir_builder->CreateAlignedLoad(vr_vec_ptr, 16); } Value * Compiler::GetVrAsFloatVec(u32 vr) { auto vr_i8_ptr = m_ir_builder->CreateConstGEP1_32(m_state.args[CompileTaskState::Args::State], (unsigned int)offsetof(PPUThread, VPR[vr])); auto vr_i128_ptr = m_ir_builder->CreateBitCast(vr_i8_ptr, m_ir_builder->getIntNTy(128)->getPointerTo()); auto vr_v4f32_ptr = m_ir_builder->CreateBitCast(vr_i128_ptr, VectorType::get(m_ir_builder->getFloatTy(), 4)->getPointerTo()); return m_ir_builder->CreateAlignedLoad(vr_v4f32_ptr, 16); } Value * Compiler::GetVrAsDoubleVec(u32 vr) { auto vr_i8_ptr = m_ir_builder->CreateConstGEP1_32(m_state.args[CompileTaskState::Args::State], (unsigned int)offsetof(PPUThread, VPR[vr])); auto vr_i128_ptr = m_ir_builder->CreateBitCast(vr_i8_ptr, m_ir_builder->getIntNTy(128)->getPointerTo()); auto vr_v2f64_ptr = m_ir_builder->CreateBitCast(vr_i128_ptr, VectorType::get(m_ir_builder->getDoubleTy(), 2)->getPointerTo()); return m_ir_builder->CreateAlignedLoad(vr_v2f64_ptr, 16); } void Compiler::SetVr(u32 vr, Value * val_x128) { auto vr_i8_ptr = m_ir_builder->CreateConstGEP1_32(m_state.args[CompileTaskState::Args::State], (unsigned int)offsetof(PPUThread, VPR[vr])); auto vr_i128_ptr = m_ir_builder->CreateBitCast(vr_i8_ptr, m_ir_builder->getIntNTy(128)->getPointerTo()); auto val_i128 = m_ir_builder->CreateBitCast(val_x128, m_ir_builder->getIntNTy(128)); m_ir_builder->CreateAlignedStore(val_i128, vr_i128_ptr, 16); } Value * Compiler::CheckBranchCondition(u32 bo, u32 bi) { bool bo0 = bo & 0x10 ? true : false; bool bo1 = bo & 0x08 ? true : false; bool bo2 = bo & 0x04 ? true : false; bool bo3 = bo & 0x02 ? true : false; auto ctr_i64 = GetCtr(); if (!bo2) { ctr_i64 = m_ir_builder->CreateSub(ctr_i64, m_ir_builder->getInt64(1)); SetCtr(ctr_i64); } Value * ctr_ok_i1 = nullptr; if (!bo2) { // TODO: Check if we should compare all bits or just the lower 32 bits. This depends on MSR[SF]. Not sure what it is for PS3. ctr_ok_i1 = m_ir_builder->CreateICmpNE(ctr_i64, m_ir_builder->getInt64(0)); if (bo3) { ctr_ok_i1 = m_ir_builder->CreateXor(ctr_ok_i1, m_ir_builder->getInt1(bo3)); } } Value * cond_ok_i1 = nullptr; if (!bo0) { auto cr_bi_i32 = GetBit(GetCr(), bi); cond_ok_i1 = m_ir_builder->CreateTrunc(cr_bi_i32, m_ir_builder->getInt1Ty()); if (!bo1) { cond_ok_i1 = m_ir_builder->CreateXor(cond_ok_i1, m_ir_builder->getInt1(!bo1)); } } Value * cmp_i1 = nullptr; if (ctr_ok_i1 && cond_ok_i1) { cmp_i1 = m_ir_builder->CreateAnd(ctr_ok_i1, cond_ok_i1); } else if (ctr_ok_i1) { cmp_i1 = ctr_ok_i1; } else if (cond_ok_i1) { cmp_i1 = cond_ok_i1; } return cmp_i1; } void Compiler::CreateBranch(llvm::Value * cmp_i1, llvm::Value * target_i32, bool lk, bool target_is_lr) { if (lk) { SetLr(m_ir_builder->getInt64(m_state.current_instruction_address + 4)); } auto current_block = m_ir_builder->GetInsertBlock(); BasicBlock * target_block = nullptr; if (dyn_cast(target_i32)) { // Target address is an immediate value. u32 target_address = (u32)(dyn_cast(target_i32)->getLimitedValue()); if (lk) { // Function call if (cmp_i1) { // There is no need to create a new block for an unconditional jump target_block = GetBasicBlockFromAddress(m_state.current_instruction_address, "target"); m_ir_builder->SetInsertPoint(target_block); } SetPc(target_i32); IndirectCall(target_address, m_ir_builder->getInt64(0), true); m_ir_builder->CreateBr(GetBasicBlockFromAddress(m_state.current_instruction_address + 4)); } else { // Local branch target_block = GetBasicBlockFromAddress(target_address); } } else { // Target address is in a register if (cmp_i1) { // There is no need to create a new block for an unconditional jump target_block = GetBasicBlockFromAddress(m_state.current_instruction_address, "target"); m_ir_builder->SetInsertPoint(target_block); } SetPc(target_i32); if (target_is_lr && !lk) { // Return from this function m_ir_builder->CreateRet(m_ir_builder->getInt32(0)); } else if (lk) { auto next_block = GetBasicBlockFromAddress(m_state.current_instruction_address + 4); auto unknown_function_block = GetBasicBlockFromAddress(m_state.current_instruction_address, "unknown_function"); auto switch_instr = m_ir_builder->CreateSwitch(target_i32, unknown_function_block); m_ir_builder->SetInsertPoint(unknown_function_block); m_ir_builder->CreateCall3(m_execute_unknown_function, m_state.args[CompileTaskState::Args::State], m_state.args[CompileTaskState::Args::Interpreter], m_ir_builder->getInt64(0)); m_ir_builder->CreateBr(next_block); auto call_i = m_state.cfg->calls.find(m_state.current_instruction_address); if (call_i != m_state.cfg->calls.end()) { for (auto function_i = call_i->second.begin(); function_i != call_i->second.end(); function_i++) { auto block = GetBasicBlockFromAddress(m_state.current_instruction_address, fmt::Format("0x%08X", *function_i)); m_ir_builder->SetInsertPoint(block); IndirectCall(*function_i, m_ir_builder->getInt64(0), true); m_ir_builder->CreateBr(next_block); switch_instr->addCase(m_ir_builder->getInt32(*function_i), block); } } } else { auto switch_instr = m_ir_builder->CreateSwitch(target_i32, GetBasicBlockFromAddress(0xFFFFFFFF)); auto branch_i = m_state.cfg->branches.find(m_state.current_instruction_address); if (branch_i != m_state.cfg->branches.end()) { for (auto next_instr_i = branch_i->second.begin(); next_instr_i != branch_i->second.end(); next_instr_i++) { switch_instr->addCase(m_ir_builder->getInt32(*next_instr_i), GetBasicBlockFromAddress(*next_instr_i)); } } } } if (cmp_i1) { // Conditional branch auto next_block = GetBasicBlockFromAddress(m_state.current_instruction_address + 4); m_ir_builder->SetInsertPoint(current_block); m_ir_builder->CreateCondBr(cmp_i1, target_block, next_block); } else { // Unconditional branch if (target_block) { m_ir_builder->SetInsertPoint(current_block); m_ir_builder->CreateBr(target_block); } } m_state.hit_branch_instruction = true; } Value * Compiler::ReadMemory(Value * addr_i64, u32 bits, u32 alignment, bool bswap, bool could_be_mmio) { if (bits != 32 || could_be_mmio == false) { auto eaddr_i64 = m_ir_builder->CreateAdd(addr_i64, m_ir_builder->getInt64((u64)vm::get_ptr(0))); auto eaddr_ix_ptr = m_ir_builder->CreateIntToPtr(eaddr_i64, m_ir_builder->getIntNTy(bits)->getPointerTo()); auto val_ix = (Value *)m_ir_builder->CreateLoad(eaddr_ix_ptr, alignment); if (bits > 8 && bswap) { val_ix = m_ir_builder->CreateCall(Intrinsic::getDeclaration(m_module, Intrinsic::bswap, m_ir_builder->getIntNTy(bits)), val_ix); } return val_ix; } else { auto cmp_i1 = m_ir_builder->CreateICmpULT(addr_i64, m_ir_builder->getInt64(RAW_SPU_BASE_ADDR)); auto then_bb = GetBasicBlockFromAddress(m_state.current_instruction_address, "then"); auto else_bb = GetBasicBlockFromAddress(m_state.current_instruction_address, "else"); auto merge_bb = GetBasicBlockFromAddress(m_state.current_instruction_address, "merge"); m_ir_builder->CreateCondBr(cmp_i1, then_bb, else_bb); m_ir_builder->SetInsertPoint(then_bb); auto eaddr_i64 = m_ir_builder->CreateAdd(addr_i64, m_ir_builder->getInt64((u64)vm::get_ptr(0))); auto eaddr_i32_ptr = m_ir_builder->CreateIntToPtr(eaddr_i64, m_ir_builder->getInt32Ty()->getPointerTo()); auto val_then_i32 = (Value *)m_ir_builder->CreateAlignedLoad(eaddr_i32_ptr, alignment); if (bswap) { val_then_i32 = m_ir_builder->CreateCall(Intrinsic::getDeclaration(m_module, Intrinsic::bswap, m_ir_builder->getInt32Ty()), val_then_i32); } m_ir_builder->CreateBr(merge_bb); m_ir_builder->SetInsertPoint(else_bb); auto val_else_i32 = Call("vm.read32", (u32(*)(u64))vm::read32, addr_i64); if (!bswap) { val_else_i32 = m_ir_builder->CreateCall(Intrinsic::getDeclaration(m_module, Intrinsic::bswap, m_ir_builder->getInt32Ty()), val_else_i32); } m_ir_builder->CreateBr(merge_bb); m_ir_builder->SetInsertPoint(merge_bb); auto phi = m_ir_builder->CreatePHI(m_ir_builder->getInt32Ty(), 2); phi->addIncoming(val_then_i32, then_bb); phi->addIncoming(val_else_i32, else_bb); return phi; } } void Compiler::WriteMemory(Value * addr_i64, Value * val_ix, u32 alignment, bool bswap, bool could_be_mmio) { addr_i64 = m_ir_builder->CreateAnd(addr_i64, 0xFFFFFFFF); if (val_ix->getType()->getIntegerBitWidth() != 32 || could_be_mmio == false) { if (val_ix->getType()->getIntegerBitWidth() > 8 && bswap) { val_ix = m_ir_builder->CreateCall(Intrinsic::getDeclaration(m_module, Intrinsic::bswap, val_ix->getType()), val_ix); } auto eaddr_i64 = m_ir_builder->CreateAdd(addr_i64, m_ir_builder->getInt64((u64)vm::get_ptr(0))); auto eaddr_ix_ptr = m_ir_builder->CreateIntToPtr(eaddr_i64, val_ix->getType()->getPointerTo()); m_ir_builder->CreateAlignedStore(val_ix, eaddr_ix_ptr, alignment); } else { auto cmp_i1 = m_ir_builder->CreateICmpULT(addr_i64, m_ir_builder->getInt64(RAW_SPU_BASE_ADDR)); auto then_bb = GetBasicBlockFromAddress(m_state.current_instruction_address, "then"); auto else_bb = GetBasicBlockFromAddress(m_state.current_instruction_address, "else"); auto merge_bb = GetBasicBlockFromAddress(m_state.current_instruction_address, "merge"); m_ir_builder->CreateCondBr(cmp_i1, then_bb, else_bb); m_ir_builder->SetInsertPoint(then_bb); Value * val_then_i32 = val_ix; if (bswap) { val_then_i32 = m_ir_builder->CreateCall(Intrinsic::getDeclaration(m_module, Intrinsic::bswap, m_ir_builder->getInt32Ty()), val_then_i32); } auto eaddr_i64 = m_ir_builder->CreateAdd(addr_i64, m_ir_builder->getInt64((u64)vm::get_ptr(0))); auto eaddr_i32_ptr = m_ir_builder->CreateIntToPtr(eaddr_i64, m_ir_builder->getInt32Ty()->getPointerTo()); m_ir_builder->CreateAlignedStore(val_then_i32, eaddr_i32_ptr, alignment); m_ir_builder->CreateBr(merge_bb); m_ir_builder->SetInsertPoint(else_bb); Value * val_else_i32 = val_ix; if (!bswap) { val_else_i32 = m_ir_builder->CreateCall(Intrinsic::getDeclaration(m_module, Intrinsic::bswap, m_ir_builder->getInt32Ty()), val_else_i32); } Call("vm.write32", (void(*)(u64, u32))vm::write32, addr_i64, val_else_i32); m_ir_builder->CreateBr(merge_bb); m_ir_builder->SetInsertPoint(merge_bb); } } template Value * Compiler::InterpreterCall(const char * name, Func function, Args... args) { auto i = m_stats.interpreter_fallback_stats.find(name); if (i == m_stats.interpreter_fallback_stats.end()) { i = m_stats.interpreter_fallback_stats.insert(m_stats.interpreter_fallback_stats.end(), std::make_pair(name, 0)); } i->second++; return Call(name, function, m_state.args[CompileTaskState::Args::Interpreter], m_ir_builder->getInt32(args)...); } template Type * Compiler::CppToLlvmType() { if (std::is_void::value) { return m_ir_builder->getVoidTy(); } else if (std::is_same::value || std::is_same::value) { return m_ir_builder->getInt64Ty(); } else if (std::is_same::value || std::is_same::value) { return m_ir_builder->getInt32Ty(); } else if (std::is_same::value || std::is_same::value) { return m_ir_builder->getInt16Ty(); } else if (std::is_same::value || std::is_same::value) { return m_ir_builder->getInt8Ty(); } else if (std::is_same::value) { return m_ir_builder->getFloatTy(); } else if (std::is_same::value) { return m_ir_builder->getDoubleTy(); } else if (std::is_pointer::value) { return m_ir_builder->getInt8PtrTy(); } else { assert(0); } return nullptr; } template Value * Compiler::Call(const char * name, Func function, Args... args) { auto fn = m_module->getFunction(name); if (!fn) { std::vector fn_args_type = {args->getType()...}; auto fn_type = FunctionType::get(CppToLlvmType(), fn_args_type, false); fn = cast(m_module->getOrInsertFunction(name, fn_type)); fn->setCallingConv(CallingConv::X86_64_Win64); m_execution_engine->addGlobalMapping(fn, (void *&)function); } std::vector fn_args = {args...}; return m_ir_builder->CreateCall(fn, fn_args); } llvm::Value * Compiler::IndirectCall(u32 address, Value * context_i64, bool is_function) { auto ordinal = m_recompilation_engine.AllocateOrdinal(address, is_function); auto location_i64 = m_ir_builder->getInt64(m_recompilation_engine.GetAddressOfExecutableLookup() + (ordinal * sizeof(u64))); auto location_i64_ptr = m_ir_builder->CreateIntToPtr(location_i64, m_ir_builder->getInt64Ty()->getPointerTo()); auto executable_i64 = m_ir_builder->CreateLoad(location_i64_ptr); auto executable_ptr = m_ir_builder->CreateIntToPtr(executable_i64, m_compiled_function_type->getPointerTo()); return m_ir_builder->CreateCall3(executable_ptr, m_state.args[CompileTaskState::Args::State], m_state.args[CompileTaskState::Args::Interpreter], context_i64); } void Compiler::InitRotateMask() { for (u32 mb = 0; mb < 64; mb++) { for (u32 me = 0; me < 64; me++) { u64 mask = ((u64)-1 >> mb) ^ ((me >= 63) ? 0 : (u64)-1 >> (me + 1)); s_rotate_mask[mb][me] = mb > me ? ~mask : mask; } } } std::mutex RecompilationEngine::s_mutex; std::shared_ptr RecompilationEngine::s_the_instance = nullptr; RecompilationEngine::RecompilationEngine() : ThreadBase("PPU Recompilation Engine") , m_next_ordinal(0) , m_compiler(*this, ExecutionEngine::ExecuteFunction, ExecutionEngine::ExecuteTillReturn) { std::string error; m_log = new raw_fd_ostream("PPULLVMRecompiler.log", error, sys::fs::F_Text); m_log->SetUnbuffered(); } RecompilationEngine::~RecompilationEngine() { Stop(); } u32 RecompilationEngine::AllocateOrdinal(u32 address, bool is_function) { std::lock_guard lock(m_address_to_ordinal_lock); auto i = m_address_to_ordinal.find(address); if (i == m_address_to_ordinal.end()) { assert(m_next_ordinal < (sizeof(m_executable_lookup) / sizeof(m_executable_lookup[0]))); m_executable_lookup[m_next_ordinal] = is_function ? ExecutionEngine::ExecuteFunction : ExecutionEngine::ExecuteTillReturn; std::atomic_thread_fence(std::memory_order_release); i = m_address_to_ordinal.insert(m_address_to_ordinal.end(), std::make_pair(address, m_next_ordinal++)); } return i->second; } u32 RecompilationEngine::GetOrdinal(u32 address) const { std::lock_guard lock(m_address_to_ordinal_lock); auto i = m_address_to_ordinal.find(address); if (i != m_address_to_ordinal.end()) { return i->second; } else { return 0xFFFFFFFF; } } const Executable RecompilationEngine::GetExecutable(u32 ordinal) const { std::atomic_thread_fence(std::memory_order_acquire); return m_executable_lookup[ordinal]; } u64 RecompilationEngine::GetAddressOfExecutableLookup() const { return (u64)m_executable_lookup; } void RecompilationEngine::NotifyTrace(ExecutionTrace * execution_trace) { { std::lock_guard lock(m_pending_execution_traces_lock); m_pending_execution_traces.push_back(execution_trace); } if (!IsAlive()) { Start(); } Notify(); // TODO: Increase the priority of the recompilation engine thread } raw_fd_ostream & RecompilationEngine::Log() { return *m_log; } void RecompilationEngine::Task() { bool is_idling = false; std::chrono::nanoseconds idling_time(0); std::chrono::nanoseconds recompiling_time(0); auto start = std::chrono::high_resolution_clock::now(); while (!TestDestroy() && !Emu.IsStopped()) { bool work_done_this_iteration = false; ExecutionTrace * execution_trace = nullptr; { std::lock_guard lock(m_pending_execution_traces_lock); auto i = m_pending_execution_traces.begin(); if (i != m_pending_execution_traces.end()) { execution_trace = *i; m_pending_execution_traces.erase(i); } } if (execution_trace) { ProcessExecutionTrace(*execution_trace); delete execution_trace; work_done_this_iteration = true; } if (!work_done_this_iteration) { // TODO: Reduce the priority of the recompilation engine thread if its set to high priority } else { is_idling = false; } if (is_idling) { auto recompiling_start = std::chrono::high_resolution_clock::now(); // Recompile the function whose CFG has changed the most since the last time it was compiled auto candidate = (BlockEntry *)nullptr; size_t max_diff = 0; for (auto block : m_block_table) { if (block->IsFunction() && block->is_compiled) { auto diff = block->cfg.GetSize() - block->last_compiled_cfg_size; if (diff > max_diff) { candidate = block; max_diff = diff; } } } if (candidate != nullptr) { Log() << "Recompiling: " << candidate->ToString() << "\n"; CompileBlock(*candidate); work_done_this_iteration = true; } auto recompiling_end = std::chrono::high_resolution_clock::now(); recompiling_time += std::chrono::duration_cast(recompiling_end - recompiling_start); } if (!work_done_this_iteration) { is_idling = true; // Wait a few ms for something to happen auto idling_start = std::chrono::high_resolution_clock::now(); WaitForAnySignal(250); auto idling_end = std::chrono::high_resolution_clock::now(); idling_time += std::chrono::duration_cast(idling_end - idling_start); } } std::chrono::high_resolution_clock::time_point end = std::chrono::high_resolution_clock::now(); auto total_time = std::chrono::duration_cast(end - start); auto compiler_stats = m_compiler.GetStats(); Log() << "Total time = " << total_time.count() / 1000000 << "ms\n"; Log() << " Time spent compiling = " << compiler_stats.total_time.count() / 1000000 << "ms\n"; Log() << " Time spent building IR = " << compiler_stats.ir_build_time.count() / 1000000 << "ms\n"; Log() << " Time spent optimizing = " << compiler_stats.optimization_time.count() / 1000000 << "ms\n"; Log() << " Time spent translating = " << compiler_stats.translation_time.count() / 1000000 << "ms\n"; Log() << " Time spent recompiling = " << recompiling_time.count() / 1000000 << "ms\n"; Log() << " Time spent idling = " << idling_time.count() / 1000000 << "ms\n"; Log() << " Time spent doing misc tasks = " << (total_time.count() - idling_time.count() - compiler_stats.total_time.count()) / 1000000 << "ms\n"; Log() << "Ordinals allocated = " << m_next_ordinal << "\n"; Log() << "\nInterpreter fallback stats:\n"; for (auto i = compiler_stats.interpreter_fallback_stats.begin(); i != compiler_stats.interpreter_fallback_stats.end(); i++) { Log() << i->first << " = " << i->second << "\n"; } LOG_NOTICE(PPU, "PPU LLVM Recompilation thread exiting."); s_the_instance = nullptr; // Can cause deadlock if this is the last instance. Need to fix this. } void RecompilationEngine::ProcessExecutionTrace(const ExecutionTrace & execution_trace) { auto execution_trace_id = execution_trace.GetId(); auto processed_execution_trace_i = m_processed_execution_traces.find(execution_trace_id); if (processed_execution_trace_i == m_processed_execution_traces.end()) { #ifdef _DEBUG Log() << "Trace: " << execution_trace.ToString() << "\n"; #endif // Find the function block BlockEntry key(execution_trace.function_address, execution_trace.function_address); auto block_i = m_block_table.find(&key); if (block_i == m_block_table.end()) { block_i = m_block_table.insert(m_block_table.end(), new BlockEntry(key.cfg.start_address, key.cfg.function_address)); } auto function_block = *block_i; block_i = m_block_table.end(); auto split_trace = false; std::vector tmp_block_list; for (auto trace_i = execution_trace.entries.begin(); trace_i != execution_trace.entries.end(); trace_i++) { if (trace_i->type == ExecutionTraceEntry::Type::CompiledBlock) { block_i = m_block_table.end(); split_trace = true; } if (block_i == m_block_table.end()) { BlockEntry key(trace_i->GetPrimaryAddress(), execution_trace.function_address); block_i = m_block_table.find(&key); if (block_i == m_block_table.end()) { block_i = m_block_table.insert(m_block_table.end(), new BlockEntry(key.cfg.start_address, key.cfg.function_address)); } tmp_block_list.push_back(*block_i); } const ExecutionTraceEntry * next_trace = nullptr; if (trace_i + 1 != execution_trace.entries.end()) { next_trace = &(*(trace_i + 1)); } else if (!split_trace && execution_trace.type == ExecutionTrace::Type::Loop) { next_trace = &(*(execution_trace.entries.begin())); } UpdateControlFlowGraph((*block_i)->cfg, *trace_i, next_trace); if (*block_i != function_block) { UpdateControlFlowGraph(function_block->cfg, *trace_i, next_trace); } } processed_execution_trace_i = m_processed_execution_traces.insert(m_processed_execution_traces.end(), std::make_pair(execution_trace_id, std::move(tmp_block_list))); } for (auto i = processed_execution_trace_i->second.begin(); i != processed_execution_trace_i->second.end(); i++) { if (!(*i)->is_compiled) { (*i)->num_hits++; if ((*i)->num_hits >= 1000) { // TODO: Make this configurable CompileBlock(*(*i)); } } } std::remove_if(processed_execution_trace_i->second.begin(), processed_execution_trace_i->second.end(), [](const BlockEntry * b)->bool { return b->is_compiled; }); } void RecompilationEngine::UpdateControlFlowGraph(ControlFlowGraph & cfg, const ExecutionTraceEntry & this_entry, const ExecutionTraceEntry * next_entry) { if (this_entry.type == ExecutionTraceEntry::Type::Instruction) { cfg.instruction_addresses.insert(this_entry.GetPrimaryAddress()); if (next_entry) { if (next_entry->type == ExecutionTraceEntry::Type::Instruction || next_entry->type == ExecutionTraceEntry::Type::CompiledBlock) { if (next_entry->GetPrimaryAddress() != (this_entry.GetPrimaryAddress() + 4)) { cfg.branches[this_entry.GetPrimaryAddress()].insert(next_entry->GetPrimaryAddress()); } } else if (next_entry->type == ExecutionTraceEntry::Type::FunctionCall) { cfg.calls[this_entry.data.instruction.address].insert(next_entry->GetPrimaryAddress()); } } } else if (this_entry.type == ExecutionTraceEntry::Type::CompiledBlock) { if (next_entry) { if (next_entry->type == ExecutionTraceEntry::Type::Instruction || next_entry->type == ExecutionTraceEntry::Type::CompiledBlock) { cfg.branches[this_entry.data.compiled_block.exit_address].insert(next_entry->GetPrimaryAddress()); } else if (next_entry->type == ExecutionTraceEntry::Type::FunctionCall) { cfg.calls[this_entry.data.compiled_block.exit_address].insert(next_entry->GetPrimaryAddress()); } } } } void RecompilationEngine::CompileBlock(BlockEntry & block_entry) { #ifdef _DEBUG Log() << "Compile: " << block_entry.ToString() << "\n"; Log() << "CFG: " << cfg->ToString() << "\n"; #endif auto ordinal = AllocateOrdinal(block_entry.cfg.start_address, block_entry.IsFunction()); auto executable = m_compiler.Compile(fmt::Format("fn_0x%08X_%u", block_entry.cfg.start_address, block_entry.revision++), block_entry.cfg, true, block_entry.IsFunction() ? true : false /*generate_linkable_exits*/); m_executable_lookup[ordinal] = executable; block_entry.last_compiled_cfg_size = block_entry.cfg.GetSize(); block_entry.is_compiled = true; } std::shared_ptr RecompilationEngine::GetInstance() { std::lock_guard lock(s_mutex); if (s_the_instance == nullptr) { s_the_instance = std::shared_ptr(new RecompilationEngine()); } return s_the_instance; } Tracer::Tracer() : m_recompilation_engine(RecompilationEngine::GetInstance()) { m_stack.reserve(100); } Tracer::~Tracer() { Terminate(); } void Tracer::Trace(TraceType trace_type, u32 arg1, u32 arg2) { ExecutionTrace * execution_trace = nullptr; switch (trace_type) { case TraceType::CallFunction: // arg1 is address of the function m_stack.back()->entries.push_back(ExecutionTraceEntry(ExecutionTraceEntry::Type::FunctionCall, arg1)); break; case TraceType::EnterFunction: // arg1 is address of the function m_stack.push_back(new ExecutionTrace(arg1)); break; case TraceType::ExitFromCompiledFunction: // arg1 is address of function. // arg2 is the address of the exit instruction. if (arg2) { m_stack.push_back(new ExecutionTrace(arg1)); m_stack.back()->entries.push_back(ExecutionTraceEntry(ExecutionTraceEntry::Type::CompiledBlock, arg1, arg2)); } break; case TraceType::Return: // No args used execution_trace = m_stack.back(); execution_trace->type = ExecutionTrace::Type::Linear; m_stack.pop_back(); break; case TraceType::Instruction: // arg1 is the address of the instruction for (int i = (int)m_stack.back()->entries.size() - 1; i >= 0; i--) { if ((m_stack.back()->entries[i].type == ExecutionTraceEntry::Type::Instruction && m_stack.back()->entries[i].data.instruction.address == arg1) || (m_stack.back()->entries[i].type == ExecutionTraceEntry::Type::CompiledBlock && m_stack.back()->entries[i].data.compiled_block.entry_address == arg1)) { // Found a loop execution_trace = new ExecutionTrace(m_stack.back()->function_address); execution_trace->type = ExecutionTrace::Type::Loop; std::copy(m_stack.back()->entries.begin() + i, m_stack.back()->entries.end(), std::back_inserter(execution_trace->entries)); m_stack.back()->entries.erase(m_stack.back()->entries.begin() + i + 1, m_stack.back()->entries.end()); break; } } if (!execution_trace) { // A loop was not found m_stack.back()->entries.push_back(ExecutionTraceEntry(ExecutionTraceEntry::Type::Instruction, arg1)); } break; case TraceType::ExitFromCompiledBlock: // arg1 is address of the compiled block. // arg2 is the address of the exit instruction. m_stack.back()->entries.push_back(ExecutionTraceEntry(ExecutionTraceEntry::Type::CompiledBlock, arg1, arg2)); if (arg2 == 0) { // Return from function execution_trace = m_stack.back(); execution_trace->type = ExecutionTrace::Type::Linear; m_stack.pop_back(); } break; default: assert(0); break; } if (execution_trace) { m_recompilation_engine->NotifyTrace(execution_trace); } } void Tracer::Terminate() { // TODO: Notify recompilation engine } ppu_recompiler_llvm::ExecutionEngine::ExecutionEngine(PPUThread & ppu) : m_ppu(ppu) , m_interpreter(new PPUInterpreter(ppu)) , m_decoder(m_interpreter) , m_last_cache_clear_time(std::chrono::high_resolution_clock::now()) , m_recompilation_engine(RecompilationEngine::GetInstance()) { } ppu_recompiler_llvm::ExecutionEngine::~ExecutionEngine() { } u8 ppu_recompiler_llvm::ExecutionEngine::DecodeMemory(const u32 address) { ExecuteFunction(&m_ppu, m_interpreter, 0); return 0; } void ppu_recompiler_llvm::ExecutionEngine::RemoveUnusedEntriesFromCache() const { auto now = std::chrono::high_resolution_clock::now(); if (std::chrono::duration_cast(now - m_last_cache_clear_time).count() > 10000) { for (auto i = m_address_to_ordinal.begin(); i != m_address_to_ordinal.end();) { auto tmp = i; i++; if (tmp->second.second == 0) { m_address_to_ordinal.erase(tmp); } else { tmp->second.second = 0; } } m_last_cache_clear_time = now; } } Executable ppu_recompiler_llvm::ExecutionEngine::GetExecutable(u32 address, Executable default_executable) const { // Find the ordinal for the specified address and insert it to the cache auto i = m_address_to_ordinal.find(address); if (i == m_address_to_ordinal.end()) { auto ordinal = m_recompilation_engine->GetOrdinal(address); if (ordinal != 0xFFFFFFFF) { i = m_address_to_ordinal.insert(m_address_to_ordinal.end(), std::make_pair(address, std::make_pair(ordinal, 0))); } } Executable executable = default_executable; if (i != m_address_to_ordinal.end()) { i->second.second++; executable = m_recompilation_engine->GetExecutable(i->second.first); } RemoveUnusedEntriesFromCache(); return executable; } u32 ppu_recompiler_llvm::ExecutionEngine::ExecuteFunction(PPUThread * ppu_state, PPUInterpreter * interpreter, u64 context) { auto execution_engine = (ExecutionEngine *)ppu_state->GetDecoder(); execution_engine->m_tracer.Trace(Tracer::TraceType::EnterFunction, ppu_state->PC, 0); return ExecuteTillReturn(ppu_state, interpreter, 0); } u32 ppu_recompiler_llvm::ExecutionEngine::ExecuteTillReturn(PPUThread * ppu_state, PPUInterpreter * interpreter, u64 context) { auto execution_engine = (ExecutionEngine *)ppu_state->GetDecoder(); auto terminate = false; auto branch_type = BranchType::NonBranch; if (context) { execution_engine->m_tracer.Trace(Tracer::TraceType::ExitFromCompiledFunction, context >> 32, context & 0xFFFFFFFF); } while (!terminate && !Emu.IsStopped()) { if (Emu.IsPaused()) { std::this_thread::sleep_for(std::chrono::milliseconds(50)); continue; } auto executable = execution_engine->GetExecutable(ppu_state->PC, ExecuteTillReturn); if (executable != ExecuteTillReturn && executable != ExecuteFunction) { auto entry = ppu_state->PC; auto exit = (u32)executable(ppu_state, interpreter, 0); execution_engine->m_tracer.Trace(Tracer::TraceType::ExitFromCompiledBlock, entry, exit); if (exit == 0) { terminate = true; } } else { execution_engine->m_tracer.Trace(Tracer::TraceType::Instruction, ppu_state->PC, 0); auto instruction = re32(vm::get_ref(ppu_state->PC)); execution_engine->m_decoder.Decode(instruction); branch_type = ppu_state->m_is_branch ? GetBranchTypeFromInstruction(instruction) : BranchType::NonBranch; ppu_state->NextPc(4); switch (branch_type) { case BranchType::Return: execution_engine->m_tracer.Trace(Tracer::TraceType::Return, 0, 0); terminate = true; break; case BranchType::FunctionCall: execution_engine->m_tracer.Trace(Tracer::TraceType::CallFunction, ppu_state->PC, 0); executable = execution_engine->GetExecutable(ppu_state->PC, ExecuteFunction); executable(ppu_state, interpreter, 0); break; case BranchType::LocalBranch: break; case BranchType::NonBranch: break; default: assert(0); break; } } } return 0; } BranchType ppu_recompiler_llvm::GetBranchTypeFromInstruction(u32 instruction) { auto type = BranchType::NonBranch; auto field1 = instruction >> 26; auto lk = instruction & 1; if (field1 == 16 || field1 == 18) { type = lk ? BranchType::FunctionCall : BranchType::LocalBranch; } else if (field1 == 19) { u32 field2 = (instruction >> 1) & 0x3FF; if (field2 == 16) { type = lk ? BranchType::FunctionCall : BranchType::Return; } else if (field2 == 528) { type = lk ? BranchType::FunctionCall : BranchType::LocalBranch; } } return type; }