//===-- BenchmarkRunner.cpp -------------------------------------*- C++ -*-===// // // The LLVM Compiler Infrastructure // // This file is distributed under the University of Illinois Open Source // License. See LICENSE.TXT for details. // //===----------------------------------------------------------------------===// #include #include #include "Assembler.h" #include "BenchmarkRunner.h" #include "MCInstrDescView.h" #include "llvm/ADT/StringExtras.h" #include "llvm/ADT/StringRef.h" #include "llvm/ADT/Twine.h" #include "llvm/Support/FileSystem.h" #include "llvm/Support/FormatVariadic.h" #include "llvm/Support/MemoryBuffer.h" #include "llvm/Support/Program.h" namespace exegesis { BenchmarkFailure::BenchmarkFailure(const llvm::Twine &S) : llvm::StringError(S, llvm::inconvertibleErrorCode()) {} BenchmarkRunner::BenchmarkRunner(const LLVMState &State, InstructionBenchmark::ModeE Mode) : State(State), RATC(State.getRegInfo(), getFunctionReservedRegs(State.getTargetMachine())), Mode(Mode) {} BenchmarkRunner::~BenchmarkRunner() = default; llvm::Expected> BenchmarkRunner::run(unsigned Opcode, unsigned NumRepetitions) { const llvm::MCInstrDesc &InstrDesc = State.getInstrInfo().get(Opcode); // Ignore instructions that we cannot run. if (InstrDesc.isPseudo()) return llvm::make_error("Unsupported opcode: isPseudo"); if (InstrDesc.isBranch() || InstrDesc.isIndirectBranch()) return llvm::make_error( "Unsupported opcode: isBranch/isIndirectBranch"); if (InstrDesc.isCall() || InstrDesc.isReturn()) return llvm::make_error( "Unsupported opcode: isCall/isReturn"); llvm::Expected> ConfigurationOrError = generateConfigurations(Opcode); if (llvm::Error E = ConfigurationOrError.takeError()) return std::move(E); std::vector InstrBenchmarks; for (const BenchmarkConfiguration &Conf : ConfigurationOrError.get()) InstrBenchmarks.push_back(runOne(Conf, Opcode, NumRepetitions)); return InstrBenchmarks; } InstructionBenchmark BenchmarkRunner::runOne(const BenchmarkConfiguration &Configuration, unsigned Opcode, unsigned NumRepetitions) const { InstructionBenchmark InstrBenchmark; InstrBenchmark.Mode = Mode; InstrBenchmark.CpuName = State.getTargetMachine().getTargetCPU(); InstrBenchmark.LLVMTriple = State.getTargetMachine().getTargetTriple().normalize(); InstrBenchmark.NumRepetitions = NumRepetitions; InstrBenchmark.Info = Configuration.Info; const std::vector &Snippet = Configuration.Snippet; if (Snippet.empty()) { InstrBenchmark.Error = "Empty snippet"; return InstrBenchmark; } InstrBenchmark.Key.Instructions = Snippet; // Repeat the snippet until there are at least NumInstructions in the // resulting code. The snippet is always repeated at least once. const auto GenerateInstructions = [&Configuration]( const int MinInstructions) { std::vector Code = Configuration.Snippet; for (int I = 0; I < MinInstructions; ++I) Code.push_back(Configuration.Snippet[I % Configuration.Snippet.size()]); return Code; }; // Assemble at least kMinInstructionsForSnippet instructions by repeating the // snippet for debug/analysis. This is so that the user clearly understands // that the inside instructions are repeated. constexpr const int kMinInstructionsForSnippet = 16; { auto ObjectFilePath = writeObjectFile(Configuration.SnippetSetup, GenerateInstructions(kMinInstructionsForSnippet)); if (llvm::Error E = ObjectFilePath.takeError()) { InstrBenchmark.Error = llvm::toString(std::move(E)); return InstrBenchmark; } const ExecutableFunction EF(State.createTargetMachine(), getObjectFromFile(*ObjectFilePath)); const auto FnBytes = EF.getFunctionBytes(); InstrBenchmark.AssembledSnippet.assign(FnBytes.begin(), FnBytes.end()); } // Assemble NumRepetitions instructions repetitions of the snippet for // measurements. auto ObjectFilePath = writeObjectFile(Configuration.SnippetSetup, GenerateInstructions(InstrBenchmark.NumRepetitions)); if (llvm::Error E = ObjectFilePath.takeError()) { InstrBenchmark.Error = llvm::toString(std::move(E)); return InstrBenchmark; } llvm::outs() << "Check generated assembly with: /usr/bin/objdump -d " << *ObjectFilePath << "\n"; const ExecutableFunction EF(State.createTargetMachine(), getObjectFromFile(*ObjectFilePath)); InstrBenchmark.Measurements = runMeasurements(EF, NumRepetitions); return InstrBenchmark; } llvm::Expected> BenchmarkRunner::generateConfigurations(unsigned Opcode) const { if (auto E = generatePrototype(Opcode)) { SnippetPrototype &Prototype = E.get(); // TODO: Generate as many configurations as needed here. BenchmarkConfiguration Configuration; Configuration.Info = Prototype.Explanation; for (InstructionInstance &II : Prototype.Snippet) { II.randomizeUnsetVariables(); Configuration.Snippet.push_back(II.build()); } Configuration.SnippetSetup.RegsToDef = computeRegsToDef(Prototype.Snippet); return std::vector{Configuration}; } else return E.takeError(); } std::vector BenchmarkRunner::computeRegsToDef( const std::vector &Snippet) const { // Collect all register uses and create an assignment for each of them. // Loop invariant: DefinedRegs[i] is true iif it has been set at least once // before the current instruction. llvm::BitVector DefinedRegs = RATC.emptyRegisters(); std::vector RegsToDef; for (const InstructionInstance &II : Snippet) { // Returns the register that this Operand sets or uses, or 0 if this is not // a register. const auto GetOpReg = [&II](const Operand &Op) -> unsigned { if (Op.ImplicitReg) { return *Op.ImplicitReg; } else if (Op.IsExplicit && II.getValueFor(Op).isReg()) { return II.getValueFor(Op).getReg(); } return 0; }; // Collect used registers that have never been def'ed. for (const Operand &Op : II.Instr.Operands) { if (!Op.IsDef) { const unsigned Reg = GetOpReg(Op); if (Reg > 0 && !DefinedRegs.test(Reg)) { RegsToDef.push_back(Reg); DefinedRegs.set(Reg); } } } // Mark defs as having been def'ed. for (const Operand &Op : II.Instr.Operands) { if (Op.IsDef) { const unsigned Reg = GetOpReg(Op); if (Reg > 0) { DefinedRegs.set(Reg); } } } } return RegsToDef; } llvm::Expected BenchmarkRunner::writeObjectFile(const BenchmarkConfiguration::Setup &Setup, llvm::ArrayRef Code) const { int ResultFD = 0; llvm::SmallString<256> ResultPath; if (llvm::Error E = llvm::errorCodeToError(llvm::sys::fs::createTemporaryFile( "snippet", "o", ResultFD, ResultPath))) return std::move(E); llvm::raw_fd_ostream OFS(ResultFD, true /*ShouldClose*/); assembleToStream(State.getExegesisTarget(), State.createTargetMachine(), Setup.RegsToDef, Code, OFS); return ResultPath.str(); } llvm::Expected BenchmarkRunner::generateSelfAliasingPrototype(const Instruction &Instr) const { const AliasingConfigurations SelfAliasing(Instr, Instr); if (SelfAliasing.empty()) { return llvm::make_error("empty self aliasing"); } SnippetPrototype Prototype; InstructionInstance II(Instr); if (SelfAliasing.hasImplicitAliasing()) { Prototype.Explanation = "implicit Self cycles, picking random values."; } else { Prototype.Explanation = "explicit self cycles, selecting one aliasing Conf."; // This is a self aliasing instruction so defs and uses are from the same // instance, hence twice II in the following call. setRandomAliasing(SelfAliasing, II, II); } Prototype.Snippet.push_back(std::move(II)); return std::move(Prototype); } llvm::Expected BenchmarkRunner::generateUnconstrainedPrototype(const Instruction &Instr, llvm::StringRef Msg) const { SnippetPrototype Prototype; Prototype.Explanation = llvm::formatv("{0}, repeating an unconstrained assignment", Msg); Prototype.Snippet.emplace_back(Instr); return std::move(Prototype); } } // namespace exegesis