//===- ExecutionDriver.cpp - Allow execution of LLVM program --------------===// // // The LLVM Compiler Infrastructure // // This file was developed by the LLVM research group and is distributed under // the University of Illinois Open Source License. See LICENSE.TXT for details. // //===----------------------------------------------------------------------===// // // This file contains code used to execute the program utilizing one of the // various ways of running LLVM bytecode. // //===----------------------------------------------------------------------===// #include "BugDriver.h" #include "ToolRunner.h" #include "llvm/Support/CommandLine.h" #include "llvm/Support/Debug.h" #include "llvm/Support/FileUtilities.h" #include "llvm/Support/SystemUtils.h" #include #include using namespace llvm; namespace { // OutputType - Allow the user to specify the way code should be run, to test // for miscompilation. // enum OutputType { AutoPick, RunLLI, RunJIT, RunLLC, RunCBE, CBE_bug, LLC_Safe }; cl::opt AbsTolerance("abs-tolerance", cl::desc("Absolute error tolerated"), cl::init(0.0)); cl::opt RelTolerance("rel-tolerance", cl::desc("Relative error tolerated"), cl::init(0.0)); cl::opt InterpreterSel(cl::desc("Specify how LLVM code should be executed:"), cl::values(clEnumValN(AutoPick, "auto", "Use best guess"), clEnumValN(RunLLI, "run-int", "Execute with the interpreter"), clEnumValN(RunJIT, "run-jit", "Execute with JIT"), clEnumValN(RunLLC, "run-llc", "Compile with LLC"), clEnumValN(RunCBE, "run-cbe", "Compile with CBE"), clEnumValN(CBE_bug,"cbe-bug", "Find CBE bugs"), clEnumValN(LLC_Safe, "llc-safe", "Use LLC for all"), clEnumValEnd), cl::init(AutoPick)); cl::opt CheckProgramExitCode("check-exit-code", cl::desc("Assume nonzero exit code is failure (default on)"), cl::init(true)); cl::opt AppendProgramExitCode("append-exit-code", cl::desc("Append the exit code to the output so it gets diff'd too"), cl::init(false)); cl::opt InputFile("input", cl::init("/dev/null"), cl::desc("Filename to pipe in as stdin (default: /dev/null)")); cl::list AdditionalSOs("additional-so", cl::desc("Additional shared objects to load " "into executing programs")); cl::list AdditionalLinkerArgs("Xlinker", cl::desc("Additional arguments to pass to the linker")); } namespace llvm { // Anything specified after the --args option are taken as arguments to the // program being debugged. cl::list InputArgv("args", cl::Positional, cl::desc("..."), cl::ZeroOrMore, cl::PositionalEatsArgs); cl::list ToolArgv("tool-args", cl::Positional, cl::desc("..."), cl::ZeroOrMore, cl::PositionalEatsArgs); } //===----------------------------------------------------------------------===// // BugDriver method implementation // /// initializeExecutionEnvironment - This method is used to set up the /// environment for executing LLVM programs. /// bool BugDriver::initializeExecutionEnvironment() { std::cout << "Initializing execution environment: "; // Create an instance of the AbstractInterpreter interface as specified on // the command line cbe = 0; std::string Message; switch (InterpreterSel) { case AutoPick: InterpreterSel = RunCBE; Interpreter = cbe = AbstractInterpreter::createCBE(getToolName(), Message, &ToolArgv); if (!Interpreter) { InterpreterSel = RunJIT; Interpreter = AbstractInterpreter::createJIT(getToolName(), Message, &ToolArgv); } if (!Interpreter) { InterpreterSel = RunLLC; Interpreter = AbstractInterpreter::createLLC(getToolName(), Message, &ToolArgv); } if (!Interpreter) { InterpreterSel = RunLLI; Interpreter = AbstractInterpreter::createLLI(getToolName(), Message, &ToolArgv); } if (!Interpreter) { InterpreterSel = AutoPick; Message = "Sorry, I can't automatically select an interpreter!\n"; } break; case RunLLI: Interpreter = AbstractInterpreter::createLLI(getToolName(), Message, &ToolArgv); break; case RunLLC: Interpreter = AbstractInterpreter::createLLC(getToolName(), Message, &ToolArgv); break; case RunJIT: Interpreter = AbstractInterpreter::createJIT(getToolName(), Message, &ToolArgv); break; case LLC_Safe: Interpreter = AbstractInterpreter::createLLC(getToolName(), Message, &ToolArgv); break; case RunCBE: case CBE_bug: Interpreter = AbstractInterpreter::createCBE(getToolName(), Message, &ToolArgv); break; default: Message = "Sorry, this back-end is not supported by bugpoint right now!\n"; break; } std::cerr << Message; // Initialize auxiliary tools for debugging if (InterpreterSel == RunCBE) { // We already created a CBE, reuse it. cbe = Interpreter; } else if (InterpreterSel == CBE_bug || InterpreterSel == LLC_Safe) { // We want to debug the CBE itself or LLC is known-good. Use LLC as the // 'known-good' compiler. std::vector ToolArgs; ToolArgs.push_back("--relocation-model=pic"); cbe = AbstractInterpreter::createLLC(getToolName(), Message, &ToolArgs); } else { cbe = AbstractInterpreter::createCBE(getToolName(), Message, &ToolArgv); } if (!cbe) { std::cout << Message << "\nExiting.\n"; exit(1); } gcc = GCC::create(getToolName(), Message); if (!gcc) { std::cout << Message << "\nExiting.\n"; exit(1); } // If there was an error creating the selected interpreter, quit with error. return Interpreter == 0; } /// compileProgram - Try to compile the specified module, throwing an exception /// if an error occurs, or returning normally if not. This is used for code /// generation crash testing. /// void BugDriver::compileProgram(Module *M) { // Emit the program to a bytecode file... sys::Path BytecodeFile ("bugpoint-test-program.bc"); std::string ErrMsg; if (BytecodeFile.makeUnique(true,&ErrMsg)) { std::cerr << ToolName << ": Error making unique filename: " << ErrMsg << "\n"; exit(1); } if (writeProgramToFile(BytecodeFile.toString(), M)) { std::cerr << ToolName << ": Error emitting bytecode to file '" << BytecodeFile << "'!\n"; exit(1); } // Remove the temporary bytecode file when we are done. FileRemover BytecodeFileRemover(BytecodeFile); // Actually compile the program! Interpreter->compileProgram(BytecodeFile.toString()); } /// executeProgram - This method runs "Program", capturing the output of the /// program to a file, returning the filename of the file. A recommended /// filename may be optionally specified. /// std::string BugDriver::executeProgram(std::string OutputFile, std::string BytecodeFile, const std::string &SharedObj, AbstractInterpreter *AI, bool *ProgramExitedNonzero) { if (AI == 0) AI = Interpreter; assert(AI && "Interpreter should have been created already!"); bool CreatedBytecode = false; std::string ErrMsg; if (BytecodeFile.empty()) { // Emit the program to a bytecode file... sys::Path uniqueFilename("bugpoint-test-program.bc"); if (uniqueFilename.makeUnique(true, &ErrMsg)) { std::cerr << ToolName << ": Error making unique filename: " << ErrMsg << "!\n"; exit(1); } BytecodeFile = uniqueFilename.toString(); if (writeProgramToFile(BytecodeFile, Program)) { std::cerr << ToolName << ": Error emitting bytecode to file '" << BytecodeFile << "'!\n"; exit(1); } CreatedBytecode = true; } // Remove the temporary bytecode file when we are done. sys::Path BytecodePath (BytecodeFile); FileRemover BytecodeFileRemover(BytecodePath, CreatedBytecode); if (OutputFile.empty()) OutputFile = "bugpoint-execution-output"; // Check to see if this is a valid output filename... sys::Path uniqueFile(OutputFile); if (uniqueFile.makeUnique(true, &ErrMsg)) { std::cerr << ToolName << ": Error making unique filename: " << ErrMsg << "\n"; exit(1); } OutputFile = uniqueFile.toString(); // Figure out which shared objects to run, if any. std::vector SharedObjs(AdditionalSOs); if (!SharedObj.empty()) SharedObjs.push_back(SharedObj); // If this is an LLC or CBE run, then the GCC compiler might get run to // compile the program. If so, we should pass the user's -Xlinker options // as the GCCArgs. int RetVal = 0; if (InterpreterSel == RunLLC || InterpreterSel == RunCBE || InterpreterSel == CBE_bug) RetVal = AI->ExecuteProgram(BytecodeFile, InputArgv, InputFile, OutputFile, AdditionalLinkerArgs, SharedObjs, Timeout); else RetVal = AI->ExecuteProgram(BytecodeFile, InputArgv, InputFile, OutputFile, std::vector(), SharedObjs, Timeout); if (RetVal == -1) { std::cerr << ""; static bool FirstTimeout = true; if (FirstTimeout) { std::cout << "\n" "*** Program execution timed out! This mechanism is designed to handle\n" " programs stuck in infinite loops gracefully. The -timeout option\n" " can be used to change the timeout threshold or disable it completely\n" " (with -timeout=0). This message is only displayed once.\n"; FirstTimeout = false; } } if (AppendProgramExitCode) { std::ofstream outFile(OutputFile.c_str(), std::ios_base::app); outFile << "exit " << RetVal << '\n'; outFile.close(); } if (ProgramExitedNonzero != 0) *ProgramExitedNonzero = (RetVal != 0); // Return the filename we captured the output to. return OutputFile; } /// executeProgramWithCBE - Used to create reference output with the C /// backend, if reference output is not provided. /// std::string BugDriver::executeProgramWithCBE(std::string OutputFile) { bool ProgramExitedNonzero; std::string outFN = executeProgram(OutputFile, "", "", cbe, &ProgramExitedNonzero); if (ProgramExitedNonzero) { std::cerr << "Warning: While generating reference output, program exited with\n" << "non-zero exit code. This will NOT be treated as a failure.\n"; CheckProgramExitCode = false; } return outFN; } std::string BugDriver::compileSharedObject(const std::string &BytecodeFile) { assert(Interpreter && "Interpreter should have been created already!"); sys::Path OutputFile; // Using CBE GCC::FileType FT = cbe->OutputCode(BytecodeFile, OutputFile); std::string SharedObjectFile; if (gcc->MakeSharedObject(OutputFile.toString(), FT, SharedObjectFile, AdditionalLinkerArgs)) exit(1); // Remove the intermediate C file OutputFile.eraseFromDisk(); return "./" + SharedObjectFile; } /// createReferenceFile - calls compileProgram and then records the output /// into ReferenceOutputFile. Returns true if reference file created, false /// otherwise. Note: initializeExecutionEnvironment should be called BEFORE /// this function. /// bool BugDriver::createReferenceFile(Module *M, const std::string &Filename) { try { compileProgram(Program); } catch (ToolExecutionError &) { return false; } try { ReferenceOutputFile = executeProgramWithCBE(Filename); std::cout << "Reference output is: " << ReferenceOutputFile << "\n\n"; } catch (ToolExecutionError &TEE) { std::cerr << TEE.what(); if (Interpreter != cbe) { std::cerr << "*** There is a bug running the C backend. Either debug" << " it (use the -run-cbe bugpoint option), or fix the error" << " some other way.\n"; } return false; } return true; } /// diffProgram - This method executes the specified module and diffs the /// output against the file specified by ReferenceOutputFile. If the output /// is different, true is returned. If there is a problem with the code /// generator (e.g., llc crashes), this will throw an exception. /// bool BugDriver::diffProgram(const std::string &BytecodeFile, const std::string &SharedObject, bool RemoveBytecode) { bool ProgramExitedNonzero; // Execute the program, generating an output file... sys::Path Output(executeProgram("", BytecodeFile, SharedObject, 0, &ProgramExitedNonzero)); // If we're checking the program exit code, assume anything nonzero is bad. if (CheckProgramExitCode && ProgramExitedNonzero) { Output.eraseFromDisk(); if (RemoveBytecode) sys::Path(BytecodeFile).eraseFromDisk(); return true; } std::string Error; bool FilesDifferent = false; if (int Diff = DiffFilesWithTolerance(sys::Path(ReferenceOutputFile), sys::Path(Output.toString()), AbsTolerance, RelTolerance, &Error)) { if (Diff == 2) { std::cerr << "While diffing output: " << Error << '\n'; exit(1); } FilesDifferent = true; } // Remove the generated output. Output.eraseFromDisk(); // Remove the bytecode file if we are supposed to. if (RemoveBytecode) sys::Path(BytecodeFile).eraseFromDisk(); return FilesDifferent; } bool BugDriver::isExecutingJIT() { return InterpreterSel == RunJIT; }