llvm/tools/bugpoint/BugDriver.h - llvm-project - Git at Google

 //===- BugDriver.h - Top-Level BugPoint class -------------------*- C++ -*-===//
 //
 //                     The LLVM Compiler Infrastructure
 //
 // This file is distributed under the University of Illinois Open Source
 // License. See LICENSE.TXT for details.
 //
 //===----------------------------------------------------------------------===//
 //
 // This class contains all of the shared state and information that is used by
 // the BugPoint tool to track down errors in optimizations.  This class is the
 // main driver class that invokes all sub-functionality.
 //
 //===----------------------------------------------------------------------===//

 #ifndef LLVM_TOOLS_BUGPOINT_BUGDRIVER_H
 #define LLVM_TOOLS_BUGPOINT_BUGDRIVER_H

 #include "llvm/IR/ValueMap.h"
 #include "llvm/Support/Error.h"
 #include "llvm/Support/FileSystem.h"
 #include "llvm/Transforms/Utils/ValueMapper.h"
 #include <memory>
 #include <string>
 #include <vector>

 namespace llvm {

 class Value;
 class PassInfo;
 class Module;
 class GlobalVariable;
 class Function;
 class BasicBlock;
 class AbstractInterpreter;
 class Instruction;
 class LLVMContext;

 class DebugCrashes;

 class CC;

 extern bool DisableSimplifyCFG;

 /// BugpointIsInterrupted - Set to true when the user presses ctrl-c.
 ///
 extern bool BugpointIsInterrupted;

 class BugDriver {
   LLVMContext &Context;
   const char *ToolName;            // argv[0] of bugpoint
   std::string ReferenceOutputFile; // Name of `good' output file
   std::unique_ptr<Module> Program; // The raw program, linked together
   std::vector<std::string> PassesToRun;
   AbstractInterpreter *Interpreter;     // How to run the program
   AbstractInterpreter *SafeInterpreter; // To generate reference output, etc.
   CC *cc;
   bool run_find_bugs;
   unsigned Timeout;
   unsigned MemoryLimit;
   bool UseValgrind;

   // FIXME: sort out public/private distinctions...
   friend class ReducePassList;
   friend class ReduceMisCodegenFunctions;

 public:
   BugDriver(const char *toolname, bool find_bugs, unsigned timeout,
             unsigned memlimit, bool use_valgrind, LLVMContext &ctxt);
   ~BugDriver();

   const char *getToolName() const { return ToolName; }

   LLVMContext &getContext() const { return Context; }

   // Set up methods... these methods are used to copy information about the
   // command line arguments into instance variables of BugDriver.
   //
   bool addSources(const std::vector<std::string> &FileNames);
   void addPass(std::string p) { PassesToRun.push_back(std::move(p)); }
   void setPassesToRun(const std::vector<std::string> &PTR) {
     PassesToRun = PTR;
   }
   const std::vector<std::string> &getPassesToRun() const { return PassesToRun; }

   /// run - The top level method that is invoked after all of the instance
   /// variables are set up from command line arguments. The \p as_child argument
   /// indicates whether the driver is to run in parent mode or child mode.
   ///
   Error run();

   /// debugOptimizerCrash - This method is called when some optimizer pass
   /// crashes on input.  It attempts to prune down the testcase to something
   /// reasonable, and figure out exactly which pass is crashing.
   ///
   Error debugOptimizerCrash(const std::string &ID = "passes");

   /// debugCodeGeneratorCrash - This method is called when the code generator
   /// crashes on an input.  It attempts to reduce the input as much as possible
   /// while still causing the code generator to crash.
   Error debugCodeGeneratorCrash();

   /// debugMiscompilation - This method is used when the passes selected are not
   /// crashing, but the generated output is semantically different from the
   /// input.
   Error debugMiscompilation();

   /// debugPassMiscompilation - This method is called when the specified pass
   /// miscompiles Program as input.  It tries to reduce the testcase to
   /// something that smaller that still miscompiles the program.
   /// ReferenceOutput contains the filename of the file containing the output we
   /// are to match.
   ///
   bool debugPassMiscompilation(const PassInfo *ThePass,
                                const std::string &ReferenceOutput);

   /// compileSharedObject - This method creates a SharedObject from a given
   /// BitcodeFile for debugging a code generator.
   ///
   Expected<std::string> compileSharedObject(const std::string &BitcodeFile);

   /// debugCodeGenerator - This method narrows down a module to a function or
   /// set of functions, using the CBE as a ``safe'' code generator for other
   /// functions that are not under consideration.
   Error debugCodeGenerator();

   /// isExecutingJIT - Returns true if bugpoint is currently testing the JIT
   ///
   bool isExecutingJIT();

   Module &getProgram() const { return *Program; }

   /// Set the current module to the specified module, returning the old one.
   std::unique_ptr<Module> swapProgramIn(std::unique_ptr<Module> M);

   AbstractInterpreter *switchToSafeInterpreter() {
     AbstractInterpreter *Old = Interpreter;
     Interpreter = (AbstractInterpreter *)SafeInterpreter;
     return Old;
   }

   void switchToInterpreter(AbstractInterpreter *AI) { Interpreter = AI; }

   /// If we reduce or update the program somehow, call this method to update
   /// bugdriver with it.  This deletes the old module and sets the specified one
   /// as the current program.
   void setNewProgram(std::unique_ptr<Module> M);

   /// Try to compile the specified module. This is used for code generation
   /// crash testing.
   Error compileProgram(Module &M) const;

   /// This method runs "Program", capturing the output of the program to a file.
   /// A recommended filename may be optionally specified.
   Expected<std::string> executeProgram(const Module &Program,
                                        std::string OutputFilename,
                                        std::string Bitcode,
                                        const std::string &SharedObjects,
                                        AbstractInterpreter *AI) const;

   /// Used to create reference output with the "safe" backend, if reference
   /// output is not provided.  If there is a problem with the code generator
   /// (e.g., llc crashes), this will return false and set Error.
   Expected<std::string>
   executeProgramSafely(const Module &Program,
                        const std::string &OutputFile) const;

   /// 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.
   Error createReferenceFile(Module &M, const std::string &Filename =
                                            "bugpoint.reference.out-%%%%%%%");

   /// This method executes the specified module and diffs the output against the
   /// file specified by ReferenceOutputFile.  If the output is different, 1 is
   /// returned.  If there is a problem with the code generator (e.g., llc
   /// crashes), this will return -1 and set Error.
   Expected<bool> diffProgram(const Module &Program,
                              const std::string &BitcodeFile = "",
                              const std::string &SharedObj = "",
                              bool RemoveBitcode = false) const;

   /// This function is used to output M to a file named "bugpoint-ID.bc".
   void EmitProgressBitcode(const Module &M, const std::string &ID,
                            bool NoFlyer = false) const;

   /// This method clones the current Program and deletes the specified
   /// instruction from the cloned module.  It then runs a series of cleanup
   /// passes (ADCE and SimplifyCFG) to eliminate any code which depends on the
   /// value. The modified module is then returned.
   ///
   std::unique_ptr<Module> deleteInstructionFromProgram(const Instruction *I,
                                                        unsigned Simp);

   /// This method clones the current Program and performs a series of cleanups
   /// intended to get rid of extra cruft on the module. If the
   /// MayModifySemantics argument is true, then the cleanups is allowed to
   /// modify how the code behaves.
   ///
   std::unique_ptr<Module> performFinalCleanups(std::unique_ptr<Module> M,
                                                bool MayModifySemantics = false);

   /// Given a module, extract up to one loop from it into a new function. This
   /// returns null if there are no extractable loops in the program or if the
   /// loop extractor crashes.
   std::unique_ptr<Module> extractLoop(Module *M);

   /// Extract all but the specified basic blocks into their own functions. The
   /// only detail is that M is actually a module cloned from the one the BBs are
   /// in, so some mapping needs to be performed. If this operation fails for
   /// some reason (ie the implementation is buggy), this function should return
   /// null, otherwise it returns a new Module.
   std::unique_ptr<Module>
   extractMappedBlocksFromModule(const std::vector<BasicBlock *> &BBs,
                                 Module *M);

   /// Carefully run the specified set of pass on the specified/ module,
   /// returning the transformed module on success, or a null pointer on failure.
   std::unique_ptr<Module> runPassesOn(Module *M,
                                       const std::vector<std::string> &Passes,
                                       unsigned NumExtraArgs = 0,
                                       const char *const *ExtraArgs = nullptr);

   /// runPasses - Run the specified passes on Program, outputting a bitcode
   /// file and writting the filename into OutputFile if successful.  If the
   /// optimizations fail for some reason (optimizer crashes), return true,
   /// otherwise return false.  If DeleteOutput is set to true, the bitcode is
   /// deleted on success, and the filename string is undefined.  This prints to
   /// outs() a single line message indicating whether compilation was successful
   /// or failed, unless Quiet is set.  ExtraArgs specifies additional arguments
   /// to pass to the child bugpoint instance.
   ///
   bool runPasses(Module &Program, const std::vector<std::string> &PassesToRun,
                  std::string &OutputFilename, bool DeleteOutput = false,
                  bool Quiet = false, unsigned NumExtraArgs = 0,
                  const char *const *ExtraArgs = nullptr) const;

   /// runPasses - Just like the method above, but this just returns true or
   /// false indicating whether or not the optimizer crashed on the specified
   /// input (true = crashed).  Does not produce any output.
   ///
   bool runPasses(Module &M, const std::vector<std::string> &PassesToRun) const {
     std::string Filename;
     return runPasses(M, PassesToRun, Filename, true);
   }

   /// Take the specified pass list and create different combinations of passes
   /// to compile the program with. Compile the program with each set and mark
   /// test to see if it compiled correctly. If the passes compiled correctly
   /// output nothing and rearrange the passes into a new order. If the passes
   /// did not compile correctly, output the command required to recreate the
   /// failure.
   Error runManyPasses(const std::vector<std::string> &AllPasses);

   /// This writes the current "Program" to the named bitcode file.  If an error
   /// occurs, true is returned.
   bool writeProgramToFile(const std::string &Filename, const Module &M) const;
   bool writeProgramToFile(const std::string &Filename, int FD,
                           const Module &M) const;
   bool writeProgramToFile(int FD, const Module &M) const;

 private:
   /// initializeExecutionEnvironment - This method is used to set up the
   /// environment for executing LLVM programs.
   ///
   Error initializeExecutionEnvironment();
 };

 struct DiscardTemp {
   sys::fs::TempFile &File;
   ~DiscardTemp();
 };

 ///  Given a bitcode or assembly input filename, parse and return it, or return
 ///  null if not possible.
 ///
 std::unique_ptr<Module> parseInputFile(StringRef InputFilename,
                                        LLVMContext &ctxt);

 /// getPassesString - Turn a list of passes into a string which indicates the
 /// command line options that must be passed to add the passes.
 ///
 std::string getPassesString(const std::vector<std::string> &Passes);

 /// PrintFunctionList - prints out list of problematic functions
 ///
 void PrintFunctionList(const std::vector<Function *> &Funcs);

 /// PrintGlobalVariableList - prints out list of problematic global variables
 ///
 void PrintGlobalVariableList(const std::vector<GlobalVariable *> &GVs);

 // DeleteGlobalInitializer - "Remove" the global variable by deleting its
 // initializer, making it external.
 //
 void DeleteGlobalInitializer(GlobalVariable *GV);

 // DeleteFunctionBody - "Remove" the function by deleting all of it's basic
 // blocks, making it external.
 //
 void DeleteFunctionBody(Function *F);

 /// Given a module and a list of functions in the module, split the functions
 /// OUT of the specified module, and place them in the new module.
 std::unique_ptr<Module>
 SplitFunctionsOutOfModule(Module *M, const std::vector<Function *> &F,
                           ValueToValueMapTy &VMap);

 } // End llvm namespace

 #endif
	//===- BugDriver.h - Top-Level BugPoint class -------------------- C++ --===//
	//
	// The LLVM Compiler Infrastructure
	//
	// This file is distributed under the University of Illinois Open Source
	// License. See LICENSE.TXT for details.
	//
	//===----------------------------------------------------------------------===//
	//
	// This class contains all of the shared state and information that is used by
	// the BugPoint tool to track down errors in optimizations. This class is the
	// main driver class that invokes all sub-functionality.
	//
	//===----------------------------------------------------------------------===//

	#ifndef LLVM_TOOLS_BUGPOINT_BUGDRIVER_H
	#define LLVM_TOOLS_BUGPOINT_BUGDRIVER_H

	#include "llvm/IR/ValueMap.h"
	#include "llvm/Support/Error.h"
	#include "llvm/Support/FileSystem.h"
	#include "llvm/Transforms/Utils/ValueMapper.h"
	#include <memory>
	#include <string>
	#include <vector>

	namespace llvm {

	class Value;
	class PassInfo;
	class Module;
	class GlobalVariable;
	class Function;
	class BasicBlock;
	class AbstractInterpreter;
	class Instruction;
	class LLVMContext;

	class DebugCrashes;

	class CC;

	extern bool DisableSimplifyCFG;

	/// BugpointIsInterrupted - Set to true when the user presses ctrl-c.
	///
	extern bool BugpointIsInterrupted;

	class BugDriver {
	LLVMContext &Context;
	const char *ToolName; // argv[0] of bugpoint
	std::string ReferenceOutputFile; // Name of `good' output file
	std::unique_ptr<Module> Program; // The raw program, linked together
	std::vector<std::string> PassesToRun;
	AbstractInterpreter *Interpreter; // How to run the program
	AbstractInterpreter *SafeInterpreter; // To generate reference output, etc.
	CC *cc;
	bool run_find_bugs;
	unsigned Timeout;
	unsigned MemoryLimit;
	bool UseValgrind;

	// FIXME: sort out public/private distinctions...
	friend class ReducePassList;
	friend class ReduceMisCodegenFunctions;

	public:
	BugDriver(const char *toolname, bool find_bugs, unsigned timeout,
	unsigned memlimit, bool use_valgrind, LLVMContext &ctxt);
	~BugDriver();

	const char *getToolName() const { return ToolName; }

	LLVMContext &getContext() const { return Context; }

	// Set up methods... these methods are used to copy information about the
	// command line arguments into instance variables of BugDriver.
	//
	bool addSources(const std::vector<std::string> &FileNames);
	void addPass(std::string p) { PassesToRun.push_back(std::move(p)); }
	void setPassesToRun(const std::vector<std::string> &PTR) {
	PassesToRun = PTR;
	}
	const std::vector<std::string> &getPassesToRun() const { return PassesToRun; }

	/// run - The top level method that is invoked after all of the instance
	/// variables are set up from command line arguments. The \p as_child argument
	/// indicates whether the driver is to run in parent mode or child mode.
	///
	Error run();

	/// debugOptimizerCrash - This method is called when some optimizer pass
	/// crashes on input. It attempts to prune down the testcase to something
	/// reasonable, and figure out exactly which pass is crashing.
	///
	Error debugOptimizerCrash(const std::string &ID = "passes");

	/// debugCodeGeneratorCrash - This method is called when the code generator
	/// crashes on an input. It attempts to reduce the input as much as possible
	/// while still causing the code generator to crash.
	Error debugCodeGeneratorCrash();

	/// debugMiscompilation - This method is used when the passes selected are not
	/// crashing, but the generated output is semantically different from the
	/// input.
	Error debugMiscompilation();

	/// debugPassMiscompilation - This method is called when the specified pass
	/// miscompiles Program as input. It tries to reduce the testcase to
	/// something that smaller that still miscompiles the program.
	/// ReferenceOutput contains the filename of the file containing the output we
	/// are to match.
	///
	bool debugPassMiscompilation(const PassInfo *ThePass,
	const std::string &ReferenceOutput);

	/// compileSharedObject - This method creates a SharedObject from a given
	/// BitcodeFile for debugging a code generator.
	///
	Expected<std::string> compileSharedObject(const std::string &BitcodeFile);

	/// debugCodeGenerator - This method narrows down a module to a function or
	/// set of functions, using the CBE as a ``safe'' code generator for other
	/// functions that are not under consideration.
	Error debugCodeGenerator();

	/// isExecutingJIT - Returns true if bugpoint is currently testing the JIT
	///
	bool isExecutingJIT();

	Module &getProgram() const { return *Program; }

	/// Set the current module to the specified module, returning the old one.
	std::unique_ptr<Module> swapProgramIn(std::unique_ptr<Module> M);

	AbstractInterpreter *switchToSafeInterpreter() {
	AbstractInterpreter *Old = Interpreter;
	Interpreter = (AbstractInterpreter *)SafeInterpreter;
	return Old;
	}

	void switchToInterpreter(AbstractInterpreter *AI) { Interpreter = AI; }

	/// If we reduce or update the program somehow, call this method to update
	/// bugdriver with it. This deletes the old module and sets the specified one
	/// as the current program.
	void setNewProgram(std::unique_ptr<Module> M);

	/// Try to compile the specified module. This is used for code generation
	/// crash testing.
	Error compileProgram(Module &M) const;

	/// This method runs "Program", capturing the output of the program to a file.
	/// A recommended filename may be optionally specified.
	Expected<std::string> executeProgram(const Module &Program,
	std::string OutputFilename,
	std::string Bitcode,
	const std::string &SharedObjects,
	AbstractInterpreter *AI) const;

	/// Used to create reference output with the "safe" backend, if reference
	/// output is not provided. If there is a problem with the code generator
	/// (e.g., llc crashes), this will return false and set Error.
	Expected<std::string>
	executeProgramSafely(const Module &Program,
	const std::string &OutputFile) const;

	/// 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.
	Error createReferenceFile(Module &M, const std::string &Filename =
	"bugpoint.reference.out-%%%%%%%");

	/// This method executes the specified module and diffs the output against the
	/// file specified by ReferenceOutputFile. If the output is different, 1 is
	/// returned. If there is a problem with the code generator (e.g., llc
	/// crashes), this will return -1 and set Error.
	Expected<bool> diffProgram(const Module &Program,
	const std::string &BitcodeFile = "",
	const std::string &SharedObj = "",
	bool RemoveBitcode = false) const;

	/// This function is used to output M to a file named "bugpoint-ID.bc".
	void EmitProgressBitcode(const Module &M, const std::string &ID,
	bool NoFlyer = false) const;

	/// This method clones the current Program and deletes the specified
	/// instruction from the cloned module. It then runs a series of cleanup
	/// passes (ADCE and SimplifyCFG) to eliminate any code which depends on the
	/// value. The modified module is then returned.
	///
	std::unique_ptr<Module> deleteInstructionFromProgram(const Instruction *I,
	unsigned Simp);

	/// This method clones the current Program and performs a series of cleanups
	/// intended to get rid of extra cruft on the module. If the
	/// MayModifySemantics argument is true, then the cleanups is allowed to
	/// modify how the code behaves.
	///
	std::unique_ptr<Module> performFinalCleanups(std::unique_ptr<Module> M,
	bool MayModifySemantics = false);

	/// Given a module, extract up to one loop from it into a new function. This
	/// returns null if there are no extractable loops in the program or if the
	/// loop extractor crashes.
	std::unique_ptr<Module> extractLoop(Module *M);

	/// Extract all but the specified basic blocks into their own functions. The
	/// only detail is that M is actually a module cloned from the one the BBs are
	/// in, so some mapping needs to be performed. If this operation fails for
	/// some reason (ie the implementation is buggy), this function should return
	/// null, otherwise it returns a new Module.
	std::unique_ptr<Module>
	extractMappedBlocksFromModule(const std::vector<BasicBlock *> &BBs,
	Module *M);

	/// Carefully run the specified set of pass on the specified/ module,
	/// returning the transformed module on success, or a null pointer on failure.
	std::unique_ptr<Module> runPassesOn(Module *M,
	const std::vector<std::string> &Passes,
	unsigned NumExtraArgs = 0,
	const char const ExtraArgs = nullptr);

	/// runPasses - Run the specified passes on Program, outputting a bitcode
	/// file and writting the filename into OutputFile if successful. If the
	/// optimizations fail for some reason (optimizer crashes), return true,
	/// otherwise return false. If DeleteOutput is set to true, the bitcode is
	/// deleted on success, and the filename string is undefined. This prints to
	/// outs() a single line message indicating whether compilation was successful
	/// or failed, unless Quiet is set. ExtraArgs specifies additional arguments
	/// to pass to the child bugpoint instance.
	///
	bool runPasses(Module &Program, const std::vector<std::string> &PassesToRun,
	std::string &OutputFilename, bool DeleteOutput = false,
	bool Quiet = false, unsigned NumExtraArgs = 0,
	const char const ExtraArgs = nullptr) const;

	/// runPasses - Just like the method above, but this just returns true or
	/// false indicating whether or not the optimizer crashed on the specified
	/// input (true = crashed). Does not produce any output.
	///
	bool runPasses(Module &M, const std::vector<std::string> &PassesToRun) const {
	std::string Filename;
	return runPasses(M, PassesToRun, Filename, true);
	}

	/// Take the specified pass list and create different combinations of passes
	/// to compile the program with. Compile the program with each set and mark
	/// test to see if it compiled correctly. If the passes compiled correctly
	/// output nothing and rearrange the passes into a new order. If the passes
	/// did not compile correctly, output the command required to recreate the
	/// failure.
	Error runManyPasses(const std::vector<std::string> &AllPasses);

	/// This writes the current "Program" to the named bitcode file. If an error
	/// occurs, true is returned.
	bool writeProgramToFile(const std::string &Filename, const Module &M) const;
	bool writeProgramToFile(const std::string &Filename, int FD,
	const Module &M) const;
	bool writeProgramToFile(int FD, const Module &M) const;

	private:
	/// initializeExecutionEnvironment - This method is used to set up the
	/// environment for executing LLVM programs.
	///
	Error initializeExecutionEnvironment();
	};

	struct DiscardTemp {
	sys::fs::TempFile &File;
	~DiscardTemp();
	};

	/// Given a bitcode or assembly input filename, parse and return it, or return
	/// null if not possible.
	///
	std::unique_ptr<Module> parseInputFile(StringRef InputFilename,
	LLVMContext &ctxt);

	/// getPassesString - Turn a list of passes into a string which indicates the
	/// command line options that must be passed to add the passes.
	///
	std::string getPassesString(const std::vector<std::string> &Passes);

	/// PrintFunctionList - prints out list of problematic functions
	///
	void PrintFunctionList(const std::vector<Function *> &Funcs);

	/// PrintGlobalVariableList - prints out list of problematic global variables
	///
	void PrintGlobalVariableList(const std::vector<GlobalVariable *> &GVs);

	// DeleteGlobalInitializer - "Remove" the global variable by deleting its
	// initializer, making it external.
	//
	void DeleteGlobalInitializer(GlobalVariable *GV);

	// DeleteFunctionBody - "Remove" the function by deleting all of it's basic
	// blocks, making it external.
	//
	void DeleteFunctionBody(Function *F);

	/// Given a module and a list of functions in the module, split the functions
	/// OUT of the specified module, and place them in the new module.
	std::unique_ptr<Module>
	SplitFunctionsOutOfModule(Module M, const std::vector<Function > &F,
	ValueToValueMapTy &VMap);

	} // End llvm namespace

	#endif