include/clang/Frontend/CompilerInstance.h - clang - Git at Google

 //===-- CompilerInstance.h - Clang Compiler Instance ------------*- C++ -*-===//
 //
 //                     The LLVM Compiler Infrastructure
 //
 // This file is distributed under the University of Illinois Open Source
 // License. See LICENSE.TXT for details.
 //
 //===----------------------------------------------------------------------===//

 #ifndef LLVM_CLANG_FRONTEND_COMPILERINSTANCE_H_
 #define LLVM_CLANG_FRONTEND_COMPILERINSTANCE_H_

 #include "clang/Frontend/CompilerInvocation.h"
 #include "llvm/ADT/StringRef.h"
 #include "llvm/ADT/OwningPtr.h"
 #include <cassert>
 #include <list>
 #include <string>

 namespace llvm {
 class LLVMContext;
 class raw_ostream;
 class raw_fd_ostream;
 class Timer;
 }

 namespace clang {
 class ASTContext;
 class ASTConsumer;
 class CodeCompleteConsumer;
 class Diagnostic;
 class DiagnosticClient;
 class ExternalASTSource;
 class FileManager;
 class FrontendAction;
 class Preprocessor;
 class Source;
 class SourceManager;
 class TargetInfo;

 /// CompilerInstance - Helper class for managing a single instance of the Clang
 /// compiler.
 ///
 /// The CompilerInstance serves two purposes:
 ///  (1) It manages the various objects which are necessary to run the compiler,
 ///      for example the preprocessor, the target information, and the AST
 ///      context.
 ///  (2) It provides utility routines for constructing and manipulating the
 ///      common Clang objects.
 ///
 /// The compiler instance generally owns the instance of all the objects that it
 /// manages. However, clients can still share objects by manually setting the
 /// object and retaking ownership prior to destroying the CompilerInstance.
 ///
 /// The compiler instance is intended to simplify clients, but not to lock them
 /// in to the compiler instance for everything. When possible, utility functions
 /// come in two forms; a short form that reuses the CompilerInstance objects,
 /// and a long form that takes explicit instances of any required objects.
 class CompilerInstance {
   /// The LLVM context used for this instance.
   llvm::OwningPtr<llvm::LLVMContext> LLVMContext;

   /// The options used in this compiler instance.
   llvm::OwningPtr<CompilerInvocation> Invocation;

   /// The diagnostics engine instance.
   llvm::OwningPtr<Diagnostic> Diagnostics;

   /// The diagnostics client instance.
   llvm::OwningPtr<DiagnosticClient> DiagClient;

   /// The target being compiled for.
   llvm::OwningPtr<TargetInfo> Target;

   /// The file manager.
   llvm::OwningPtr<FileManager> FileMgr;

   /// The source manager.
   llvm::OwningPtr<SourceManager> SourceMgr;

   /// The preprocessor.
   llvm::OwningPtr<Preprocessor> PP;

   /// The AST context.
   llvm::OwningPtr<ASTContext> Context;

   /// The AST consumer.
   llvm::OwningPtr<ASTConsumer> Consumer;

   /// The code completion consumer.
   llvm::OwningPtr<CodeCompleteConsumer> CompletionConsumer;

   /// The frontend timer
   llvm::OwningPtr<llvm::Timer> FrontendTimer;

   /// The list of active output files.
   std::list< std::pair<std::string, llvm::raw_ostream*> > OutputFiles;

   void operator=(const CompilerInstance &);  // DO NOT IMPLEMENT
   CompilerInstance(const CompilerInstance&); // DO NOT IMPLEMENT
 public:
   CompilerInstance();
   ~CompilerInstance();

   /// @name High-Level Operations
   /// {

   /// ExecuteAction - Execute the provided action against the compiler's
   /// CompilerInvocation object.
   ///
   /// This function makes the following assumptions:
   ///
   ///  - The invocation options should be initialized. This function does not
   ///    handle the '-help' or '-version' options, clients should handle those
   ///    directly.
   ///
   ///  - The diagnostics engine should have already been created by the client.
   ///
   ///  - No other CompilerInstance state should have been initialized (this is
   ///    an unchecked error).
   ///
   ///  - Clients should have initialized any LLVM target features that may be
   ///    required.
   ///
   ///  - Clients should eventually call llvm_shutdown() upon the completion of
   ///    this routine to ensure that any managed objects are properly destroyed.
   ///
   /// Note that this routine may write output to 'stderr'.
   ///
   /// \param Act - The action to execute.
   /// \return - True on success.
   //
   // FIXME: This function should take the stream to write any debugging /
   // verbose output to as an argument.
   //
   // FIXME: Eliminate the llvm_shutdown requirement, that should either be part
   // of the context or else not CompilerInstance specific.
   bool ExecuteAction(FrontendAction &Act);

   /// }
   /// @name LLVM Context
   /// {

   bool hasLLVMContext() const { return LLVMContext != 0; }

   llvm::LLVMContext &getLLVMContext() const {
     assert(LLVMContext && "Compiler instance has no LLVM context!");
     return *LLVMContext;
   }

   llvm::LLVMContext *takeLLVMContext() { return LLVMContext.take(); }

   /// setLLVMContext - Replace the current LLVM context and take ownership of
   /// \arg Value.
   void setLLVMContext(llvm::LLVMContext *Value);

   /// }
   /// @name Compiler Invocation and Options
   /// {

   bool hasInvocation() const { return Invocation != 0; }

   CompilerInvocation &getInvocation() {
     assert(Invocation && "Compiler instance has no invocation!");
     return *Invocation;
   }

   CompilerInvocation *takeInvocation() { return Invocation.take(); }

   /// setInvocation - Replace the current invocation; the compiler instance
   /// takes ownership of \arg Value.
   void setInvocation(CompilerInvocation *Value);

   /// }
   /// @name Forwarding Methods
   /// {

   AnalyzerOptions &getAnalyzerOpts() {
     return Invocation->getAnalyzerOpts();
   }
   const AnalyzerOptions &getAnalyzerOpts() const {
     return Invocation->getAnalyzerOpts();
   }

   CodeGenOptions &getCodeGenOpts() {
     return Invocation->getCodeGenOpts();
   }
   const CodeGenOptions &getCodeGenOpts() const {
     return Invocation->getCodeGenOpts();
   }

   DependencyOutputOptions &getDependencyOutputOpts() {
     return Invocation->getDependencyOutputOpts();
   }
   const DependencyOutputOptions &getDependencyOutputOpts() const {
     return Invocation->getDependencyOutputOpts();
   }

   DiagnosticOptions &getDiagnosticOpts() {
     return Invocation->getDiagnosticOpts();
   }
   const DiagnosticOptions &getDiagnosticOpts() const {
     return Invocation->getDiagnosticOpts();
   }

   FrontendOptions &getFrontendOpts() {
     return Invocation->getFrontendOpts();
   }
   const FrontendOptions &getFrontendOpts() const {
     return Invocation->getFrontendOpts();
   }

   HeaderSearchOptions &getHeaderSearchOpts() {
     return Invocation->getHeaderSearchOpts();
   }
   const HeaderSearchOptions &getHeaderSearchOpts() const {
     return Invocation->getHeaderSearchOpts();
   }

   LangOptions &getLangOpts() {
     return Invocation->getLangOpts();
   }
   const LangOptions &getLangOpts() const {
     return Invocation->getLangOpts();
   }

   PreprocessorOptions &getPreprocessorOpts() {
     return Invocation->getPreprocessorOpts();
   }
   const PreprocessorOptions &getPreprocessorOpts() const {
     return Invocation->getPreprocessorOpts();
   }

   PreprocessorOutputOptions &getPreprocessorOutputOpts() {
     return Invocation->getPreprocessorOutputOpts();
   }
   const PreprocessorOutputOptions &getPreprocessorOutputOpts() const {
     return Invocation->getPreprocessorOutputOpts();
   }

   TargetOptions &getTargetOpts() {
     return Invocation->getTargetOpts();
   }
   const TargetOptions &getTargetOpts() const {
     return Invocation->getTargetOpts();
   }

   /// }
   /// @name Diagnostics Engine
   /// {

   bool hasDiagnostics() const { return Diagnostics != 0; }

   Diagnostic &getDiagnostics() const {
     assert(Diagnostics && "Compiler instance has no diagnostics!");
     return *Diagnostics;
   }

   /// takeDiagnostics - Remove the current diagnostics engine and give ownership
   /// to the caller.
   Diagnostic *takeDiagnostics() { return Diagnostics.take(); }

   /// setDiagnostics - Replace the current diagnostics engine; the compiler
   /// instance takes ownership of \arg Value.
   void setDiagnostics(Diagnostic *Value);

   DiagnosticClient &getDiagnosticClient() const {
     assert(DiagClient && "Compiler instance has no diagnostic client!");
     return *DiagClient;
   }

   /// takeDiagnosticClient - Remove the current diagnostics client and give
   /// ownership to the caller.
   DiagnosticClient *takeDiagnosticClient() { return DiagClient.take(); }

   /// setDiagnosticClient - Replace the current diagnostics client; the compiler
   /// instance takes ownership of \arg Value.
   void setDiagnosticClient(DiagnosticClient *Value);

   /// }
   /// @name Target Info
   /// {

   bool hasTarget() const { return Target != 0; }

   TargetInfo &getTarget() const {
     assert(Target && "Compiler instance has no target!");
     return *Target;
   }

   /// takeTarget - Remove the current diagnostics engine and give ownership
   /// to the caller.
   TargetInfo *takeTarget() { return Target.take(); }

   /// setTarget - Replace the current diagnostics engine; the compiler
   /// instance takes ownership of \arg Value.
   void setTarget(TargetInfo *Value);

   /// }
   /// @name File Manager
   /// {

   bool hasFileManager() const { return FileMgr != 0; }

   FileManager &getFileManager() const {
     assert(FileMgr && "Compiler instance has no file manager!");
     return *FileMgr;
   }

   /// takeFileManager - Remove the current file manager and give ownership to
   /// the caller.
   FileManager *takeFileManager() { return FileMgr.take(); }

   /// setFileManager - Replace the current file manager; the compiler instance
   /// takes ownership of \arg Value.
   void setFileManager(FileManager *Value);

   /// }
   /// @name Source Manager
   /// {

   bool hasSourceManager() const { return SourceMgr != 0; }

   SourceManager &getSourceManager() const {
     assert(SourceMgr && "Compiler instance has no source manager!");
     return *SourceMgr;
   }

   /// takeSourceManager - Remove the current source manager and give ownership
   /// to the caller.
   SourceManager *takeSourceManager() { return SourceMgr.take(); }

   /// setSourceManager - Replace the current source manager; the compiler
   /// instance takes ownership of \arg Value.
   void setSourceManager(SourceManager *Value);

   /// }
   /// @name Preprocessor
   /// {

   bool hasPreprocessor() const { return PP != 0; }

   Preprocessor &getPreprocessor() const {
     assert(PP && "Compiler instance has no preprocessor!");
     return *PP;
   }

   /// takePreprocessor - Remove the current preprocessor and give ownership to
   /// the caller.
   Preprocessor *takePreprocessor() { return PP.take(); }

   /// setPreprocessor - Replace the current preprocessor; the compiler instance
   /// takes ownership of \arg Value.
   void setPreprocessor(Preprocessor *Value);

   /// }
   /// @name ASTContext
   /// {

   bool hasASTContext() const { return Context != 0; }

   ASTContext &getASTContext() const {
     assert(Context && "Compiler instance has no AST context!");
     return *Context;
   }

   /// takeASTContext - Remove the current AST context and give ownership to the
   /// caller.
   ASTContext *takeASTContext() { return Context.take(); }

   /// setASTContext - Replace the current AST context; the compiler instance
   /// takes ownership of \arg Value.
   void setASTContext(ASTContext *Value);

   /// }
   /// @name ASTConsumer
   /// {

   bool hasASTConsumer() const { return Consumer != 0; }

   ASTConsumer &getASTConsumer() const {
     assert(Consumer && "Compiler instance has no AST consumer!");
     return *Consumer;
   }

   /// takeASTConsumer - Remove the current AST consumer and give ownership to
   /// the caller.
   ASTConsumer *takeASTConsumer() { return Consumer.take(); }

   /// setASTConsumer - Replace the current AST consumer; the compiler instance
   /// takes ownership of \arg Value.
   void setASTConsumer(ASTConsumer *Value);

   /// }
   /// @name Code Completion
   /// {

   bool hasCodeCompletionConsumer() const { return CompletionConsumer != 0; }

   CodeCompleteConsumer &getCodeCompletionConsumer() const {
     assert(CompletionConsumer &&
            "Compiler instance has no code completion consumer!");
     return *CompletionConsumer;
   }

   /// takeCodeCompletionConsumer - Remove the current code completion consumer
   /// and give ownership to the caller.
   CodeCompleteConsumer *takeCodeCompletionConsumer() {
     return CompletionConsumer.take();
   }

   /// setCodeCompletionConsumer - Replace the current code completion consumer;
   /// the compiler instance takes ownership of \arg Value.
   void setCodeCompletionConsumer(CodeCompleteConsumer *Value);

   /// }
   /// @name Frontend timer
   /// {

   bool hasFrontendTimer() const { return FrontendTimer != 0; }

   llvm::Timer &getFrontendTimer() const {
     assert(FrontendTimer && "Compiler instance has no frontend timer!");
     return *FrontendTimer;
   }

   /// }
   /// @name Output Files
   /// {

   /// getOutputFileList - Get the list of (path, output stream) pairs of output
   /// files; the path may be empty but the stream will always be non-null.
   const std::list< std::pair<std::string,
                              llvm::raw_ostream*> > &getOutputFileList() const;

   /// addOutputFile - Add an output file onto the list of tracked output files.
   ///
   /// \param Path - The path to the output file, or empty.
   /// \param OS - The output stream, which should be non-null.
   void addOutputFile(llvm::StringRef Path, llvm::raw_ostream *OS);

   /// clearOutputFiles - Clear the output file list, destroying the contained
   /// output streams.
   ///
   /// \param EraseFiles - If true, attempt to erase the files from disk.
   void clearOutputFiles(bool EraseFiles);

   /// }
   /// @name Construction Utility Methods
   /// {

   /// Create the diagnostics engine using the invocation's diagnostic options
   /// and replace any existing one with it.
   ///
   /// Note that this routine also replaces the diagnostic client.
   void createDiagnostics(int Argc, char **Argv);

   /// Create a Diagnostic object with a the TextDiagnosticPrinter.
   ///
   /// The \arg Argc and \arg Argv arguments are used only for logging purposes,
   /// when the diagnostic options indicate that the compiler should output
   /// logging information.
   ///
   /// Note that this creates an unowned DiagnosticClient, if using directly the
   /// caller is responsible for releasing the returned Diagnostic's client
   /// eventually.
   ///
   /// \param Opts - The diagnostic options; note that the created text
   /// diagnostic object contains a reference to these options and its lifetime
   /// must extend past that of the diagnostic engine.
   ///
   /// \return The new object on success, or null on failure.
   static Diagnostic *createDiagnostics(const DiagnosticOptions &Opts,
                                        int Argc, char **Argv);

   /// Create the file manager and replace any existing one with it.
   void createFileManager();

   /// Create the source manager and replace any existing one with it.
   void createSourceManager();

   /// Create the preprocessor, using the invocation, file, and source managers,
   /// and replace any existing one with it.
   void createPreprocessor();

   /// Create a Preprocessor object.
   ///
   /// Note that this also creates a new HeaderSearch object which will be owned
   /// by the resulting Preprocessor.
   ///
   /// \return The new object on success, or null on failure.
   static Preprocessor *createPreprocessor(Diagnostic &, const LangOptions &,
                                           const PreprocessorOptions &,
                                           const HeaderSearchOptions &,
                                           const DependencyOutputOptions &,
                                           const TargetInfo &,
                                           const FrontendOptions &,
                                           SourceManager &, FileManager &);

   /// Create the AST context.
   void createASTContext();

   /// Create an external AST source to read a PCH file and attach it to the AST
   /// context.
   void createPCHExternalASTSource(llvm::StringRef Path);

   /// Create an external AST source to read a PCH file.
   ///
   /// \return - The new object on success, or null on failure.
   static ExternalASTSource *
   createPCHExternalASTSource(llvm::StringRef Path, const std::string &Sysroot,
                              Preprocessor &PP, ASTContext &Context);

   /// Create a code completion consumer using the invocation; note that this
   /// will cause the source manager to truncate the input source file at the
   /// completion point.
   void createCodeCompletionConsumer();

   /// Create a code completion consumer to print code completion results, at
   /// \arg Filename, \arg Line, and \arg Column, to the given output stream \arg
   /// OS.
   static CodeCompleteConsumer *
   createCodeCompletionConsumer(Preprocessor &PP, const std::string &Filename,
                                unsigned Line, unsigned Column,
                                bool UseDebugPrinter, bool ShowMacros,
                                llvm::raw_ostream &OS);

   /// Create the frontend timer and replace any existing one with it.
   void createFrontendTimer();

   /// Create the default output file (from the invocation's options) and add it
   /// to the list of tracked output files.
   ///
   /// \return - Null on error.
   llvm::raw_fd_ostream *
   createDefaultOutputFile(bool Binary = true, llvm::StringRef BaseInput = "",
                           llvm::StringRef Extension = "");

   /// Create a new output file and add it to the list of tracked output files,
   /// optionally deriving the output path name.
   ///
   /// \return - Null on error.
   llvm::raw_fd_ostream *
   createOutputFile(llvm::StringRef OutputPath, bool Binary = true,
                    llvm::StringRef BaseInput = "",
                    llvm::StringRef Extension = "");

   /// Create a new output file, optionally deriving the output path name.
   ///
   /// If \arg OutputPath is empty, then createOutputFile will derive an output
   /// path location as \arg BaseInput, with any suffix removed, and \arg
   /// Extension appended.
   ///
   /// \param OutputPath - If given, the path to the output file.
   /// \param Error [out] - On failure, the error message.
   /// \param BaseInput - If \arg OutputPath is empty, the input path name to use
   /// for deriving the output path.
   /// \param Extension - The extension to use for derived output names.
   /// \param Binary - The mode to open the file in.
   /// \param ResultPathName [out] - If given, the result path name will be
   /// stored here on success.
   static llvm::raw_fd_ostream *
   createOutputFile(llvm::StringRef OutputPath, std::string &Error,
                    bool Binary = true, llvm::StringRef BaseInput = "",
                    llvm::StringRef Extension = "",
                    std::string *ResultPathName = 0);

   /// }
   /// @name Initialization Utility Methods
   /// {

   /// InitializeSourceManager - Initialize the source manager to set InputFile
   /// as the main file.
   ///
   /// \return True on success.
   bool InitializeSourceManager(llvm::StringRef InputFile);

   /// InitializeSourceManager - Initialize the source manager to set InputFile
   /// as the main file.
   ///
   /// \return True on success.
   static bool InitializeSourceManager(llvm::StringRef InputFile,
                                       Diagnostic &Diags,
                                       FileManager &FileMgr,
                                       SourceManager &SourceMgr,
                                       const FrontendOptions &Opts);

   /// }
 };

 } // end namespace clang

 #endif
	//===-- CompilerInstance.h - Clang Compiler Instance ------------- C++ --===//
	//
	// The LLVM Compiler Infrastructure
	//
	// This file is distributed under the University of Illinois Open Source
	// License. See LICENSE.TXT for details.
	//
	//===----------------------------------------------------------------------===//

	#ifndef LLVM_CLANG_FRONTEND_COMPILERINSTANCE_H_
	#define LLVM_CLANG_FRONTEND_COMPILERINSTANCE_H_

	#include "clang/Frontend/CompilerInvocation.h"
	#include "llvm/ADT/StringRef.h"
	#include "llvm/ADT/OwningPtr.h"
	#include <cassert>
	#include <list>
	#include <string>

	namespace llvm {
	class LLVMContext;
	class raw_ostream;
	class raw_fd_ostream;
	class Timer;
	}

	namespace clang {
	class ASTContext;
	class ASTConsumer;
	class CodeCompleteConsumer;
	class Diagnostic;
	class DiagnosticClient;
	class ExternalASTSource;
	class FileManager;
	class FrontendAction;
	class Preprocessor;
	class Source;
	class SourceManager;
	class TargetInfo;

	/// CompilerInstance - Helper class for managing a single instance of the Clang
	/// compiler.
	///
	/// The CompilerInstance serves two purposes:
	/// (1) It manages the various objects which are necessary to run the compiler,
	/// for example the preprocessor, the target information, and the AST
	/// context.
	/// (2) It provides utility routines for constructing and manipulating the
	/// common Clang objects.
	///
	/// The compiler instance generally owns the instance of all the objects that it
	/// manages. However, clients can still share objects by manually setting the
	/// object and retaking ownership prior to destroying the CompilerInstance.
	///
	/// The compiler instance is intended to simplify clients, but not to lock them
	/// in to the compiler instance for everything. When possible, utility functions
	/// come in two forms; a short form that reuses the CompilerInstance objects,
	/// and a long form that takes explicit instances of any required objects.
	class CompilerInstance {
	/// The LLVM context used for this instance.
	llvm::OwningPtr<llvm::LLVMContext> LLVMContext;

	/// The options used in this compiler instance.
	llvm::OwningPtr<CompilerInvocation> Invocation;

	/// The diagnostics engine instance.
	llvm::OwningPtr<Diagnostic> Diagnostics;

	/// The diagnostics client instance.
	llvm::OwningPtr<DiagnosticClient> DiagClient;

	/// The target being compiled for.
	llvm::OwningPtr<TargetInfo> Target;

	/// The file manager.
	llvm::OwningPtr<FileManager> FileMgr;

	/// The source manager.
	llvm::OwningPtr<SourceManager> SourceMgr;

	/// The preprocessor.
	llvm::OwningPtr<Preprocessor> PP;

	/// The AST context.
	llvm::OwningPtr<ASTContext> Context;

	/// The AST consumer.
	llvm::OwningPtr<ASTConsumer> Consumer;

	/// The code completion consumer.
	llvm::OwningPtr<CodeCompleteConsumer> CompletionConsumer;

	/// The frontend timer
	llvm::OwningPtr<llvm::Timer> FrontendTimer;

	/// The list of active output files.
	std::list< std::pair<std::string, llvm::raw_ostream*> > OutputFiles;

	void operator=(const CompilerInstance &); // DO NOT IMPLEMENT
	CompilerInstance(const CompilerInstance&); // DO NOT IMPLEMENT
	public:
	CompilerInstance();
	~CompilerInstance();

	/// @name High-Level Operations
	/// {

	/// ExecuteAction - Execute the provided action against the compiler's
	/// CompilerInvocation object.
	///
	/// This function makes the following assumptions:
	///
	/// - The invocation options should be initialized. This function does not
	/// handle the '-help' or '-version' options, clients should handle those
	/// directly.
	///
	/// - The diagnostics engine should have already been created by the client.
	///
	/// - No other CompilerInstance state should have been initialized (this is
	/// an unchecked error).
	///
	/// - Clients should have initialized any LLVM target features that may be
	/// required.
	///
	/// - Clients should eventually call llvm_shutdown() upon the completion of
	/// this routine to ensure that any managed objects are properly destroyed.
	///
	/// Note that this routine may write output to 'stderr'.
	///
	/// \param Act - The action to execute.
	/// \return - True on success.
	//
	// FIXME: This function should take the stream to write any debugging /
	// verbose output to as an argument.
	//
	// FIXME: Eliminate the llvm_shutdown requirement, that should either be part
	// of the context or else not CompilerInstance specific.
	bool ExecuteAction(FrontendAction &Act);

	/// }
	/// @name LLVM Context
	/// {

	bool hasLLVMContext() const { return LLVMContext != 0; }

	llvm::LLVMContext &getLLVMContext() const {
	assert(LLVMContext && "Compiler instance has no LLVM context!");
	return *LLVMContext;
	}

	llvm::LLVMContext *takeLLVMContext() { return LLVMContext.take(); }

	/// setLLVMContext - Replace the current LLVM context and take ownership of
	/// \arg Value.
	void setLLVMContext(llvm::LLVMContext *Value);

	/// }
	/// @name Compiler Invocation and Options
	/// {

	bool hasInvocation() const { return Invocation != 0; }

	CompilerInvocation &getInvocation() {
	assert(Invocation && "Compiler instance has no invocation!");
	return *Invocation;
	}

	CompilerInvocation *takeInvocation() { return Invocation.take(); }

	/// setInvocation - Replace the current invocation; the compiler instance
	/// takes ownership of \arg Value.
	void setInvocation(CompilerInvocation *Value);

	/// }
	/// @name Forwarding Methods
	/// {

	AnalyzerOptions &getAnalyzerOpts() {
	return Invocation->getAnalyzerOpts();
	}
	const AnalyzerOptions &getAnalyzerOpts() const {
	return Invocation->getAnalyzerOpts();
	}

	CodeGenOptions &getCodeGenOpts() {
	return Invocation->getCodeGenOpts();
	}
	const CodeGenOptions &getCodeGenOpts() const {
	return Invocation->getCodeGenOpts();
	}

	DependencyOutputOptions &getDependencyOutputOpts() {
	return Invocation->getDependencyOutputOpts();
	}
	const DependencyOutputOptions &getDependencyOutputOpts() const {
	return Invocation->getDependencyOutputOpts();
	}

	DiagnosticOptions &getDiagnosticOpts() {
	return Invocation->getDiagnosticOpts();
	}
	const DiagnosticOptions &getDiagnosticOpts() const {
	return Invocation->getDiagnosticOpts();
	}

	FrontendOptions &getFrontendOpts() {
	return Invocation->getFrontendOpts();
	}
	const FrontendOptions &getFrontendOpts() const {
	return Invocation->getFrontendOpts();
	}

	HeaderSearchOptions &getHeaderSearchOpts() {
	return Invocation->getHeaderSearchOpts();
	}
	const HeaderSearchOptions &getHeaderSearchOpts() const {
	return Invocation->getHeaderSearchOpts();
	}

	LangOptions &getLangOpts() {
	return Invocation->getLangOpts();
	}
	const LangOptions &getLangOpts() const {
	return Invocation->getLangOpts();
	}

	PreprocessorOptions &getPreprocessorOpts() {
	return Invocation->getPreprocessorOpts();
	}
	const PreprocessorOptions &getPreprocessorOpts() const {
	return Invocation->getPreprocessorOpts();
	}

	PreprocessorOutputOptions &getPreprocessorOutputOpts() {
	return Invocation->getPreprocessorOutputOpts();
	}
	const PreprocessorOutputOptions &getPreprocessorOutputOpts() const {
	return Invocation->getPreprocessorOutputOpts();
	}

	TargetOptions &getTargetOpts() {
	return Invocation->getTargetOpts();
	}
	const TargetOptions &getTargetOpts() const {
	return Invocation->getTargetOpts();
	}

	/// }
	/// @name Diagnostics Engine
	/// {

	bool hasDiagnostics() const { return Diagnostics != 0; }

	Diagnostic &getDiagnostics() const {
	assert(Diagnostics && "Compiler instance has no diagnostics!");
	return *Diagnostics;
	}

	/// takeDiagnostics - Remove the current diagnostics engine and give ownership
	/// to the caller.
	Diagnostic *takeDiagnostics() { return Diagnostics.take(); }

	/// setDiagnostics - Replace the current diagnostics engine; the compiler
	/// instance takes ownership of \arg Value.
	void setDiagnostics(Diagnostic *Value);

	DiagnosticClient &getDiagnosticClient() const {
	assert(DiagClient && "Compiler instance has no diagnostic client!");
	return *DiagClient;
	}

	/// takeDiagnosticClient - Remove the current diagnostics client and give
	/// ownership to the caller.
	DiagnosticClient *takeDiagnosticClient() { return DiagClient.take(); }

	/// setDiagnosticClient - Replace the current diagnostics client; the compiler
	/// instance takes ownership of \arg Value.
	void setDiagnosticClient(DiagnosticClient *Value);

	/// }
	/// @name Target Info
	/// {

	bool hasTarget() const { return Target != 0; }

	TargetInfo &getTarget() const {
	assert(Target && "Compiler instance has no target!");
	return *Target;
	}

	/// takeTarget - Remove the current diagnostics engine and give ownership
	/// to the caller.
	TargetInfo *takeTarget() { return Target.take(); }

	/// setTarget - Replace the current diagnostics engine; the compiler
	/// instance takes ownership of \arg Value.
	void setTarget(TargetInfo *Value);

	/// }
	/// @name File Manager
	/// {

	bool hasFileManager() const { return FileMgr != 0; }

	FileManager &getFileManager() const {
	assert(FileMgr && "Compiler instance has no file manager!");
	return *FileMgr;
	}

	/// takeFileManager - Remove the current file manager and give ownership to
	/// the caller.
	FileManager *takeFileManager() { return FileMgr.take(); }

	/// setFileManager - Replace the current file manager; the compiler instance
	/// takes ownership of \arg Value.
	void setFileManager(FileManager *Value);

	/// }
	/// @name Source Manager
	/// {

	bool hasSourceManager() const { return SourceMgr != 0; }

	SourceManager &getSourceManager() const {
	assert(SourceMgr && "Compiler instance has no source manager!");
	return *SourceMgr;
	}

	/// takeSourceManager - Remove the current source manager and give ownership
	/// to the caller.
	SourceManager *takeSourceManager() { return SourceMgr.take(); }

	/// setSourceManager - Replace the current source manager; the compiler
	/// instance takes ownership of \arg Value.
	void setSourceManager(SourceManager *Value);

	/// }
	/// @name Preprocessor
	/// {

	bool hasPreprocessor() const { return PP != 0; }

	Preprocessor &getPreprocessor() const {
	assert(PP && "Compiler instance has no preprocessor!");
	return *PP;
	}

	/// takePreprocessor - Remove the current preprocessor and give ownership to
	/// the caller.
	Preprocessor *takePreprocessor() { return PP.take(); }

	/// setPreprocessor - Replace the current preprocessor; the compiler instance
	/// takes ownership of \arg Value.
	void setPreprocessor(Preprocessor *Value);

	/// }
	/// @name ASTContext
	/// {

	bool hasASTContext() const { return Context != 0; }

	ASTContext &getASTContext() const {
	assert(Context && "Compiler instance has no AST context!");
	return *Context;
	}

	/// takeASTContext - Remove the current AST context and give ownership to the
	/// caller.
	ASTContext *takeASTContext() { return Context.take(); }

	/// setASTContext - Replace the current AST context; the compiler instance
	/// takes ownership of \arg Value.
	void setASTContext(ASTContext *Value);

	/// }
	/// @name ASTConsumer
	/// {

	bool hasASTConsumer() const { return Consumer != 0; }

	ASTConsumer &getASTConsumer() const {
	assert(Consumer && "Compiler instance has no AST consumer!");
	return *Consumer;
	}

	/// takeASTConsumer - Remove the current AST consumer and give ownership to
	/// the caller.
	ASTConsumer *takeASTConsumer() { return Consumer.take(); }

	/// setASTConsumer - Replace the current AST consumer; the compiler instance
	/// takes ownership of \arg Value.
	void setASTConsumer(ASTConsumer *Value);

	/// }
	/// @name Code Completion
	/// {

	bool hasCodeCompletionConsumer() const { return CompletionConsumer != 0; }

	CodeCompleteConsumer &getCodeCompletionConsumer() const {
	assert(CompletionConsumer &&
	"Compiler instance has no code completion consumer!");
	return *CompletionConsumer;
	}

	/// takeCodeCompletionConsumer - Remove the current code completion consumer
	/// and give ownership to the caller.
	CodeCompleteConsumer *takeCodeCompletionConsumer() {
	return CompletionConsumer.take();
	}

	/// setCodeCompletionConsumer - Replace the current code completion consumer;
	/// the compiler instance takes ownership of \arg Value.
	void setCodeCompletionConsumer(CodeCompleteConsumer *Value);

	/// }
	/// @name Frontend timer
	/// {

	bool hasFrontendTimer() const { return FrontendTimer != 0; }

	llvm::Timer &getFrontendTimer() const {
	assert(FrontendTimer && "Compiler instance has no frontend timer!");
	return *FrontendTimer;
	}

	/// }
	/// @name Output Files
	/// {

	/// getOutputFileList - Get the list of (path, output stream) pairs of output
	/// files; the path may be empty but the stream will always be non-null.
	const std::list< std::pair<std::string,
	llvm::raw_ostream*> > &getOutputFileList() const;

	/// addOutputFile - Add an output file onto the list of tracked output files.
	///
	/// \param Path - The path to the output file, or empty.
	/// \param OS - The output stream, which should be non-null.
	void addOutputFile(llvm::StringRef Path, llvm::raw_ostream *OS);

	/// clearOutputFiles - Clear the output file list, destroying the contained
	/// output streams.
	///
	/// \param EraseFiles - If true, attempt to erase the files from disk.
	void clearOutputFiles(bool EraseFiles);

	/// }
	/// @name Construction Utility Methods
	/// {

	/// Create the diagnostics engine using the invocation's diagnostic options
	/// and replace any existing one with it.
	///
	/// Note that this routine also replaces the diagnostic client.
	void createDiagnostics(int Argc, char **Argv);

	/// Create a Diagnostic object with a the TextDiagnosticPrinter.
	///
	/// The \arg Argc and \arg Argv arguments are used only for logging purposes,
	/// when the diagnostic options indicate that the compiler should output
	/// logging information.
	///
	/// Note that this creates an unowned DiagnosticClient, if using directly the
	/// caller is responsible for releasing the returned Diagnostic's client
	/// eventually.
	///
	/// \param Opts - The diagnostic options; note that the created text
	/// diagnostic object contains a reference to these options and its lifetime
	/// must extend past that of the diagnostic engine.
	///
	/// \return The new object on success, or null on failure.
	static Diagnostic *createDiagnostics(const DiagnosticOptions &Opts,
	int Argc, char **Argv);

	/// Create the file manager and replace any existing one with it.
	void createFileManager();

	/// Create the source manager and replace any existing one with it.
	void createSourceManager();

	/// Create the preprocessor, using the invocation, file, and source managers,
	/// and replace any existing one with it.
	void createPreprocessor();

	/// Create a Preprocessor object.
	///
	/// Note that this also creates a new HeaderSearch object which will be owned
	/// by the resulting Preprocessor.
	///
	/// \return The new object on success, or null on failure.
	static Preprocessor *createPreprocessor(Diagnostic &, const LangOptions &,
	const PreprocessorOptions &,
	const HeaderSearchOptions &,
	const DependencyOutputOptions &,
	const TargetInfo &,
	const FrontendOptions &,
	SourceManager &, FileManager &);

	/// Create the AST context.
	void createASTContext();

	/// Create an external AST source to read a PCH file and attach it to the AST
	/// context.
	void createPCHExternalASTSource(llvm::StringRef Path);

	/// Create an external AST source to read a PCH file.
	///
	/// \return - The new object on success, or null on failure.
	static ExternalASTSource *
	createPCHExternalASTSource(llvm::StringRef Path, const std::string &Sysroot,
	Preprocessor &PP, ASTContext &Context);

	/// Create a code completion consumer using the invocation; note that this
	/// will cause the source manager to truncate the input source file at the
	/// completion point.
	void createCodeCompletionConsumer();

	/// Create a code completion consumer to print code completion results, at
	/// \arg Filename, \arg Line, and \arg Column, to the given output stream \arg
	/// OS.
	static CodeCompleteConsumer *
	createCodeCompletionConsumer(Preprocessor &PP, const std::string &Filename,
	unsigned Line, unsigned Column,
	bool UseDebugPrinter, bool ShowMacros,
	llvm::raw_ostream &OS);

	/// Create the frontend timer and replace any existing one with it.
	void createFrontendTimer();

	/// Create the default output file (from the invocation's options) and add it
	/// to the list of tracked output files.
	///
	/// \return - Null on error.
	llvm::raw_fd_ostream *
	createDefaultOutputFile(bool Binary = true, llvm::StringRef BaseInput = "",
	llvm::StringRef Extension = "");

	/// Create a new output file and add it to the list of tracked output files,
	/// optionally deriving the output path name.
	///
	/// \return - Null on error.
	llvm::raw_fd_ostream *
	createOutputFile(llvm::StringRef OutputPath, bool Binary = true,
	llvm::StringRef BaseInput = "",
	llvm::StringRef Extension = "");

	/// Create a new output file, optionally deriving the output path name.
	///
	/// If \arg OutputPath is empty, then createOutputFile will derive an output
	/// path location as \arg BaseInput, with any suffix removed, and \arg
	/// Extension appended.
	///
	/// \param OutputPath - If given, the path to the output file.
	/// \param Error [out] - On failure, the error message.
	/// \param BaseInput - If \arg OutputPath is empty, the input path name to use
	/// for deriving the output path.
	/// \param Extension - The extension to use for derived output names.
	/// \param Binary - The mode to open the file in.
	/// \param ResultPathName [out] - If given, the result path name will be
	/// stored here on success.
	static llvm::raw_fd_ostream *
	createOutputFile(llvm::StringRef OutputPath, std::string &Error,
	bool Binary = true, llvm::StringRef BaseInput = "",
	llvm::StringRef Extension = "",
	std::string *ResultPathName = 0);

	/// }
	/// @name Initialization Utility Methods
	/// {

	/// InitializeSourceManager - Initialize the source manager to set InputFile
	/// as the main file.
	///
	/// \return True on success.
	bool InitializeSourceManager(llvm::StringRef InputFile);

	/// InitializeSourceManager - Initialize the source manager to set InputFile
	/// as the main file.
	///
	/// \return True on success.
	static bool InitializeSourceManager(llvm::StringRef InputFile,
	Diagnostic &Diags,
	FileManager &FileMgr,
	SourceManager &SourceMgr,
	const FrontendOptions &Opts);

	/// }
	};

	} // end namespace clang

	#endif