include/clang/Driver/ArgList.h - clang - Git at Google

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

 #ifndef CLANG_DRIVER_ARGLIST_H_
 #define CLANG_DRIVER_ARGLIST_H_

 #include "clang/Driver/OptSpecifier.h"
 #include "clang/Driver/Util.h"
 #include "llvm/ADT/SmallVector.h"
 #include "llvm/ADT/StringRef.h"

 #include <list>
 #include <string>

 namespace llvm {
   class Twine;
 }

 namespace clang {
 namespace driver {
   class Arg;
   class ArgList;
   class Option;

   /// arg_iterator - Iterates through arguments stored inside an ArgList.
   class arg_iterator {
     /// The current argument.
     llvm::SmallVectorImpl<Arg*>::const_iterator Current;

     /// The argument list we are iterating over.
     const ArgList &Args;

     /// Optional filters on the arguments which will be match. Most clients
     /// should never want to iterate over arguments without filters, so we won't
     /// bother to factor this into two separate iterator implementations.
     //
     // FIXME: Make efficient; the idea is to provide efficient iteration over
     // all arguments which match a particular id and then just provide an
     // iterator combinator which takes multiple iterators which can be
     // efficiently compared and returns them in order.
     OptSpecifier Id0, Id1, Id2;

     void SkipToNextArg();

   public:
     typedef const Arg*                  value_type;
     typedef const Arg*                  reference;
     typedef const Arg*                  pointer;
     typedef std::forward_iterator_tag   iterator_category;
     typedef std::ptrdiff_t              difference_type;

     arg_iterator(llvm::SmallVectorImpl<Arg*>::const_iterator it,
                  const ArgList &_Args, OptSpecifier _Id0 = 0U,
                  OptSpecifier _Id1 = 0U, OptSpecifier _Id2 = 0U)
       : Current(it), Args(_Args), Id0(_Id0), Id1(_Id1), Id2(_Id2) {
       SkipToNextArg();
     }

     operator const Arg*() { return *Current; }
     reference operator*() const { return *Current; }
     pointer operator->() const { return *Current; }

     arg_iterator &operator++() {
       ++Current;
       SkipToNextArg();
       return *this;
     }

     arg_iterator operator++(int) {
       arg_iterator tmp(*this);
       ++(*this);
       return tmp;
     }

     friend bool operator==(arg_iterator LHS, arg_iterator RHS) {
       return LHS.Current == RHS.Current;
     }
     friend bool operator!=(arg_iterator LHS, arg_iterator RHS) {
       return !(LHS == RHS);
     }
   };

   /// ArgList - Ordered collection of driver arguments.
   ///
   /// The ArgList class manages a list of Arg instances as well as
   /// auxiliary data and convenience methods to allow Tools to quickly
   /// check for the presence of Arg instances for a particular Option
   /// and to iterate over groups of arguments.
   class ArgList {
   public:
     typedef llvm::SmallVector<Arg*, 16> arglist_type;
     typedef arglist_type::iterator iterator;
     typedef arglist_type::const_iterator const_iterator;
     typedef arglist_type::reverse_iterator reverse_iterator;
     typedef arglist_type::const_reverse_iterator const_reverse_iterator;

   private:
     /// The full list of arguments.
     arglist_type &Args;

   protected:
     ArgList(arglist_type &Args);

   public:
     virtual ~ArgList();

     /// @name Arg Access
     /// @{

     /// append - Append \arg A to the arg list.
     void append(Arg *A);

     arglist_type &getArgs() { return Args; }
     const arglist_type &getArgs() const { return Args; }

     unsigned size() const { return Args.size(); }

     /// @}
     /// @name Arg Iteration
     /// @{

     iterator begin() { return Args.begin(); }
     iterator end() { return Args.end(); }

     reverse_iterator rbegin() { return Args.rbegin(); }
     reverse_iterator rend() { return Args.rend(); }

     const_iterator begin() const { return Args.begin(); }
     const_iterator end() const { return Args.end(); }

     const_reverse_iterator rbegin() const { return Args.rbegin(); }
     const_reverse_iterator rend() const { return Args.rend(); }

     arg_iterator filtered_begin(OptSpecifier Id0 = 0U, OptSpecifier Id1 = 0U,
                                 OptSpecifier Id2 = 0U) const {
       return arg_iterator(Args.begin(), *this, Id0, Id1, Id2);
     }
     arg_iterator filtered_end() const {
       return arg_iterator(Args.end(), *this);
     }

     /// @}
     /// @name Arg Access
     /// @{

     /// hasArg - Does the arg list contain any option matching \arg Id.
     ///
     /// \arg Claim Whether the argument should be claimed, if it exists.
     bool hasArgNoClaim(OptSpecifier Id) const {
       return getLastArgNoClaim(Id) != 0;
     }
     bool hasArg(OptSpecifier Id) const {
       return getLastArg(Id) != 0;
     }
     bool hasArg(OptSpecifier Id0, OptSpecifier Id1) const {
       return getLastArg(Id0, Id1) != 0;
     }
     bool hasArg(OptSpecifier Id0, OptSpecifier Id1, OptSpecifier Id2) const {
       return getLastArg(Id0, Id1, Id2) != 0;
     }

     /// getLastArg - Return the last argument matching \arg Id, or null.
     ///
     /// \arg Claim Whether the argument should be claimed, if it exists.
     Arg *getLastArgNoClaim(OptSpecifier Id) const;
     Arg *getLastArg(OptSpecifier Id) const;
     Arg *getLastArg(OptSpecifier Id0, OptSpecifier Id1) const;
     Arg *getLastArg(OptSpecifier Id0, OptSpecifier Id1, OptSpecifier Id2) const;

     /// getArgString - Return the input argument string at \arg Index.
     virtual const char *getArgString(unsigned Index) const = 0;
     /// @name Translation Utilities
     /// @{

     /// hasFlag - Given an option \arg Pos and its negative form \arg
     /// Neg, return true if the option is present, false if the
     /// negation is present, and \arg Default if neither option is
     /// given. If both the option and its negation are present, the
     /// last one wins.
     bool hasFlag(OptSpecifier Pos, OptSpecifier Neg, bool Default=true) const;

     /// AddLastArg - Render only the last argument match \arg Id0, if
     /// present.
     void AddLastArg(ArgStringList &Output, OptSpecifier Id0) const;

     /// AddAllArgs - Render all arguments matching the given ids.
     void AddAllArgs(ArgStringList &Output, OptSpecifier Id0,
                     OptSpecifier Id1 = 0U, OptSpecifier Id2 = 0U) const;

     /// AddAllArgValues - Render the argument values of all arguments
     /// matching the given ids.
     void AddAllArgValues(ArgStringList &Output, OptSpecifier Id0,
                          OptSpecifier Id1 = 0U, OptSpecifier Id2 = 0U) const;

     /// AddAllArgsTranslated - Render all the arguments matching the
     /// given ids, but forced to separate args and using the provided
     /// name instead of the first option value.
     ///
     /// \param Joined - If true, render the argument as joined with
     /// the option specifier.
     void AddAllArgsTranslated(ArgStringList &Output, OptSpecifier Id0,
                               const char *Translation,
                               bool Joined = false) const;

     /// ClaimAllArgs - Claim all arguments which match the given
     /// option id.
     void ClaimAllArgs(OptSpecifier Id0) const;

     /// @}
     /// @name Arg Synthesis
     /// @{

     /// MakeArgString - Construct a constant string pointer whose
     /// lifetime will match that of the ArgList.
     virtual const char *MakeArgString(llvm::StringRef Str) const = 0;
     const char *MakeArgString(const char *Str) const {
       return MakeArgString(llvm::StringRef(Str));
     }
     const char *MakeArgString(std::string Str) const {
       return MakeArgString(llvm::StringRef(Str));
     }
     const char *MakeArgString(const llvm::Twine &Str) const;

     /// @}
   };

   class InputArgList : public ArgList  {
   private:
     /// The internal list of arguments.
     arglist_type ActualArgs;

     /// List of argument strings used by the contained Args.
     ///
     /// This is mutable since we treat the ArgList as being the list
     /// of Args, and allow routines to add new strings (to have a
     /// convenient place to store the memory) via MakeIndex.
     mutable ArgStringList ArgStrings;

     /// Strings for synthesized arguments.
     ///
     /// This is mutable since we treat the ArgList as being the list
     /// of Args, and allow routines to add new strings (to have a
     /// convenient place to store the memory) via MakeIndex.
     mutable std::list<std::string> SynthesizedStrings;

     /// The number of original input argument strings.
     unsigned NumInputArgStrings;

   public:
     InputArgList(const char **ArgBegin, const char **ArgEnd);
     InputArgList(const ArgList &);
     ~InputArgList();

     virtual const char *getArgString(unsigned Index) const {
       return ArgStrings[Index];
     }

     /// getNumInputArgStrings - Return the number of original input
     /// argument strings.
     unsigned getNumInputArgStrings() const { return NumInputArgStrings; }

     /// @name Arg Synthesis
     /// @{

   public:
     /// MakeIndex - Get an index for the given string(s).
     unsigned MakeIndex(llvm::StringRef String0) const;
     unsigned MakeIndex(llvm::StringRef String0, llvm::StringRef String1) const;

     virtual const char *MakeArgString(llvm::StringRef Str) const;

     /// @}
   };

   /// DerivedArgList - An ordered collection of driver arguments,
   /// whose storage may be in another argument list.
   class DerivedArgList : public ArgList {
     InputArgList &BaseArgs;

     /// The internal list of arguments.
     arglist_type ActualArgs;

     /// The list of arguments we synthesized.
     arglist_type SynthesizedArgs;

     /// Is this only a proxy for the base ArgList?
     bool OnlyProxy;

   public:
     /// Construct a new derived arg list from \arg BaseArgs.
     ///
     /// \param OnlyProxy - If true, this is only a proxy for the base
     /// list (to adapt the type), and it's Args list is unused.
     DerivedArgList(InputArgList &BaseArgs, bool OnlyProxy);
     ~DerivedArgList();

     virtual const char *getArgString(unsigned Index) const {
       return BaseArgs.getArgString(Index);
     }

     /// @name Arg Synthesis
     /// @{

     virtual const char *MakeArgString(llvm::StringRef Str) const;

     /// MakeFlagArg - Construct a new FlagArg for the given option
     /// \arg Id.
     Arg *MakeFlagArg(const Arg *BaseArg, const Option *Opt) const;

     /// MakePositionalArg - Construct a new Positional arg for the
     /// given option \arg Id, with the provided \arg Value.
     Arg *MakePositionalArg(const Arg *BaseArg, const Option *Opt,
                            llvm::StringRef Value) const;

     /// MakeSeparateArg - Construct a new Positional arg for the
     /// given option \arg Id, with the provided \arg Value.
     Arg *MakeSeparateArg(const Arg *BaseArg, const Option *Opt,
                          llvm::StringRef Value) const;

     /// MakeJoinedArg - Construct a new Positional arg for the
     /// given option \arg Id, with the provided \arg Value.
     Arg *MakeJoinedArg(const Arg *BaseArg, const Option *Opt,
                        llvm::StringRef Value) const;

     /// @}
   };

 } // end namespace driver
 } // end namespace clang

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

	#ifndef CLANG_DRIVER_ARGLIST_H_
	#define CLANG_DRIVER_ARGLIST_H_

	#include "clang/Driver/OptSpecifier.h"
	#include "clang/Driver/Util.h"
	#include "llvm/ADT/SmallVector.h"
	#include "llvm/ADT/StringRef.h"

	#include <list>
	#include <string>

	namespace llvm {
	class Twine;
	}

	namespace clang {
	namespace driver {
	class Arg;
	class ArgList;
	class Option;

	/// arg_iterator - Iterates through arguments stored inside an ArgList.
	class arg_iterator {
	/// The current argument.
	llvm::SmallVectorImpl<Arg*>::const_iterator Current;

	/// The argument list we are iterating over.
	const ArgList &Args;

	/// Optional filters on the arguments which will be match. Most clients
	/// should never want to iterate over arguments without filters, so we won't
	/// bother to factor this into two separate iterator implementations.
	//
	// FIXME: Make efficient; the idea is to provide efficient iteration over
	// all arguments which match a particular id and then just provide an
	// iterator combinator which takes multiple iterators which can be
	// efficiently compared and returns them in order.
	OptSpecifier Id0, Id1, Id2;

	void SkipToNextArg();

	public:
	typedef const Arg* value_type;
	typedef const Arg* reference;
	typedef const Arg* pointer;
	typedef std::forward_iterator_tag iterator_category;
	typedef std::ptrdiff_t difference_type;

	arg_iterator(llvm::SmallVectorImpl<Arg*>::const_iterator it,
	const ArgList &_Args, OptSpecifier _Id0 = 0U,
	OptSpecifier _Id1 = 0U, OptSpecifier _Id2 = 0U)
	: Current(it), Args(_Args), Id0(_Id0), Id1(_Id1), Id2(_Id2) {
	SkipToNextArg();
	}

	operator const Arg() { return Current; }
	reference operator() const { return Current; }
	pointer operator->() const { return *Current; }

	arg_iterator &operator++() {
	++Current;
	SkipToNextArg();
	return *this;
	}

	arg_iterator operator++(int) {
	arg_iterator tmp(*this);
	++(*this);
	return tmp;
	}

	friend bool operator==(arg_iterator LHS, arg_iterator RHS) {
	return LHS.Current == RHS.Current;
	}
	friend bool operator!=(arg_iterator LHS, arg_iterator RHS) {
	return !(LHS == RHS);
	}
	};

	/// ArgList - Ordered collection of driver arguments.
	///
	/// The ArgList class manages a list of Arg instances as well as
	/// auxiliary data and convenience methods to allow Tools to quickly
	/// check for the presence of Arg instances for a particular Option
	/// and to iterate over groups of arguments.
	class ArgList {
	public:
	typedef llvm::SmallVector<Arg*, 16> arglist_type;
	typedef arglist_type::iterator iterator;
	typedef arglist_type::const_iterator const_iterator;
	typedef arglist_type::reverse_iterator reverse_iterator;
	typedef arglist_type::const_reverse_iterator const_reverse_iterator;

	private:
	/// The full list of arguments.
	arglist_type &Args;

	protected:
	ArgList(arglist_type &Args);

	public:
	virtual ~ArgList();

	/// @name Arg Access
	/// @{

	/// append - Append \arg A to the arg list.
	void append(Arg *A);

	arglist_type &getArgs() { return Args; }
	const arglist_type &getArgs() const { return Args; }

	unsigned size() const { return Args.size(); }

	/// @}
	/// @name Arg Iteration
	/// @{

	iterator begin() { return Args.begin(); }
	iterator end() { return Args.end(); }

	reverse_iterator rbegin() { return Args.rbegin(); }
	reverse_iterator rend() { return Args.rend(); }

	const_iterator begin() const { return Args.begin(); }
	const_iterator end() const { return Args.end(); }

	const_reverse_iterator rbegin() const { return Args.rbegin(); }
	const_reverse_iterator rend() const { return Args.rend(); }

	arg_iterator filtered_begin(OptSpecifier Id0 = 0U, OptSpecifier Id1 = 0U,
	OptSpecifier Id2 = 0U) const {
	return arg_iterator(Args.begin(), *this, Id0, Id1, Id2);
	}
	arg_iterator filtered_end() const {
	return arg_iterator(Args.end(), *this);
	}

	/// @}
	/// @name Arg Access
	/// @{

	/// hasArg - Does the arg list contain any option matching \arg Id.
	///
	/// \arg Claim Whether the argument should be claimed, if it exists.
	bool hasArgNoClaim(OptSpecifier Id) const {
	return getLastArgNoClaim(Id) != 0;
	}
	bool hasArg(OptSpecifier Id) const {
	return getLastArg(Id) != 0;
	}
	bool hasArg(OptSpecifier Id0, OptSpecifier Id1) const {
	return getLastArg(Id0, Id1) != 0;
	}
	bool hasArg(OptSpecifier Id0, OptSpecifier Id1, OptSpecifier Id2) const {
	return getLastArg(Id0, Id1, Id2) != 0;
	}

	/// getLastArg - Return the last argument matching \arg Id, or null.
	///
	/// \arg Claim Whether the argument should be claimed, if it exists.
	Arg *getLastArgNoClaim(OptSpecifier Id) const;
	Arg *getLastArg(OptSpecifier Id) const;
	Arg *getLastArg(OptSpecifier Id0, OptSpecifier Id1) const;
	Arg *getLastArg(OptSpecifier Id0, OptSpecifier Id1, OptSpecifier Id2) const;

	/// getArgString - Return the input argument string at \arg Index.
	virtual const char *getArgString(unsigned Index) const = 0;
	/// @name Translation Utilities
	/// @{

	/// hasFlag - Given an option \arg Pos and its negative form \arg
	/// Neg, return true if the option is present, false if the
	/// negation is present, and \arg Default if neither option is
	/// given. If both the option and its negation are present, the
	/// last one wins.
	bool hasFlag(OptSpecifier Pos, OptSpecifier Neg, bool Default=true) const;

	/// AddLastArg - Render only the last argument match \arg Id0, if
	/// present.
	void AddLastArg(ArgStringList &Output, OptSpecifier Id0) const;

	/// AddAllArgs - Render all arguments matching the given ids.
	void AddAllArgs(ArgStringList &Output, OptSpecifier Id0,
	OptSpecifier Id1 = 0U, OptSpecifier Id2 = 0U) const;

	/// AddAllArgValues - Render the argument values of all arguments
	/// matching the given ids.
	void AddAllArgValues(ArgStringList &Output, OptSpecifier Id0,
	OptSpecifier Id1 = 0U, OptSpecifier Id2 = 0U) const;

	/// AddAllArgsTranslated - Render all the arguments matching the
	/// given ids, but forced to separate args and using the provided
	/// name instead of the first option value.
	///
	/// \param Joined - If true, render the argument as joined with
	/// the option specifier.
	void AddAllArgsTranslated(ArgStringList &Output, OptSpecifier Id0,
	const char *Translation,
	bool Joined = false) const;

	/// ClaimAllArgs - Claim all arguments which match the given
	/// option id.
	void ClaimAllArgs(OptSpecifier Id0) const;

	/// @}
	/// @name Arg Synthesis
	/// @{

	/// MakeArgString - Construct a constant string pointer whose
	/// lifetime will match that of the ArgList.
	virtual const char *MakeArgString(llvm::StringRef Str) const = 0;
	const char MakeArgString(const char Str) const {
	return MakeArgString(llvm::StringRef(Str));
	}
	const char *MakeArgString(std::string Str) const {
	return MakeArgString(llvm::StringRef(Str));
	}
	const char *MakeArgString(const llvm::Twine &Str) const;

	/// @}
	};

	class InputArgList : public ArgList {
	private:
	/// The internal list of arguments.
	arglist_type ActualArgs;

	/// List of argument strings used by the contained Args.
	///
	/// This is mutable since we treat the ArgList as being the list
	/// of Args, and allow routines to add new strings (to have a
	/// convenient place to store the memory) via MakeIndex.
	mutable ArgStringList ArgStrings;

	/// Strings for synthesized arguments.
	///
	/// This is mutable since we treat the ArgList as being the list
	/// of Args, and allow routines to add new strings (to have a
	/// convenient place to store the memory) via MakeIndex.
	mutable std::list<std::string> SynthesizedStrings;

	/// The number of original input argument strings.
	unsigned NumInputArgStrings;

	public:
	InputArgList(const char ArgBegin, const char ArgEnd);
	InputArgList(const ArgList &);
	~InputArgList();

	virtual const char *getArgString(unsigned Index) const {
	return ArgStrings[Index];
	}

	/// getNumInputArgStrings - Return the number of original input
	/// argument strings.
	unsigned getNumInputArgStrings() const { return NumInputArgStrings; }

	/// @name Arg Synthesis
	/// @{

	public:
	/// MakeIndex - Get an index for the given string(s).
	unsigned MakeIndex(llvm::StringRef String0) const;
	unsigned MakeIndex(llvm::StringRef String0, llvm::StringRef String1) const;

	virtual const char *MakeArgString(llvm::StringRef Str) const;

	/// @}
	};

	/// DerivedArgList - An ordered collection of driver arguments,
	/// whose storage may be in another argument list.
	class DerivedArgList : public ArgList {
	InputArgList &BaseArgs;

	/// The internal list of arguments.
	arglist_type ActualArgs;

	/// The list of arguments we synthesized.
	arglist_type SynthesizedArgs;

	/// Is this only a proxy for the base ArgList?
	bool OnlyProxy;

	public:
	/// Construct a new derived arg list from \arg BaseArgs.
	///
	/// \param OnlyProxy - If true, this is only a proxy for the base
	/// list (to adapt the type), and it's Args list is unused.
	DerivedArgList(InputArgList &BaseArgs, bool OnlyProxy);
	~DerivedArgList();

	virtual const char *getArgString(unsigned Index) const {
	return BaseArgs.getArgString(Index);
	}

	/// @name Arg Synthesis
	/// @{

	virtual const char *MakeArgString(llvm::StringRef Str) const;

	/// MakeFlagArg - Construct a new FlagArg for the given option
	/// \arg Id.
	Arg MakeFlagArg(const Arg BaseArg, const Option *Opt) const;

	/// MakePositionalArg - Construct a new Positional arg for the
	/// given option \arg Id, with the provided \arg Value.
	Arg MakePositionalArg(const Arg BaseArg, const Option *Opt,
	llvm::StringRef Value) const;

	/// MakeSeparateArg - Construct a new Positional arg for the
	/// given option \arg Id, with the provided \arg Value.
	Arg MakeSeparateArg(const Arg BaseArg, const Option *Opt,
	llvm::StringRef Value) const;

	/// MakeJoinedArg - Construct a new Positional arg for the
	/// given option \arg Id, with the provided \arg Value.
	Arg MakeJoinedArg(const Arg BaseArg, const Option *Opt,
	llvm::StringRef Value) const;

	/// @}
	};

	} // end namespace driver
	} // end namespace clang

	#endif