boost/functional/lightweight_forward_adapter.hpp - platform/external/boost - Git at Google

 /*=============================================================================
     Copyright (c) 2007 Tobias Schwinger

     Use modification and distribution are subject to the Boost Software
     License, Version 1.0. (See accompanying file LICENSE_1_0.txt or copy at
     http://www.boost.org/LICENSE_1_0.txt).
 ==============================================================================*/

 #ifndef BOOST_FUNCTIONAL_LIGHTWEIGHT_FORWARD_ADAPTER_HPP_INCLUDED
 #   ifndef BOOST_PP_IS_ITERATING

 #   include <boost/config.hpp>
 #   include <boost/detail/workaround.hpp>

 #   include <boost/preprocessor/cat.hpp>
 #   include <boost/preprocessor/iteration/iterate.hpp>
 #   include <boost/preprocessor/repetition/enum.hpp>
 #   include <boost/preprocessor/repetition/enum_params.hpp>
 #   include <boost/preprocessor/repetition/enum_binary_params.hpp>
 #   include <boost/preprocessor/facilities/intercept.hpp>

 #   include <boost/utility/result_of.hpp>
 #   include <boost/ref.hpp>

 #   ifndef BOOST_FUNCTIONAL_LIGHTWEIGHT_FORWARD_ADAPTER_MAX_ARITY
 #     define BOOST_FUNCTIONAL_LIGHTWEIGHT_FORWARD_ADAPTER_MAX_ARITY 10
 #   elif BOOST_FUNCTIONAL_FORDWARD_ADAPTER_MAX_ARITY < 3
 #     undef  BOOST_FUNCTIONAL_LIGHTWEIGHT_FORWARD_ADAPTER_MAX_ARITY
 #     define BOOST_FUNCTIONAL_LIGHTWEIGHT_FORWARD_ADAPTER_MAX_ARITY 3
 #   endif

 namespace boost
 {
     template< typename Function, int Arity_Or_MinArity = -1, int MaxArity = -1 >
     class lightweight_forward_adapter;

     //----- ---- --- -- - -  -   -

     namespace detail
     {
         template< class MostDerived, typename Function, typename FunctionConst,
             int Arity, int MinArity >
         struct lightweight_forward_adapter_impl;

         struct lightweight_forward_adapter_result
         {
             template< typename Sig > struct apply;

             // Utility metafunction for argument transform
             template< typename T > struct x  { typedef T const& t; };
             template< typename T > struct x< boost::reference_wrapper<T> >
             { typedef T& t; };
             template< typename T > struct x<T&>       : x<T> { };
             template< typename T > struct x<T const&> : x<T> { };
             template< typename T > struct x<T const>  : x<T> { };

             // Utility metafunction to choose target function qualification
             template< typename T > struct c
             { typedef typename T::target_function_t t; };
             template< typename T > struct c<T&      >
             { typedef typename T::target_function_t t; };
             template< typename T > struct c<T const >
             { typedef typename T::target_function_const_t t; };
             template< typename T > struct c<T const&>
             { typedef typename T::target_function_const_t t; };
         };
     }

 #   define BOOST_TMP_MACRO(f,fn,fc) \
         boost::detail::lightweight_forward_adapter_impl< \
             lightweight_forward_adapter<f,Arity_Or_MinArity,MaxArity>, fn, fc, \
             (MaxArity!=-1? MaxArity :Arity_Or_MinArity!=-1? Arity_Or_MinArity \
                 :BOOST_FUNCTIONAL_LIGHTWEIGHT_FORWARD_ADAPTER_MAX_ARITY), \
             (Arity_Or_MinArity!=-1? Arity_Or_MinArity : 0) >

     template< typename Function, int Arity_Or_MinArity, int MaxArity >
     class lightweight_forward_adapter
         : public BOOST_TMP_MACRO(Function,Function,Function const)
         , private Function
     {
       public:
         lightweight_forward_adapter(Function const& f = Function())
           : Function(f)
         { }

         typedef Function        target_function_t;
         typedef Function const  target_function_const_t;

         Function       & target_function()       { return *this; }
         Function const & target_function() const { return *this; }

         template< typename Sig > struct result
             : detail::lightweight_forward_adapter_result::template apply<Sig>
         { };

         using BOOST_TMP_MACRO(Function,Function, Function const)::operator();
     };
     template< typename Function, int Arity_Or_MinArity, int MaxArity >
     class lightweight_forward_adapter< Function const, Arity_Or_MinArity,
         MaxArity >
         : public BOOST_TMP_MACRO(Function const, Function const, Function const)
         , private Function
     {
       public:
         lightweight_forward_adapter(Function const& f = Function())
           : Function(f)
         { }

         typedef Function const target_function_t;
         typedef Function const target_function_const_t;

         Function const & target_function() const { return *this; }

         template< typename Sig > struct result
             : detail::lightweight_forward_adapter_result::template apply<Sig>
         { };

         using BOOST_TMP_MACRO(Function const,Function const, Function const)
             ::operator();
     };
     template< typename Function, int Arity_Or_MinArity, int MaxArity >
     class lightweight_forward_adapter< Function &, Arity_Or_MinArity, MaxArity >
         : public BOOST_TMP_MACRO(Function&, Function, Function)
     {
         Function& ref_function;
       public:
         lightweight_forward_adapter(Function& f)
           : ref_function(f)
         { }

         typedef Function target_function_t;
         typedef Function target_function_const_t;

         Function & target_function() const { return this->ref_function; }

         template< typename Sig > struct result
             : detail::lightweight_forward_adapter_result::template apply<Sig>
         { };

         using BOOST_TMP_MACRO(Function&, Function, Function)::operator();
     };

     #undef BOOST_TMP_MACRO

     namespace detail
     {
         template< class Self >
         struct lightweight_forward_adapter_result::apply< Self() >
             : boost::result_of< BOOST_DEDUCED_TYPENAME c<Self>::t() >
         { };

         template< class MD, class F, class FC >
         struct lightweight_forward_adapter_impl<MD,F,FC,0,0>
             : lightweight_forward_adapter_result
         {
             inline typename boost::result_of< FC() >::type
             operator()() const
             {
                 return static_cast<MD const*>(this)->target_function()();
             }

             inline typename boost::result_of< F() >::type
             operator()()
             {
                 return static_cast<MD*>(this)->target_function()();
             }
         };

 #       define  BOOST_PP_FILENAME_1 \
             <boost/functional/lightweight_forward_adapter.hpp>
 #       define  BOOST_PP_ITERATION_LIMITS                                     \
             (1,BOOST_FUNCTIONAL_LIGHTWEIGHT_FORWARD_ADAPTER_MAX_ARITY)
 #       include BOOST_PP_ITERATE()

     } // namespace detail

     template<class F, int A0, int A1>
     struct result_of<boost::lightweight_forward_adapter<F,A0,A1> const ()>
         : boost::detail::lightweight_forward_adapter_result::template apply<
             boost::lightweight_forward_adapter<F,A0,A1> const () >
     { };
     template<class F, int A0, int A1>
     struct result_of<boost::lightweight_forward_adapter<F,A0,A1>()>
         : boost::detail::lightweight_forward_adapter_result::template apply<
             boost::lightweight_forward_adapter<F,A0,A1>() >
     { };
     template<class F, int A0, int A1>
     struct result_of<boost::lightweight_forward_adapter<F,A0,A1> const& ()>
         : boost::detail::lightweight_forward_adapter_result::template apply<
             boost::lightweight_forward_adapter<F,A0,A1> const () >
     { };
     template<class F, int A0, int A1>
     struct result_of<boost::lightweight_forward_adapter<F,A0,A1>& ()>
         : boost::detail::lightweight_forward_adapter_result::template apply<
             boost::lightweight_forward_adapter<F,A0,A1>() >
     { };
 }

 #     define BOOST_FUNCTIONAL_LIGHTWEIGHT_FORWARD_ADAPTER_HPP_INCLUDED

 #   else // defined(BOOST_PP_IS_ITERATING)
 #     define N BOOST_PP_ITERATION()

         template< class Self, BOOST_PP_ENUM_PARAMS(N,typename T) >
         struct lightweight_forward_adapter_result::apply<
             Self (BOOST_PP_ENUM_PARAMS(N,T)) >
             : boost::result_of<
                 BOOST_DEDUCED_TYPENAME c<Self>::t (BOOST_PP_ENUM_BINARY_PARAMS(N,
                     typename x<T,>::t BOOST_PP_INTERCEPT)) >
         { };

         template< class MD, class F, class FC >
         struct lightweight_forward_adapter_impl<MD,F,FC,BOOST_PP_DEC(N),N>
             : lightweight_forward_adapter_result
         {
             template< BOOST_PP_ENUM_PARAMS(N,typename T) >
             inline typename boost::result_of< F(BOOST_PP_ENUM_BINARY_PARAMS(N,
                 T,const& BOOST_PP_INTERCEPT)) >::type
             operator()(BOOST_PP_ENUM_BINARY_PARAMS(N,T,& BOOST_PP_INTERCEPT));
         };

         template< class MD, class F, class FC, int MinArity >
         struct lightweight_forward_adapter_impl<MD,F,FC,N,MinArity>
             : lightweight_forward_adapter_impl<MD,F,FC,BOOST_PP_DEC(N),MinArity>
         {
             using lightweight_forward_adapter_impl<MD,F,FC,BOOST_PP_DEC(N),
                 MinArity>::operator();

 #     define M(z,i,d) \
           static_cast<typename d::template x<T##i>::t>(a##i)

             template< BOOST_PP_ENUM_PARAMS(N,typename T) >
             inline typename lightweight_forward_adapter_result::template apply<
                 MD const (BOOST_PP_ENUM_BINARY_PARAMS(N,
                     T,const& BOOST_PP_INTERCEPT)) >::type
             operator()(BOOST_PP_ENUM_BINARY_PARAMS(N,T,const& a)) const
             {
                 typedef lightweight_forward_adapter_result _;
                 return static_cast<MD const*>(this)->target_function()(
                     BOOST_PP_ENUM(N,M,_));
             }
             template< BOOST_PP_ENUM_PARAMS(N,typename T) >
             inline typename lightweight_forward_adapter_result::template apply<
                 MD (BOOST_PP_ENUM_BINARY_PARAMS(N,
                     T,const& BOOST_PP_INTERCEPT)) >::type
             operator()(BOOST_PP_ENUM_BINARY_PARAMS(N,T,const& a))
             {
                 typedef lightweight_forward_adapter_result _;
                 return static_cast<MD*>(this)->target_function()(
                     BOOST_PP_ENUM(N,M,_));
             }
 #     undef M
       };

 #     undef N
 #   endif // defined(BOOST_PP_IS_ITERATING)

 #endif // include guard
	/*=============================================================================
	Copyright (c) 2007 Tobias Schwinger

	Use modification and distribution are subject to the Boost Software
	License, Version 1.0. (See accompanying file LICENSE_1_0.txt or copy at
	http://www.boost.org/LICENSE_1_0.txt).
	==============================================================================*/

	#ifndef BOOST_FUNCTIONAL_LIGHTWEIGHT_FORWARD_ADAPTER_HPP_INCLUDED
	# ifndef BOOST_PP_IS_ITERATING

	# include <boost/config.hpp>
	# include <boost/detail/workaround.hpp>

	# include <boost/preprocessor/cat.hpp>
	# include <boost/preprocessor/iteration/iterate.hpp>
	# include <boost/preprocessor/repetition/enum.hpp>
	# include <boost/preprocessor/repetition/enum_params.hpp>
	# include <boost/preprocessor/repetition/enum_binary_params.hpp>
	# include <boost/preprocessor/facilities/intercept.hpp>

	# include <boost/utility/result_of.hpp>
	# include <boost/ref.hpp>

	# ifndef BOOST_FUNCTIONAL_LIGHTWEIGHT_FORWARD_ADAPTER_MAX_ARITY
	# define BOOST_FUNCTIONAL_LIGHTWEIGHT_FORWARD_ADAPTER_MAX_ARITY 10
	# elif BOOST_FUNCTIONAL_FORDWARD_ADAPTER_MAX_ARITY < 3
	# undef BOOST_FUNCTIONAL_LIGHTWEIGHT_FORWARD_ADAPTER_MAX_ARITY
	# define BOOST_FUNCTIONAL_LIGHTWEIGHT_FORWARD_ADAPTER_MAX_ARITY 3
	# endif

	namespace boost
	{
	template< typename Function, int Arity_Or_MinArity = -1, int MaxArity = -1 >
	class lightweight_forward_adapter;

	//----- ---- --- -- - - - -

	namespace detail
	{
	template< class MostDerived, typename Function, typename FunctionConst,
	int Arity, int MinArity >
	struct lightweight_forward_adapter_impl;

	struct lightweight_forward_adapter_result
	{
	template< typename Sig > struct apply;

	// Utility metafunction for argument transform
	template< typename T > struct x { typedef T const& t; };
	template< typename T > struct x< boost::reference_wrapper<T> >
	{ typedef T& t; };
	template< typename T > struct x<T&> : x<T> { };
	template< typename T > struct x<T const&> : x<T> { };
	template< typename T > struct x<T const> : x<T> { };

	// Utility metafunction to choose target function qualification
	template< typename T > struct c
	{ typedef typename T::target_function_t t; };
	template< typename T > struct c<T& >
	{ typedef typename T::target_function_t t; };
	template< typename T > struct c<T const >
	{ typedef typename T::target_function_const_t t; };
	template< typename T > struct c<T const&>
	{ typedef typename T::target_function_const_t t; };
	};
	}

	# define BOOST_TMP_MACRO(f,fn,fc) \
	boost::detail::lightweight_forward_adapter_impl< \
	lightweight_forward_adapter<f,Arity_Or_MinArity,MaxArity>, fn, fc, \
	(MaxArity!=-1? MaxArity :Arity_Or_MinArity!=-1? Arity_Or_MinArity \
	:BOOST_FUNCTIONAL_LIGHTWEIGHT_FORWARD_ADAPTER_MAX_ARITY), \
	(Arity_Or_MinArity!=-1? Arity_Or_MinArity : 0) >

	template< typename Function, int Arity_Or_MinArity, int MaxArity >
	class lightweight_forward_adapter
	: public BOOST_TMP_MACRO(Function,Function,Function const)
	, private Function
	{
	public:
	lightweight_forward_adapter(Function const& f = Function())
	: Function(f)
	{ }

	typedef Function target_function_t;
	typedef Function const target_function_const_t;

	Function & target_function() { return *this; }
	Function const & target_function() const { return *this; }

	template< typename Sig > struct result
	: detail::lightweight_forward_adapter_result::template apply<Sig>
	{ };

	using BOOST_TMP_MACRO(Function,Function, Function const)::operator();
	};
	template< typename Function, int Arity_Or_MinArity, int MaxArity >
	class lightweight_forward_adapter< Function const, Arity_Or_MinArity,
	MaxArity >
	: public BOOST_TMP_MACRO(Function const, Function const, Function const)
	, private Function
	{
	public:
	lightweight_forward_adapter(Function const& f = Function())
	: Function(f)
	{ }

	typedef Function const target_function_t;
	typedef Function const target_function_const_t;

	Function const & target_function() const { return *this; }

	template< typename Sig > struct result
	: detail::lightweight_forward_adapter_result::template apply<Sig>
	{ };

	using BOOST_TMP_MACRO(Function const,Function const, Function const)
	::operator();
	};
	template< typename Function, int Arity_Or_MinArity, int MaxArity >
	class lightweight_forward_adapter< Function &, Arity_Or_MinArity, MaxArity >
	: public BOOST_TMP_MACRO(Function&, Function, Function)
	{
	Function& ref_function;
	public:
	lightweight_forward_adapter(Function& f)
	: ref_function(f)
	{ }

	typedef Function target_function_t;
	typedef Function target_function_const_t;

	Function & target_function() const { return this->ref_function; }

	template< typename Sig > struct result
	: detail::lightweight_forward_adapter_result::template apply<Sig>
	{ };

	using BOOST_TMP_MACRO(Function&, Function, Function)::operator();
	};

	#undef BOOST_TMP_MACRO

	namespace detail
	{
	template< class Self >
	struct lightweight_forward_adapter_result::apply< Self() >
	: boost::result_of< BOOST_DEDUCED_TYPENAME c<Self>::t() >
	{ };

	template< class MD, class F, class FC >
	struct lightweight_forward_adapter_impl<MD,F,FC,0,0>
	: lightweight_forward_adapter_result
	{
	inline typename boost::result_of< FC() >::type
	operator()() const
	{
	return static_cast<MD const*>(this)->target_function()();
	}

	inline typename boost::result_of< F() >::type
	operator()()
	{
	return static_cast<MD*>(this)->target_function()();
	}
	};

	# define BOOST_PP_FILENAME_1 \
	<boost/functional/lightweight_forward_adapter.hpp>
	# define BOOST_PP_ITERATION_LIMITS \
	(1,BOOST_FUNCTIONAL_LIGHTWEIGHT_FORWARD_ADAPTER_MAX_ARITY)
	# include BOOST_PP_ITERATE()

	} // namespace detail

	template<class F, int A0, int A1>
	struct result_of<boost::lightweight_forward_adapter<F,A0,A1> const ()>
	: boost::detail::lightweight_forward_adapter_result::template apply<
	boost::lightweight_forward_adapter<F,A0,A1> const () >
	{ };
	template<class F, int A0, int A1>
	struct result_of<boost::lightweight_forward_adapter<F,A0,A1>()>
	: boost::detail::lightweight_forward_adapter_result::template apply<
	boost::lightweight_forward_adapter<F,A0,A1>() >
	{ };
	template<class F, int A0, int A1>
	struct result_of<boost::lightweight_forward_adapter<F,A0,A1> const& ()>
	: boost::detail::lightweight_forward_adapter_result::template apply<
	boost::lightweight_forward_adapter<F,A0,A1> const () >
	{ };
	template<class F, int A0, int A1>
	struct result_of<boost::lightweight_forward_adapter<F,A0,A1>& ()>
	: boost::detail::lightweight_forward_adapter_result::template apply<
	boost::lightweight_forward_adapter<F,A0,A1>() >
	{ };
	}

	# define BOOST_FUNCTIONAL_LIGHTWEIGHT_FORWARD_ADAPTER_HPP_INCLUDED

	# else // defined(BOOST_PP_IS_ITERATING)
	# define N BOOST_PP_ITERATION()

	template< class Self, BOOST_PP_ENUM_PARAMS(N,typename T) >
	struct lightweight_forward_adapter_result::apply<
	Self (BOOST_PP_ENUM_PARAMS(N,T)) >
	: boost::result_of<
	BOOST_DEDUCED_TYPENAME c<Self>::t (BOOST_PP_ENUM_BINARY_PARAMS(N,
	typename x<T,>::t BOOST_PP_INTERCEPT)) >
	{ };

	template< class MD, class F, class FC >
	struct lightweight_forward_adapter_impl<MD,F,FC,BOOST_PP_DEC(N),N>
	: lightweight_forward_adapter_result
	{
	template< BOOST_PP_ENUM_PARAMS(N,typename T) >
	inline typename boost::result_of< F(BOOST_PP_ENUM_BINARY_PARAMS(N,
	T,const& BOOST_PP_INTERCEPT)) >::type
	operator()(BOOST_PP_ENUM_BINARY_PARAMS(N,T,& BOOST_PP_INTERCEPT));
	};

	template< class MD, class F, class FC, int MinArity >
	struct lightweight_forward_adapter_impl<MD,F,FC,N,MinArity>
	: lightweight_forward_adapter_impl<MD,F,FC,BOOST_PP_DEC(N),MinArity>
	{
	using lightweight_forward_adapter_impl<MD,F,FC,BOOST_PP_DEC(N),
	MinArity>::operator();

	# define M(z,i,d) \
	static_cast<typename d::template x<T##i>::t>(a##i)

	template< BOOST_PP_ENUM_PARAMS(N,typename T) >
	inline typename lightweight_forward_adapter_result::template apply<
	MD const (BOOST_PP_ENUM_BINARY_PARAMS(N,
	T,const& BOOST_PP_INTERCEPT)) >::type
	operator()(BOOST_PP_ENUM_BINARY_PARAMS(N,T,const& a)) const
	{
	typedef lightweight_forward_adapter_result _;
	return static_cast<MD const*>(this)->target_function()(
	BOOST_PP_ENUM(N,M,_));
	}
	template< BOOST_PP_ENUM_PARAMS(N,typename T) >
	inline typename lightweight_forward_adapter_result::template apply<
	MD (BOOST_PP_ENUM_BINARY_PARAMS(N,
	T,const& BOOST_PP_INTERCEPT)) >::type
	operator()(BOOST_PP_ENUM_BINARY_PARAMS(N,T,const& a))
	{
	typedef lightweight_forward_adapter_result _;
	return static_cast<MD*>(this)->target_function()(
	BOOST_PP_ENUM(N,M,_));
	}
	# undef M
	};

	# undef N
	# endif // defined(BOOST_PP_IS_ITERATING)

	#endif // include guard