third_party/boost/proto/include/boost/proto/transform/call.hpp - platform/external/sdv/vsomeip - Git at Google

 ///////////////////////////////////////////////////////////////////////////////
 /// \file call.hpp
 /// Contains definition of the call<> transform.
 //
 //  Copyright 2008 Eric Niebler. Distributed under 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_PROTO_TRANSFORM_CALL_HPP_EAN_11_02_2007
 #define BOOST_PROTO_TRANSFORM_CALL_HPP_EAN_11_02_2007

 #if defined(_MSC_VER)
 # pragma warning(push)
 # pragma warning(disable: 4714) // function 'xxx' marked as __forceinline not inlined
 #endif

 #include <boost/preprocessor/cat.hpp>
 #include <boost/preprocessor/facilities/intercept.hpp>
 #include <boost/preprocessor/iteration/iterate.hpp>
 #include <boost/preprocessor/repetition/enum.hpp>
 #include <boost/preprocessor/repetition/repeat.hpp>
 #include <boost/preprocessor/repetition/enum_params.hpp>
 #include <boost/preprocessor/repetition/enum_binary_params.hpp>
 #include <boost/preprocessor/repetition/enum_trailing_params.hpp>
 #include <boost/ref.hpp>
 #include <boost/utility/result_of.hpp>
 #include <boost/proto/proto_fwd.hpp>
 #include <boost/proto/traits.hpp>
 #include <boost/proto/transform/impl.hpp>
 #include <boost/proto/detail/as_lvalue.hpp>
 #include <boost/proto/detail/poly_function.hpp>
 #include <boost/proto/transform/detail/pack.hpp>

 namespace boost { namespace proto
 {
     /// \brief Wrap \c PrimitiveTransform so that <tt>when\<\></tt> knows
     /// it is callable. Requires that the parameter is actually a
     /// PrimitiveTransform.
     ///
     /// This form of <tt>call\<\></tt> is useful for annotating an
     /// arbitrary PrimitiveTransform as callable when using it with
     /// <tt>when\<\></tt>. Consider the following transform, which
     /// is parameterized with another transform.
     ///
     /// \code
     /// template<typename Grammar>
     /// struct Foo
     ///   : when<
     ///         unary_plus<Grammar>
     ///       , Grammar(_child)   // May or may not work.
     ///     >
     /// {};
     /// \endcode
     ///
     /// The problem with the above is that <tt>when\<\></tt> may or
     /// may not recognize \c Grammar as callable, depending on how
     /// \c Grammar is implemented. (See <tt>is_callable\<\></tt> for
     /// a discussion of this issue.) You can guard against
     /// the issue by wrapping \c Grammar in <tt>call\<\></tt>, such
     /// as:
     ///
     /// \code
     /// template<typename Grammar>
     /// struct Foo
     ///   : when<
     ///         unary_plus<Grammar>
     ///       , call<Grammar>(_child)   // OK, this works
     ///     >
     /// {};
     /// \endcode
     ///
     /// The above could also have been written as:
     ///
     /// \code
     /// template<typename Grammar>
     /// struct Foo
     ///   : when<
     ///         unary_plus<Grammar>
     ///       , call<Grammar(_child)>   // OK, this works, too
     ///     >
     /// {};
     /// \endcode
     template<typename PrimitiveTransform>
     struct call
       : PrimitiveTransform
     {};

     /// \brief A specialization that treats function pointer Transforms as
     /// if they were function type Transforms.
     ///
     /// This specialization requires that \c Fun is actually a function type.
     ///
     /// This specialization is required for nested transforms such as
     /// <tt>call\<T0(T1(_))\></tt>. In C++, functions that are used as
     /// parameters to other functions automatically decay to funtion
     /// pointer types. In other words, the type <tt>T0(T1(_))</tt> is
     /// indistinguishable from <tt>T0(T1(*)(_))</tt>. This specialization
     /// is required to handle these nested function pointer type transforms
     /// properly.
     template<typename Fun>
     struct call<Fun *>
       : call<Fun>
     {};

     /// INTERNAL ONLY
     template<typename Fun>
     struct call<detail::msvc_fun_workaround<Fun> >
       : call<Fun>
     {};

     /// \brief Either call the PolymorphicFunctionObject with 0
     /// arguments, or invoke the PrimitiveTransform with 3
     /// arguments.
     template<typename Fun>
     struct call<Fun()> : transform<call<Fun()> >
     {
         /// INTERNAL ONLY
         template<typename Expr, typename State, typename Data, bool B>
         struct impl2
           : transform_impl<Expr, State, Data>
         {
             typedef typename BOOST_PROTO_RESULT_OF<Fun()>::type result_type;

             BOOST_FORCEINLINE
             result_type operator()(
                 typename impl2::expr_param
               , typename impl2::state_param
               , typename impl2::data_param
             ) const
             {
                 return Fun()();
             }
         };

         /// INTERNAL ONLY
         template<typename Expr, typename State, typename Data>
         struct impl2<Expr, State, Data, true>
           : Fun::template impl<Expr, State, Data>
         {};

         /// Either call the PolymorphicFunctionObject \c Fun with 0 arguments; or
         /// invoke the PrimitiveTransform \c Fun with 3 arguments: the current
         /// expression, state, and data.
         ///
         /// If \c Fun is a nullary PolymorphicFunctionObject, return <tt>Fun()()</tt>.
         /// Otherwise, return <tt>Fun()(e, s, d)</tt>.
         ///
         /// \param e The current expression
         /// \param s The current state
         /// \param d An arbitrary data

         /// If \c Fun is a nullary PolymorphicFunctionObject, \c type is a typedef
         /// for <tt>boost::result_of\<Fun()\>::type</tt>. Otherwise, it is
         /// a typedef for <tt>boost::result_of\<Fun(Expr, State, Data)\>::type</tt>.
         template<typename Expr, typename State, typename Data>
         struct impl
           : impl2<Expr, State, Data, detail::is_transform_<Fun>::value>
         {};
     };

     /// \brief Either call the PolymorphicFunctionObject with 1
     /// argument, or invoke the PrimitiveTransform with 3
     /// arguments.
     template<typename Fun, typename A0>
     struct call<Fun(A0)> : transform<call<Fun(A0)> >
     {
         template<typename Expr, typename State, typename Data, bool B>
         struct impl2
           : transform_impl<Expr, State, Data>
         {
             typedef typename when<_, A0>::template impl<Expr, State, Data>::result_type a0;
             typedef typename detail::poly_function_traits<Fun, Fun(a0)>::result_type result_type;

             BOOST_FORCEINLINE
             result_type operator ()(
                 typename impl2::expr_param   e
               , typename impl2::state_param  s
               , typename impl2::data_param   d
             ) const
             {
                 return typename detail::poly_function_traits<Fun, Fun(a0)>::function_type()(
                     detail::as_lvalue(typename when<_, A0>::template impl<Expr, State, Data>()(e, s, d))
                 );
             }
         };

         template<typename Expr, typename State, typename Data>
         struct impl2<Expr, State, Data, true>
           : transform_impl<Expr, State, Data>
         {
             typedef typename when<_, A0>::template impl<Expr, State, Data>::result_type a0;
             typedef typename Fun::template impl<a0, State, Data>::result_type result_type;

             BOOST_FORCEINLINE
             result_type operator ()(
                 typename impl2::expr_param   e
               , typename impl2::state_param  s
               , typename impl2::data_param   d
             ) const
             {
                 return typename Fun::template impl<a0, State, Data>()(
                     typename when<_, A0>::template impl<Expr, State, Data>()(e, s, d)
                   , s
                   , d
                 );
             }
         };
         /// Let \c x be <tt>when\<_, A0\>()(e, s, d)</tt> and \c X
         /// be the type of \c x.
         /// If \c Fun is a unary PolymorphicFunctionObject that accepts \c x,
         /// then \c type is a typedef for <tt>boost::result_of\<Fun(X)\>::type</tt>.
         /// Otherwise, it is a typedef for <tt>boost::result_of\<Fun(X, State, Data)\>::type</tt>.

         /// Either call the PolymorphicFunctionObject with 1 argument:
         /// the result of applying the \c A0 transform; or
         /// invoke the PrimitiveTransform with 3 arguments:
         /// result of applying the \c A0 transform, the state, and the
         /// data.
         ///
         /// Let \c x be <tt>when\<_, A0\>()(e, s, d)</tt>.
         /// If \c Fun is a unary PolymorphicFunctionObject that accepts \c x,
         /// then return <tt>Fun()(x)</tt>. Otherwise, return
         /// <tt>Fun()(x, s, d)</tt>.
         ///
         /// \param e The current expression
         /// \param s The current state
         /// \param d An arbitrary data
         template<typename Expr, typename State, typename Data>
         struct impl
           : impl2<Expr, State, Data, detail::is_transform_<Fun>::value>
         {};
     };

     /// \brief Either call the PolymorphicFunctionObject with 2
     /// arguments, or invoke the PrimitiveTransform with 3
     /// arguments.
     template<typename Fun, typename A0, typename A1>
     struct call<Fun(A0, A1)> : transform<call<Fun(A0, A1)> >
     {
         template<typename Expr, typename State, typename Data, bool B>
         struct impl2
           : transform_impl<Expr, State, Data>
         {
             typedef typename when<_, A0>::template impl<Expr, State, Data>::result_type a0;
             typedef typename when<_, A1>::template impl<Expr, State, Data>::result_type a1;
             typedef typename detail::poly_function_traits<Fun, Fun(a0, a1)>::result_type result_type;

             BOOST_FORCEINLINE
             result_type operator ()(
                 typename impl2::expr_param   e
               , typename impl2::state_param  s
               , typename impl2::data_param   d
             ) const
             {
                 return typename detail::poly_function_traits<Fun, Fun(a0, a1)>::function_type()(
                     detail::as_lvalue(typename when<_, A0>::template impl<Expr, State, Data>()(e, s, d))
                   , detail::as_lvalue(typename when<_, A1>::template impl<Expr, State, Data>()(e, s, d))
                 );
             }
         };

         template<typename Expr, typename State, typename Data>
         struct impl2<Expr, State, Data, true>
           : transform_impl<Expr, State, Data>
         {
             typedef typename when<_, A0>::template impl<Expr, State, Data>::result_type a0;
             typedef typename when<_, A1>::template impl<Expr, State, Data>::result_type a1;
             typedef typename Fun::template impl<a0, a1, Data>::result_type result_type;

             BOOST_FORCEINLINE
             result_type operator ()(
                 typename impl2::expr_param   e
               , typename impl2::state_param  s
               , typename impl2::data_param   d
             ) const
             {
                 return typename Fun::template impl<a0, a1, Data>()(
                     typename when<_, A0>::template impl<Expr, State, Data>()(e, s, d)
                   , typename when<_, A1>::template impl<Expr, State, Data>()(e, s, d)
                   , d
                 );
             }
         };

             /// Let \c x be <tt>when\<_, A0\>()(e, s, d)</tt> and \c X
             /// be the type of \c x.
             /// Let \c y be <tt>when\<_, A1\>()(e, s, d)</tt> and \c Y
             /// be the type of \c y.
             /// If \c Fun is a binary PolymorphicFunction object that accepts \c x
             /// and \c y, then \c type is a typedef for
             /// <tt>boost::result_of\<Fun(X, Y)\>::type</tt>. Otherwise, it is
             /// a typedef for <tt>boost::result_of\<Fun(X, Y, Data)\>::type</tt>.

         /// Either call the PolymorphicFunctionObject with 2 arguments:
         /// the result of applying the \c A0 transform, and the
         /// result of applying the \c A1 transform; or invoke the
         /// PrimitiveTransform with 3 arguments: the result of applying
         /// the \c A0 transform, the result of applying the \c A1
         /// transform, and the data.
         ///
         /// Let \c x be <tt>when\<_, A0\>()(e, s, d)</tt>.
         /// Let \c y be <tt>when\<_, A1\>()(e, s, d)</tt>.
         /// If \c Fun is a binary PolymorphicFunction object that accepts \c x
         /// and \c y, return <tt>Fun()(x, y)</tt>. Otherwise, return
         /// <tt>Fun()(x, y, d)</tt>.
         ///
         /// \param e The current expression
         /// \param s The current state
         /// \param d An arbitrary data
         template<typename Expr, typename State, typename Data>
         struct impl
           : impl2<Expr, State, Data, detail::is_transform_<Fun>::value>
         {};
     };

     /// \brief Call the PolymorphicFunctionObject or the
     /// PrimitiveTransform with the current expression, state
     /// and data, transformed according to \c A0, \c A1, and
     /// \c A2, respectively.
     template<typename Fun, typename A0, typename A1, typename A2>
     struct call<Fun(A0, A1, A2)> : transform<call<Fun(A0, A1, A2)> >
     {
         template<typename Expr, typename State, typename Data, bool B>
         struct impl2
           : transform_impl<Expr, State, Data>
         {
             typedef typename when<_, A0>::template impl<Expr, State, Data>::result_type a0;
             typedef typename when<_, A1>::template impl<Expr, State, Data>::result_type a1;
             typedef typename when<_, A2>::template impl<Expr, State, Data>::result_type a2;
             typedef typename detail::poly_function_traits<Fun, Fun(a0, a1, a2)>::result_type result_type;

             BOOST_FORCEINLINE
             result_type operator ()(
                 typename impl2::expr_param   e
               , typename impl2::state_param  s
               , typename impl2::data_param   d
             ) const
             {
                 return typename detail::poly_function_traits<Fun, Fun(a0, a1, a2)>::function_type()(
                     detail::as_lvalue(typename when<_, A0>::template impl<Expr, State, Data>()(e, s, d))
                   , detail::as_lvalue(typename when<_, A1>::template impl<Expr, State, Data>()(e, s, d))
                   , detail::as_lvalue(typename when<_, A2>::template impl<Expr, State, Data>()(e, s, d))
                 );
             }
         };

         template<typename Expr, typename State, typename Data>
         struct impl2<Expr, State, Data, true>
           : transform_impl<Expr, State, Data>
         {
             typedef typename when<_, A0>::template impl<Expr, State, Data>::result_type a0;
             typedef typename when<_, A1>::template impl<Expr, State, Data>::result_type a1;
             typedef typename when<_, A2>::template impl<Expr, State, Data>::result_type a2;
             typedef typename Fun::template impl<a0, a1, a2>::result_type result_type;

             BOOST_FORCEINLINE
             result_type operator ()(
                 typename impl2::expr_param   e
               , typename impl2::state_param  s
               , typename impl2::data_param   d
             ) const
             {
                 return typename Fun::template impl<a0, a1, a2>()(
                     typename when<_, A0>::template impl<Expr, State, Data>()(e, s, d)
                   , typename when<_, A1>::template impl<Expr, State, Data>()(e, s, d)
                   , typename when<_, A2>::template impl<Expr, State, Data>()(e, s, d)
                 );
             }
         };

         /// Let \c x be <tt>when\<_, A0\>()(e, s, d)</tt>.
         /// Let \c y be <tt>when\<_, A1\>()(e, s, d)</tt>.
         /// Let \c z be <tt>when\<_, A2\>()(e, s, d)</tt>.
         /// Return <tt>Fun()(x, y, z)</tt>.
         ///
         /// \param e The current expression
         /// \param s The current state
         /// \param d An arbitrary data

         template<typename Expr, typename State, typename Data>
         struct impl
           : impl2<Expr, State, Data, detail::is_transform_<Fun>::value>
         {};
     };

     #include <boost/proto/transform/detail/call.hpp>

     /// INTERNAL ONLY
     ///
     template<typename Fun>
     struct is_callable<call<Fun> >
       : mpl::true_
     {};

 }} // namespace boost::proto

 #if defined(_MSC_VER)
 # pragma warning(pop)
 #endif

 #endif
	///////////////////////////////////////////////////////////////////////////////
	/// \file call.hpp
	/// Contains definition of the call<> transform.
	//
	// Copyright 2008 Eric Niebler. Distributed under 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_PROTO_TRANSFORM_CALL_HPP_EAN_11_02_2007
	#define BOOST_PROTO_TRANSFORM_CALL_HPP_EAN_11_02_2007

	#if defined(_MSC_VER)
	# pragma warning(push)
	# pragma warning(disable: 4714) // function 'xxx' marked as __forceinline not inlined
	#endif

	#include <boost/preprocessor/cat.hpp>
	#include <boost/preprocessor/facilities/intercept.hpp>
	#include <boost/preprocessor/iteration/iterate.hpp>
	#include <boost/preprocessor/repetition/enum.hpp>
	#include <boost/preprocessor/repetition/repeat.hpp>
	#include <boost/preprocessor/repetition/enum_params.hpp>
	#include <boost/preprocessor/repetition/enum_binary_params.hpp>
	#include <boost/preprocessor/repetition/enum_trailing_params.hpp>
	#include <boost/ref.hpp>
	#include <boost/utility/result_of.hpp>
	#include <boost/proto/proto_fwd.hpp>
	#include <boost/proto/traits.hpp>
	#include <boost/proto/transform/impl.hpp>
	#include <boost/proto/detail/as_lvalue.hpp>
	#include <boost/proto/detail/poly_function.hpp>
	#include <boost/proto/transform/detail/pack.hpp>

	namespace boost { namespace proto
	{
	/// \brief Wrap \c PrimitiveTransform so that <tt>when\<\></tt> knows
	/// it is callable. Requires that the parameter is actually a
	/// PrimitiveTransform.
	///
	/// This form of <tt>call\<\></tt> is useful for annotating an
	/// arbitrary PrimitiveTransform as callable when using it with
	/// <tt>when\<\></tt>. Consider the following transform, which
	/// is parameterized with another transform.
	///
	/// \code
	/// template<typename Grammar>
	/// struct Foo
	/// : when<
	/// unary_plus<Grammar>
	/// , Grammar(_child) // May or may not work.
	/// >
	/// {};
	/// \endcode
	///
	/// The problem with the above is that <tt>when\<\></tt> may or
	/// may not recognize \c Grammar as callable, depending on how
	/// \c Grammar is implemented. (See <tt>is_callable\<\></tt> for
	/// a discussion of this issue.) You can guard against
	/// the issue by wrapping \c Grammar in <tt>call\<\></tt>, such
	/// as:
	///
	/// \code
	/// template<typename Grammar>
	/// struct Foo
	/// : when<
	/// unary_plus<Grammar>
	/// , call<Grammar>(_child) // OK, this works
	/// >
	/// {};
	/// \endcode
	///
	/// The above could also have been written as:
	///
	/// \code
	/// template<typename Grammar>
	/// struct Foo
	/// : when<
	/// unary_plus<Grammar>
	/// , call<Grammar(_child)> // OK, this works, too
	/// >
	/// {};
	/// \endcode
	template<typename PrimitiveTransform>
	struct call
	: PrimitiveTransform
	{};

	/// \brief A specialization that treats function pointer Transforms as
	/// if they were function type Transforms.
	///
	/// This specialization requires that \c Fun is actually a function type.
	///
	/// This specialization is required for nested transforms such as
	/// <tt>call\<T0(T1(_))\></tt>. In C++, functions that are used as
	/// parameters to other functions automatically decay to funtion
	/// pointer types. In other words, the type <tt>T0(T1(_))</tt> is
	/// indistinguishable from <tt>T0(T1(*)(_))</tt>. This specialization
	/// is required to handle these nested function pointer type transforms
	/// properly.
	template<typename Fun>
	struct call<Fun *>
	: call<Fun>
	{};

	/// INTERNAL ONLY
	template<typename Fun>
	struct call<detail::msvc_fun_workaround<Fun> >
	: call<Fun>
	{};

	/// \brief Either call the PolymorphicFunctionObject with 0
	/// arguments, or invoke the PrimitiveTransform with 3
	/// arguments.
	template<typename Fun>
	struct call<Fun()> : transform<call<Fun()> >
	{
	/// INTERNAL ONLY
	template<typename Expr, typename State, typename Data, bool B>
	struct impl2
	: transform_impl<Expr, State, Data>
	{
	typedef typename BOOST_PROTO_RESULT_OF<Fun()>::type result_type;

	BOOST_FORCEINLINE
	result_type operator()(
	typename impl2::expr_param
	, typename impl2::state_param
	, typename impl2::data_param
	) const
	{
	return Fun()();
	}
	};

	/// INTERNAL ONLY
	template<typename Expr, typename State, typename Data>
	struct impl2<Expr, State, Data, true>
	: Fun::template impl<Expr, State, Data>
	{};

	/// Either call the PolymorphicFunctionObject \c Fun with 0 arguments; or
	/// invoke the PrimitiveTransform \c Fun with 3 arguments: the current
	/// expression, state, and data.
	///
	/// If \c Fun is a nullary PolymorphicFunctionObject, return <tt>Fun()()</tt>.
	/// Otherwise, return <tt>Fun()(e, s, d)</tt>.
	///
	/// \param e The current expression
	/// \param s The current state
	/// \param d An arbitrary data

	/// If \c Fun is a nullary PolymorphicFunctionObject, \c type is a typedef
	/// for <tt>boost::result_of\<Fun()\>::type</tt>. Otherwise, it is
	/// a typedef for <tt>boost::result_of\<Fun(Expr, State, Data)\>::type</tt>.
	template<typename Expr, typename State, typename Data>
	struct impl
	: impl2<Expr, State, Data, detail::is_transform_<Fun>::value>
	{};
	};

	/// \brief Either call the PolymorphicFunctionObject with 1
	/// argument, or invoke the PrimitiveTransform with 3
	/// arguments.
	template<typename Fun, typename A0>
	struct call<Fun(A0)> : transform<call<Fun(A0)> >
	{
	template<typename Expr, typename State, typename Data, bool B>
	struct impl2
	: transform_impl<Expr, State, Data>
	{
	typedef typename when<_, A0>::template impl<Expr, State, Data>::result_type a0;
	typedef typename detail::poly_function_traits<Fun, Fun(a0)>::result_type result_type;

	BOOST_FORCEINLINE
	result_type operator ()(
	typename impl2::expr_param e
	, typename impl2::state_param s
	, typename impl2::data_param d
	) const
	{
	return typename detail::poly_function_traits<Fun, Fun(a0)>::function_type()(
	detail::as_lvalue(typename when<_, A0>::template impl<Expr, State, Data>()(e, s, d))
	);
	}
	};

	template<typename Expr, typename State, typename Data>
	struct impl2<Expr, State, Data, true>
	: transform_impl<Expr, State, Data>
	{
	typedef typename when<_, A0>::template impl<Expr, State, Data>::result_type a0;
	typedef typename Fun::template impl<a0, State, Data>::result_type result_type;

	BOOST_FORCEINLINE
	result_type operator ()(
	typename impl2::expr_param e
	, typename impl2::state_param s
	, typename impl2::data_param d
	) const
	{
	return typename Fun::template impl<a0, State, Data>()(
	typename when<_, A0>::template impl<Expr, State, Data>()(e, s, d)
	, s
	, d
	);
	}
	};
	/// Let \c x be <tt>when\<_, A0\>()(e, s, d)</tt> and \c X
	/// be the type of \c x.
	/// If \c Fun is a unary PolymorphicFunctionObject that accepts \c x,
	/// then \c type is a typedef for <tt>boost::result_of\<Fun(X)\>::type</tt>.
	/// Otherwise, it is a typedef for <tt>boost::result_of\<Fun(X, State, Data)\>::type</tt>.

	/// Either call the PolymorphicFunctionObject with 1 argument:
	/// the result of applying the \c A0 transform; or
	/// invoke the PrimitiveTransform with 3 arguments:
	/// result of applying the \c A0 transform, the state, and the
	/// data.
	///
	/// Let \c x be <tt>when\<_, A0\>()(e, s, d)</tt>.
	/// If \c Fun is a unary PolymorphicFunctionObject that accepts \c x,
	/// then return <tt>Fun()(x)</tt>. Otherwise, return
	/// <tt>Fun()(x, s, d)</tt>.
	///
	/// \param e The current expression
	/// \param s The current state
	/// \param d An arbitrary data
	template<typename Expr, typename State, typename Data>
	struct impl
	: impl2<Expr, State, Data, detail::is_transform_<Fun>::value>
	{};
	};

	/// \brief Either call the PolymorphicFunctionObject with 2
	/// arguments, or invoke the PrimitiveTransform with 3
	/// arguments.
	template<typename Fun, typename A0, typename A1>
	struct call<Fun(A0, A1)> : transform<call<Fun(A0, A1)> >
	{
	template<typename Expr, typename State, typename Data, bool B>
	struct impl2
	: transform_impl<Expr, State, Data>
	{
	typedef typename when<_, A0>::template impl<Expr, State, Data>::result_type a0;
	typedef typename when<_, A1>::template impl<Expr, State, Data>::result_type a1;
	typedef typename detail::poly_function_traits<Fun, Fun(a0, a1)>::result_type result_type;

	BOOST_FORCEINLINE
	result_type operator ()(
	typename impl2::expr_param e
	, typename impl2::state_param s
	, typename impl2::data_param d
	) const
	{
	return typename detail::poly_function_traits<Fun, Fun(a0, a1)>::function_type()(
	detail::as_lvalue(typename when<_, A0>::template impl<Expr, State, Data>()(e, s, d))
	, detail::as_lvalue(typename when<_, A1>::template impl<Expr, State, Data>()(e, s, d))
	);
	}
	};

	template<typename Expr, typename State, typename Data>
	struct impl2<Expr, State, Data, true>
	: transform_impl<Expr, State, Data>
	{
	typedef typename when<_, A0>::template impl<Expr, State, Data>::result_type a0;
	typedef typename when<_, A1>::template impl<Expr, State, Data>::result_type a1;
	typedef typename Fun::template impl<a0, a1, Data>::result_type result_type;

	BOOST_FORCEINLINE
	result_type operator ()(
	typename impl2::expr_param e
	, typename impl2::state_param s
	, typename impl2::data_param d
	) const
	{
	return typename Fun::template impl<a0, a1, Data>()(
	typename when<_, A0>::template impl<Expr, State, Data>()(e, s, d)
	, typename when<_, A1>::template impl<Expr, State, Data>()(e, s, d)
	, d
	);
	}
	};

	/// Let \c x be <tt>when\<_, A0\>()(e, s, d)</tt> and \c X
	/// be the type of \c x.
	/// Let \c y be <tt>when\<_, A1\>()(e, s, d)</tt> and \c Y
	/// be the type of \c y.
	/// If \c Fun is a binary PolymorphicFunction object that accepts \c x
	/// and \c y, then \c type is a typedef for
	/// <tt>boost::result_of\<Fun(X, Y)\>::type</tt>. Otherwise, it is
	/// a typedef for <tt>boost::result_of\<Fun(X, Y, Data)\>::type</tt>.

	/// Either call the PolymorphicFunctionObject with 2 arguments:
	/// the result of applying the \c A0 transform, and the
	/// result of applying the \c A1 transform; or invoke the
	/// PrimitiveTransform with 3 arguments: the result of applying
	/// the \c A0 transform, the result of applying the \c A1
	/// transform, and the data.
	///
	/// Let \c x be <tt>when\<_, A0\>()(e, s, d)</tt>.
	/// Let \c y be <tt>when\<_, A1\>()(e, s, d)</tt>.
	/// If \c Fun is a binary PolymorphicFunction object that accepts \c x
	/// and \c y, return <tt>Fun()(x, y)</tt>. Otherwise, return
	/// <tt>Fun()(x, y, d)</tt>.
	///
	/// \param e The current expression
	/// \param s The current state
	/// \param d An arbitrary data
	template<typename Expr, typename State, typename Data>
	struct impl
	: impl2<Expr, State, Data, detail::is_transform_<Fun>::value>
	{};
	};

	/// \brief Call the PolymorphicFunctionObject or the
	/// PrimitiveTransform with the current expression, state
	/// and data, transformed according to \c A0, \c A1, and
	/// \c A2, respectively.
	template<typename Fun, typename A0, typename A1, typename A2>
	struct call<Fun(A0, A1, A2)> : transform<call<Fun(A0, A1, A2)> >
	{
	template<typename Expr, typename State, typename Data, bool B>
	struct impl2
	: transform_impl<Expr, State, Data>
	{
	typedef typename when<_, A0>::template impl<Expr, State, Data>::result_type a0;
	typedef typename when<_, A1>::template impl<Expr, State, Data>::result_type a1;
	typedef typename when<_, A2>::template impl<Expr, State, Data>::result_type a2;
	typedef typename detail::poly_function_traits<Fun, Fun(a0, a1, a2)>::result_type result_type;

	BOOST_FORCEINLINE
	result_type operator ()(
	typename impl2::expr_param e
	, typename impl2::state_param s
	, typename impl2::data_param d
	) const
	{
	return typename detail::poly_function_traits<Fun, Fun(a0, a1, a2)>::function_type()(
	detail::as_lvalue(typename when<_, A0>::template impl<Expr, State, Data>()(e, s, d))
	, detail::as_lvalue(typename when<_, A1>::template impl<Expr, State, Data>()(e, s, d))
	, detail::as_lvalue(typename when<_, A2>::template impl<Expr, State, Data>()(e, s, d))
	);
	}
	};

	template<typename Expr, typename State, typename Data>
	struct impl2<Expr, State, Data, true>
	: transform_impl<Expr, State, Data>
	{
	typedef typename when<_, A0>::template impl<Expr, State, Data>::result_type a0;
	typedef typename when<_, A1>::template impl<Expr, State, Data>::result_type a1;
	typedef typename when<_, A2>::template impl<Expr, State, Data>::result_type a2;
	typedef typename Fun::template impl<a0, a1, a2>::result_type result_type;

	BOOST_FORCEINLINE
	result_type operator ()(
	typename impl2::expr_param e
	, typename impl2::state_param s
	, typename impl2::data_param d
	) const
	{
	return typename Fun::template impl<a0, a1, a2>()(
	typename when<_, A0>::template impl<Expr, State, Data>()(e, s, d)
	, typename when<_, A1>::template impl<Expr, State, Data>()(e, s, d)
	, typename when<_, A2>::template impl<Expr, State, Data>()(e, s, d)
	);
	}
	};

	/// Let \c x be <tt>when\<_, A0\>()(e, s, d)</tt>.
	/// Let \c y be <tt>when\<_, A1\>()(e, s, d)</tt>.
	/// Let \c z be <tt>when\<_, A2\>()(e, s, d)</tt>.
	/// Return <tt>Fun()(x, y, z)</tt>.
	///
	/// \param e The current expression
	/// \param s The current state
	/// \param d An arbitrary data

	template<typename Expr, typename State, typename Data>
	struct impl
	: impl2<Expr, State, Data, detail::is_transform_<Fun>::value>
	{};
	};

	#include <boost/proto/transform/detail/call.hpp>

	/// INTERNAL ONLY
	///
	template<typename Fun>
	struct is_callable<call<Fun> >
	: mpl::true_
	{};

	}} // namespace boost::proto

	#if defined(_MSC_VER)
	# pragma warning(pop)
	#endif

	#endif