ndnboost/lambda/detail/lambda_functors.hpp - ndn-cxx - Gitiles

 // Boost Lambda Library -  lambda_functors.hpp -------------------------------

 // Copyright (C) 1999, 2000 Jaakko Jarvi (jaakko.jarvi@cs.utu.fi)
 //
 // 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)
 //
 // For more information, see http://www.boost.org

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

 #ifndef BOOST_LAMBDA_LAMBDA_FUNCTORS_HPP
 #define BOOST_LAMBDA_LAMBDA_FUNCTORS_HPP

 #include <ndnboost/config.hpp>
 #include <ndnboost/detail/workaround.hpp>
 #include <ndnboost/utility/result_of.hpp>

 #if BOOST_WORKAROUND(BOOST_MSVC, == 1310)

 #include <ndnboost/mpl/or.hpp>
 #include <ndnboost/utility/enable_if.hpp>
 #include <ndnboost/type_traits/is_array.hpp>

 #define BOOST_LAMBDA_DISABLE_IF_ARRAY1(A1, R1)\
   typename lazy_disable_if<is_array<A1>, typename R1 >::type
 #define BOOST_LAMBDA_DISABLE_IF_ARRAY2(A1, A2, R1, R2) \
   typename lazy_disable_if<mpl::or_<is_array<A1>, is_array<A2> >, typename R1, R2 >::type
 #define BOOST_LAMBDA_DISABLE_IF_ARRAY3(A1, A2, A3, R1, R2, R3) \
   typename lazy_disable_if<mpl::or_<is_array<A1>, is_array<A2>, is_array<A3> >, typename R1, R2, R3 >::type

 #else

 #define BOOST_LAMBDA_DISABLE_IF_ARRAY1(A1, R1) typename R1::type
 #define BOOST_LAMBDA_DISABLE_IF_ARRAY2(A1, A2, R1, R2) typename R1, R2::type
 #define BOOST_LAMBDA_DISABLE_IF_ARRAY3(A1, A2, A3, R1, R2, R3) typename R1, R2, R3::type

 #endif

 namespace ndnboost {
 namespace lambda {

 // -- lambda_functor --------------------------------------------
 // --------------------------------------------------------------

 //inline const null_type const_null_type() { return null_type(); }

 namespace detail {
 namespace {

   static const null_type constant_null_type = null_type();

 } // unnamed
 } // detail

 class unused {};

 #define cnull_type() detail::constant_null_type

 // -- free variables types --------------------------------------------------

   // helper to work around the case where the nullary return type deduction
   // is always performed, even though the functor is not nullary
 namespace detail {
   template<int N, class Tuple> struct get_element_or_null_type {
     typedef typename
       detail::tuple_element_as_reference<N, Tuple>::type type;
   };
   template<int N> struct get_element_or_null_type<N, null_type> {
     typedef null_type type;
   };
 }

 template <int I> struct placeholder;

 template<> struct placeholder<FIRST> {

   template<class SigArgs> struct sig {
     typedef typename detail::get_element_or_null_type<0, SigArgs>::type type;
   };

   template<class RET, CALL_TEMPLATE_ARGS>
   RET call(CALL_FORMAL_ARGS) const {
     BOOST_STATIC_ASSERT(ndnboost::is_reference<RET>::value);
     CALL_USE_ARGS; // does nothing, prevents warnings for unused args
     return a;
   }
 };

 template<> struct placeholder<SECOND> {

   template<class SigArgs> struct sig {
     typedef typename detail::get_element_or_null_type<1, SigArgs>::type type;
   };

   template<class RET, CALL_TEMPLATE_ARGS>
   RET call(CALL_FORMAL_ARGS) const { CALL_USE_ARGS; return b; }
 };

 template<> struct placeholder<THIRD> {

   template<class SigArgs> struct sig {
     typedef typename detail::get_element_or_null_type<2, SigArgs>::type type;
   };

   template<class RET, CALL_TEMPLATE_ARGS>
   RET call(CALL_FORMAL_ARGS) const { CALL_USE_ARGS; return c; }
 };

 template<> struct placeholder<EXCEPTION> {

   template<class SigArgs> struct sig {
     typedef typename detail::get_element_or_null_type<3, SigArgs>::type type;
   };

   template<class RET, CALL_TEMPLATE_ARGS>
   RET call(CALL_FORMAL_ARGS) const { CALL_USE_ARGS; return env; }
 };

 typedef const lambda_functor<placeholder<FIRST> >  placeholder1_type;
 typedef const lambda_functor<placeholder<SECOND> > placeholder2_type;
 typedef const lambda_functor<placeholder<THIRD> >  placeholder3_type;


 ///////////////////////////////////////////////////////////////////////////////


 // free variables are lambda_functors. This is to allow uniform handling with
 // other lambda_functors.
 // -------------------------------------------------------------------

 #if BOOST_WORKAROUND(BOOST_MSVC, >= 1400)
 #pragma warning(push)
 #pragma warning(disable:4512) //assignment operator could not be generated
 #endif

 // -- lambda_functor NONE ------------------------------------------------
 template <class T>
 class lambda_functor : public T
 {

 BOOST_STATIC_CONSTANT(int, arity_bits = get_arity<T>::value);

 public:
   typedef T inherited;

   lambda_functor() {}
   lambda_functor(const lambda_functor& l) : inherited(l) {}

   lambda_functor(const T& t) : inherited(t) {}

   template <class SigArgs> struct sig {
     typedef typename inherited::template
       sig<typename SigArgs::tail_type>::type type;
   };

   // Note that this return type deduction template is instantiated, even
   // if the nullary
   // operator() is not called at all. One must make sure that it does not fail.
   typedef typename
     inherited::template sig<null_type>::type
       nullary_return_type;

   // Support for ndnboost::result_of.
   template <class Sig> struct result;
   template <class F>
   struct result<F()> {
     typedef nullary_return_type type;
   };
   template <class F, class A>
   struct result<F(A)> {
     typedef typename sig<tuple<F, A> >::type type;
   };
   template <class F, class A, class B>
   struct result<F(A, B)> {
     typedef typename sig<tuple<F, A, B> >::type type;
   };
   template <class F, class A, class B, class C>
   struct result<F(A, B, C)> {
     typedef typename sig<tuple<F, A, B, C> >::type type;
   };

   nullary_return_type operator()() const {
     return inherited::template
       call<nullary_return_type>
         (cnull_type(), cnull_type(), cnull_type(), cnull_type());
   }

   template<class A>
   typename inherited::template sig<tuple<A&> >::type
   operator()(A& a) const {
     return inherited::template call<
       typename inherited::template sig<tuple<A&> >::type
     >(a, cnull_type(), cnull_type(), cnull_type());
   }

   template<class A>
   BOOST_LAMBDA_DISABLE_IF_ARRAY1(A, inherited::template sig<tuple<A const&> >)
   operator()(A const& a) const {
     return inherited::template call<
       typename inherited::template sig<tuple<A const&> >::type
     >(a, cnull_type(), cnull_type(), cnull_type());
   }

   template<class A, class B>
   typename inherited::template sig<tuple<A&, B&> >::type
   operator()(A& a, B& b) const {
     return inherited::template call<
       typename inherited::template sig<tuple<A&, B&> >::type
     >(a, b, cnull_type(), cnull_type());
   }

   template<class A, class B>
   BOOST_LAMBDA_DISABLE_IF_ARRAY2(A, B, inherited::template sig<tuple<A const&, B&> >)
   operator()(A const& a, B& b) const {
     return inherited::template call<
       typename inherited::template sig<tuple<A const&, B&> >::type
     >(a, b, cnull_type(), cnull_type());
   }

   template<class A, class B>
   BOOST_LAMBDA_DISABLE_IF_ARRAY2(A, B, inherited::template sig<tuple<A&, B const&> >)
   operator()(A& a, B const& b) const {
     return inherited::template call<
       typename inherited::template sig<tuple<A&, B const&> >::type
     >(a, b, cnull_type(), cnull_type());
   }

   template<class A, class B>
   BOOST_LAMBDA_DISABLE_IF_ARRAY2(A, B, inherited::template sig<tuple<A const&, B const&> >)
   operator()(A const& a, B const& b) const {
     return inherited::template call<
       typename inherited::template sig<tuple<A const&, B const&> >::type
     >(a, b, cnull_type(), cnull_type());
   }

   template<class A, class B, class C>
   typename inherited::template sig<tuple<A&, B&, C&> >::type
   operator()(A& a, B& b, C& c) const
   {
     return inherited::template call<
       typename inherited::template sig<tuple<A&, B&, C&> >::type
     >(a, b, c, cnull_type());
   }

   template<class A, class B, class C>
   BOOST_LAMBDA_DISABLE_IF_ARRAY3(A, B, C, inherited::template sig<tuple<A const&, B const&, C const&> >)
   operator()(A const& a, B const& b, C const& c) const
   {
     return inherited::template call<
       typename inherited::template sig<tuple<A const&, B const&, C const&> >::type
     >(a, b, c, cnull_type());
   }

   // for internal calls with env
   template<CALL_TEMPLATE_ARGS>
   typename inherited::template sig<tuple<CALL_REFERENCE_TYPES> >::type
   internal_call(CALL_FORMAL_ARGS) const {
      return inherited::template
        call<typename inherited::template
          sig<tuple<CALL_REFERENCE_TYPES> >::type>(CALL_ACTUAL_ARGS);
   }

   template<class A>
   const lambda_functor<lambda_functor_base<
                   other_action<assignment_action>,
                   ndnboost::tuple<lambda_functor,
                   typename const_copy_argument <const A>::type> > >
   operator=(const A& a) const {
     return lambda_functor_base<
                   other_action<assignment_action>,
                   ndnboost::tuple<lambda_functor,
                   typename const_copy_argument <const A>::type> >
      (  ndnboost::tuple<lambda_functor,
              typename const_copy_argument <const A>::type>(*this, a) );
   }

   template<class A>
   const lambda_functor<lambda_functor_base<
                   other_action<subscript_action>,
                   ndnboost::tuple<lambda_functor,
                         typename const_copy_argument <const A>::type> > >
   operator[](const A& a) const {
     return lambda_functor_base<
                   other_action<subscript_action>,
                   ndnboost::tuple<lambda_functor,
                         typename const_copy_argument <const A>::type> >
      ( ndnboost::tuple<lambda_functor,
              typename const_copy_argument <const A>::type>(*this, a ) );
   }
 };

 #if BOOST_WORKAROUND(BOOST_MSVC, >= 1400)
 #pragma warning(pop)
 #endif

 } // namespace lambda
 } // namespace ndnboost

 namespace ndnboost {

 #if !defined(BOOST_RESULT_OF_USE_DECLTYPE) || defined(BOOST_NO_DECLTYPE)

 template<class T>
 struct result_of<ndnboost::lambda::lambda_functor<T>()>
 {
     typedef typename ndnboost::lambda::lambda_functor<T>::nullary_return_type type;
 };

 template<class T>
 struct result_of<const ndnboost::lambda::lambda_functor<T>()>
 {
     typedef typename ndnboost::lambda::lambda_functor<T>::nullary_return_type type;
 };

 #endif

 template<class T>
 struct tr1_result_of<ndnboost::lambda::lambda_functor<T>()>
 {
     typedef typename ndnboost::lambda::lambda_functor<T>::nullary_return_type type;
 };

 template<class T>
 struct tr1_result_of<const ndnboost::lambda::lambda_functor<T>()>
 {
     typedef typename ndnboost::lambda::lambda_functor<T>::nullary_return_type type;
 };

 }

 // is_placeholder

 #include <ndnboost/is_placeholder.hpp>

 namespace ndnboost
 {

 template<> struct is_placeholder< lambda::lambda_functor< lambda::placeholder<lambda::FIRST> > >
 {
     enum _vt { value = 1 };
 };

 template<> struct is_placeholder< lambda::lambda_functor< lambda::placeholder<lambda::SECOND> > >
 {
     enum _vt { value = 2 };
 };

 template<> struct is_placeholder< lambda::lambda_functor< lambda::placeholder<lambda::THIRD> > >
 {
     enum _vt { value = 3 };
 };

 } // namespace ndnboost

 #endif
	// Boost Lambda Library - lambda_functors.hpp -------------------------------

	// Copyright (C) 1999, 2000 Jaakko Jarvi (jaakko.jarvi@cs.utu.fi)
	//
	// 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)
	//
	// For more information, see http://www.boost.org

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

	#ifndef BOOST_LAMBDA_LAMBDA_FUNCTORS_HPP
	#define BOOST_LAMBDA_LAMBDA_FUNCTORS_HPP

	#include <ndnboost/config.hpp>
	#include <ndnboost/detail/workaround.hpp>
	#include <ndnboost/utility/result_of.hpp>

	#if BOOST_WORKAROUND(BOOST_MSVC, == 1310)

	#include <ndnboost/mpl/or.hpp>
	#include <ndnboost/utility/enable_if.hpp>
	#include <ndnboost/type_traits/is_array.hpp>

	#define BOOST_LAMBDA_DISABLE_IF_ARRAY1(A1, R1)\
	typename lazy_disable_if<is_array<A1>, typename R1 >::type
	#define BOOST_LAMBDA_DISABLE_IF_ARRAY2(A1, A2, R1, R2) \
	typename lazy_disable_if<mpl::or_<is_array<A1>, is_array<A2> >, typename R1, R2 >::type
	#define BOOST_LAMBDA_DISABLE_IF_ARRAY3(A1, A2, A3, R1, R2, R3) \
	typename lazy_disable_if<mpl::or_<is_array<A1>, is_array<A2>, is_array<A3> >, typename R1, R2, R3 >::type

	#else

	#define BOOST_LAMBDA_DISABLE_IF_ARRAY1(A1, R1) typename R1::type
	#define BOOST_LAMBDA_DISABLE_IF_ARRAY2(A1, A2, R1, R2) typename R1, R2::type
	#define BOOST_LAMBDA_DISABLE_IF_ARRAY3(A1, A2, A3, R1, R2, R3) typename R1, R2, R3::type

	#endif

	namespace ndnboost {
	namespace lambda {

	// -- lambda_functor --------------------------------------------
	// --------------------------------------------------------------

	//inline const null_type const_null_type() { return null_type(); }

	namespace detail {
	namespace {

	static const null_type constant_null_type = null_type();

	} // unnamed
	} // detail

	class unused {};

	#define cnull_type() detail::constant_null_type

	// -- free variables types --------------------------------------------------

	// helper to work around the case where the nullary return type deduction
	// is always performed, even though the functor is not nullary
	namespace detail {
	template<int N, class Tuple> struct get_element_or_null_type {
	typedef typename
	detail::tuple_element_as_reference<N, Tuple>::type type;
	};
	template<int N> struct get_element_or_null_type<N, null_type> {
	typedef null_type type;
	};
	}

	template <int I> struct placeholder;

	template<> struct placeholder<FIRST> {

	template<class SigArgs> struct sig {
	typedef typename detail::get_element_or_null_type<0, SigArgs>::type type;
	};

	template<class RET, CALL_TEMPLATE_ARGS>
	RET call(CALL_FORMAL_ARGS) const {
	BOOST_STATIC_ASSERT(ndnboost::is_reference<RET>::value);
	CALL_USE_ARGS; // does nothing, prevents warnings for unused args
	return a;
	}
	};

	template<> struct placeholder<SECOND> {

	template<class SigArgs> struct sig {
	typedef typename detail::get_element_or_null_type<1, SigArgs>::type type;
	};

	template<class RET, CALL_TEMPLATE_ARGS>
	RET call(CALL_FORMAL_ARGS) const { CALL_USE_ARGS; return b; }
	};

	template<> struct placeholder<THIRD> {

	template<class SigArgs> struct sig {
	typedef typename detail::get_element_or_null_type<2, SigArgs>::type type;
	};

	template<class RET, CALL_TEMPLATE_ARGS>
	RET call(CALL_FORMAL_ARGS) const { CALL_USE_ARGS; return c; }
	};

	template<> struct placeholder<EXCEPTION> {

	template<class SigArgs> struct sig {
	typedef typename detail::get_element_or_null_type<3, SigArgs>::type type;
	};

	template<class RET, CALL_TEMPLATE_ARGS>
	RET call(CALL_FORMAL_ARGS) const { CALL_USE_ARGS; return env; }
	};

	typedef const lambda_functor<placeholder<FIRST> > placeholder1_type;
	typedef const lambda_functor<placeholder<SECOND> > placeholder2_type;
	typedef const lambda_functor<placeholder<THIRD> > placeholder3_type;


	///////////////////////////////////////////////////////////////////////////////


	// free variables are lambda_functors. This is to allow uniform handling with
	// other lambda_functors.
	// -------------------------------------------------------------------

	#if BOOST_WORKAROUND(BOOST_MSVC, >= 1400)
	#pragma warning(push)
	#pragma warning(disable:4512) //assignment operator could not be generated
	#endif

	// -- lambda_functor NONE ------------------------------------------------
	template <class T>
	class lambda_functor : public T
	{

	BOOST_STATIC_CONSTANT(int, arity_bits = get_arity<T>::value);

	public:
	typedef T inherited;

	lambda_functor() {}
	lambda_functor(const lambda_functor& l) : inherited(l) {}

	lambda_functor(const T& t) : inherited(t) {}

	template <class SigArgs> struct sig {
	typedef typename inherited::template
	sig<typename SigArgs::tail_type>::type type;
	};

	// Note that this return type deduction template is instantiated, even
	// if the nullary
	// operator() is not called at all. One must make sure that it does not fail.
	typedef typename
	inherited::template sig<null_type>::type
	nullary_return_type;

	// Support for ndnboost::result_of.
	template <class Sig> struct result;
	template <class F>
	struct result<F()> {
	typedef nullary_return_type type;
	};
	template <class F, class A>
	struct result<F(A)> {
	typedef typename sig<tuple<F, A> >::type type;
	};
	template <class F, class A, class B>
	struct result<F(A, B)> {
	typedef typename sig<tuple<F, A, B> >::type type;
	};
	template <class F, class A, class B, class C>
	struct result<F(A, B, C)> {
	typedef typename sig<tuple<F, A, B, C> >::type type;
	};

	nullary_return_type operator()() const {
	return inherited::template
	call<nullary_return_type>
	(cnull_type(), cnull_type(), cnull_type(), cnull_type());
	}

	template<class A>
	typename inherited::template sig<tuple<A&> >::type
	operator()(A& a) const {
	return inherited::template call<
	typename inherited::template sig<tuple<A&> >::type
	>(a, cnull_type(), cnull_type(), cnull_type());
	}

	template<class A>
	BOOST_LAMBDA_DISABLE_IF_ARRAY1(A, inherited::template sig<tuple<A const&> >)
	operator()(A const& a) const {
	return inherited::template call<
	typename inherited::template sig<tuple<A const&> >::type
	>(a, cnull_type(), cnull_type(), cnull_type());
	}

	template<class A, class B>
	typename inherited::template sig<tuple<A&, B&> >::type
	operator()(A& a, B& b) const {
	return inherited::template call<
	typename inherited::template sig<tuple<A&, B&> >::type
	>(a, b, cnull_type(), cnull_type());
	}

	template<class A, class B>
	BOOST_LAMBDA_DISABLE_IF_ARRAY2(A, B, inherited::template sig<tuple<A const&, B&> >)
	operator()(A const& a, B& b) const {
	return inherited::template call<
	typename inherited::template sig<tuple<A const&, B&> >::type
	>(a, b, cnull_type(), cnull_type());
	}

	template<class A, class B>
	BOOST_LAMBDA_DISABLE_IF_ARRAY2(A, B, inherited::template sig<tuple<A&, B const&> >)
	operator()(A& a, B const& b) const {
	return inherited::template call<
	typename inherited::template sig<tuple<A&, B const&> >::type
	>(a, b, cnull_type(), cnull_type());
	}

	template<class A, class B>
	BOOST_LAMBDA_DISABLE_IF_ARRAY2(A, B, inherited::template sig<tuple<A const&, B const&> >)
	operator()(A const& a, B const& b) const {
	return inherited::template call<
	typename inherited::template sig<tuple<A const&, B const&> >::type
	>(a, b, cnull_type(), cnull_type());
	}

	template<class A, class B, class C>
	typename inherited::template sig<tuple<A&, B&, C&> >::type
	operator()(A& a, B& b, C& c) const
	{
	return inherited::template call<
	typename inherited::template sig<tuple<A&, B&, C&> >::type
	>(a, b, c, cnull_type());
	}

	template<class A, class B, class C>
	BOOST_LAMBDA_DISABLE_IF_ARRAY3(A, B, C, inherited::template sig<tuple<A const&, B const&, C const&> >)
	operator()(A const& a, B const& b, C const& c) const
	{
	return inherited::template call<
	typename inherited::template sig<tuple<A const&, B const&, C const&> >::type
	>(a, b, c, cnull_type());
	}

	// for internal calls with env
	template<CALL_TEMPLATE_ARGS>
	typename inherited::template sig<tuple<CALL_REFERENCE_TYPES> >::type
	internal_call(CALL_FORMAL_ARGS) const {
	return inherited::template
	call<typename inherited::template
	sig<tuple<CALL_REFERENCE_TYPES> >::type>(CALL_ACTUAL_ARGS);
	}

	template<class A>
	const lambda_functor<lambda_functor_base<
	other_action<assignment_action>,
	ndnboost::tuple<lambda_functor,
	typename const_copy_argument <const A>::type> > >
	operator=(const A& a) const {
	return lambda_functor_base<
	other_action<assignment_action>,
	ndnboost::tuple<lambda_functor,
	typename const_copy_argument <const A>::type> >
	( ndnboost::tuple<lambda_functor,
	typename const_copy_argument <const A>::type>(*this, a) );
	}

	template<class A>
	const lambda_functor<lambda_functor_base<
	other_action<subscript_action>,
	ndnboost::tuple<lambda_functor,
	typename const_copy_argument <const A>::type> > >
	operator[](const A& a) const {
	return lambda_functor_base<
	other_action<subscript_action>,
	ndnboost::tuple<lambda_functor,
	typename const_copy_argument <const A>::type> >
	( ndnboost::tuple<lambda_functor,
	typename const_copy_argument <const A>::type>(*this, a ) );
	}
	};

	#if BOOST_WORKAROUND(BOOST_MSVC, >= 1400)
	#pragma warning(pop)
	#endif

	} // namespace lambda
	} // namespace ndnboost

	namespace ndnboost {

	#if !defined(BOOST_RESULT_OF_USE_DECLTYPE) \|\| defined(BOOST_NO_DECLTYPE)

	template<class T>
	struct result_of<ndnboost::lambda::lambda_functor<T>()>
	{
	typedef typename ndnboost::lambda::lambda_functor<T>::nullary_return_type type;
	};

	template<class T>
	struct result_of<const ndnboost::lambda::lambda_functor<T>()>
	{
	typedef typename ndnboost::lambda::lambda_functor<T>::nullary_return_type type;
	};

	#endif

	template<class T>
	struct tr1_result_of<ndnboost::lambda::lambda_functor<T>()>
	{
	typedef typename ndnboost::lambda::lambda_functor<T>::nullary_return_type type;
	};

	template<class T>
	struct tr1_result_of<const ndnboost::lambda::lambda_functor<T>()>
	{
	typedef typename ndnboost::lambda::lambda_functor<T>::nullary_return_type type;
	};

	}

	// is_placeholder

	#include <ndnboost/is_placeholder.hpp>

	namespace ndnboost
	{

	template<> struct is_placeholder< lambda::lambda_functor< lambda::placeholder<lambda::FIRST> > >
	{
	enum _vt { value = 1 };
	};

	template<> struct is_placeholder< lambda::lambda_functor< lambda::placeholder<lambda::SECOND> > >
	{
	enum _vt { value = 2 };
	};

	template<> struct is_placeholder< lambda::lambda_functor< lambda::placeholder<lambda::THIRD> > >
	{
	enum _vt { value = 3 };
	};

	} // namespace ndnboost

	#endif