boost/accumulators/numeric/functional.hpp
/////////////////////////////////////////////////////////////////////////////// /// \file functional.hpp /// // Copyright 2005 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_NUMERIC_FUNCTIONAL_HPP_EAN_08_12_2005 #define BOOST_NUMERIC_FUNCTIONAL_HPP_EAN_08_12_2005 #include <limits> #include <functional> #include <boost/static_assert.hpp> #include <boost/mpl/if.hpp> #include <boost/mpl/and.hpp> #include <boost/type_traits/remove_const.hpp> #include <boost/type_traits/add_reference.hpp> #include <boost/type_traits/is_empty.hpp> #include <boost/type_traits/is_integral.hpp> #include <boost/type_traits/is_floating_point.hpp> #include <boost/utility/enable_if.hpp> #include <boost/typeof/typeof.hpp> #include <boost/accumulators/accumulators_fwd.hpp> #include <boost/accumulators/numeric/functional_fwd.hpp> #include <boost/accumulators/numeric/detail/function1.hpp> #include <boost/accumulators/numeric/detail/function2.hpp> #include <boost/accumulators/numeric/detail/pod_singleton.hpp> #ifdef BOOST_NUMERIC_FUNCTIONAL_STD_VECTOR_SUPPORT # include <boost/accumulators/numeric/functional/vector.hpp> #endif #ifdef BOOST_NUMERIC_FUNCTIONAL_STD_VALARRAY_SUPPORT # include <boost/accumulators/numeric/functional/valarray.hpp> #endif #ifdef BOOST_NUMERIC_FUNCTIONAL_STD_COMPLEX_SUPPORT # include <boost/accumulators/numeric/functional/complex.hpp> #endif /// INTERNAL ONLY /// #define BOOST_NUMERIC_FUNCTIONAL_HPP_INCLUDED #ifdef BOOST_NUMERIC_FUNCTIONAL_DOXYGEN_INVOKED // Hack to make Doxygen show the inheritance relationships /// INTERNAL ONLY /// namespace std { /// INTERNAL ONLY /// template<class Arg, class Ret> struct unary_function {}; /// INTERNAL ONLY /// template<class Left, class Right, class Ret> struct binary_function {}; } #endif namespace boost { namespace numeric { namespace functional { /// INTERNAL ONLY /// template<typename A0, typename A1> struct are_integral : mpl::and_<is_integral<A0>, is_integral<A1> > {}; template<typename Left, typename Right> struct left_ref { typedef Left &type; }; namespace detail { template<typename T> T &lvalue_of(); } } // TODO: handle complex weight, valarray, MTL vectors /// INTERNAL ONLY /// #define BOOST_NUMERIC_FUNCTIONAL_DEFINE_UNARY_OP(Name, Op) \ namespace functional \ { \ template<typename Arg> \ struct result_of_ ## Name \ { \ BOOST_TYPEOF_NESTED_TYPEDEF_TPL( \ nested \ , Op boost::numeric::functional::detail::lvalue_of<Arg>() \ ) \ typedef typename nested::type type; \ }; \ template<typename Arg, typename EnableIf> \ struct Name ## _base \ { \ typedef typename remove_const<Arg>::type argument_type; \ typedef typename result_of_ ## Name<Arg>::type result_type; \ typename result_of_ ## Name<Arg>::type operator ()(Arg &arg) const \ { \ return Op arg; \ } \ }; \ template<typename Arg, typename ArgTag> \ struct Name \ : Name ## _base<Arg, void> \ {}; \ } \ namespace op \ { \ struct Name \ : boost::detail::function1<functional::Name<_, functional::tag<_> > > \ {}; \ } \ namespace \ { \ op::Name const &Name = boost::detail::pod_singleton<op::Name>::instance; \ } \ /**/ /// INTERNAL ONLY /// #define BOOST_NUMERIC_FUNCTIONAL_DEFINE_BINARY_OP(Name, Op, RetType) \ namespace functional \ { \ template<typename Left, typename Right, typename EnableIf> \ struct result_of_ ## Name \ { \ RetType(Left, Op, Right) \ }; \ template<typename Left, typename Right, typename EnableIf> \ struct Name ## _base \ { \ typedef typename remove_const<Left>::type first_argument_type; \ typedef typename remove_const<Right>::type second_argument_type; \ typedef typename result_of_ ## Name<Left, Right>::type result_type; \ typename result_of_ ## Name<Left, Right>::type \ operator ()(Left &left, Right &right) const \ { \ return left Op right; \ } \ }; \ template<typename Left, typename Right, typename LeftTag, typename RightTag> \ struct Name \ : Name ## _base<Left, Right, void> \ {}; \ } \ namespace op \ { \ struct Name \ : boost::detail::function2< \ functional::Name<_1, _2, functional::tag<_1>, functional::tag<_2> > \ > \ {}; \ } \ namespace \ { \ op::Name const &Name = boost::detail::pod_singleton<op::Name>::instance; \ } \ BOOST_ACCUMULATORS_IGNORE_GLOBAL(Name) \ /**/ /// INTERNAL ONLY /// #define BOOST_NUMERIC_FUNCTIONAL_DEDUCED(Left, Op, Right) \ BOOST_TYPEOF_NESTED_TYPEDEF_TPL( \ nested \ , boost::numeric::functional::detail::lvalue_of<Left>() Op \ boost::numeric::functional::detail::lvalue_of<Right>() \ ) \ typedef typename nested::type type; \ /**/ /// INTERNAL ONLY /// #define BOOST_NUMERIC_FUNCTIONAL_LEFT(Left, Op, Right) \ typedef Left &type; \ /**/ BOOST_NUMERIC_FUNCTIONAL_DEFINE_BINARY_OP(plus, +, BOOST_NUMERIC_FUNCTIONAL_DEDUCED) BOOST_NUMERIC_FUNCTIONAL_DEFINE_BINARY_OP(minus, -, BOOST_NUMERIC_FUNCTIONAL_DEDUCED) BOOST_NUMERIC_FUNCTIONAL_DEFINE_BINARY_OP(multiplies, *, BOOST_NUMERIC_FUNCTIONAL_DEDUCED) BOOST_NUMERIC_FUNCTIONAL_DEFINE_BINARY_OP(divides, /, BOOST_NUMERIC_FUNCTIONAL_DEDUCED) BOOST_NUMERIC_FUNCTIONAL_DEFINE_BINARY_OP(modulus, %, BOOST_NUMERIC_FUNCTIONAL_DEDUCED) BOOST_NUMERIC_FUNCTIONAL_DEFINE_BINARY_OP(greater, >, BOOST_NUMERIC_FUNCTIONAL_DEDUCED) BOOST_NUMERIC_FUNCTIONAL_DEFINE_BINARY_OP(greater_equal, >=, BOOST_NUMERIC_FUNCTIONAL_DEDUCED) BOOST_NUMERIC_FUNCTIONAL_DEFINE_BINARY_OP(less, <, BOOST_NUMERIC_FUNCTIONAL_DEDUCED) BOOST_NUMERIC_FUNCTIONAL_DEFINE_BINARY_OP(less_equal, <=, BOOST_NUMERIC_FUNCTIONAL_DEDUCED) BOOST_NUMERIC_FUNCTIONAL_DEFINE_BINARY_OP(equal_to, ==, BOOST_NUMERIC_FUNCTIONAL_DEDUCED) BOOST_NUMERIC_FUNCTIONAL_DEFINE_BINARY_OP(not_equal_to, !=, BOOST_NUMERIC_FUNCTIONAL_DEDUCED) BOOST_NUMERIC_FUNCTIONAL_DEFINE_BINARY_OP(assign, =, BOOST_NUMERIC_FUNCTIONAL_LEFT) BOOST_NUMERIC_FUNCTIONAL_DEFINE_BINARY_OP(plus_assign, +=, BOOST_NUMERIC_FUNCTIONAL_LEFT) BOOST_NUMERIC_FUNCTIONAL_DEFINE_BINARY_OP(minus_assign, -=, BOOST_NUMERIC_FUNCTIONAL_LEFT) BOOST_NUMERIC_FUNCTIONAL_DEFINE_BINARY_OP(multiplies_assign, *=, BOOST_NUMERIC_FUNCTIONAL_LEFT) BOOST_NUMERIC_FUNCTIONAL_DEFINE_BINARY_OP(divides_assign, /=, BOOST_NUMERIC_FUNCTIONAL_LEFT) BOOST_NUMERIC_FUNCTIONAL_DEFINE_BINARY_OP(modulus_assign, %=, BOOST_NUMERIC_FUNCTIONAL_LEFT) BOOST_NUMERIC_FUNCTIONAL_DEFINE_UNARY_OP(unary_plus, +) BOOST_NUMERIC_FUNCTIONAL_DEFINE_UNARY_OP(unary_minus, -) BOOST_NUMERIC_FUNCTIONAL_DEFINE_UNARY_OP(complement, ~) BOOST_NUMERIC_FUNCTIONAL_DEFINE_UNARY_OP(logical_not, !) #undef BOOST_NUMERIC_FUNCTIONAL_LEFT #undef BOOST_NUMERIC_FUNCTIONAL_DEDUCED #undef BOOST_NUMERIC_FUNCTIONAL_DEFINE_UNARY_OP #undef BOOST_NUMERIC_FUNCTIONAL_DEFINE_BINARY_OP namespace functional { template<typename Left, typename Right, typename EnableIf> struct min_assign_base { typedef Left first_argument_type; typedef Right second_argument_type; typedef void result_type; void operator ()(Left &left, Right &right) const { if(numeric::less(right, left)) { left = right; } } }; template<typename Left, typename Right, typename EnableIf> struct max_assign_base { typedef Left first_argument_type; typedef Right second_argument_type; typedef void result_type; void operator ()(Left &left, Right &right) const { if(numeric::greater(right, left)) { left = right; } } }; template<typename Left, typename Right, typename EnableIf> struct fdiv_base : functional::divides<Left, Right> {}; // partial specialization that promotes the arguments to double for // integral division. template<typename Left, typename Right> struct fdiv_base<Left, Right, typename enable_if<are_integral<Left, Right> >::type> : functional::divides<double const, double const> {}; template<typename To, typename From, typename EnableIf> struct promote_base { typedef From argument_type; typedef To result_type; To operator ()(From &from) const { return from; } }; template<typename ToFrom> struct promote_base<ToFrom, ToFrom, void> { typedef ToFrom argument_type; typedef ToFrom result_type; ToFrom &operator ()(ToFrom &tofrom) { return tofrom; } }; template<typename Arg, typename EnableIf> struct as_min_base { BOOST_STATIC_ASSERT(std::numeric_limits<typename remove_const<Arg>::type>::is_specialized); typedef Arg argument_type; typedef typename remove_const<Arg>::type result_type; typename remove_const<Arg>::type operator ()(Arg &) const { return (std::numeric_limits<typename remove_const<Arg>::type>::min)(); } }; template<typename Arg> struct as_min_base<Arg, typename enable_if<is_floating_point<Arg> >::type> { BOOST_STATIC_ASSERT(std::numeric_limits<typename remove_const<Arg>::type>::is_specialized); typedef Arg argument_type; typedef typename remove_const<Arg>::type result_type; typename remove_const<Arg>::type operator ()(Arg &) const { return -(std::numeric_limits<typename remove_const<Arg>::type>::max)(); } }; template<typename Arg, typename EnableIf> struct as_max_base { BOOST_STATIC_ASSERT(std::numeric_limits<typename remove_const<Arg>::type>::is_specialized); typedef Arg argument_type; typedef typename remove_const<Arg>::type result_type; typename remove_const<Arg>::type operator ()(Arg &) const { return (std::numeric_limits<typename remove_const<Arg>::type>::max)(); } }; template<typename Arg, typename EnableIf> struct as_zero_base { typedef Arg argument_type; typedef typename remove_const<Arg>::type result_type; typename remove_const<Arg>::type operator ()(Arg &) const { return numeric::zero<typename remove_const<Arg>::type>::value; } }; template<typename Arg, typename EnableIf> struct as_one_base { typedef Arg argument_type; typedef typename remove_const<Arg>::type result_type; typename remove_const<Arg>::type operator ()(Arg &) const { return numeric::one<typename remove_const<Arg>::type>::value; } }; template<typename To, typename From, typename ToTag, typename FromTag> struct promote : promote_base<To, From, void> {}; template<typename Left, typename Right, typename LeftTag, typename RightTag> struct min_assign : min_assign_base<Left, Right, void> {}; template<typename Left, typename Right, typename LeftTag, typename RightTag> struct max_assign : max_assign_base<Left, Right, void> {}; template<typename Left, typename Right, typename LeftTag, typename RightTag> struct fdiv : fdiv_base<Left, Right, void> {}; /// INTERNAL ONLY /// For back-compat only. Use fdiv. template<typename Left, typename Right, typename LeftTag, typename RightTag> struct average : fdiv<Left, Right, LeftTag, RightTag> {}; template<typename Arg, typename Tag> struct as_min : as_min_base<Arg, void> {}; template<typename Arg, typename Tag> struct as_max : as_max_base<Arg, void> {}; template<typename Arg, typename Tag> struct as_zero : as_zero_base<Arg, void> {}; template<typename Arg, typename Tag> struct as_one : as_one_base<Arg, void> {}; } namespace op { template<typename To> struct promote : boost::detail::function1<functional::promote<To, _, typename functional::tag<To>::type, functional::tag<_> > > {}; struct min_assign : boost::detail::function2<functional::min_assign<_1, _2, functional::tag<_1>, functional::tag<_2> > > {}; struct max_assign : boost::detail::function2<functional::max_assign<_1, _2, functional::tag<_1>, functional::tag<_2> > > {}; struct fdiv : boost::detail::function2<functional::fdiv<_1, _2, functional::tag<_1>, functional::tag<_2> > > {}; /// INTERNAL ONLY struct average : boost::detail::function2<functional::fdiv<_1, _2, functional::tag<_1>, functional::tag<_2> > > {}; struct as_min : boost::detail::function1<functional::as_min<_, functional::tag<_> > > {}; struct as_max : boost::detail::function1<functional::as_max<_, functional::tag<_> > > {}; struct as_zero : boost::detail::function1<functional::as_zero<_, functional::tag<_> > > {}; struct as_one : boost::detail::function1<functional::as_one<_, functional::tag<_> > > {}; } namespace { op::min_assign const &min_assign = boost::detail::pod_singleton<op::min_assign>::instance; op::max_assign const &max_assign = boost::detail::pod_singleton<op::max_assign>::instance; op::fdiv const &fdiv = boost::detail::pod_singleton<op::fdiv>::instance; op::fdiv const &average = boost::detail::pod_singleton<op::fdiv>::instance; ///< INTERNAL ONLY op::as_min const &as_min = boost::detail::pod_singleton<op::as_min>::instance; op::as_max const &as_max = boost::detail::pod_singleton<op::as_max>::instance; op::as_zero const &as_zero = boost::detail::pod_singleton<op::as_zero>::instance; op::as_one const &as_one = boost::detail::pod_singleton<op::as_one>::instance; BOOST_ACCUMULATORS_IGNORE_GLOBAL(min_assign) BOOST_ACCUMULATORS_IGNORE_GLOBAL(max_assign) BOOST_ACCUMULATORS_IGNORE_GLOBAL(fdiv) BOOST_ACCUMULATORS_IGNORE_GLOBAL(average) BOOST_ACCUMULATORS_IGNORE_GLOBAL(as_min) BOOST_ACCUMULATORS_IGNORE_GLOBAL(as_max) BOOST_ACCUMULATORS_IGNORE_GLOBAL(as_zero) BOOST_ACCUMULATORS_IGNORE_GLOBAL(as_one) } /////////////////////////////////////////////////////////////////////////////// // promote template<typename To, typename From> typename lazy_disable_if<is_const<From>, mpl::if_<is_same<To, From>, To &, To> >::type promote(From &from) { return functional::promote<To, From>()(from); } template<typename To, typename From> typename mpl::if_<is_same<To const, From const>, To const &, To const>::type promote(From const &from) { return functional::promote<To const, From const>()(from); } template<typename T> struct default_ { typedef default_ type; typedef T value_type; static T const value; operator T const & () const { return default_::value; } }; template<typename T> T const default_<T>::value = T(); template<typename T> struct one { typedef one type; typedef T value_type; static T const value; operator T const & () const { return one::value; } }; template<typename T> T const one<T>::value = T(1); template<typename T> struct zero { typedef zero type; typedef T value_type; static T const value; operator T const & () const { return zero::value; } }; template<typename T> T const zero<T>::value = T(); template<typename T> struct one_or_default : mpl::if_<is_empty<T>, default_<T>, one<T> >::type {}; template<typename T> struct zero_or_default : mpl::if_<is_empty<T>, default_<T>, zero<T> >::type {}; }} // namespace boost::numeric #endif