boost/phoenix/stl/algorithm/transformation.hpp
// Copyright 2005 Daniel Wallin. // Copyright 2005 Joel de Guzman. // Copyright 2005 Dan Marsden. // // Use, modification and distribution is 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) // // Modeled after range_ex, Copyright 2004 Eric Niebler #ifndef BOOST_PHOENIX_ALGORITHM_TRANSFORMATION_HPP #define BOOST_PHOENIX_ALGORITHM_TRANSFORMATION_HPP #include <algorithm> #include <numeric> #include <boost/phoenix/core/limits.hpp> #include <boost/phoenix/stl/algorithm/detail/has_sort.hpp> #include <boost/phoenix/stl/algorithm/detail/has_remove.hpp> #include <boost/phoenix/stl/algorithm/detail/has_remove_if.hpp> #include <boost/phoenix/stl/algorithm/detail/has_unique.hpp> #include <boost/phoenix/stl/algorithm/detail/has_reverse.hpp> #include <boost/phoenix/stl/algorithm/detail/has_sort.hpp> #include <boost/phoenix/stl/algorithm/detail/begin.hpp> #include <boost/phoenix/stl/algorithm/detail/end.hpp> #include <boost/phoenix/stl/algorithm/detail/decay_array.hpp> #include <boost/phoenix/function/adapt_callable.hpp> #include <boost/range/result_iterator.hpp> #include <boost/range/difference_type.hpp> #include <boost/mpl/if.hpp> #include <boost/type_traits/is_void.hpp> namespace boost { namespace phoenix { namespace impl { struct swap { typedef void result_type; template <class A, class B> void operator()(A& a, B& b) const { using std::swap; swap(a, b); } }; struct copy { template <typename Sig> struct result; template<typename This, class R, class I> struct result<This(R&, I)> : detail::decay_array<I> {}; template<class R, class I> typename detail::decay_array<I>::type operator()(R& r, I i) const { return std::copy(detail::begin_(r), detail::end_(r), i); } }; struct copy_backward { template <typename Sig> struct result; template<typename This, class R, class I> struct result<This(R&, I)> : result<This(R&, I const &)> {}; template<typename This, class R, class I> struct result<This(R&, I &)> { typedef I type; }; template<class R, class I> I operator()(R& r, I & i) const { return std::copy_backward(detail::begin_(r), detail::end_(r), i); } template<class R, class I> I const operator()(R& r, I const & i) const { return std::copy_backward(detail::begin_(r), detail::end_(r), i); } }; struct transform { template <typename Sig> struct result; template<typename This, class R, class OutorI1, class ForOut> struct result<This(R&, OutorI1, ForOut)> : detail::decay_array<OutorI1> { }; template<typename This, class R, class OutorI1, class ForOut, class BinF> struct result<This(R&, OutorI1, ForOut, BinF)> : detail::decay_array<ForOut> { }; template<class R, class O, class F> typename result<transform(R&,O,F)>::type operator()(R& r, O o, F f) const { return std::transform(detail::begin_(r), detail::end_(r), o, f); } template<class R, class I, class O, class F> typename result<transform(R&,I,O,F)>::type operator()(R& r, I i, O o, F f) const { return std::transform(detail::begin_(r), detail::end_(r), i, o, f); } }; struct replace { typedef void result_type; template<class R, class T> void operator()(R& r, T const& what, T const& with) const { std::replace(detail::begin_(r), detail::end_(r), what, with); } }; struct replace_if { typedef void result_type; template<class R, class P, class T> void operator()(R& r, P p, T const& with) const { std::replace_if(detail::begin_(r), detail::end_(r), p, with); } }; struct replace_copy { template <typename Sig> struct result; template<typename This, class R, class O, class T, class T2> struct result<This(R&, O, T const&, T2 const&)> : detail::decay_array<O> {}; template<class R, class O, class T> typename detail::decay_array<O>::type operator()(R& r, O o, T const& what, T const& with) const { return std::replace_copy(detail::begin_(r), detail::end_(r), o, what, with); } }; struct replace_copy_if { template <typename Sig> struct result; template<typename This, class R, class O, class P, class T> struct result<This(R&, O, P, T const&)> : detail::decay_array<O> {}; template<class R, class O, class P, class T> typename detail::decay_array<O>::type operator()(R& r, O o, P p, T const& with) const { return std::replace_copy_if(detail::begin_(r), detail::end_(r), o, p, with); } }; struct fill { typedef void result_type; template<class R, class T> void operator()(R& r, T const& x) const { std::fill(detail::begin_(r), detail::end_(r), x); } }; struct fill_n { typedef void result_type; template<class R, class N, class T> void operator()(R& r, N n, T const& x) const { std::fill_n(detail::begin_(r), n, x); } }; struct generate { typedef void result_type; template<class R, class G> void operator()(R& r, G const & g) const { std::generate(detail::begin_(r), detail::end_(r), g); } }; struct generate_n { typedef void result_type; template<class R, class N, class G> void operator()(R& r, N n, G g) const { std::generate_n(detail::begin_(r), n, g); } }; struct remove { template <typename Sig> struct result; template<typename This, class R, class T> struct result<This(R&, T const&)> : range_result_iterator<R> { }; template<class R, class T> typename range_result_iterator<R>::type execute(R& r, T const& x, mpl::true_) const { r.remove(x); return detail::end_(r); } template<class R, class T> typename range_result_iterator<R>::type execute(R& r, T const& x, mpl::false_) const { return std::remove(detail::begin_(r), detail::end_(r), x); } template<class R, class T> typename range_result_iterator<R>::type operator()(R& r, T const& x) const { return execute(r, x, has_remove<R>()); } }; struct remove_if { template <typename Sig> struct result; template <typename This, class R, class P> struct result<This(R&,P)> : range_result_iterator<R> { }; template<class R, class P> typename range_result_iterator<R>::type execute(R& r, P p, mpl::true_) const { r.remove_if(p); return detail::end_(r); } template<class R, class P> typename range_result_iterator<R>::type execute(R& r, P p, mpl::false_) const { return std::remove_if(detail::begin_(r), detail::end_(r), p); } template<class R, class P> typename range_result_iterator<R>::type operator()(R& r, P p) const { return execute(r, p, has_remove_if<R>()); } }; struct remove_copy { template <typename Sig> struct result; template<typename This, class R, class O, class T> struct result<This(R&, O, T)> : detail::decay_array<O> {}; template<class R, class O, class T> typename detail::decay_array<O>::type operator()(R& r, O o, T const& x) const { return std::remove_copy(detail::begin_(r), detail::end_(r), o, x); } }; struct remove_copy_if { template <typename Sig> struct result; template<typename This, class R, class O, class P> struct result<This(R&, O, P)> : detail::decay_array<O> {}; template<class R, class O, class P> typename detail::decay_array<O>::type operator()(R& r, O o, P p) const { return std::remove_copy_if(detail::begin_(r), detail::end_(r), o, p); } }; struct unique { template <typename Sig> struct result; template<typename This, class R> struct result<This(R&)> : range_result_iterator<R> {}; template<typename This, class R, class P> struct result<This(R&, P)> : range_result_iterator<R> {}; template<class R> typename range_result_iterator<R>::type execute(R& r, mpl::true_) const { r.unique(); return detail::end_(r); } template<class R> typename range_result_iterator<R>::type execute(R& r, mpl::false_) const { return std::unique(detail::begin_(r), detail::end_(r)); } template<class R> typename range_result_iterator<R>::type operator()(R& r) const { return execute(r, has_unique<R>()); } template<class R, class P> typename range_result_iterator<R>::type execute(R& r, P p, mpl::true_) const { r.unique(p); return detail::end_(r); } template<class R, class P> typename range_result_iterator<R>::type execute(R& r, P p, mpl::false_) const { return std::unique(detail::begin_(r), detail::end_(r), p); } template<class R, class P> typename range_result_iterator<R>::type operator()(R& r, P p) const { return execute(r, p, has_unique<R>()); } }; struct unique_copy { template <typename Sig> struct result; template<typename This, class R, class O> struct result<This(R&, O)> : detail::decay_array<O> {}; template<typename This, class R, class O, class P> struct result<This(R&, O, P)> : detail::decay_array<O> {}; template<class R, class O> typename detail::decay_array<O>::type operator()(R& r, O o) const { return std::unique_copy( detail::begin_(r) , detail::end_(r) , o ); } template<class R, class O, class P> typename detail::decay_array<O>::type operator()(R& r, O o, P p) const { return std::unique_copy( detail::begin_(r) , detail::end_(r) , o , p ); } }; struct reverse { typedef void result_type; template<class R> void execute(R& r, mpl::true_) const { r.reverse(); } template<class R> void execute(R& r, mpl::false_) const { std::reverse(detail::begin_(r), detail::end_(r)); } template<class R> void operator()(R& r) const { execute(r, has_reverse<R>()); } }; struct reverse_copy { template <typename Sig> struct result; template<typename This, class R, class O> struct result<This(R&, O)> : detail::decay_array<O> {}; template<class R, class O> typename detail::decay_array<O>::type operator()(R& r, O o) const { return std::reverse_copy( detail::begin_(r) , detail::end_(r) , o ); } }; struct rotate { typedef void result_type; template<class R, class M> void operator()(R& r, M m) const { std::rotate( detail::begin_(r) , m , detail::end_(r) ); } }; struct rotate_copy { template <typename Sig> struct result; template<typename This, class R, class M, class O> struct result<This(R&, M, O)> : detail::decay_array<O> {}; template<class R, class M, class O> typename detail::decay_array<O>::type operator()(R& r, M m, O o) const { return std::rotate_copy( detail::begin_(r) , m , detail::end_(r) , o ); } }; struct random_shuffle { typedef void result_type; template<class R> void operator()(R& r) const { return std::random_shuffle(detail::begin_(r), detail::end_(r)); } template<class R, class G> void operator()(R& r, G g) const { return std::random_shuffle(detail::begin_(r), detail::end_(r), g); } }; struct partition { template <typename Sig> struct result; template <typename This, class R, class P> struct result<This(R&, P)> : range_result_iterator<R> {}; template<class R, class P> typename range_result_iterator<R>::type operator()(R& r, P p) const { return std::partition(detail::begin_(r), detail::end_(r), p); } }; struct stable_partition { template <typename Sig> struct result; template <typename This, class R, class P> struct result<This(R&, P)> : range_result_iterator<R> {}; template<class R, class P> typename range_result_iterator<R>::type operator()(R& r, P p) const { return std::stable_partition(detail::begin_(r), detail::end_(r), p); } }; struct sort { typedef void result_type; template<class R> void execute(R& r, mpl::true_) const { r.sort(); } template<class R> void execute(R& r, mpl::false_) const { std::sort(detail::begin_(r), detail::end_(r)); } template<class R> void operator()(R& r) const { execute(r, has_sort<R>()); } template<class R, class C> void execute(R& r, C c, mpl::true_) const { r.sort(c); } template<class R, class C> void execute(R& r, C c, mpl::false_) const { std::sort(detail::begin_(r), detail::end_(r), c); } template<class R, class C> void operator()(R& r, C c) const { execute(r, c, has_sort<R>()); } }; struct stable_sort { typedef void result_type; template<class R> void operator()(R& r) const { std::stable_sort(detail::begin_(r), detail::end_(r)); } template<class R, class C> void operator()(R& r, C c) const { std::stable_sort(detail::begin_(r), detail::end_(r), c); } }; struct partial_sort { typedef void result_type; template<class R, class M> void operator()(R& r, M m) const { std::partial_sort(detail::begin_(r), m, detail::end_(r)); } template<class R, class M, class C> void operator()(R& r, M m, C c) const { std::partial_sort(detail::begin_(r), m, detail::end_(r), c); } }; struct partial_sort_copy { template <typename Sig> struct result; template <typename This, class R1, class R2> struct result<This(R1&, R2&)> : range_result_iterator<R2> {}; template <typename This, class R1, class R2, class C> struct result<This(R1&, R2&, C)> : range_result_iterator<R2> {}; template <class R1, class R2> typename range_result_iterator<R2>::type operator()(R1& r1, R2& r2) const { return std::partial_sort_copy( detail::begin_(r1), detail::end_(r1) , detail::begin_(r2), detail::end_(r2) ); } template <class R1, class R2, class C> typename range_result_iterator<R2>::type operator()(R1& r1, R2& r2, C c) const { return std::partial_sort_copy( detail::begin_(r1), detail::end_(r1) , detail::begin_(r2), detail::end_(r2) , c ); } }; struct nth_element { typedef void result_type; template<class R, class N> void operator()(R& r, N n) const { return std::nth_element(detail::begin_(r), n, detail::end_(r)); } template<class R, class N, class C> void operator()(R& r, N n, C c) const { return std::nth_element(detail::begin_(r), n, detail::end_(r), c); } }; struct merge { template <typename Sig> struct result; template<typename This, class R1, class R2, class O> struct result<This(R1&, R2&, O)> : detail::decay_array<O> {}; template<typename This, class R1, class R2, class O, class C> struct result<This(R1&, R2&, O, C)> : detail::decay_array<O> {}; template<class R1, class R2, class O> typename detail::decay_array<O>::type operator()(R1& r1, R2& r2, O o) const { return std::merge( detail::begin_(r1), detail::end_(r1) , detail::begin_(r2), detail::end_(r2) , o ); } template<class R1, class R2, class O, class C> typename detail::decay_array<O>::type operator()(R1& r1, R2& r2, O o, C c) const { return std::merge( detail::begin_(r1), detail::end_(r1) , detail::begin_(r2), detail::end_(r2) , o , c ); } }; struct inplace_merge { typedef void result_type; template<class R, class M> void operator()(R& r, M m) const { return std::inplace_merge(detail::begin_(r), m, detail::end_(r)); } template<class R, class M, class C> void operator()(R& r, M m, C c) const { return std::inplace_merge(detail::begin_(r), m, detail::end_(r), c); } }; struct next_permutation { typedef bool result_type; template<class R> bool operator()(R& r) const { return std::next_permutation(detail::begin_(r), detail::end_(r)); } template<class R, class C> bool operator()(R& r, C c) const { return std::next_permutation(detail::begin_(r), detail::end_(r), c); } }; struct prev_permutation { typedef bool result_type; template<class R> bool operator()(R& r) const { return std::prev_permutation(detail::begin_(r), detail::end_(r)); } template<class R, class C> bool operator()(R& r, C c) const { return std::prev_permutation(detail::begin_(r), detail::end_(r), c); } }; struct inner_product { template <typename Sig> struct result; template <typename This, typename R, typename I, typename T> struct result<This(R&, I, T)> : result<This(R&, I const &, T)> {}; template <typename This, typename R, typename I, typename T> struct result<This(R&, I, T &)> { typedef T type; }; template <typename This, typename R, typename I, typename T, typename C1, typename C2> struct result<This(R&, I, T, C1, C2)> : result<This(R&, I, T const &, C1, C2)> {}; template <typename This, typename R, typename I, typename T, typename C1, typename C2> struct result<This(R&, I, T &, C1, C2)> { typedef T type; }; template <class R, class I, class T> T operator()(R& r, I i, T t) const { return std::inner_product( detail::begin_(r), detail::end_(r), i, t); } template <class R, class I, class T, class C1, class C2> T operator()(R& r, I i, T t, C1 c1, C2 c2) const { return std::inner_product( detail::begin_(r), detail::end_(r), i, t, c1, c2); } }; struct partial_sum { template <typename Sig> struct result; template <typename This, class R, class I> struct result<This(R&, I)> : detail::decay_array<I> {}; template <typename This, class R, class I, class C> struct result<This(R&, I, C)> : detail::decay_array<I> {}; template <class R, class I> typename detail::decay_array<I>::type operator()(R& r, I i) const { return std::partial_sum( detail::begin_(r), detail::end_(r), i); } template <class R, class I, class C> typename detail::decay_array<I>::type operator()(R& r, I i, C c) const { return std::partial_sum( detail::begin_(r), detail::end_(r), i, c); } }; struct adjacent_difference { template <typename Sig> struct result; template <typename This, class R, class I> struct result<This(R&, I)> : detail::decay_array<I> {}; template <typename This,class R, class I, class C> struct result<This(R&, I, C)> : detail::decay_array<I> {}; template <class R, class I> typename detail::decay_array<I>::type operator()(R& r, I i) const { return std::adjacent_difference( detail::begin_(r), detail::end_(r), i); } template <class R, class I, class C> typename detail::decay_array<I>::type operator()(R& r, I i, C c) const { return std::adjacent_difference( detail::begin_(r), detail::end_(r), i, c); } }; struct push_heap { typedef void result_type; template <class R> void operator()(R& r) const { std::push_heap(detail::begin_(r), detail::end_(r)); } template <class R, class C> void operator()(R& r, C c) const { std::push_heap(detail::begin_(r), detail::end_(r), c); } }; struct pop_heap { typedef void result_type; template <class R> void operator()(R& r) const { std::pop_heap(detail::begin_(r), detail::end_(r)); } template <class R, class C> void operator()(R& r, C c) const { std::pop_heap(detail::begin_(r), detail::end_(r), c); } }; struct make_heap { typedef void result_type; template <class R> void operator()(R& r) const { std::make_heap(detail::begin_(r), detail::end_(r)); } template <class R, class C> void operator()(R& r, C c) const { std::make_heap(detail::begin_(r), detail::end_(r), c); } }; struct sort_heap { typedef void result_type; template <class R> void operator()(R& r) const { std::sort_heap(detail::begin_(r), detail::end_(r)); } template <class R, class C> void operator()(R& r, C c) const { std::sort_heap(detail::begin_(r), detail::end_(r), c); } }; struct set_union { template <typename Sig> struct result; template <typename This, class R1, class R2, class O> struct result<This(R1&, R2&, O)> : detail::decay_array<O> {}; template <typename This, class R1, class R2, class O, typename C> struct result<This(R1&, R2&, O, C)> : detail::decay_array<O> {}; template <class R1, class R2, class O> typename detail::decay_array<O>::type operator()(R1& r1, R2& r2, O o) const { return std::set_union( detail::begin_(r1), detail::end_(r1) , detail::begin_(r2), detail::end_(r2) , o ); } template <class R1, class R2, class O, class C> typename detail::decay_array<O>::type operator()(R1& r1, R2& r2, O o, C c) const { return std::set_union( detail::begin_(r1), detail::end_(r1) , detail::begin_(r2), detail::end_(r2) , o , c ); } }; struct set_intersection { template <typename Sig> struct result; template <typename This, class R1, class R2, class O> struct result<This(R1&, R2&, O)> : detail::decay_array<O> {}; template <typename This, class R1, class R2, class O, typename C> struct result<This(R1&, R2&, O, C)> : detail::decay_array<O> {}; template <class R1, class R2, class O> typename detail::decay_array<O>::type operator()(R1& r1, R2& r2, O o) const { return std::set_intersection( detail::begin_(r1), detail::end_(r1) , detail::begin_(r2), detail::end_(r2) , o ); } template <class R1, class R2, class O, class C> typename detail::decay_array<O>::type operator()(R1& r1, R2& r2, O o, C c) const { return std::set_intersection( detail::begin_(r1), detail::end_(r1) , detail::begin_(r2), detail::end_(r2) , o , c ); } }; struct set_difference { template <typename Sig> struct result; template <typename This, class R1, class R2, class O> struct result<This(R1&, R2&, O)> : detail::decay_array<O> {}; template <typename This, class R1, class R2, class O, class C> struct result<This(R1&, R2&, O, C)> : detail::decay_array<O> {}; template <class R1, class R2, class O> typename detail::decay_array<O>::type operator()(R1& r1, R2& r2, O o) const { return std::set_difference( detail::begin_(r1), detail::end_(r1) , detail::begin_(r2), detail::end_(r2) , o ); } template <class R1, class R2, class O, class C> typename detail::decay_array<O>::type operator()(R1& r1, R2& r2, O o, C c) const { return std::set_difference( detail::begin_(r1), detail::end_(r1) , detail::begin_(r2), detail::end_(r2) , o , c ); } }; struct set_symmetric_difference { template <typename Sig> struct result; template <typename This, class R1, class R2, class O> struct result<This(R1&, R2, O)> : detail::decay_array<O> {}; template <typename This, class R1, class R2, class O, class C> struct result<This(R1&, R2, O, C)> : detail::decay_array<O> {}; template <class R1, class R2, class O> typename detail::decay_array<O>::type operator()(R1& r1, R2& r2, O o) const { return std::set_symmetric_difference( detail::begin_(r1), detail::end_(r1) , detail::begin_(r2), detail::end_(r2) , o ); } template <class R1, class R2, class O, class C> typename detail::decay_array<O>::type operator()(R1& r1, R2& r2, O o, C c) const { return std::set_symmetric_difference( detail::begin_(r1), detail::end_(r1) , detail::begin_(r2), detail::end_(r2) , o , c ); } }; }}} // boost::phoenix::impl namespace boost { namespace phoenix { BOOST_PHOENIX_ADAPT_CALLABLE(swap, impl::swap, 2) BOOST_PHOENIX_ADAPT_CALLABLE(copy, impl::copy, 2) BOOST_PHOENIX_ADAPT_CALLABLE(copy_backward, impl::copy_backward, 2) BOOST_PHOENIX_ADAPT_CALLABLE(transform, impl::transform, 3) BOOST_PHOENIX_ADAPT_CALLABLE(transform, impl::transform, 4) BOOST_PHOENIX_ADAPT_CALLABLE(replace, impl::replace, 3) BOOST_PHOENIX_ADAPT_CALLABLE(replace_if, impl::replace_if, 3) BOOST_PHOENIX_ADAPT_CALLABLE(replace_copy, impl::replace_copy, 4) BOOST_PHOENIX_ADAPT_CALLABLE(replace_copy_if, impl::replace_copy_if, 4) BOOST_PHOENIX_ADAPT_CALLABLE(fill, impl::fill, 2) BOOST_PHOENIX_ADAPT_CALLABLE(fill_n, impl::fill_n, 3) BOOST_PHOENIX_ADAPT_CALLABLE(generate, impl::generate, 2) BOOST_PHOENIX_ADAPT_CALLABLE(generate_n, impl::generate_n, 3) BOOST_PHOENIX_ADAPT_CALLABLE(remove, impl::remove, 2) BOOST_PHOENIX_ADAPT_CALLABLE(remove_if, impl::remove_if, 2) BOOST_PHOENIX_ADAPT_CALLABLE(remove_copy, impl::remove_copy, 3) BOOST_PHOENIX_ADAPT_CALLABLE(remove_copy_if, impl::remove_copy_if, 3) BOOST_PHOENIX_ADAPT_CALLABLE(unique, impl::unique, 1) BOOST_PHOENIX_ADAPT_CALLABLE(unique, impl::unique, 2) BOOST_PHOENIX_ADAPT_CALLABLE(unique_copy, impl::unique_copy, 2) BOOST_PHOENIX_ADAPT_CALLABLE(unique_copy, impl::unique_copy, 3) BOOST_PHOENIX_ADAPT_CALLABLE(reverse, impl::reverse, 1) BOOST_PHOENIX_ADAPT_CALLABLE(reverse_copy, impl::reverse_copy, 2) BOOST_PHOENIX_ADAPT_CALLABLE(rotate, impl::rotate, 2) BOOST_PHOENIX_ADAPT_CALLABLE(rotate_copy, impl::rotate_copy, 3) BOOST_PHOENIX_ADAPT_CALLABLE(random_shuffle, impl::random_shuffle, 1) BOOST_PHOENIX_ADAPT_CALLABLE(random_shuffle, impl::random_shuffle, 2) BOOST_PHOENIX_ADAPT_CALLABLE(partition, impl::partition, 2) BOOST_PHOENIX_ADAPT_CALLABLE(stable_partition, impl::stable_partition, 2) BOOST_PHOENIX_ADAPT_CALLABLE(sort, impl::sort, 1) BOOST_PHOENIX_ADAPT_CALLABLE(sort, impl::sort, 2) BOOST_PHOENIX_ADAPT_CALLABLE(stable_sort, impl::stable_sort, 1) BOOST_PHOENIX_ADAPT_CALLABLE(stable_sort, impl::stable_sort, 2) BOOST_PHOENIX_ADAPT_CALLABLE(partial_sort, impl::partial_sort, 2) BOOST_PHOENIX_ADAPT_CALLABLE(partial_sort, impl::partial_sort, 3) BOOST_PHOENIX_ADAPT_CALLABLE(partial_sort_copy, impl::partial_sort_copy, 2) BOOST_PHOENIX_ADAPT_CALLABLE(partial_sort_copy, impl::partial_sort_copy, 3) BOOST_PHOENIX_ADAPT_CALLABLE(nth_element, impl::nth_element, 2) BOOST_PHOENIX_ADAPT_CALLABLE(nth_element, impl::nth_element, 3) BOOST_PHOENIX_ADAPT_CALLABLE(merge, impl::merge, 3) BOOST_PHOENIX_ADAPT_CALLABLE(merge, impl::merge, 4) BOOST_PHOENIX_ADAPT_CALLABLE(inplace_merge, impl::inplace_merge, 2) BOOST_PHOENIX_ADAPT_CALLABLE(inplace_merge, impl::inplace_merge, 3) BOOST_PHOENIX_ADAPT_CALLABLE(next_permutation, impl::next_permutation, 1) BOOST_PHOENIX_ADAPT_CALLABLE(next_permutation, impl::next_permutation, 2) BOOST_PHOENIX_ADAPT_CALLABLE(prev_permutation, impl::prev_permutation, 1) BOOST_PHOENIX_ADAPT_CALLABLE(prev_permutation, impl::prev_permutation, 2) BOOST_PHOENIX_ADAPT_CALLABLE(inner_product, impl::inner_product, 3) BOOST_PHOENIX_ADAPT_CALLABLE(inner_product, impl::inner_product, 5) BOOST_PHOENIX_ADAPT_CALLABLE(partial_sum, impl::partial_sum, 2) BOOST_PHOENIX_ADAPT_CALLABLE(partial_sum, impl::partial_sum, 3) BOOST_PHOENIX_ADAPT_CALLABLE(adjacent_difference, impl::adjacent_difference, 2) BOOST_PHOENIX_ADAPT_CALLABLE(adjacent_difference, impl::adjacent_difference, 3) BOOST_PHOENIX_ADAPT_CALLABLE(push_heap, impl::push_heap, 1) BOOST_PHOENIX_ADAPT_CALLABLE(push_heap, impl::push_heap, 2) BOOST_PHOENIX_ADAPT_CALLABLE(pop_heap, impl::pop_heap, 1) BOOST_PHOENIX_ADAPT_CALLABLE(pop_heap, impl::pop_heap, 2) BOOST_PHOENIX_ADAPT_CALLABLE(make_heap, impl::make_heap, 1) BOOST_PHOENIX_ADAPT_CALLABLE(make_heap, impl::make_heap, 2) BOOST_PHOENIX_ADAPT_CALLABLE(sort_heap, impl::sort_heap, 1) BOOST_PHOENIX_ADAPT_CALLABLE(sort_heap, impl::sort_heap, 2) BOOST_PHOENIX_ADAPT_CALLABLE(set_union, impl::set_union, 3) BOOST_PHOENIX_ADAPT_CALLABLE(set_union, impl::set_union, 4) BOOST_PHOENIX_ADAPT_CALLABLE(set_intersection, impl::set_intersection, 3) BOOST_PHOENIX_ADAPT_CALLABLE(set_intersection, impl::set_intersection, 4) BOOST_PHOENIX_ADAPT_CALLABLE(set_difference, impl::set_difference, 3) BOOST_PHOENIX_ADAPT_CALLABLE(set_difference, impl::set_difference, 4) BOOST_PHOENIX_ADAPT_CALLABLE(set_symmetric_difference, impl::set_symmetric_difference, 3) BOOST_PHOENIX_ADAPT_CALLABLE(set_symmetric_difference, impl::set_symmetric_difference, 4) }} #endif