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- /*!
- @file
- Defines `boost::hana::sort`.
- @copyright Louis Dionne 2013-2017
- Distributed under the Boost Software License, Version 1.0.
- (See accompanying file LICENSE.md or copy at http://boost.org/LICENSE_1_0.txt)
- */
- #ifndef BOOST_HANA_SORT_HPP
- #define BOOST_HANA_SORT_HPP
- #include <boost/hana/fwd/sort.hpp>
- #include <boost/hana/at.hpp>
- #include <boost/hana/concept/sequence.hpp>
- #include <boost/hana/config.hpp>
- #include <boost/hana/core/dispatch.hpp>
- #include <boost/hana/core/make.hpp>
- #include <boost/hana/detail/nested_by.hpp> // required by fwd decl
- #include <boost/hana/length.hpp>
- #include <boost/hana/less.hpp>
- #include <utility> // std::declval, std::index_sequence
- BOOST_HANA_NAMESPACE_BEGIN
- //! @cond
- template <typename Xs, typename Predicate>
- constexpr auto sort_t::operator()(Xs&& xs, Predicate&& pred) const {
- using S = typename hana::tag_of<Xs>::type;
- using Sort = BOOST_HANA_DISPATCH_IF(sort_impl<S>,
- hana::Sequence<S>::value
- );
- #ifndef BOOST_HANA_CONFIG_DISABLE_CONCEPT_CHECKS
- static_assert(hana::Sequence<S>::value,
- "hana::sort(xs, predicate) requires 'xs' to be a Sequence");
- #endif
- return Sort::apply(static_cast<Xs&&>(xs),
- static_cast<Predicate&&>(pred));
- }
- template <typename Xs>
- constexpr auto sort_t::operator()(Xs&& xs) const {
- using S = typename hana::tag_of<Xs>::type;
- using Sort = BOOST_HANA_DISPATCH_IF(sort_impl<S>,
- hana::Sequence<S>::value
- );
- #ifndef BOOST_HANA_CONFIG_DISABLE_CONCEPT_CHECKS
- static_assert(hana::Sequence<S>::value,
- "hana::sort(xs) requires 'xs' to be a Sequence");
- #endif
- return Sort::apply(static_cast<Xs&&>(xs));
- }
- //! @endcond
- namespace detail {
- template <typename Xs, typename Pred>
- struct sort_predicate {
- template <std::size_t I, std::size_t J>
- using apply = decltype(std::declval<Pred>()(
- hana::at_c<I>(std::declval<Xs>()),
- hana::at_c<J>(std::declval<Xs>())
- ));
- };
- template <typename Left, typename Right>
- struct concat;
- template <std::size_t ...l, std::size_t ...r>
- struct concat<std::index_sequence<l...>, std::index_sequence<r...>> {
- using type = std::index_sequence<l..., r...>;
- };
- template <typename Pred, bool PickRight, typename Left, typename Right>
- struct merge;
- template <
- typename Pred,
- std::size_t l0,
- std::size_t l1,
- std::size_t ...l,
- std::size_t r0,
- std::size_t ...r>
- struct merge<
- Pred,
- false,
- std::index_sequence<l0, l1, l...>,
- std::index_sequence<r0, r...>
- > {
- using type = typename concat<
- std::index_sequence<l0>,
- typename merge<
- Pred,
- (bool)Pred::template apply<r0, l1>::value,
- std::index_sequence<l1, l...>,
- std::index_sequence<r0, r...>
- >::type
- >::type;
- };
- template <
- typename Pred,
- std::size_t l0,
- std::size_t r0,
- std::size_t ...r>
- struct merge<
- Pred,
- false,
- std::index_sequence<l0>,
- std::index_sequence<r0, r...>
- > {
- using type = std::index_sequence<l0, r0, r...>;
- };
- template <
- typename Pred,
- std::size_t l0,
- std::size_t ...l,
- std::size_t r0,
- std::size_t r1,
- std::size_t ...r>
- struct merge<
- Pred,
- true,
- std::index_sequence<l0, l...>,
- std::index_sequence<r0, r1, r...>
- > {
- using type = typename concat<
- std::index_sequence<r0>,
- typename merge<
- Pred,
- (bool)Pred::template apply<r1, l0>::value,
- std::index_sequence<l0, l...>,
- std::index_sequence<r1, r...>
- >::type
- >::type;
- };
- template <
- typename Pred,
- std::size_t l0,
- std::size_t ...l,
- std::size_t r0>
- struct merge<
- Pred,
- true,
- std::index_sequence<l0, l...>,
- std::index_sequence<r0>
- > {
- using type = std::index_sequence<r0, l0, l...>;
- };
- template <typename Pred, typename Left, typename Right>
- struct merge_helper;
- template <
- typename Pred,
- std::size_t l0,
- std::size_t ...l,
- std::size_t r0,
- std::size_t ...r>
- struct merge_helper<
- Pred,
- std::index_sequence<l0, l...>,
- std::index_sequence<r0, r...>
- > {
- using type = typename merge<
- Pred,
- (bool)Pred::template apply<r0, l0>::value,
- std::index_sequence<l0, l...>,
- std::index_sequence<r0, r...>
- >::type;
- };
- // split templated structure, Nr represents the number of elements
- // from Right to move to Left
- // There are two specializations:
- // The first handles the generic case (Nr > 0)
- // The second handles the stop condition (Nr == 0)
- // These two specializations are not strictly ordered as
- // the first cannot match Nr==0 && empty Right
- // the second cannot match Nr!=0
- // std::enable_if<Nr!=0> is therefore required to make sure these two
- // specializations will never both be candidates during an overload
- // resolution (otherwise ambiguity occurs for Nr==0 and non-empty Right)
- template <std::size_t Nr, typename Left, typename Right, typename=void>
- struct split;
- template <
- std::size_t Nr,
- std::size_t ...l,
- std::size_t ...r,
- std::size_t r0>
- struct split<
- Nr,
- std::index_sequence<l...>,
- std::index_sequence<r0, r...>,
- typename std::enable_if<Nr!=0>::type
- > {
- using sp = split<
- Nr-1,
- std::index_sequence<l..., r0>,
- std::index_sequence<r...>
- >;
- using left = typename sp::left;
- using right = typename sp::right;
- };
- template <std::size_t ...l, std::size_t ...r>
- struct split<0, std::index_sequence<l...>, std::index_sequence<r...>> {
- using left = std::index_sequence<l...>;
- using right = std::index_sequence<r...>;
- };
- template <typename Pred, typename Sequence>
- struct merge_sort_impl;
- template <typename Pred, std::size_t ...seq>
- struct merge_sort_impl<Pred, std::index_sequence<seq...>> {
- using sequence = std::index_sequence<seq...>;
- using sp = split<
- sequence::size() / 2,
- std::index_sequence<>,
- sequence
- >;
- using type = typename merge_helper<
- Pred,
- typename merge_sort_impl<Pred, typename sp::left>::type,
- typename merge_sort_impl<Pred, typename sp::right>::type
- >::type;
- };
- template <typename Pred, std::size_t x>
- struct merge_sort_impl<Pred, std::index_sequence<x>> {
- using type = std::index_sequence<x>;
- };
- template <typename Pred>
- struct merge_sort_impl<Pred, std::index_sequence<>> {
- using type = std::index_sequence<>;
- };
- } // end namespace detail
- template <typename S, bool condition>
- struct sort_impl<S, when<condition>> : default_ {
- template <typename Xs, std::size_t ...i>
- static constexpr auto apply_impl(Xs&& xs, std::index_sequence<i...>) {
- return hana::make<S>(hana::at_c<i>(static_cast<Xs&&>(xs))...);
- }
- template <typename Xs, typename Pred>
- static constexpr auto apply(Xs&& xs, Pred const&) {
- constexpr std::size_t Len = decltype(hana::length(xs))::value;
- using Indices = typename detail::merge_sort_impl<
- detail::sort_predicate<Xs&&, Pred>,
- std::make_index_sequence<Len>
- >::type;
- return apply_impl(static_cast<Xs&&>(xs), Indices{});
- }
- template <typename Xs>
- static constexpr auto apply(Xs&& xs)
- { return sort_impl::apply(static_cast<Xs&&>(xs), hana::less); }
- };
- BOOST_HANA_NAMESPACE_END
- #endif // !BOOST_HANA_SORT_HPP
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