/*!
@file
Defines `boost::hana::scan_left`.
@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_SCAN_LEFT_HPP
#define BOOST_HANA_SCAN_LEFT_HPP
#include <boost/hana/fwd/scan_left.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/empty.hpp>
#include <boost/hana/length.hpp>
#include <boost/hana/prepend.hpp>
#include <cstddef>
#include <utility>
BOOST_HANA_NAMESPACE_BEGIN
//! @cond
template <typename Xs, typename F>
constexpr auto scan_left_t::operator()(Xs&& xs, F const& f) const {
using S = typename hana::tag_of<Xs>::type;
using ScanLeft = BOOST_HANA_DISPATCH_IF(scan_left_impl<S>,
hana::Sequence<S>::value
);
#ifndef BOOST_HANA_CONFIG_DISABLE_CONCEPT_CHECKS
static_assert(hana::Sequence<S>::value,
"hana::scan_left(xs, f) requires 'xs' to be a Sequence");
#endif
return ScanLeft::apply(static_cast<Xs&&>(xs), f);
}
template <typename Xs, typename State, typename F>
constexpr auto scan_left_t::operator()(Xs&& xs, State&& state, F const& f) const {
using S = typename hana::tag_of<Xs>::type;
using ScanLeft = BOOST_HANA_DISPATCH_IF(scan_left_impl<S>,
hana::Sequence<S>::value
);
#ifndef BOOST_HANA_CONFIG_DISABLE_CONCEPT_CHECKS
static_assert(hana::Sequence<S>::value,
"hana::scan_left(xs, state, f) requires 'xs' to be a Sequence");
#endif
return ScanLeft::apply(static_cast<Xs&&>(xs),
static_cast<State&&>(state), f);
}
//! @endcond
template <typename S, bool condition>
struct scan_left_impl<S, when<condition>> : default_ {
// Without initial state
template <typename Xs, typename F, std::size_t n1, std::size_t n2, std::size_t ...ns>
static constexpr auto
apply1_impl(Xs&& xs, F const& f, std::index_sequence<n1, n2, ns...>) {
static_assert(n1 == 0, "logic error in Boost.Hana: file a bug report");
// Use scan_left with the first element as an initial state.
return scan_left_impl::apply_impl(
static_cast<Xs&&>(xs),
hana::at_c<0>(static_cast<Xs&&>(xs)),
f, std::index_sequence<n2, ns...>{}
);
}
template <typename Xs, typename F, std::size_t n>
static constexpr auto apply1_impl(Xs&& xs, F const&, std::index_sequence<n>) {
return hana::make<S>(hana::at_c<n>(static_cast<Xs&&>(xs)));
}
template <typename Xs, typename F>
static constexpr auto apply1_impl(Xs&&, F const&, std::index_sequence<>) {
return hana::empty<S>();
}
template <typename Xs, typename F>
static constexpr auto apply(Xs&& xs, F const& f) {
constexpr std::size_t Len = decltype(hana::length(xs))::value;
return scan_left_impl::apply1_impl(static_cast<Xs&&>(xs),
f, std::make_index_sequence<Len>{});
}
// With initial state
template <typename Xs, typename State, typename F,
std::size_t n1, std::size_t n2, std::size_t ...ns>
static constexpr auto
apply_impl(Xs&& xs, State&& state, F const& f,
std::index_sequence<n1, n2, ns...>)
{
auto rest = scan_left_impl::apply_impl(
static_cast<Xs&&>(xs),
f(state, hana::at_c<n1>(static_cast<Xs&&>(xs))),
f, std::index_sequence<n2, ns...>{});
return hana::prepend(std::move(rest), static_cast<State&&>(state));
}
template <typename Xs, typename State, typename F, std::size_t n>
static constexpr auto
apply_impl(Xs&& xs, State&& state, F const& f, std::index_sequence<n>) {
auto new_state = f(state, hana::at_c<n>(static_cast<Xs&&>(xs)));
return hana::make<S>(static_cast<State&&>(state), std::move(new_state));
}
template <typename Xs, typename State, typename F>
static constexpr auto
apply_impl(Xs&&, State&& state, F const&, std::index_sequence<>) {
return hana::make<S>(static_cast<State&&>(state));
}
template <typename Xs, typename State, typename F>
static constexpr auto apply(Xs&& xs, State&& state, F const& f) {
constexpr std::size_t Len = decltype(hana::length(xs))::value;
return scan_left_impl::apply_impl(static_cast<Xs&&>(xs),
static_cast<State&&>(state),
f, std::make_index_sequence<Len>{});
}
};
BOOST_HANA_NAMESPACE_END
#endif // !BOOST_HANA_SCAN_LEFT_HPP