/*=============================================================================
Copyright (c) 2016 Paul Fultz II
limit.h
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_HOF_GUARD_LIMIT_H
#define BOOST_HOF_GUARD_LIMIT_H
/// limit
/// =====
///
/// Description
/// -----------
///
/// The `limit` function decorator annotates the function with the max number
/// of parameters. The `limit_c` version can be used to give the max number
/// directly(instead of relying on an integral constant). The parameter limit
/// can be read by using the [`function_param_limit`](function_param_limit)
/// trait. Using `limit` is useful to improve error reporting with partially
/// evaluated functions.
///
/// Synopsis
/// --------
///
/// template<class IntegralConstant>
/// constexpr auto limit(IntegralConstant);
///
/// template<std::size_t N, class F>
/// constexpr auto limit_c(F);
///
/// Requirements
/// ------------
///
/// IntegralConstant must be:
///
/// * IntegralConstant
///
/// F must be:
///
/// * [ConstInvocable](ConstInvocable)
/// * MoveConstructible
///
/// Example
/// -------
///
/// #include <boost/hof.hpp>
/// #include <cassert>
/// using namespace boost::hof;
///
/// struct sum_f
/// {
/// template<class T>
/// int operator()(T x, T y) const
/// {
/// return x+y;
/// }
/// };
/// BOOST_HOF_STATIC_FUNCTION(sum) = limit_c<2>(sum_f());
///
/// int main() {
/// assert(3 == sum(1, 2));
/// }
///
/// See Also
/// --------
///
/// * [Partial function evaluation](<Partial function evaluation>)
/// * [function_param_limit](function_param_limit)
///
#include <boost/hof/detail/callable_base.hpp>
#include <boost/hof/detail/forward.hpp>
#include <boost/hof/detail/delegate.hpp>
#include <boost/hof/detail/move.hpp>
#include <boost/hof/detail/static_const_var.hpp>
#include <boost/hof/always.hpp>
#include <boost/hof/function_param_limit.hpp>
namespace boost { namespace hof {
namespace detail {
// TODO: Make this work with fit_rewritable1_tag
template<std::size_t N, class F>
struct limit_adaptor : detail::callable_base<F>
{
typedef std::integral_constant<std::size_t, N> fit_function_param_limit;
BOOST_HOF_INHERIT_CONSTRUCTOR(limit_adaptor, detail::callable_base<F>)
template<class... Ts>
constexpr const detail::callable_base<F>& base_function(Ts&&... xs) const
{
return boost::hof::always_ref(*this)(xs...);
}
BOOST_HOF_RETURNS_CLASS(limit_adaptor);
template<class... Ts, class=typename std::enable_if<(sizeof...(Ts) <= N)>::type>
constexpr BOOST_HOF_SFINAE_RESULT(const detail::callable_base<F>&, id_<Ts>...)
operator()(Ts&&... xs) const BOOST_HOF_SFINAE_RETURNS
(
(BOOST_HOF_MANGLE_CAST(const detail::callable_base<F>&)(BOOST_HOF_CONST_THIS->base_function(xs...)))
(BOOST_HOF_FORWARD(Ts)(xs)...)
);
};
template<std::size_t N>
struct make_limit_f
{
constexpr make_limit_f()
{}
template<class F>
constexpr limit_adaptor<N, F> operator()(F f) const
{
return limit_adaptor<N, F>(static_cast<F&&>(f));
}
};
struct limit_f
{
template<class IntegralConstant, std::size_t N=IntegralConstant::type::value>
constexpr make_limit_f<N> operator()(IntegralConstant) const
{
return {};
}
};
}
template<std::size_t N, class F>
constexpr detail::limit_adaptor<N, F> limit_c(F f)
{
return detail::limit_adaptor<N, F>(static_cast<F&&>(f));
}
BOOST_HOF_DECLARE_STATIC_VAR(limit, detail::limit_f);
}} // namespace boost::hof
#endif