boost/histogram/axis/variant.hpp
// Copyright 2015-2019 Hans Dembinski // // 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_HISTOGRAM_AXIS_VARIANT_HPP #define BOOST_HISTOGRAM_AXIS_VARIANT_HPP #include <boost/core/nvp.hpp> #include <boost/histogram/axis/iterator.hpp> #include <boost/histogram/axis/polymorphic_bin.hpp> #include <boost/histogram/axis/traits.hpp> #include <boost/histogram/detail/relaxed_equal.hpp> #include <boost/histogram/detail/static_if.hpp> #include <boost/histogram/detail/type_name.hpp> #include <boost/histogram/detail/variant_proxy.hpp> #include <boost/mp11/algorithm.hpp> // mp_contains #include <boost/mp11/list.hpp> // mp_first #include <boost/throw_exception.hpp> #include <boost/variant2/variant.hpp> #include <stdexcept> #include <type_traits> #include <utility> namespace boost { namespace histogram { namespace axis { /// Polymorphic axis type template <class... Ts> class variant : public iterator_mixin<variant<Ts...>> { using impl_type = boost::variant2::variant<Ts...>; template <class T> using is_bounded_type = mp11::mp_contains<variant, std::decay_t<T>>; template <class T> using requires_bounded_type = std::enable_if_t<is_bounded_type<T>::value>; using metadata_type = std::remove_const_t<std::remove_reference_t<decltype(traits::metadata( std::declval<std::remove_pointer_t<mp11::mp_first<variant>>>()))>>; public: // cannot import ctors with using directive, it breaks gcc and msvc variant() = default; variant(const variant&) = default; variant& operator=(const variant&) = default; variant(variant&&) = default; variant& operator=(variant&&) = default; template <class T, class = requires_bounded_type<T>> variant(T&& t) : impl(std::forward<T>(t)) {} template <class T, class = requires_bounded_type<T>> variant& operator=(T&& t) { impl = std::forward<T>(t); return *this; } template <class... Us> variant(const variant<Us...>& u) { this->operator=(u); } template <class... Us> variant& operator=(const variant<Us...>& u) { visit( [this](const auto& u) { using U = std::decay_t<decltype(u)>; detail::static_if<is_bounded_type<U>>( [this](const auto& u) { this->operator=(u); }, [](const auto&) { BOOST_THROW_EXCEPTION(std::runtime_error( detail::type_name<U>() + " is not convertible to a bounded type of " + detail::type_name<variant>())); }, u); }, u); return *this; } /// Return size of axis. index_type size() const { return visit([](const auto& a) -> index_type { return a.size(); }, *this); } /// Return options of axis or option::none_t if axis has no options. unsigned options() const { return visit([](const auto& a) { return traits::options(a); }, *this); } /// Returns true if the axis is inclusive or false. bool inclusive() const { return visit([](const auto& a) { return traits::inclusive(a); }, *this); } /// Returns true if the axis is ordered or false. bool ordered() const { return visit([](const auto& a) { return traits::ordered(a); }, *this); } /// Returns true if the axis is continuous or false. bool continuous() const { return visit([](const auto& a) { return traits::continuous(a); }, *this); } /// Return reference to const metadata or instance of null_type if axis has no /// metadata. metadata_type& metadata() const { return visit( [](const auto& a) -> metadata_type& { using M = decltype(traits::metadata(a)); return detail::static_if<std::is_same<M, metadata_type&>>( [](const auto& a) -> metadata_type& { return traits::metadata(a); }, [](const auto&) -> metadata_type& { BOOST_THROW_EXCEPTION(std::runtime_error( "cannot return metadata of type " + detail::type_name<M>() + " through axis::variant interface which uses type " + detail::type_name<metadata_type>() + "; use boost::histogram::axis::get to obtain a reference " "of this axis type")); }, a); }, *this); } /// Return reference to metadata or instance of null_type if axis has no /// metadata. metadata_type& metadata() { return visit( [](auto& a) -> metadata_type& { using M = decltype(traits::metadata(a)); return detail::static_if<std::is_same<M, metadata_type&>>( [](auto& a) -> metadata_type& { return traits::metadata(a); }, [](auto&) -> metadata_type& { BOOST_THROW_EXCEPTION(std::runtime_error( "cannot return metadata of type " + detail::type_name<M>() + " through axis::variant interface which uses type " + detail::type_name<metadata_type>() + "; use boost::histogram::axis::get to obtain a reference " "of this axis type")); }, a); }, *this); } /** Return index for value argument. Throws std::invalid_argument if axis has incompatible call signature. */ template <class U> index_type index(const U& u) const { return visit([&u](const auto& a) { return traits::index(a, u); }, *this); } /** Return value for index argument. Only works for axes with value method that returns something convertible to double and will throw a runtime_error otherwise, see axis::traits::value(). */ double value(real_index_type idx) const { return visit([idx](const auto& a) { return traits::value_as<double>(a, idx); }, *this); } /** Return bin for index argument. Only works for axes with value method that returns something convertible to double and will throw a runtime_error otherwise, see axis::traits::value(). */ auto bin(index_type idx) const { return visit( [idx](const auto& a) { return detail::value_method_switch( [idx](const auto& a) { // axis is discrete const double x = traits::value_as<double>(a, idx); return polymorphic_bin<double>(x, x); }, [idx](const auto& a) { // axis is continuous const double x1 = traits::value_as<double>(a, idx); const double x2 = traits::value_as<double>(a, idx + 1); return polymorphic_bin<double>(x1, x2); }, a, detail::priority<1>{}); }, *this); } template <class Archive> void serialize(Archive& ar, unsigned /* version */) { detail::variant_proxy<variant> p{*this}; ar& make_nvp("variant", p); } private: impl_type impl; friend struct detail::variant_access; friend struct boost::histogram::unsafe_access; }; // specialization for empty argument list, useful for meta-programming template <> class variant<> {}; /// Apply visitor to variant (reference). template <class Visitor, class... Us> decltype(auto) visit(Visitor&& vis, variant<Us...>& var) { return detail::variant_access::visit(vis, var); } /// Apply visitor to variant (movable reference). template <class Visitor, class... Us> decltype(auto) visit(Visitor&& vis, variant<Us...>&& var) { return detail::variant_access::visit(vis, std::move(var)); } /// Apply visitor to variant (const reference). template <class Visitor, class... Us> decltype(auto) visit(Visitor&& vis, const variant<Us...>& var) { return detail::variant_access::visit(vis, var); } /// Returns pointer to T in variant or null pointer if type does not match. template <class T, class... Us> auto get_if(variant<Us...>* v) { return detail::variant_access::template get_if<T>(v); } /// Returns pointer to const T in variant or null pointer if type does not match. template <class T, class... Us> auto get_if(const variant<Us...>* v) { return detail::variant_access::template get_if<T>(v); } /// Return reference to T, throws std::runtime_error if type does not match. template <class T, class... Us> decltype(auto) get(variant<Us...>& v) { auto tp = get_if<T>(&v); if (!tp) BOOST_THROW_EXCEPTION(std::runtime_error("T is not the held type")); return *tp; } /// Return movable reference to T, throws unspecified exception if type does not match. template <class T, class... Us> decltype(auto) get(variant<Us...>&& v) { auto tp = get_if<T>(&v); if (!tp) BOOST_THROW_EXCEPTION(std::runtime_error("T is not the held type")); return std::move(*tp); } /// Return const reference to T, throws unspecified exception if type does not match. template <class T, class... Us> decltype(auto) get(const variant<Us...>& v) { auto tp = get_if<T>(&v); if (!tp) BOOST_THROW_EXCEPTION(std::runtime_error("T is not the held type")); return *tp; } // pass-through version of visit for generic programming template <class Visitor, class T> decltype(auto) visit(Visitor&& vis, T&& var) { return std::forward<Visitor>(vis)(std::forward<T>(var)); } // pass-through version of get for generic programming template <class T, class U> decltype(auto) get(U&& u) { return std::forward<U>(u); } // pass-through version of get_if for generic programming template <class T, class U> auto get_if(U* u) { return reinterpret_cast<T*>(std::is_same<T, std::decay_t<U>>::value ? u : nullptr); } // pass-through version of get_if for generic programming template <class T, class U> auto get_if(const U* u) { return reinterpret_cast<const T*>(std::is_same<T, std::decay_t<U>>::value ? u : nullptr); } /** Compare two variants. Return true if the variants point to the same concrete axis type and the types compare equal. Otherwise return false. */ template <class... Us, class... Vs> bool operator==(const variant<Us...>& u, const variant<Vs...>& v) noexcept { return visit([&](const auto& vi) { return u == vi; }, v); } /** Compare variant with a concrete axis type. Return true if the variant point to the same concrete axis type and the types compare equal. Otherwise return false. */ template <class... Us, class T> bool operator==(const variant<Us...>& u, const T& t) noexcept { using V = variant<Us...>; return detail::static_if_c<(mp11::mp_contains<V, T>::value || mp11::mp_contains<V, T*>::value || mp11::mp_contains<V, const T*>::value)>( [&](const auto& t) { using U = std::decay_t<decltype(t)>; const U* tp = detail::variant_access::template get_if<U>(&u); return tp && detail::relaxed_equal{}(*tp, t); }, [&](const auto&) { return false; }, t); } template <class T, class... Us> bool operator==(const T& t, const variant<Us...>& u) noexcept { return u == t; } /// The negation of operator==. template <class... Us, class... Ts> bool operator!=(const variant<Us...>& u, const variant<Ts...>& t) noexcept { return !(u == t); } /// The negation of operator==. template <class... Us, class T> bool operator!=(const variant<Us...>& u, const T& t) noexcept { return !(u == t); } /// The negation of operator==. template <class T, class... Us> bool operator!=(const T& t, const variant<Us...>& u) noexcept { return u != t; } } // namespace axis } // namespace histogram } // namespace boost #endif