boost/pfr/detail/core14_classic.hpp
// Copyright (c) 2016-2022 Antony Polukhin // // 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_PFR_DETAIL_CORE14_CLASSIC_HPP #define BOOST_PFR_DETAIL_CORE14_CLASSIC_HPP #pragma once #include <boost/pfr/detail/config.hpp> #include <type_traits> #include <utility> // metaprogramming stuff #include <boost/pfr/detail/sequence_tuple.hpp> #include <boost/pfr/detail/offset_based_getter.hpp> #include <boost/pfr/detail/fields_count.hpp> #include <boost/pfr/detail/make_flat_tuple_of_references.hpp> #include <boost/pfr/detail/make_integer_sequence.hpp> #include <boost/pfr/detail/size_array.hpp> #include <boost/pfr/detail/size_t_.hpp> #include <boost/pfr/detail/rvalue_t.hpp> #ifdef __clang__ # pragma clang diagnostic push # pragma clang diagnostic ignored "-Wmissing-braces" # pragma clang diagnostic ignored "-Wundefined-inline" # pragma clang diagnostic ignored "-Wundefined-internal" # pragma clang diagnostic ignored "-Wmissing-field-initializers" #endif namespace boost { namespace pfr { namespace detail { ///////////////////// General utility stuff template <class T> struct identity { typedef T type; }; template <class T> constexpr T construct_helper() noexcept { // adding const here allows to deal with copyable only types return {}; } template <class T> constexpr size_array<sizeof(T) * 3> fields_count_and_type_ids_with_zeros() noexcept; template <class T> constexpr auto flat_array_of_type_ids() noexcept; ///////////////////// All the stuff for representing Type as integer and converting integer back to type namespace typeid_conversions { ///////////////////// Helper constants and typedefs #ifdef _MSC_VER # pragma warning( push ) // '<<': check operator precedence for possible error; use parentheses to clarify precedence # pragma warning( disable : 4554 ) #endif constexpr std::size_t native_types_mask = 31; constexpr std::size_t bits_per_extension = 3; constexpr std::size_t extension_mask = ( static_cast<std::size_t>((1 << bits_per_extension) - 1) << static_cast<std::size_t>(sizeof(std::size_t) * 8 - bits_per_extension) ); constexpr std::size_t native_ptr_type = ( static_cast<std::size_t>(1) << static_cast<std::size_t>(sizeof(std::size_t) * 8 - bits_per_extension) ); constexpr std::size_t native_const_ptr_type = ( static_cast<std::size_t>(2) << static_cast<std::size_t>(sizeof(std::size_t) * 8 - bits_per_extension) ); constexpr std::size_t native_const_volatile_ptr_type = ( static_cast<std::size_t>(3) << static_cast<std::size_t>(sizeof(std::size_t) * 8 - bits_per_extension) ); constexpr std::size_t native_volatile_ptr_type = ( static_cast<std::size_t>(4) << static_cast<std::size_t>(sizeof(std::size_t) * 8 - bits_per_extension) ); constexpr std::size_t native_ref_type = ( static_cast<std::size_t>(5) << static_cast<std::size_t>(sizeof(std::size_t) * 8 - bits_per_extension) ); template <std::size_t Index, std::size_t Extension> using if_extension = std::enable_if_t< (Index & extension_mask) == Extension >*; ///////////////////// Helper functions template <std::size_t Unptr> constexpr std::size_t type_to_id_extension_apply(std::size_t ext) noexcept { constexpr std::size_t native_id = (Unptr & native_types_mask); constexpr std::size_t extensions = (Unptr & ~native_types_mask); static_assert( !((extensions >> bits_per_extension) & native_types_mask), "====================> Boost.PFR: Too many extensions for a single field (something close to `int************************** p;` is in the POD type)." ); return (extensions >> bits_per_extension) | native_id | ext; } template <std::size_t Index> using remove_1_ext = size_t_< ((Index & ~native_types_mask) << bits_per_extension) | (Index & native_types_mask) >; #ifdef _MSC_VER # pragma warning( pop ) #endif ///////////////////// Forward declarations template <class Type> constexpr std::size_t type_to_id(identity<Type*>) noexcept; template <class Type> constexpr std::size_t type_to_id(identity<const Type*>) noexcept; template <class Type> constexpr std::size_t type_to_id(identity<const volatile Type*>) noexcept; template <class Type> constexpr std::size_t type_to_id(identity<volatile Type*>) noexcept; template <class Type> constexpr std::size_t type_to_id(identity<Type&>) noexcept; template <class Type> constexpr std::size_t type_to_id(identity<Type>, std::enable_if_t<std::is_enum<Type>::value>* = 0) noexcept; template <class Type> constexpr std::size_t type_to_id(identity<Type>, std::enable_if_t<std::is_empty<Type>::value>* = 0) noexcept; template <class Type> constexpr std::size_t type_to_id(identity<Type>, std::enable_if_t<std::is_union<Type>::value>* = 0) noexcept; template <class Type> constexpr size_array<sizeof(Type) * 3> type_to_id(identity<Type>, std::enable_if_t<!std::is_enum<Type>::value && !std::is_empty<Type>::value && !std::is_union<Type>::value>* = 0) noexcept; template <std::size_t Index> constexpr auto id_to_type(size_t_<Index >, if_extension<Index, native_const_ptr_type> = 0) noexcept; template <std::size_t Index> constexpr auto id_to_type(size_t_<Index >, if_extension<Index, native_ptr_type> = 0) noexcept; template <std::size_t Index> constexpr auto id_to_type(size_t_<Index >, if_extension<Index, native_const_volatile_ptr_type> = 0) noexcept; template <std::size_t Index> constexpr auto id_to_type(size_t_<Index >, if_extension<Index, native_volatile_ptr_type> = 0) noexcept; template <std::size_t Index> constexpr auto id_to_type(size_t_<Index >, if_extension<Index, native_ref_type> = 0) noexcept; ///////////////////// Definitions of type_to_id and id_to_type for fundamental types /// @cond #define BOOST_MAGIC_GET_REGISTER_TYPE(Type, Index) \ constexpr std::size_t type_to_id(identity<Type>) noexcept { \ return Index; \ } \ constexpr Type id_to_type( size_t_<Index > ) noexcept { \ return detail::construct_helper<Type>(); \ } \ /**/ /// @endcond // Register all base types here BOOST_MAGIC_GET_REGISTER_TYPE(unsigned char , 1) BOOST_MAGIC_GET_REGISTER_TYPE(unsigned short , 2) BOOST_MAGIC_GET_REGISTER_TYPE(unsigned int , 3) BOOST_MAGIC_GET_REGISTER_TYPE(unsigned long , 4) BOOST_MAGIC_GET_REGISTER_TYPE(unsigned long long , 5) BOOST_MAGIC_GET_REGISTER_TYPE(signed char , 6) BOOST_MAGIC_GET_REGISTER_TYPE(short , 7) BOOST_MAGIC_GET_REGISTER_TYPE(int , 8) BOOST_MAGIC_GET_REGISTER_TYPE(long , 9) BOOST_MAGIC_GET_REGISTER_TYPE(long long , 10) BOOST_MAGIC_GET_REGISTER_TYPE(char , 11) BOOST_MAGIC_GET_REGISTER_TYPE(wchar_t , 12) BOOST_MAGIC_GET_REGISTER_TYPE(char16_t , 13) BOOST_MAGIC_GET_REGISTER_TYPE(char32_t , 14) BOOST_MAGIC_GET_REGISTER_TYPE(float , 15) BOOST_MAGIC_GET_REGISTER_TYPE(double , 16) BOOST_MAGIC_GET_REGISTER_TYPE(long double , 17) BOOST_MAGIC_GET_REGISTER_TYPE(bool , 18) BOOST_MAGIC_GET_REGISTER_TYPE(void* , 19) BOOST_MAGIC_GET_REGISTER_TYPE(const void* , 20) BOOST_MAGIC_GET_REGISTER_TYPE(volatile void* , 21) BOOST_MAGIC_GET_REGISTER_TYPE(const volatile void* , 22) BOOST_MAGIC_GET_REGISTER_TYPE(std::nullptr_t , 23) constexpr std::size_t tuple_begin_tag = 24; constexpr std::size_t tuple_end_tag = 25; #undef BOOST_MAGIC_GET_REGISTER_TYPE ///////////////////// Definitions of type_to_id and id_to_type for types with extensions and nested types template <class Type> constexpr std::size_t type_to_id(identity<Type*>) noexcept { constexpr auto unptr = typeid_conversions::type_to_id(identity<Type>{}); static_assert( std::is_same<const std::size_t, decltype(unptr)>::value, "====================> Boost.PFR: Pointers to user defined types are not supported." ); return typeid_conversions::type_to_id_extension_apply<unptr>(native_ptr_type); } template <class Type> constexpr std::size_t type_to_id(identity<const Type*>) noexcept { constexpr auto unptr = typeid_conversions::type_to_id(identity<Type>{}); static_assert( std::is_same<const std::size_t, decltype(unptr)>::value, "====================> Boost.PFR: Const pointers to user defined types are not supported." ); return typeid_conversions::type_to_id_extension_apply<unptr>(native_const_ptr_type); } template <class Type> constexpr std::size_t type_to_id(identity<const volatile Type*>) noexcept { constexpr auto unptr = typeid_conversions::type_to_id(identity<Type>{}); static_assert( std::is_same<const std::size_t, decltype(unptr)>::value, "====================> Boost.PFR: Const volatile pointers to user defined types are not supported." ); return typeid_conversions::type_to_id_extension_apply<unptr>(native_const_volatile_ptr_type); } template <class Type> constexpr std::size_t type_to_id(identity<volatile Type*>) noexcept { constexpr auto unptr = typeid_conversions::type_to_id(identity<Type>{}); static_assert( std::is_same<const std::size_t, decltype(unptr)>::value, "====================> Boost.PFR: Volatile pointers to user defined types are not supported." ); return typeid_conversions::type_to_id_extension_apply<unptr>(native_volatile_ptr_type); } template <class Type> constexpr std::size_t type_to_id(identity<Type&>) noexcept { constexpr auto unptr = typeid_conversions::type_to_id(identity<Type>{}); static_assert( std::is_same<const std::size_t, decltype(unptr)>::value, "====================> Boost.PFR: References to user defined types are not supported." ); return typeid_conversions::type_to_id_extension_apply<unptr>(native_ref_type); } template <class Type> constexpr std::size_t type_to_id(identity<Type>, std::enable_if_t<std::is_enum<Type>::value>*) noexcept { return typeid_conversions::type_to_id(identity<typename std::underlying_type<Type>::type >{}); } template <class Type> constexpr std::size_t type_to_id(identity<Type>, std::enable_if_t<std::is_empty<Type>::value>*) noexcept { static_assert(!std::is_empty<Type>::value, "====================> Boost.PFR: Empty classes/structures as members are not supported."); return 0; } template <class Type> constexpr std::size_t type_to_id(identity<Type>, std::enable_if_t<std::is_union<Type>::value>*) noexcept { static_assert( !std::is_union<Type>::value, "====================> Boost.PFR: For safety reasons it is forbidden to reflect unions. See `Reflection of unions` section in the docs for more info." ); return 0; } template <class Type> constexpr size_array<sizeof(Type) * 3> type_to_id(identity<Type>, std::enable_if_t<!std::is_enum<Type>::value && !std::is_empty<Type>::value && !std::is_union<Type>::value>*) noexcept { constexpr auto t = detail::flat_array_of_type_ids<Type>(); size_array<sizeof(Type) * 3> result {{tuple_begin_tag}}; constexpr bool requires_tuplening = ( (t.count_nonzeros() != 1) || (t.count_nonzeros() == t.count_from_opening_till_matching_parenthis_seq(0, tuple_begin_tag, tuple_end_tag)) ); if (requires_tuplening) { for (std::size_t i = 0; i < t.size(); ++i) result.data[i + 1] = t.data[i]; result.data[result.size() - 1] = tuple_end_tag; } else { for (std::size_t i = 0; i < t.size(); ++i) result.data[i] = t.data[i]; } return result; } template <std::size_t Index> constexpr auto id_to_type(size_t_<Index >, if_extension<Index, native_ptr_type>) noexcept { typedef decltype( typeid_conversions::id_to_type(remove_1_ext<Index>()) )* res_t; return detail::construct_helper<res_t>(); } template <std::size_t Index> constexpr auto id_to_type(size_t_<Index >, if_extension<Index, native_const_ptr_type>) noexcept { typedef const decltype( typeid_conversions::id_to_type(remove_1_ext<Index>()) )* res_t; return detail::construct_helper<res_t>(); } template <std::size_t Index> constexpr auto id_to_type(size_t_<Index >, if_extension<Index, native_const_volatile_ptr_type>) noexcept { typedef const volatile decltype( typeid_conversions::id_to_type(remove_1_ext<Index>()) )* res_t; return detail::construct_helper<res_t>(); } template <std::size_t Index> constexpr auto id_to_type(size_t_<Index >, if_extension<Index, native_volatile_ptr_type>) noexcept { typedef volatile decltype( typeid_conversions::id_to_type(remove_1_ext<Index>()) )* res_t; return detail::construct_helper<res_t>(); } template <std::size_t Index> constexpr auto id_to_type(size_t_<Index >, if_extension<Index, native_ref_type>) noexcept { static_assert(!Index, "====================> Boost.PFR: References are not supported"); return nullptr; } } // namespace typeid_conversions ///////////////////// Structure that remembers types as integers on a `constexpr operator Type()` call struct ubiq_val { std::size_t* ref_; template <class T> constexpr void assign(const T& typeids) const noexcept { for (std::size_t i = 0; i < T::size(); ++i) ref_[i] = typeids.data[i]; } constexpr void assign(std::size_t val) const noexcept { ref_[0] = val; } template <class Type> constexpr operator Type() const noexcept { constexpr auto typeids = typeid_conversions::type_to_id(identity<Type>{}); assign(typeids); return detail::construct_helper<Type>(); } }; ///////////////////// Structure that remembers size of the type on a `constexpr operator Type()` call struct ubiq_sizes { std::size_t& ref_; template <class Type> constexpr operator Type() const noexcept { ref_ = sizeof(Type); return detail::construct_helper<Type>(); } }; ///////////////////// Returns array of (offsets without accounting alignments). Required for keeping places for nested type ids template <class T, std::size_t N, std::size_t... I> constexpr size_array<N> get_type_offsets() noexcept { typedef size_array<N> array_t; array_t sizes{}; T tmp{ ubiq_sizes{sizes.data[I]}... }; (void)tmp; array_t offsets{{0}}; for (std::size_t i = 1; i < N; ++i) offsets.data[i] = offsets.data[i - 1] + sizes.data[i - 1]; return offsets; } ///////////////////// Returns array of typeids and zeros if construtor of a type accepts sizeof...(I) parameters template <class T, std::size_t N, std::size_t... I> constexpr void* flat_type_to_array_of_type_ids(std::size_t* types, std::index_sequence<I...>) noexcept { static_assert( N <= sizeof(T), "====================> Boost.PFR: Bit fields are not supported." ); constexpr auto offsets = detail::get_type_offsets<T, N, I...>(); T tmp{ ubiq_val{types + get<I>(offsets) * 3}... }; (void)types; (void)tmp; (void)offsets; // If type is empty offsets are not used return nullptr; } ///////////////////// Returns array of typeids and zeros template <class T> constexpr size_array<sizeof(T) * 3> fields_count_and_type_ids_with_zeros() noexcept { size_array<sizeof(T) * 3> types{}; constexpr std::size_t N = detail::fields_count<T>(); detail::flat_type_to_array_of_type_ids<T, N>(types.data, detail::make_index_sequence<N>()); return types; } ///////////////////// Returns array of typeids without zeros template <class T> constexpr auto flat_array_of_type_ids() noexcept { constexpr auto types = detail::fields_count_and_type_ids_with_zeros<T>(); constexpr std::size_t count = types.count_nonzeros(); size_array<count> res{}; std::size_t j = 0; for (std::size_t i = 0; i < decltype(types)::size(); ++i) { if (types.data[i]) { res.data[j] = types.data[i]; ++ j; } } return res; } ///////////////////// Convert array of typeids into sequence_tuple::tuple template <class T, std::size_t First, std::size_t... I> constexpr auto as_flat_tuple_impl(std::index_sequence<First, I...>) noexcept; template <class T> constexpr sequence_tuple::tuple<> as_flat_tuple_impl(std::index_sequence<>) noexcept { return sequence_tuple::tuple<>{}; } template <std::size_t Increment, std::size_t... I> constexpr auto increment_index_sequence(std::index_sequence<I...>) noexcept { return std::index_sequence<I + Increment...>{}; } template <class T, std::size_t V, std::size_t I, std::size_t SubtupleLength> constexpr auto prepare_subtuples(size_t_<V>, size_t_<I>, size_t_<SubtupleLength>) noexcept { static_assert(SubtupleLength == 0, "====================> Boost.PFR: Internal error while representing nested field as tuple"); return typeid_conversions::id_to_type(size_t_<V>{}); } template <class T, std::size_t I, std::size_t SubtupleLength> constexpr auto prepare_subtuples(size_t_<typeid_conversions::tuple_end_tag>, size_t_<I>, size_t_<SubtupleLength>) noexcept { static_assert(sizeof(T) == 0, "====================> Boost.PFR: Internal error while representing nested field as tuple"); return int{}; } template <class T, std::size_t I, std::size_t SubtupleLength> constexpr auto prepare_subtuples(size_t_<typeid_conversions::tuple_begin_tag>, size_t_<I>, size_t_<SubtupleLength>) noexcept { static_assert(SubtupleLength > 2, "====================> Boost.PFR: Internal error while representing nested field as tuple"); constexpr auto seq = detail::make_index_sequence<SubtupleLength - 2>{}; return detail::as_flat_tuple_impl<T>( detail::increment_index_sequence<I + 1>(seq) ); } template <class Array> constexpr Array remove_subtuples(Array indexes_plus_1, const Array& subtuple_lengths) noexcept { for (std::size_t i = 0; i < subtuple_lengths.size(); ++i) { if (subtuple_lengths.data[i]) { const std::size_t skips_count = subtuple_lengths.data[i]; for (std::size_t j = i + 1; j < skips_count + i; ++j) { indexes_plus_1.data[j] = 0; } i += skips_count - 1; } } return indexes_plus_1; } template <std::size_t N, class Array> constexpr size_array<N> resize_dropping_zeros_and_decrementing(size_t_<N>, const Array& a) noexcept { size_array<N> result{}; std::size_t result_indx = 0; for (std::size_t i = 0; i < a.size(); ++i) { if (a.data[i]) { result.data[result_indx] = static_cast<std::size_t>(a.data[i] - 1); ++ result_indx; } } return result; } template <class T, std::size_t First, std::size_t... I, std::size_t... INew> constexpr auto as_flat_tuple_impl_drop_helpers(std::index_sequence<First, I...>, std::index_sequence<INew...>) noexcept { constexpr auto a = detail::flat_array_of_type_ids<T>(); constexpr size_array<sizeof...(I) + 1> subtuples_length {{ a.count_from_opening_till_matching_parenthis_seq(First, typeid_conversions::tuple_begin_tag, typeid_conversions::tuple_end_tag), a.count_from_opening_till_matching_parenthis_seq(I, typeid_conversions::tuple_begin_tag, typeid_conversions::tuple_end_tag)... }}; constexpr size_array<sizeof...(I) + 1> type_indexes_with_subtuple_internals {{ 1, 1 + I - First...}}; constexpr auto type_indexes_plus_1_and_zeros_as_skips = detail::remove_subtuples(type_indexes_with_subtuple_internals, subtuples_length); constexpr auto new_size = size_t_<type_indexes_plus_1_and_zeros_as_skips.count_nonzeros()>{}; constexpr auto type_indexes = detail::resize_dropping_zeros_and_decrementing(new_size, type_indexes_plus_1_and_zeros_as_skips); typedef sequence_tuple::tuple< decltype(detail::prepare_subtuples<T>( size_t_< a.data[ First + type_indexes.data[INew] ] >{}, // id of type size_t_< First + type_indexes.data[INew] >{}, // index of current id in `a` size_t_< subtuples_length.data[ type_indexes.data[INew] ] >{} // if id of type is tuple, then length of that tuple ))... > subtuples_uncleanuped_t; return subtuples_uncleanuped_t{}; } template <class Array> constexpr std::size_t count_skips_in_array(std::size_t begin_index, std::size_t end_index, const Array& a) noexcept { std::size_t skips = 0; for (std::size_t i = begin_index; i < end_index; ++i) { if (a.data[i] == typeid_conversions::tuple_begin_tag) { const std::size_t this_tuple_size = a.count_from_opening_till_matching_parenthis_seq(i, typeid_conversions::tuple_begin_tag, typeid_conversions::tuple_end_tag) - 1; skips += this_tuple_size; i += this_tuple_size - 1; } } return skips; } template <class T, std::size_t First, std::size_t... I> constexpr auto as_flat_tuple_impl(std::index_sequence<First, I...>) noexcept { constexpr auto a = detail::flat_array_of_type_ids<T>(); constexpr std::size_t count_of_I = sizeof...(I); return detail::as_flat_tuple_impl_drop_helpers<T>( std::index_sequence<First, I...>{}, detail::make_index_sequence< 1 + count_of_I - count_skips_in_array(First, First + count_of_I, a) >{} ); } template <class T> constexpr auto internal_tuple_with_same_alignment() noexcept { typedef typename std::remove_cv<T>::type type; static_assert( std::is_trivial<type>::value && std::is_standard_layout<type>::value, "====================> Boost.PFR: Type can not be reflected without Loophole or C++17, because it's not POD" ); static_assert(!std::is_reference<type>::value, "====================> Boost.PFR: Not applyable"); constexpr auto res = detail::as_flat_tuple_impl<type>( detail::make_index_sequence< decltype(detail::flat_array_of_type_ids<type>())::size() >() ); return res; } template <class T> using internal_tuple_with_same_alignment_t = decltype( detail::internal_tuple_with_same_alignment<T>() ); ///////////////////// Flattening struct ubiq_is_flat_refelectable { bool& is_flat_refelectable; template <class Type> constexpr operator Type() const noexcept { is_flat_refelectable = std::is_fundamental<std::remove_pointer_t<Type>>::value; return {}; } }; template <class T, std::size_t... I> constexpr bool is_flat_refelectable(std::index_sequence<I...>) noexcept { constexpr std::size_t fields = sizeof...(I); bool result[fields] = {static_cast<bool>(I)...}; const T v{ ubiq_is_flat_refelectable{result[I]}... }; (void)v; for (std::size_t i = 0; i < fields; ++i) { if (!result[i]) { return false; } } return true; } template<class T> constexpr bool is_flat_refelectable(std::index_sequence<>) noexcept { return true; ///< all empty structs always flat refelectable } template <class T> auto tie_as_flat_tuple(T& lvalue) noexcept { static_assert( !std::is_union<T>::value, "====================> Boost.PFR: For safety reasons it is forbidden to reflect unions. See `Reflection of unions` section in the docs for more info." ); using type = std::remove_cv_t<T>; using tuple_type = internal_tuple_with_same_alignment_t<type>; offset_based_getter<type, tuple_type> getter; return boost::pfr::detail::make_flat_tuple_of_references(lvalue, getter, size_t_<0>{}, size_t_<tuple_type::size_v>{}); } template <class T> auto tie_as_tuple(T& val) noexcept { static_assert( !std::is_union<T>::value, "====================> Boost.PFR: For safety reasons it is forbidden to reflect unions. See `Reflection of unions` section in the docs for more info." ); static_assert( boost::pfr::detail::is_flat_refelectable<T>( detail::make_index_sequence<boost::pfr::detail::fields_count<T>()>{} ), "====================> Boost.PFR: Not possible in C++14 to represent that type without loosing information. Change type definition or enable C++17" ); return boost::pfr::detail::tie_as_flat_tuple(val); } ///////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////// ///////////////////// Structure that can be converted to copy of anything struct ubiq_constructor_constexpr_copy { std::size_t ignore; template <class Type> constexpr operator Type() const noexcept { static_assert( std::is_trivially_destructible<Type>::value, "====================> Boost.PFR: One of the fields in the type passed to `for_each_field` has non trivial destructor." ); return {}; } }; ///////////////////// template <class T, std::size_t... I> struct is_constexpr_aggregate_initializable { template<class T2, std::size_t... I2> static constexpr void* constexpr_aggregate_initializer() noexcept { T2 tmp{ ubiq_constructor_constexpr_copy{I2}... }; (void)tmp; return nullptr; } template <void* = constexpr_aggregate_initializer<T, I...>() > static std::true_type test(long) noexcept; static std::false_type test(...) noexcept; static constexpr bool value = decltype(test(0)){}; }; template <class T, class F, std::size_t I0, std::size_t... I, class... Fields> void for_each_field_in_depth(T& t, F&& f, std::index_sequence<I0, I...>, identity<Fields>...); template <class T, class F, class... Fields> void for_each_field_in_depth(T& t, F&& f, std::index_sequence<>, identity<Fields>...); template <class T, class F, class IndexSeq, class... Fields> struct next_step { T& t; F& f; template <class Field> operator Field() const { boost::pfr::detail::for_each_field_in_depth( t, std::forward<F>(f), IndexSeq{}, identity<Fields>{}..., identity<Field>{} ); return {}; } }; template <class T, class F, std::size_t I0, std::size_t... I, class... Fields> void for_each_field_in_depth(T& t, F&& f, std::index_sequence<I0, I...>, identity<Fields>...) { (void)std::add_const_t<std::remove_reference_t<T>>{ Fields{}..., next_step<T, F, std::index_sequence<I...>, Fields...>{t, f}, ubiq_constructor_constexpr_copy{I}... }; } template <class T, class F, class... Fields> void for_each_field_in_depth(T& lvalue, F&& f, std::index_sequence<>, identity<Fields>...) { using tuple_type = sequence_tuple::tuple<Fields...>; offset_based_getter<std::remove_cv_t<std::remove_reference_t<T>>, tuple_type> getter; std::forward<F>(f)( boost::pfr::detail::make_flat_tuple_of_references(lvalue, getter, size_t_<0>{}, size_t_<sizeof...(Fields)>{}) ); } template <class T, class F, std::size_t... I> void for_each_field_dispatcher_1(T& t, F&& f, std::index_sequence<I...>, std::true_type /*is_flat_refelectable*/) { std::forward<F>(f)( boost::pfr::detail::tie_as_flat_tuple(t) ); } template <class T, class F, std::size_t... I> void for_each_field_dispatcher_1(T& t, F&& f, std::index_sequence<I...>, std::false_type /*is_flat_refelectable*/) { boost::pfr::detail::for_each_field_in_depth( t, std::forward<F>(f), std::index_sequence<I...>{} ); } template <class T, class F, std::size_t... I> void for_each_field_dispatcher(T& t, F&& f, std::index_sequence<I...>) { static_assert( !std::is_union<T>::value, "====================> Boost.PFR: For safety reasons it is forbidden to reflect unions. See `Reflection of unions` section in the docs for more info." ); static_assert(is_constexpr_aggregate_initializable<T, I...>::value, "====================> Boost.PFR: T must be a constexpr initializable type"); constexpr bool is_flat_refelectable_val = detail::is_flat_refelectable<T>( std::index_sequence<I...>{} ); detail::for_each_field_dispatcher_1( t, std::forward<F>(f), std::index_sequence<I...>{}, std::integral_constant<bool, is_flat_refelectable_val>{} ); } ///////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////// #ifdef __clang__ # pragma clang diagnostic pop #endif }}} // namespace boost::pfr::detail #endif // BOOST_PFR_DETAIL_CORE14_CLASSIC_HPP