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#pragma once
#include "name-of.hpp"
#include "accessor.hpp"
#include "util.hpp"
#include <cstddef>
#include <concepts>
#include <type_traits>
#include <utility>
#include <tuple>
#include <array>
#include <compat/function2.hpp>
#include <Corrade/Containers/StringView.h>
namespace floormat::entities {
template<typename F, typename T, typename FieldType>
concept FieldReader_memfn = requires(const T x, F f) {
{ (x.*f)() } -> std::convertible_to<FieldType>;
};
template<typename F, typename T, typename FieldType>
concept FieldReader_ptr = requires(const T x, F f) {
{ x.*f } -> std::convertible_to<FieldType>;
};
template<typename F, typename T, typename FieldType>
concept FieldReader_function = requires(const T x, F f) {
{ f(x) } -> std::convertible_to<FieldType>;
};
template<typename F, typename T, typename FieldType>
concept FieldReader = requires {
requires FieldReader_memfn<F, T, FieldType> ||
FieldReader_ptr<F, T, FieldType> ||
FieldReader_function<F, T, FieldType>;
};
template<typename F, typename T, typename FieldType>
concept FieldWriter_memfn = requires(T x, move_qualified<FieldType> value, F f) {
{ (x.*f)(value) } -> std::same_as<void>;
};
template<typename F, typename T, typename FieldType>
concept FieldWriter_ptr = requires(T x, move_qualified<FieldType> value, F f) {
{ x.*f = value };
};
template<typename F, typename T, typename FieldType>
concept FieldWriter_function = requires(T x, move_qualified<FieldType> value, F f) {
{ f(x, value) } -> std::same_as<void>;
};
template<typename F, typename T, typename FieldType>
concept FieldWriter = requires {
requires FieldWriter_memfn<F, T, FieldType> ||
FieldWriter_ptr<F, T, FieldType> ||
FieldWriter_function<F, T, FieldType> ||
std::same_as<F, std::nullptr_t>;
};
namespace detail {
template<typename Obj, typename Type, FieldReader<Obj, Type> R>
struct read_field {
static constexpr Type read(const Obj& x, R r) { return r(x); }
};
template<typename Obj, typename Type>
struct read_field<Obj, Type, Type (Obj::*)() const> {
static constexpr Type read(const Obj& x, Type (Obj::*r)() const) { return (x.*r)(); }
};
template<typename Obj, typename Type>
struct read_field<Obj, Type, Type Obj::*> {
static constexpr Type read(const Obj& x, Type Obj::*r) { return x.*r; }
};
template<typename Obj, typename Type, bool Owning, bool Copyable, typename Capacity, bool Throwing, bool ExcGuarantee>
struct read_field<Obj, Type, fu2::function_base<Owning, Copyable, Capacity, Throwing, ExcGuarantee, void(const Obj&, move_qualified<Type>) const>>
{
template<typename F> static constexpr Type read(const Obj& x, F&& fun) { return fun(x); }
};
template<typename Obj, typename FieldType, FieldWriter<Obj, FieldType> W> struct write_field {
static constexpr void write(Obj& x, W w, move_qualified<FieldType> value) { w(x, value); }
};
template<typename Obj, typename FieldType>
struct write_field<Obj, FieldType, void(Obj::*)(move_qualified<FieldType>)> {
static constexpr void write(Obj& x, void(Obj::*w)(move_qualified<FieldType>), move_qualified<FieldType> value) { (x.*w)(value); }
};
template<typename Obj, typename FieldType>
struct write_field<Obj, FieldType, FieldType Obj::*> {
static constexpr void write(Obj& x, FieldType Obj::* w, move_qualified<FieldType> value) { x.*w = value; }
};
template<typename Obj, typename Type, bool Owning, bool Copyable, typename Capacity, bool Throwing, bool ExcGuarantee>
struct write_field<Obj, Type, fu2::function_base<Owning, Copyable, Capacity, Throwing, ExcGuarantee, void(Obj&, move_qualified<Type>) const>> {
template<typename F> static constexpr void write(Obj& x, F&& fun, move_qualified<Type> value) { fun(x, value); }
};
template<typename Obj, typename FieldType>
struct write_field<Obj, FieldType, std::nullptr_t> {
static constexpr void write(Obj&, std::nullptr_t, move_qualified<FieldType>) { fm_abort("no writing for this accessor"); }
};
template<typename F, typename Tuple, std::size_t N>
requires std::invocable<F, decltype(std::get<N>(std::declval<Tuple>()))>
constexpr CORRADE_ALWAYS_INLINE void visit_tuple(F&& fun, Tuple&& tuple)
{
using Size = std::tuple_size<std::remove_cvref_t<Tuple>>;
static_assert(N < Size());
fun(std::get<N>(tuple));
if constexpr(N+1 < Size())
visit_tuple<F, Tuple, N+1>(std::forward<F>(fun), std::forward<Tuple>(tuple));
}
template<typename F, typename Tuple, std::size_t N>
requires std::is_invocable_r_v<bool, F, decltype(std::get<N>(std::declval<Tuple>()))>
constexpr CORRADE_ALWAYS_INLINE bool find_in_tuple(F&& fun, Tuple&& tuple)
{
using Size = std::tuple_size<std::remove_cvref_t<Tuple>>;
static_assert(N < Size());
if (fun(std::get<N>(tuple)))
return true;
if constexpr(N+1 < Size())
return find_in_tuple<F, Tuple, N+1>(std::forward<F>(fun), std::forward<Tuple>(tuple));
return false;
}
template<typename T> struct decay_tuple_;
template<typename... Ts> struct decay_tuple_<std::tuple<Ts...>> { using type = std::tuple<std::decay_t<Ts>...>; };
template<typename T> using decay_tuple = typename decay_tuple_<T>::type;
template<typename T> struct accessors_for_ { using type = decay_tuple<std::decay_t<decltype(T::accessors())>>; };
template<typename T> using accessors_for = typename accessors_for_<T>::type;
} // namespace detail
template<typename Obj, typename Type> struct entity_field_base {};
template<typename Obj, typename Type, FieldReader<Obj, Type> R, FieldWriter<Obj, Type> W>
struct entity_field : entity_field_base<Obj, Type> {
using ObjectType = Obj;
using FieldType = Type;
using Reader = R;
using Writer = W;
StringView name;
[[no_unique_address]] R reader;
[[no_unique_address]] W writer;
constexpr entity_field(const entity_field&) = default;
constexpr entity_field& operator=(const entity_field&) = default;
static constexpr decltype(auto) read(const R& reader, const Obj& x) { return detail::read_field<Obj, Type, R>::read(x, reader); }
static constexpr void write(const W& writer, Obj& x, move_qualified<Type> v);
constexpr decltype(auto) read(const Obj& x) const { return read(reader, x); }
constexpr void write(Obj& x, move_qualified<Type> value) const { write(writer, x, value); }
static constexpr bool can_write = !std::is_same_v<std::nullptr_t, decltype(entity_field<Obj, Type, R, W>::writer)>;
constexpr entity_field(StringView name, R r, W w) noexcept : name{name}, reader{r}, writer{w} {}
constexpr erased_accessor erased() const;
};
template<typename Obj, typename Type, FieldReader<Obj, Type> R, FieldWriter<Obj, Type> W>
constexpr void entity_field<Obj, Type, R, W>::write(const W& writer, Obj& x, move_qualified<Type> v)
{
static_assert(can_write); detail::write_field<Obj, Type, W>::write(x, writer, v);
}
template<typename Obj, typename Type, FieldReader<Obj, Type> R, FieldWriter<Obj, Type> W>
constexpr erased_accessor entity_field<Obj, Type, R, W>::erased() const
{
using reader_t = typename erased_accessor::erased_reader_t;
using writer_t = typename erased_accessor::erased_writer_t;
constexpr auto obj_name = name_of<Obj>, field_name = name_of<Type>;
constexpr auto reader_fn = [](const void* obj, const reader_t* reader, void* value) {
const auto& obj_ = *reinterpret_cast<const Obj*>(obj);
const auto& reader_ = *reinterpret_cast<const R*>(reader);
auto& value_ = *reinterpret_cast<Type*>(value);
value_ = read(reader_, obj_);
};
constexpr auto writer_fn = [](void* obj, const writer_t* writer, void* value) {
auto& obj_ = *reinterpret_cast<Obj*>(obj);
const auto& writer_ = *reinterpret_cast<const W*>(writer);
move_qualified<Type> value_ = std::move(*reinterpret_cast<Type*>(value));
write(writer_, obj_, value_);
};
constexpr auto writer_stub_fn = [](void*, const writer_t*, void*) {
fm_abort("no writer for this accessor");
};
return erased_accessor {
(void*)&reader, writer ? (void*)&writer : nullptr,
name,
obj_name, field_name,
reader_fn, writer ? writer_fn : writer_stub_fn,
};
}
template<typename Obj>
struct Entity final {
static_assert(std::is_same_v<Obj, std::decay_t<Obj>>);
template<typename Type>
struct type final
{
template<FieldReader<Obj, Type> R, FieldWriter<Obj, Type> W>
struct field final : entity_field<Obj, Type, R, W>
{
constexpr field(StringView field_name, R r, W w) noexcept :
entity_field<Obj, Type, R, W>{field_name, r, w}
{}
};
template<FieldReader<Obj, Type> R, FieldWriter<Obj, Type> W>
field(StringView name, R r, W w) -> field<R, W>;
};
};
template<typename F, typename Tuple>
constexpr void visit_tuple(F&& fun, Tuple&& tuple)
{
using Size = std::tuple_size<std::decay_t<Tuple>>;
if constexpr(Size() > 0)
detail::visit_tuple<F, Tuple, 0>(std::forward<F>(fun), std::forward<Tuple>(tuple));
}
template<typename F, typename Tuple>
constexpr bool find_in_tuple(F&& fun, Tuple&& tuple)
{
using Size = std::tuple_size<std::decay_t<Tuple>>;
if constexpr(Size() > 0)
return detail::find_in_tuple<F, Tuple, 0>(std::forward<F>(fun), std::forward<Tuple>(tuple));
else
return false;
}
} // namespace floormat::entities
namespace floormat {
template<typename T>
requires std::is_same_v<T, std::decay_t<T>>
class entity_metadata final {
template<typename... Ts>
static consteval auto erased_helper(const std::tuple<Ts...>& tuple)
{
std::array<entities::erased_accessor, sizeof...(Ts)> array { std::get<Ts>(tuple).erased()..., };
return array;
}
public:
static constexpr StringView class_name = name_of<T>;
static constexpr std::size_t size = std::tuple_size_v<entities::detail::accessors_for<T>>;
static constexpr entities::detail::accessors_for<T> accessors = T::accessors();
static constexpr auto erased_accessors = erased_helper(accessors);
};
} // namespace floormat
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