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GiantsTools/Sdk/External/entt/entt.hpp

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Update to new SDK.
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// #include "core/algorithm.hpp"
#ifndef ENTT_CORE_ALGORITHM_HPP
#define ENTT_CORE_ALGORITHM_HPP
#include <vector>
#include <utility>
#include <iterator>
#include <algorithm>
#include <functional>
// #include "utility.hpp"
#ifndef ENTT_CORE_UTILITY_HPP
#define ENTT_CORE_UTILITY_HPP
#include <utility>
// #include "../config/config.h"
#ifndef ENTT_CONFIG_CONFIG_H
#define ENTT_CONFIG_CONFIG_H
#ifndef ENTT_NOEXCEPT
# define ENTT_NOEXCEPT noexcept
#endif
#ifndef ENTT_HS_SUFFIX
# define ENTT_HS_SUFFIX _hs
#endif
#ifndef ENTT_HWS_SUFFIX
# define ENTT_HWS_SUFFIX _hws
#endif
#ifndef ENTT_USE_ATOMIC
# define ENTT_MAYBE_ATOMIC(Type) Type
#else
# include <atomic>
# define ENTT_MAYBE_ATOMIC(Type) std::atomic<Type>
#endif
#ifndef ENTT_ID_TYPE
# include <cstdint>
# define ENTT_ID_TYPE std::uint32_t
#endif
#ifndef ENTT_PAGE_SIZE
# define ENTT_PAGE_SIZE 32768
#endif
#ifndef ENTT_ASSERT
# include <cassert>
# define ENTT_ASSERT(condition) assert(condition)
#endif
#ifndef ENTT_NO_ETO
# include <type_traits>
# define ENTT_IS_EMPTY(Type) std::is_empty<Type>
#else
# include <type_traits>
# define ENTT_IS_EMPTY(Type) std::false_type
#endif
#ifndef ENTT_STANDARD_CPP
# if defined __clang__ || (defined __GNUC__ && __GNUC__ > 8)
# define ENTT_PRETTY_FUNCTION_CONSTEXPR
# define ENTT_PRETTY_FUNCTION __PRETTY_FUNCTION__
# define ENTT_PRETTY_FUNCTION_PREFIX '='
# define ENTT_PRETTY_FUNCTION_SUFFIX ']'
# elif defined __GNUC__
# define ENTT_PRETTY_FUNCTION __PRETTY_FUNCTION__
# define ENTT_PRETTY_FUNCTION_PREFIX '='
# define ENTT_PRETTY_FUNCTION_SUFFIX ']'
# elif defined _MSC_VER
# define ENTT_PRETTY_FUNCTION_CONSTEXPR
# define ENTT_PRETTY_FUNCTION __FUNCSIG__
# define ENTT_PRETTY_FUNCTION_PREFIX '<'
# define ENTT_PRETTY_FUNCTION_SUFFIX '>'
# endif
#endif
#ifndef ENTT_STANDALONE
# define ENTT_FAST_PATH(...) false
#else
# define ENTT_FAST_PATH(Cond) Cond
#endif
#endif
namespace entt {
/*! @brief Identity function object (waiting for C++20). */
struct identity {
/**
* @brief Returns its argument unchanged.
* @tparam Type Type of the argument.
* @param value The actual argument.
* @return The submitted value as-is.
*/
template<class Type>
[[nodiscard]] constexpr Type && operator()(Type &&value) const ENTT_NOEXCEPT {
return std::forward<Type>(value);
}
};
/**
* @brief Constant utility to disambiguate overloaded members of a class.
* @tparam Type Type of the desired overload.
* @tparam Class Type of class to which the member belongs.
* @param member A valid pointer to a member.
* @return Pointer to the member.
*/
template<typename Type, typename Class>
[[nodiscard]] constexpr auto overload(Type Class:: *member) ENTT_NOEXCEPT { return member; }
/**
* @brief Constant utility to disambiguate overloaded functions.
* @tparam Func Function type of the desired overload.
* @param func A valid pointer to a function.
* @return Pointer to the function.
*/
template<typename Func>
[[nodiscard]] constexpr auto overload(Func *func) ENTT_NOEXCEPT { return func; }
/**
* @brief Helper type for visitors.
* @tparam Func Types of function objects.
*/
template<class... Func>
struct overloaded: Func... {
using Func::operator()...;
};
/**
* @brief Deduction guide.
* @tparam Func Types of function objects.
*/
template<class... Func>
overloaded(Func...) -> overloaded<Func...>;
/**
* @brief Basic implementation of a y-combinator.
* @tparam Func Type of a potentially recursive function.
*/
template<class Func>
struct y_combinator {
/**
* @brief Constructs a y-combinator from a given function.
* @param recursive A potentially recursive function.
*/
y_combinator(Func recursive):
func{std::move(recursive)}
{}
/**
* @brief Invokes a y-combinator and therefore its underlying function.
* @tparam Args Types of arguments to use to invoke the underlying function.
* @param args Parameters to use to invoke the underlying function.
* @return Return value of the underlying function, if any.
*/
template <class... Args>
decltype(auto) operator()(Args &&... args) const {
return func(*this, std::forward<Args>(args)...);
}
/*! @copydoc operator()() */
template <class... Args>
decltype(auto) operator()(Args &&... args) {
return func(*this, std::forward<Args>(args)...);
}
private:
Func func;
};
}
#endif
namespace entt {
/**
* @brief Function object to wrap `std::sort` in a class type.
*
* Unfortunately, `std::sort` cannot be passed as template argument to a class
* template or a function template.<br/>
* This class fills the gap by wrapping some flavors of `std::sort` in a
* function object.
*/
struct std_sort {
/**
* @brief Sorts the elements in a range.
*
* Sorts the elements in a range using the given binary comparison function.
*
* @tparam It Type of random access iterator.
* @tparam Compare Type of comparison function object.
* @tparam Args Types of arguments to forward to the sort function.
* @param first An iterator to the first element of the range to sort.
* @param last An iterator past the last element of the range to sort.
* @param compare A valid comparison function object.
* @param args Arguments to forward to the sort function, if any.
*/
template<typename It, typename Compare = std::less<>, typename... Args>
void operator()(It first, It last, Compare compare = Compare{}, Args &&... args) const {
std::sort(std::forward<Args>(args)..., std::move(first), std::move(last), std::move(compare));
}
};
/*! @brief Function object for performing insertion sort. */
struct insertion_sort {
/**
* @brief Sorts the elements in a range.
*
* Sorts the elements in a range using the given binary comparison function.
*
* @tparam It Type of random access iterator.
* @tparam Compare Type of comparison function object.
* @param first An iterator to the first element of the range to sort.
* @param last An iterator past the last element of the range to sort.
* @param compare A valid comparison function object.
*/
template<typename It, typename Compare = std::less<>>
void operator()(It first, It last, Compare compare = Compare{}) const {
if(first < last) {
for(auto it = first+1; it < last; ++it) {
auto value = std::move(*it);
auto pre = it;
for(; pre > first && compare(value, *(pre-1)); --pre) {
*pre = std::move(*(pre-1));
}
*pre = std::move(value);
}
}
}
};
/**
* @brief Function object for performing LSD radix sort.
* @tparam Bit Number of bits processed per pass.
* @tparam N Maximum number of bits to sort.
*/
template<std::size_t Bit, std::size_t N>
struct radix_sort {
static_assert((N % Bit) == 0, "The maximum number of bits to sort must be a multiple of the number of bits processed per pass");
/**
* @brief Sorts the elements in a range.
*
* Sorts the elements in a range using the given _getter_ to access the
* actual data to be sorted.
*
* This implementation is inspired by the online book
* [Physically Based Rendering](http://www.pbr-book.org/3ed-2018/Primitives_and_Intersection_Acceleration/Bounding_Volume_Hierarchies.html#RadixSort).
*
* @tparam It Type of random access iterator.
* @tparam Getter Type of _getter_ function object.
* @param first An iterator to the first element of the range to sort.
* @param last An iterator past the last element of the range to sort.
* @param getter A valid _getter_ function object.
*/
template<typename It, typename Getter = identity>
void operator()(It first, It last, Getter getter = Getter{}) const {
if(first < last) {
static constexpr auto mask = (1 << Bit) - 1;
static constexpr auto buckets = 1 << Bit;
static constexpr auto passes = N / Bit;
using value_type = typename std::iterator_traits<It>::value_type;
std::vector<value_type> aux(std::distance(first, last));
auto part = [getter = std::move(getter)](auto from, auto to, auto out, auto start) {
std::size_t index[buckets]{};
std::size_t count[buckets]{};
std::for_each(from, to, [&getter, &count, start](const value_type &item) {
++count[(getter(item) >> start) & mask];
});
std::for_each(std::next(std::begin(index)), std::end(index), [index = std::begin(index), count = std::begin(count)](auto &item) mutable {
item = *(index++) + *(count++);
});
std::for_each(from, to, [&getter, &out, &index, start](value_type &item) {
out[index[(getter(item) >> start) & mask]++] = std::move(item);
});
};
for(std::size_t pass = 0; pass < (passes & ~1); pass += 2) {
part(first, last, aux.begin(), pass * Bit);
part(aux.begin(), aux.end(), first, (pass + 1) * Bit);
}
if constexpr(passes & 1) {
part(first, last, aux.begin(), (passes - 1) * Bit);
std::move(aux.begin(), aux.end(), first);
}
}
}
};
}
#endif
// #include "core/attribute.h"
#ifndef ENTT_CORE_ATTRIBUTE_H
#define ENTT_CORE_ATTRIBUTE_H
#ifndef ENTT_EXPORT
# if defined _WIN32 || defined __CYGWIN__ || defined _MSC_VER
# define ENTT_EXPORT __declspec(dllexport)
# define ENTT_IMPORT __declspec(dllimport)
# define ENTT_HIDDEN
# elif defined __GNUC__ && __GNUC__ >= 4
# define ENTT_EXPORT __attribute__((visibility("default")))
# define ENTT_IMPORT __attribute__((visibility("default")))
# define ENTT_HIDDEN __attribute__((visibility("hidden")))
# else /* Unsupported compiler */
# define ENTT_EXPORT
# define ENTT_IMPORT
# define ENTT_HIDDEN
# endif
#endif
#ifndef ENTT_API
# if defined ENTT_API_EXPORT
# define ENTT_API ENTT_EXPORT
# elif defined ENTT_API_IMPORT
# define ENTT_API ENTT_IMPORT
# else /* No API */
# define ENTT_API
# endif
#endif
#endif
// #include "core/family.hpp"
#ifndef ENTT_CORE_FAMILY_HPP
#define ENTT_CORE_FAMILY_HPP
// #include "../config/config.h"
// #include "fwd.hpp"
#ifndef ENTT_CORE_FWD_HPP
#define ENTT_CORE_FWD_HPP
// #include "../config/config.h"
namespace entt {
/*! @brief Alias declaration for type identifiers. */
using id_type = ENTT_ID_TYPE;
}
#endif
namespace entt {
/**
* @brief Dynamic identifier generator.
*
* Utility class template that can be used to assign unique identifiers to types
* at runtime. Use different specializations to create separate sets of
* identifiers.
*/
template<typename...>
class family {
inline static ENTT_MAYBE_ATOMIC(id_type) identifier{};
public:
/*! @brief Unsigned integer type. */
using family_type = id_type;
/*! @brief Statically generated unique identifier for the given type. */
template<typename... Type>
// at the time I'm writing, clang crashes during compilation if auto is used instead of family_type
inline static const family_type type = identifier++;
};
}
#endif
// #include "core/hashed_string.hpp"
#ifndef ENTT_CORE_HASHED_STRING_HPP
#define ENTT_CORE_HASHED_STRING_HPP
#include <cstddef>
#include <cstdint>
// #include "../config/config.h"
// #include "fwd.hpp"
namespace entt {
/**
* @cond TURN_OFF_DOXYGEN
* Internal details not to be documented.
*/
namespace internal {
template<typename>
struct fnv1a_traits;
template<>
struct fnv1a_traits<std::uint32_t> {
using type = std::uint32_t;
static constexpr std::uint32_t offset = 2166136261;
static constexpr std::uint32_t prime = 16777619;
};
template<>
struct fnv1a_traits<std::uint64_t> {
using type = std::uint64_t;
static constexpr std::uint64_t offset = 14695981039346656037ull;
static constexpr std::uint64_t prime = 1099511628211ull;
};
}
/**
* Internal details not to be documented.
* @endcond
*/
/**
* @brief Zero overhead unique identifier.
*
* A hashed string is a compile-time tool that allows users to use
* human-readable identifers in the codebase while using their numeric
* counterparts at runtime.<br/>
* Because of that, a hashed string can also be used in constant expressions if
* required.
*
* @tparam Char Character type.
*/
template<typename Char>
class basic_hashed_string {
using traits_type = internal::fnv1a_traits<id_type>;
struct const_wrapper {
// non-explicit constructor on purpose
constexpr const_wrapper(const Char *curr) ENTT_NOEXCEPT: str{curr} {}
const Char *str;
};
// FowlerNollVo hash function v. 1a - the good
[[nodiscard]] static constexpr id_type helper(const Char *curr) ENTT_NOEXCEPT {
auto value = traits_type::offset;
while(*curr != 0) {
value = (value ^ static_cast<traits_type::type>(*(curr++))) * traits_type::prime;
}
return value;
}
public:
/*! @brief Character type. */
using value_type = Char;
/*! @brief Unsigned integer type. */
using hash_type = id_type;
/**
* @brief Returns directly the numeric representation of a string.
*
* Forcing template resolution avoids implicit conversions. An
* human-readable identifier can be anything but a plain, old bunch of
* characters.<br/>
* Example of use:
* @code{.cpp}
* const auto value = basic_hashed_string<char>::to_value("my.png");
* @endcode
*
* @tparam N Number of characters of the identifier.
* @param str Human-readable identifer.
* @return The numeric representation of the string.
*/
template<std::size_t N>
[[nodiscard]] static constexpr hash_type value(const value_type (&str)[N]) ENTT_NOEXCEPT {
return helper(str);
}
/**
* @brief Returns directly the numeric representation of a string.
* @param wrapper Helps achieving the purpose by relying on overloading.
* @return The numeric representation of the string.
*/
[[nodiscard]] static hash_type value(const_wrapper wrapper) ENTT_NOEXCEPT {
return helper(wrapper.str);
}
/**
* @brief Returns directly the numeric representation of a string view.
* @param str Human-readable identifer.
* @param size Length of the string to hash.
* @return The numeric representation of the string.
*/
[[nodiscard]] static hash_type value(const value_type *str, std::size_t size) ENTT_NOEXCEPT {
id_type partial{traits_type::offset};
while(size--) { partial = (partial^(str++)[0])*traits_type::prime; }
return partial;
}
/*! @brief Constructs an empty hashed string. */
constexpr basic_hashed_string() ENTT_NOEXCEPT
: str{nullptr}, hash{}
{}
/**
* @brief Constructs a hashed string from an array of const characters.
*
* Forcing template resolution avoids implicit conversions. An
* human-readable identifier can be anything but a plain, old bunch of
* characters.<br/>
* Example of use:
* @code{.cpp}
* basic_hashed_string<char> hs{"my.png"};
* @endcode
*
* @tparam N Number of characters of the identifier.
* @param curr Human-readable identifer.
*/
template<std::size_t N>
constexpr basic_hashed_string(const value_type (&curr)[N]) ENTT_NOEXCEPT
: str{curr}, hash{helper(curr)}
{}
/**
* @brief Explicit constructor on purpose to avoid constructing a hashed
* string directly from a `const value_type *`.
* @param wrapper Helps achieving the purpose by relying on overloading.
*/
explicit constexpr basic_hashed_string(const_wrapper wrapper) ENTT_NOEXCEPT
: str{wrapper.str}, hash{helper(wrapper.str)}
{}
/**
* @brief Returns the human-readable representation of a hashed string.
* @return The string used to initialize the instance.
*/
[[nodiscard]] constexpr const value_type * data() const ENTT_NOEXCEPT {
return str;
}
/**
* @brief Returns the numeric representation of a hashed string.
* @return The numeric representation of the instance.
*/
[[nodiscard]] constexpr hash_type value() const ENTT_NOEXCEPT {
return hash;
}
/*! @copydoc data */
[[nodiscard]] constexpr operator const value_type *() const ENTT_NOEXCEPT { return data(); }
/**
* @brief Returns the numeric representation of a hashed string.
* @return The numeric representation of the instance.
*/
[[nodiscard]] constexpr operator hash_type() const ENTT_NOEXCEPT { return value(); }
/**
* @brief Compares two hashed strings.
* @param other Hashed string with which to compare.
* @return True if the two hashed strings are identical, false otherwise.
*/
[[nodiscard]] constexpr bool operator==(const basic_hashed_string &other) const ENTT_NOEXCEPT {
return hash == other.hash;
}
private:
const value_type *str;
hash_type hash;
};
/**
* @brief Deduction guide.
*
* It allows to deduce the character type of the hashed string directly from a
* human-readable identifer provided to the constructor.
*
* @tparam Char Character type.
* @tparam N Number of characters of the identifier.
* @param str Human-readable identifer.
*/
template<typename Char, std::size_t N>
basic_hashed_string(const Char (&str)[N]) ENTT_NOEXCEPT
-> basic_hashed_string<Char>;
/**
* @brief Compares two hashed strings.
* @tparam Char Character type.
* @param lhs A valid hashed string.
* @param rhs A valid hashed string.
* @return True if the two hashed strings are identical, false otherwise.
*/
template<typename Char>
[[nodiscard]] constexpr bool operator!=(const basic_hashed_string<Char> &lhs, const basic_hashed_string<Char> &rhs) ENTT_NOEXCEPT {
return !(lhs == rhs);
}
/*! @brief Aliases for common character types. */
using hashed_string = basic_hashed_string<char>;
/*! @brief Aliases for common character types. */
using hashed_wstring = basic_hashed_string<wchar_t>;
}
/**
* @brief User defined literal for hashed strings.
* @param str The literal without its suffix.
* @return A properly initialized hashed string.
*/
[[nodiscard]] constexpr entt::hashed_string operator"" ENTT_HS_SUFFIX(const char *str, std::size_t) ENTT_NOEXCEPT {
return entt::hashed_string{str};
}
/**
* @brief User defined literal for hashed wstrings.
* @param str The literal without its suffix.
* @return A properly initialized hashed wstring.
*/
[[nodiscard]] constexpr entt::hashed_wstring operator"" ENTT_HWS_SUFFIX(const wchar_t *str, std::size_t) ENTT_NOEXCEPT {
return entt::hashed_wstring{str};
}
#endif
// #include "core/ident.hpp"
#ifndef ENTT_CORE_IDENT_HPP
#define ENTT_CORE_IDENT_HPP
#include <tuple>
#include <cstddef>
#include <utility>
#include <type_traits>
// #include "../config/config.h"
// #include "fwd.hpp"
namespace entt {
/**
* @brief Types identifiers.
*
* Variable template used to generate identifiers at compile-time for the given
* types. Use the `get` member function to know what's the identifier associated
* to the specific type.
*
* @note
* Identifiers are constant expression and can be used in any context where such
* an expression is required. As an example:
* @code{.cpp}
* using id = entt::identifier<a_type, another_type>;
*
* switch(a_type_identifier) {
* case id::type<a_type>:
* // ...
* break;
* case id::type<another_type>:
* // ...
* break;
* default:
* // ...
* }
* @endcode
*
* @tparam Types List of types for which to generate identifiers.
*/
template<typename... Types>
class identifier {
using tuple_type = std::tuple<std::decay_t<Types>...>;
template<typename Type, std::size_t... Indexes>
[[nodiscard]] static constexpr id_type get(std::index_sequence<Indexes...>) {
static_assert(std::disjunction_v<std::is_same<Type, Types>...>, "Invalid type");
return (0 + ... + (std::is_same_v<Type, std::tuple_element_t<Indexes, tuple_type>> ? id_type(Indexes) : id_type{}));
}
public:
/*! @brief Unsigned integer type. */
using identifier_type = id_type;
/*! @brief Statically generated unique identifier for the given type. */
template<typename Type>
static constexpr identifier_type type = get<std::decay_t<Type>>(std::index_sequence_for<Types...>{});
};
}
#endif
// #include "core/monostate.hpp"
#ifndef ENTT_CORE_MONOSTATE_HPP
#define ENTT_CORE_MONOSTATE_HPP
// #include "../config/config.h"
// #include "fwd.hpp"
namespace entt {
/**
* @brief Minimal implementation of the monostate pattern.
*
* A minimal, yet complete configuration system built on top of the monostate
* pattern. Thread safe by design, it works only with basic types like `int`s or
* `bool`s.<br/>
* Multiple types and therefore more than one value can be associated with a
* single key. Because of this, users must pay attention to use the same type
* both during an assignment and when they try to read back their data.
* Otherwise, they can incur in unexpected results.
*/
template<id_type>
struct monostate {
/**
* @brief Assigns a value of a specific type to a given key.
* @tparam Type Type of the value to assign.
* @param val User data to assign to the given key.
*/
template<typename Type>
void operator=(Type val) const ENTT_NOEXCEPT {
value<Type> = val;
}
/**
* @brief Gets a value of a specific type for a given key.
* @tparam Type Type of the value to get.
* @return Stored value, if any.
*/
template<typename Type>
operator Type() const ENTT_NOEXCEPT {
return value<Type>;
}
private:
template<typename Type>
inline static ENTT_MAYBE_ATOMIC(Type) value{};
};
/**
* @brief Helper variable template.
* @tparam Value Value used to differentiate between different variables.
*/
template<id_type Value>
inline monostate<Value> monostate_v = {};
}
#endif
// #include "core/type_info.hpp"
#ifndef ENTT_CORE_TYPE_INFO_HPP
#define ENTT_CORE_TYPE_INFO_HPP
#include <string_view>
// #include "../config/config.h"
// #include "../core/attribute.h"
#ifndef ENTT_CORE_ATTRIBUTE_H
#define ENTT_CORE_ATTRIBUTE_H
#ifndef ENTT_EXPORT
# if defined _WIN32 || defined __CYGWIN__ || defined _MSC_VER
# define ENTT_EXPORT __declspec(dllexport)
# define ENTT_IMPORT __declspec(dllimport)
# define ENTT_HIDDEN
# elif defined __GNUC__ && __GNUC__ >= 4
# define ENTT_EXPORT __attribute__((visibility("default")))
# define ENTT_IMPORT __attribute__((visibility("default")))
# define ENTT_HIDDEN __attribute__((visibility("hidden")))
# else /* Unsupported compiler */
# define ENTT_EXPORT
# define ENTT_IMPORT
# define ENTT_HIDDEN
# endif
#endif
#ifndef ENTT_API
# if defined ENTT_API_EXPORT
# define ENTT_API ENTT_EXPORT
# elif defined ENTT_API_IMPORT
# define ENTT_API ENTT_IMPORT
# else /* No API */
# define ENTT_API
# endif
#endif
#endif
// #include "hashed_string.hpp"
// #include "fwd.hpp"
namespace entt {
/**
* @cond TURN_OFF_DOXYGEN
* Internal details not to be documented.
*/
namespace internal {
struct ENTT_API type_index {
[[nodiscard]] static id_type next() ENTT_NOEXCEPT {
static ENTT_MAYBE_ATOMIC(id_type) value{};
return value++;
}
};
template<typename Type>
[[nodiscard]] constexpr auto type_name() ENTT_NOEXCEPT {
#if defined ENTT_PRETTY_FUNCTION
std::string_view pretty_function{ENTT_PRETTY_FUNCTION};
auto first = pretty_function.find_first_not_of(' ', pretty_function.find_first_of(ENTT_PRETTY_FUNCTION_PREFIX)+1);
auto value = pretty_function.substr(first, pretty_function.find_last_of(ENTT_PRETTY_FUNCTION_SUFFIX) - first);
return value;
#else
return std::string_view{};
#endif
}
}
/**
* Internal details not to be documented.
* @endcond
*/
/**
* @brief Type index.
* @tparam Type Type for which to generate a sequential identifier.
*/
template<typename Type, typename = void>
struct ENTT_API type_index {
/**
* @brief Returns the sequential identifier of a given type.
* @return The sequential identifier of a given type.
*/
[[nodiscard]] static id_type value() ENTT_NOEXCEPT {
static const id_type value = internal::type_index::next();
return value;
}
};
/**
* @brief Provides the member constant `value` to true if a given type is
* indexable, false otherwise.
* @tparam Type Potentially indexable type.
*/
template<typename, typename = void>
struct has_type_index: std::false_type {};
/*! @brief has_type_index */
template<typename Type>
struct has_type_index<Type, std::void_t<decltype(type_index<Type>::value())>>: std::true_type {};
/**
* @brief Helper variable template.
* @tparam Type Potentially indexable type.
*/
template<typename Type>
inline constexpr bool has_type_index_v = has_type_index<Type>::value;
/**
* @brief Type info.
* @tparam Type Type for which to generate information.
*/
template<typename Type, typename = void>
struct type_info {
/**
* @brief Returns the numeric representation of a given type.
* @return The numeric representation of the given type.
*/
#if defined ENTT_PRETTY_FUNCTION_CONSTEXPR
[[nodiscard]] static constexpr id_type id() ENTT_NOEXCEPT {
constexpr auto value = hashed_string::value(ENTT_PRETTY_FUNCTION);
return value;
}
#elif defined ENTT_PRETTY_FUNCTION
[[nodiscard]] static id_type id() ENTT_NOEXCEPT {
static const auto value = hashed_string::value(ENTT_PRETTY_FUNCTION);
return value;
}
#else
[[nodiscard]] static id_type id() ENTT_NOEXCEPT {
return type_index<Type>::value();
}
#endif
/**
* @brief Returns the name of a given type.
* @return The name of the given type.
*/
#if defined ENTT_PRETTY_FUNCTION_CONSTEXPR
[[nodiscard]] static constexpr std::string_view name() ENTT_NOEXCEPT {
constexpr auto value = internal::type_name<Type>();
return value;
}
#elif defined ENTT_PRETTY_FUNCTION
[[nodiscard]] static std::string_view name() ENTT_NOEXCEPT {
static const auto value = internal::type_name<Type>();
return value;
}
#else
[[nodiscard]] static constexpr std::string_view name() ENTT_NOEXCEPT {
return internal::type_name<Type>();
}
#endif
};
}
#endif
// #include "core/type_traits.hpp"
#ifndef ENTT_CORE_TYPE_TRAITS_HPP
#define ENTT_CORE_TYPE_TRAITS_HPP
#include <cstddef>
#include <utility>
#include <type_traits>
// #include "../config/config.h"
// #include "fwd.hpp"
namespace entt {
/**
* @brief Using declaration to be used to _repeat_ the same type a number of
* times equal to the size of a given parameter pack.
* @tparam Type A type to repeat.
*/
template<typename Type, typename>
using unpack_as_t = Type;
/**
* @brief Helper variable template to be used to _repeat_ the same value a
* number of times equal to the size of a given parameter pack.
* @tparam Value A value to repeat.
*/
template<auto Value, typename>
inline constexpr auto unpack_as_v = Value;
/**
* @brief Wraps a static constant.
* @tparam Value A static constant.
*/
template<auto Value>
using integral_constant = std::integral_constant<decltype(Value), Value>;
/**
* @brief Alias template to ease the creation of named values.
* @tparam Value A constant value at least convertible to `id_type`.
*/
template<id_type Value>
using tag = integral_constant<Value>;
/**
* @brief Utility class to disambiguate overloaded functions.
* @tparam N Number of choices available.
*/
template<std::size_t N>
struct choice_t
// Unfortunately, doxygen cannot parse such a construct.
/*! @cond TURN_OFF_DOXYGEN */
: choice_t<N-1>
/*! @endcond */
{};
/*! @copybrief choice_t */
template<>
struct choice_t<0> {};
/**
* @brief Variable template for the choice trick.
* @tparam N Number of choices available.
*/
template<std::size_t N>
inline constexpr choice_t<N> choice{};
/*! @brief A class to use to push around lists of types, nothing more. */
template<typename...>
struct type_list {};
/*! @brief Primary template isn't defined on purpose. */
template<typename>
struct type_list_size;
/**
* @brief Compile-time number of elements in a type list.
* @tparam Type Types provided by the type list.
*/
template<typename... Type>
struct type_list_size<type_list<Type...>>
: std::integral_constant<std::size_t, sizeof...(Type)>
{};
/**
* @brief Helper variable template.
* @tparam List Type list.
*/
template<class List>
inline constexpr auto type_list_size_v = type_list_size<List>::value;
/*! @brief Primary template isn't defined on purpose. */
template<typename...>
struct type_list_cat;
/*! @brief Concatenates multiple type lists. */
template<>
struct type_list_cat<> {
/*! @brief A type list composed by the types of all the type lists. */
using type = type_list<>;
};
/**
* @brief Concatenates multiple type lists.
* @tparam Type Types provided by the first type list.
* @tparam Other Types provided by the second type list.
* @tparam List Other type lists, if any.
*/
template<typename... Type, typename... Other, typename... List>
struct type_list_cat<type_list<Type...>, type_list<Other...>, List...> {
/*! @brief A type list composed by the types of all the type lists. */
using type = typename type_list_cat<type_list<Type..., Other...>, List...>::type;
};
/**
* @brief Concatenates multiple type lists.
* @tparam Type Types provided by the type list.
*/
template<typename... Type>
struct type_list_cat<type_list<Type...>> {
/*! @brief A type list composed by the types of all the type lists. */
using type = type_list<Type...>;
};
/**
* @brief Helper type.
* @tparam List Type lists to concatenate.
*/
template<typename... List>
using type_list_cat_t = typename type_list_cat<List...>::type;
/*! @brief Primary template isn't defined on purpose. */
template<typename>
struct type_list_unique;
/**
* @brief Removes duplicates types from a type list.
* @tparam Type One of the types provided by the given type list.
* @tparam Other The other types provided by the given type list.
*/
template<typename Type, typename... Other>
struct type_list_unique<type_list<Type, Other...>> {
/*! @brief A type list without duplicate types. */
using type = std::conditional_t<
std::disjunction_v<std::is_same<Type, Other>...>,
typename type_list_unique<type_list<Other...>>::type,
type_list_cat_t<type_list<Type>, typename type_list_unique<type_list<Other...>>::type>
>;
};
/*! @brief Removes duplicates types from a type list. */
template<>
struct type_list_unique<type_list<>> {
/*! @brief A type list without duplicate types. */
using type = type_list<>;
};
/**
* @brief Helper type.
* @tparam Type A type list.
*/
template<typename Type>
using type_list_unique_t = typename type_list_unique<Type>::type;
/**
* @brief Provides the member constant `value` to true if a given type is
* equality comparable, false otherwise.
* @tparam Type Potentially equality comparable type.
*/
template<typename Type, typename = std::void_t<>>
struct is_equality_comparable: std::false_type {};
/*! @copydoc is_equality_comparable */
template<typename Type>
struct is_equality_comparable<Type, std::void_t<decltype(std::declval<Type>() == std::declval<Type>())>>
: std::true_type
{};
/**
* @brief Helper variable template.
* @tparam Type Potentially equality comparable type.
*/
template<class Type>
inline constexpr auto is_equality_comparable_v = is_equality_comparable<Type>::value;
/**
* @brief Provides the member constant `value` to true if a given type is empty
* and the empty type optimization is enabled, false otherwise.
* @tparam Type Potential empty type.
*/
template<typename Type, typename = void>
struct is_eto_eligible
: ENTT_IS_EMPTY(Type)
{};
/**
* @brief Helper variable template.
* @tparam Type Potential empty type.
*/
template<typename Type>
inline constexpr auto is_eto_eligible_v = is_eto_eligible<Type>::value;
/**
* @brief Extracts the class of a non-static member object or function.
* @tparam Member A pointer to a non-static member object or function.
*/
template<typename Member>
class member_class {
static_assert(std::is_member_pointer_v<Member>, "Invalid pointer type to non-static member object or function");
template<typename Class, typename Ret, typename... Args>
static Class * clazz(Ret(Class:: *)(Args...));
template<typename Class, typename Ret, typename... Args>
static Class * clazz(Ret(Class:: *)(Args...) const);
template<typename Class, typename Type>
static Class * clazz(Type Class:: *);
public:
/*! @brief The class of the given non-static member object or function. */
using type = std::remove_pointer_t<decltype(clazz(std::declval<Member>()))>;
};
/**
* @brief Helper type.
* @tparam Member A pointer to a non-static member object or function.
*/
template<typename Member>
using member_class_t = typename member_class<Member>::type;
}
#endif
// #include "core/utility.hpp"
// #include "entity/actor.hpp"
#ifndef ENTT_ENTITY_ACTOR_HPP
#define ENTT_ENTITY_ACTOR_HPP
#include <utility>
#include <type_traits>
// #include "../config/config.h"
#ifndef ENTT_CONFIG_CONFIG_H
#define ENTT_CONFIG_CONFIG_H
#ifndef ENTT_NOEXCEPT
# define ENTT_NOEXCEPT noexcept
#endif
#ifndef ENTT_HS_SUFFIX
# define ENTT_HS_SUFFIX _hs
#endif
#ifndef ENTT_HWS_SUFFIX
# define ENTT_HWS_SUFFIX _hws
#endif
#ifndef ENTT_USE_ATOMIC
# define ENTT_MAYBE_ATOMIC(Type) Type
#else
# include <atomic>
# define ENTT_MAYBE_ATOMIC(Type) std::atomic<Type>
#endif
#ifndef ENTT_ID_TYPE
# include <cstdint>
# define ENTT_ID_TYPE std::uint32_t
#endif
#ifndef ENTT_PAGE_SIZE
# define ENTT_PAGE_SIZE 32768
#endif
#ifndef ENTT_ASSERT
# include <cassert>
# define ENTT_ASSERT(condition) assert(condition)
#endif
#ifndef ENTT_NO_ETO
# include <type_traits>
# define ENTT_IS_EMPTY(Type) std::is_empty<Type>
#else
# include <type_traits>
# define ENTT_IS_EMPTY(Type) std::false_type
#endif
#ifndef ENTT_STANDARD_CPP
# if defined __clang__ || (defined __GNUC__ && __GNUC__ > 8)
# define ENTT_PRETTY_FUNCTION_CONSTEXPR
# define ENTT_PRETTY_FUNCTION __PRETTY_FUNCTION__
# define ENTT_PRETTY_FUNCTION_PREFIX '='
# define ENTT_PRETTY_FUNCTION_SUFFIX ']'
# elif defined __GNUC__
# define ENTT_PRETTY_FUNCTION __PRETTY_FUNCTION__
# define ENTT_PRETTY_FUNCTION_PREFIX '='
# define ENTT_PRETTY_FUNCTION_SUFFIX ']'
# elif defined _MSC_VER
# define ENTT_PRETTY_FUNCTION_CONSTEXPR
# define ENTT_PRETTY_FUNCTION __FUNCSIG__
# define ENTT_PRETTY_FUNCTION_PREFIX '<'
# define ENTT_PRETTY_FUNCTION_SUFFIX '>'
# endif
#endif
#ifndef ENTT_STANDALONE
# define ENTT_FAST_PATH(...) false
#else
# define ENTT_FAST_PATH(Cond) Cond
#endif
#endif
// #include "registry.hpp"
#ifndef ENTT_ENTITY_REGISTRY_HPP
#define ENTT_ENTITY_REGISTRY_HPP
#include <algorithm>
#include <cstddef>
#include <iterator>
#include <memory>
#include <tuple>
#include <type_traits>
#include <utility>
#include <vector>
// #include "../config/config.h"
// #include "../core/algorithm.hpp"
#ifndef ENTT_CORE_ALGORITHM_HPP
#define ENTT_CORE_ALGORITHM_HPP
#include <vector>
#include <utility>
#include <iterator>
#include <algorithm>
#include <functional>
// #include "utility.hpp"
#ifndef ENTT_CORE_UTILITY_HPP
#define ENTT_CORE_UTILITY_HPP
#include <utility>
// #include "../config/config.h"
#ifndef ENTT_CONFIG_CONFIG_H
#define ENTT_CONFIG_CONFIG_H
#ifndef ENTT_NOEXCEPT
# define ENTT_NOEXCEPT noexcept
#endif
#ifndef ENTT_HS_SUFFIX
# define ENTT_HS_SUFFIX _hs
#endif
#ifndef ENTT_HWS_SUFFIX
# define ENTT_HWS_SUFFIX _hws
#endif
#ifndef ENTT_USE_ATOMIC
# define ENTT_MAYBE_ATOMIC(Type) Type
#else
# include <atomic>
# define ENTT_MAYBE_ATOMIC(Type) std::atomic<Type>
#endif
#ifndef ENTT_ID_TYPE
# include <cstdint>
# define ENTT_ID_TYPE std::uint32_t
#endif
#ifndef ENTT_PAGE_SIZE
# define ENTT_PAGE_SIZE 32768
#endif
#ifndef ENTT_ASSERT
# include <cassert>
# define ENTT_ASSERT(condition) assert(condition)
#endif
#ifndef ENTT_NO_ETO
# include <type_traits>
# define ENTT_IS_EMPTY(Type) std::is_empty<Type>
#else
# include <type_traits>
# define ENTT_IS_EMPTY(Type) std::false_type
#endif
#ifndef ENTT_STANDARD_CPP
# if defined __clang__ || (defined __GNUC__ && __GNUC__ > 8)
# define ENTT_PRETTY_FUNCTION_CONSTEXPR
# define ENTT_PRETTY_FUNCTION __PRETTY_FUNCTION__
# define ENTT_PRETTY_FUNCTION_PREFIX '='
# define ENTT_PRETTY_FUNCTION_SUFFIX ']'
# elif defined __GNUC__
# define ENTT_PRETTY_FUNCTION __PRETTY_FUNCTION__
# define ENTT_PRETTY_FUNCTION_PREFIX '='
# define ENTT_PRETTY_FUNCTION_SUFFIX ']'
# elif defined _MSC_VER
# define ENTT_PRETTY_FUNCTION_CONSTEXPR
# define ENTT_PRETTY_FUNCTION __FUNCSIG__
# define ENTT_PRETTY_FUNCTION_PREFIX '<'
# define ENTT_PRETTY_FUNCTION_SUFFIX '>'
# endif
#endif
#ifndef ENTT_STANDALONE
# define ENTT_FAST_PATH(...) false
#else
# define ENTT_FAST_PATH(Cond) Cond
#endif
#endif
namespace entt {
/*! @brief Identity function object (waiting for C++20). */
struct identity {
/**
* @brief Returns its argument unchanged.
* @tparam Type Type of the argument.
* @param value The actual argument.
* @return The submitted value as-is.
*/
template<class Type>
[[nodiscard]] constexpr Type && operator()(Type &&value) const ENTT_NOEXCEPT {
return std::forward<Type>(value);
}
};
/**
* @brief Constant utility to disambiguate overloaded members of a class.
* @tparam Type Type of the desired overload.
* @tparam Class Type of class to which the member belongs.
* @param member A valid pointer to a member.
* @return Pointer to the member.
*/
template<typename Type, typename Class>
[[nodiscard]] constexpr auto overload(Type Class:: *member) ENTT_NOEXCEPT { return member; }
/**
* @brief Constant utility to disambiguate overloaded functions.
* @tparam Func Function type of the desired overload.
* @param func A valid pointer to a function.
* @return Pointer to the function.
*/
template<typename Func>
[[nodiscard]] constexpr auto overload(Func *func) ENTT_NOEXCEPT { return func; }
/**
* @brief Helper type for visitors.
* @tparam Func Types of function objects.
*/
template<class... Func>
struct overloaded: Func... {
using Func::operator()...;
};
/**
* @brief Deduction guide.
* @tparam Func Types of function objects.
*/
template<class... Func>
overloaded(Func...) -> overloaded<Func...>;
/**
* @brief Basic implementation of a y-combinator.
* @tparam Func Type of a potentially recursive function.
*/
template<class Func>
struct y_combinator {
/**
* @brief Constructs a y-combinator from a given function.
* @param recursive A potentially recursive function.
*/
y_combinator(Func recursive):
func{std::move(recursive)}
{}
/**
* @brief Invokes a y-combinator and therefore its underlying function.
* @tparam Args Types of arguments to use to invoke the underlying function.
* @param args Parameters to use to invoke the underlying function.
* @return Return value of the underlying function, if any.
*/
template <class... Args>
decltype(auto) operator()(Args &&... args) const {
return func(*this, std::forward<Args>(args)...);
}
/*! @copydoc operator()() */
template <class... Args>
decltype(auto) operator()(Args &&... args) {
return func(*this, std::forward<Args>(args)...);
}
private:
Func func;
};
}
#endif
namespace entt {
/**
* @brief Function object to wrap `std::sort` in a class type.
*
* Unfortunately, `std::sort` cannot be passed as template argument to a class
* template or a function template.<br/>
* This class fills the gap by wrapping some flavors of `std::sort` in a
* function object.
*/
struct std_sort {
/**
* @brief Sorts the elements in a range.
*
* Sorts the elements in a range using the given binary comparison function.
*
* @tparam It Type of random access iterator.
* @tparam Compare Type of comparison function object.
* @tparam Args Types of arguments to forward to the sort function.
* @param first An iterator to the first element of the range to sort.
* @param last An iterator past the last element of the range to sort.
* @param compare A valid comparison function object.
* @param args Arguments to forward to the sort function, if any.
*/
template<typename It, typename Compare = std::less<>, typename... Args>
void operator()(It first, It last, Compare compare = Compare{}, Args &&... args) const {
std::sort(std::forward<Args>(args)..., std::move(first), std::move(last), std::move(compare));
}
};
/*! @brief Function object for performing insertion sort. */
struct insertion_sort {
/**
* @brief Sorts the elements in a range.
*
* Sorts the elements in a range using the given binary comparison function.
*
* @tparam It Type of random access iterator.
* @tparam Compare Type of comparison function object.
* @param first An iterator to the first element of the range to sort.
* @param last An iterator past the last element of the range to sort.
* @param compare A valid comparison function object.
*/
template<typename It, typename Compare = std::less<>>
void operator()(It first, It last, Compare compare = Compare{}) const {
if(first < last) {
for(auto it = first+1; it < last; ++it) {
auto value = std::move(*it);
auto pre = it;
for(; pre > first && compare(value, *(pre-1)); --pre) {
*pre = std::move(*(pre-1));
}
*pre = std::move(value);
}
}
}
};
/**
* @brief Function object for performing LSD radix sort.
* @tparam Bit Number of bits processed per pass.
* @tparam N Maximum number of bits to sort.
*/
template<std::size_t Bit, std::size_t N>
struct radix_sort {
static_assert((N % Bit) == 0, "The maximum number of bits to sort must be a multiple of the number of bits processed per pass");
/**
* @brief Sorts the elements in a range.
*
* Sorts the elements in a range using the given _getter_ to access the
* actual data to be sorted.
*
* This implementation is inspired by the online book
* [Physically Based Rendering](http://www.pbr-book.org/3ed-2018/Primitives_and_Intersection_Acceleration/Bounding_Volume_Hierarchies.html#RadixSort).
*
* @tparam It Type of random access iterator.
* @tparam Getter Type of _getter_ function object.
* @param first An iterator to the first element of the range to sort.
* @param last An iterator past the last element of the range to sort.
* @param getter A valid _getter_ function object.
*/
template<typename It, typename Getter = identity>
void operator()(It first, It last, Getter getter = Getter{}) const {
if(first < last) {
static constexpr auto mask = (1 << Bit) - 1;
static constexpr auto buckets = 1 << Bit;
static constexpr auto passes = N / Bit;
using value_type = typename std::iterator_traits<It>::value_type;
std::vector<value_type> aux(std::distance(first, last));
auto part = [getter = std::move(getter)](auto from, auto to, auto out, auto start) {
std::size_t index[buckets]{};
std::size_t count[buckets]{};
std::for_each(from, to, [&getter, &count, start](const value_type &item) {
++count[(getter(item) >> start) & mask];
});
std::for_each(std::next(std::begin(index)), std::end(index), [index = std::begin(index), count = std::begin(count)](auto &item) mutable {
item = *(index++) + *(count++);
});
std::for_each(from, to, [&getter, &out, &index, start](value_type &item) {
out[index[(getter(item) >> start) & mask]++] = std::move(item);
});
};
for(std::size_t pass = 0; pass < (passes & ~1); pass += 2) {
part(first, last, aux.begin(), pass * Bit);
part(aux.begin(), aux.end(), first, (pass + 1) * Bit);
}
if constexpr(passes & 1) {
part(first, last, aux.begin(), (passes - 1) * Bit);
std::move(aux.begin(), aux.end(), first);
}
}
}
};
}
#endif
// #include "../core/fwd.hpp"
#ifndef ENTT_CORE_FWD_HPP
#define ENTT_CORE_FWD_HPP
// #include "../config/config.h"
namespace entt {
/*! @brief Alias declaration for type identifiers. */
using id_type = ENTT_ID_TYPE;
}
#endif
// #include "../core/type_info.hpp"
#ifndef ENTT_CORE_TYPE_INFO_HPP
#define ENTT_CORE_TYPE_INFO_HPP
#include <string_view>
// #include "../config/config.h"
// #include "../core/attribute.h"
#ifndef ENTT_CORE_ATTRIBUTE_H
#define ENTT_CORE_ATTRIBUTE_H
#ifndef ENTT_EXPORT
# if defined _WIN32 || defined __CYGWIN__ || defined _MSC_VER
# define ENTT_EXPORT __declspec(dllexport)
# define ENTT_IMPORT __declspec(dllimport)
# define ENTT_HIDDEN
# elif defined __GNUC__ && __GNUC__ >= 4
# define ENTT_EXPORT __attribute__((visibility("default")))
# define ENTT_IMPORT __attribute__((visibility("default")))
# define ENTT_HIDDEN __attribute__((visibility("hidden")))
# else /* Unsupported compiler */
# define ENTT_EXPORT
# define ENTT_IMPORT
# define ENTT_HIDDEN
# endif
#endif
#ifndef ENTT_API
# if defined ENTT_API_EXPORT
# define ENTT_API ENTT_EXPORT
# elif defined ENTT_API_IMPORT
# define ENTT_API ENTT_IMPORT
# else /* No API */
# define ENTT_API
# endif
#endif
#endif
// #include "hashed_string.hpp"
#ifndef ENTT_CORE_HASHED_STRING_HPP
#define ENTT_CORE_HASHED_STRING_HPP
#include <cstddef>
#include <cstdint>
// #include "../config/config.h"
// #include "fwd.hpp"
namespace entt {
/**
* @cond TURN_OFF_DOXYGEN
* Internal details not to be documented.
*/
namespace internal {
template<typename>
struct fnv1a_traits;
template<>
struct fnv1a_traits<std::uint32_t> {
using type = std::uint32_t;
static constexpr std::uint32_t offset = 2166136261;
static constexpr std::uint32_t prime = 16777619;
};
template<>
struct fnv1a_traits<std::uint64_t> {
using type = std::uint64_t;
static constexpr std::uint64_t offset = 14695981039346656037ull;
static constexpr std::uint64_t prime = 1099511628211ull;
};
}
/**
* Internal details not to be documented.
* @endcond
*/
/**
* @brief Zero overhead unique identifier.
*
* A hashed string is a compile-time tool that allows users to use
* human-readable identifers in the codebase while using their numeric
* counterparts at runtime.<br/>
* Because of that, a hashed string can also be used in constant expressions if
* required.
*
* @tparam Char Character type.
*/
template<typename Char>
class basic_hashed_string {
using traits_type = internal::fnv1a_traits<id_type>;
struct const_wrapper {
// non-explicit constructor on purpose
constexpr const_wrapper(const Char *curr) ENTT_NOEXCEPT: str{curr} {}
const Char *str;
};
// FowlerNollVo hash function v. 1a - the good
[[nodiscard]] static constexpr id_type helper(const Char *curr) ENTT_NOEXCEPT {
auto value = traits_type::offset;
while(*curr != 0) {
value = (value ^ static_cast<traits_type::type>(*(curr++))) * traits_type::prime;
}
return value;
}
public:
/*! @brief Character type. */
using value_type = Char;
/*! @brief Unsigned integer type. */
using hash_type = id_type;
/**
* @brief Returns directly the numeric representation of a string.
*
* Forcing template resolution avoids implicit conversions. An
* human-readable identifier can be anything but a plain, old bunch of
* characters.<br/>
* Example of use:
* @code{.cpp}
* const auto value = basic_hashed_string<char>::to_value("my.png");
* @endcode
*
* @tparam N Number of characters of the identifier.
* @param str Human-readable identifer.
* @return The numeric representation of the string.
*/
template<std::size_t N>
[[nodiscard]] static constexpr hash_type value(const value_type (&str)[N]) ENTT_NOEXCEPT {
return helper(str);
}
/**
* @brief Returns directly the numeric representation of a string.
* @param wrapper Helps achieving the purpose by relying on overloading.
* @return The numeric representation of the string.
*/
[[nodiscard]] static hash_type value(const_wrapper wrapper) ENTT_NOEXCEPT {
return helper(wrapper.str);
}
/**
* @brief Returns directly the numeric representation of a string view.
* @param str Human-readable identifer.
* @param size Length of the string to hash.
* @return The numeric representation of the string.
*/
[[nodiscard]] static hash_type value(const value_type *str, std::size_t size) ENTT_NOEXCEPT {
id_type partial{traits_type::offset};
while(size--) { partial = (partial^(str++)[0])*traits_type::prime; }
return partial;
}
/*! @brief Constructs an empty hashed string. */
constexpr basic_hashed_string() ENTT_NOEXCEPT
: str{nullptr}, hash{}
{}
/**
* @brief Constructs a hashed string from an array of const characters.
*
* Forcing template resolution avoids implicit conversions. An
* human-readable identifier can be anything but a plain, old bunch of
* characters.<br/>
* Example of use:
* @code{.cpp}
* basic_hashed_string<char> hs{"my.png"};
* @endcode
*
* @tparam N Number of characters of the identifier.
* @param curr Human-readable identifer.
*/
template<std::size_t N>
constexpr basic_hashed_string(const value_type (&curr)[N]) ENTT_NOEXCEPT
: str{curr}, hash{helper(curr)}
{}
/**
* @brief Explicit constructor on purpose to avoid constructing a hashed
* string directly from a `const value_type *`.
* @param wrapper Helps achieving the purpose by relying on overloading.
*/
explicit constexpr basic_hashed_string(const_wrapper wrapper) ENTT_NOEXCEPT
: str{wrapper.str}, hash{helper(wrapper.str)}
{}
/**
* @brief Returns the human-readable representation of a hashed string.
* @return The string used to initialize the instance.
*/
[[nodiscard]] constexpr const value_type * data() const ENTT_NOEXCEPT {
return str;
}
/**
* @brief Returns the numeric representation of a hashed string.
* @return The numeric representation of the instance.
*/
[[nodiscard]] constexpr hash_type value() const ENTT_NOEXCEPT {
return hash;
}
/*! @copydoc data */
[[nodiscard]] constexpr operator const value_type *() const ENTT_NOEXCEPT { return data(); }
/**
* @brief Returns the numeric representation of a hashed string.
* @return The numeric representation of the instance.
*/
[[nodiscard]] constexpr operator hash_type() const ENTT_NOEXCEPT { return value(); }
/**
* @brief Compares two hashed strings.
* @param other Hashed string with which to compare.
* @return True if the two hashed strings are identical, false otherwise.
*/
[[nodiscard]] constexpr bool operator==(const basic_hashed_string &other) const ENTT_NOEXCEPT {
return hash == other.hash;
}
private:
const value_type *str;
hash_type hash;
};
/**
* @brief Deduction guide.
*
* It allows to deduce the character type of the hashed string directly from a
* human-readable identifer provided to the constructor.
*
* @tparam Char Character type.
* @tparam N Number of characters of the identifier.
* @param str Human-readable identifer.
*/
template<typename Char, std::size_t N>
basic_hashed_string(const Char (&str)[N]) ENTT_NOEXCEPT
-> basic_hashed_string<Char>;
/**
* @brief Compares two hashed strings.
* @tparam Char Character type.
* @param lhs A valid hashed string.
* @param rhs A valid hashed string.
* @return True if the two hashed strings are identical, false otherwise.
*/
template<typename Char>
[[nodiscard]] constexpr bool operator!=(const basic_hashed_string<Char> &lhs, const basic_hashed_string<Char> &rhs) ENTT_NOEXCEPT {
return !(lhs == rhs);
}
/*! @brief Aliases for common character types. */
using hashed_string = basic_hashed_string<char>;
/*! @brief Aliases for common character types. */
using hashed_wstring = basic_hashed_string<wchar_t>;
}
/**
* @brief User defined literal for hashed strings.
* @param str The literal without its suffix.
* @return A properly initialized hashed string.
*/
[[nodiscard]] constexpr entt::hashed_string operator"" ENTT_HS_SUFFIX(const char *str, std::size_t) ENTT_NOEXCEPT {
return entt::hashed_string{str};
}
/**
* @brief User defined literal for hashed wstrings.
* @param str The literal without its suffix.
* @return A properly initialized hashed wstring.
*/
[[nodiscard]] constexpr entt::hashed_wstring operator"" ENTT_HWS_SUFFIX(const wchar_t *str, std::size_t) ENTT_NOEXCEPT {
return entt::hashed_wstring{str};
}
#endif
// #include "fwd.hpp"
namespace entt {
/**
* @cond TURN_OFF_DOXYGEN
* Internal details not to be documented.
*/
namespace internal {
struct ENTT_API type_index {
[[nodiscard]] static id_type next() ENTT_NOEXCEPT {
static ENTT_MAYBE_ATOMIC(id_type) value{};
return value++;
}
};
template<typename Type>
[[nodiscard]] constexpr auto type_name() ENTT_NOEXCEPT {
#if defined ENTT_PRETTY_FUNCTION
std::string_view pretty_function{ENTT_PRETTY_FUNCTION};
auto first = pretty_function.find_first_not_of(' ', pretty_function.find_first_of(ENTT_PRETTY_FUNCTION_PREFIX)+1);
auto value = pretty_function.substr(first, pretty_function.find_last_of(ENTT_PRETTY_FUNCTION_SUFFIX) - first);
return value;
#else
return std::string_view{};
#endif
}
}
/**
* Internal details not to be documented.
* @endcond
*/
/**
* @brief Type index.
* @tparam Type Type for which to generate a sequential identifier.
*/
template<typename Type, typename = void>
struct ENTT_API type_index {
/**
* @brief Returns the sequential identifier of a given type.
* @return The sequential identifier of a given type.
*/
[[nodiscard]] static id_type value() ENTT_NOEXCEPT {
static const id_type value = internal::type_index::next();
return value;
}
};
/**
* @brief Provides the member constant `value` to true if a given type is
* indexable, false otherwise.
* @tparam Type Potentially indexable type.
*/
template<typename, typename = void>
struct has_type_index: std::false_type {};
/*! @brief has_type_index */
template<typename Type>
struct has_type_index<Type, std::void_t<decltype(type_index<Type>::value())>>: std::true_type {};
/**
* @brief Helper variable template.
* @tparam Type Potentially indexable type.
*/
template<typename Type>
inline constexpr bool has_type_index_v = has_type_index<Type>::value;
/**
* @brief Type info.
* @tparam Type Type for which to generate information.
*/
template<typename Type, typename = void>
struct type_info {
/**
* @brief Returns the numeric representation of a given type.
* @return The numeric representation of the given type.
*/
#if defined ENTT_PRETTY_FUNCTION_CONSTEXPR
[[nodiscard]] static constexpr id_type id() ENTT_NOEXCEPT {
constexpr auto value = hashed_string::value(ENTT_PRETTY_FUNCTION);
return value;
}
#elif defined ENTT_PRETTY_FUNCTION
[[nodiscard]] static id_type id() ENTT_NOEXCEPT {
static const auto value = hashed_string::value(ENTT_PRETTY_FUNCTION);
return value;
}
#else
[[nodiscard]] static id_type id() ENTT_NOEXCEPT {
return type_index<Type>::value();
}
#endif
/**
* @brief Returns the name of a given type.
* @return The name of the given type.
*/
#if defined ENTT_PRETTY_FUNCTION_CONSTEXPR
[[nodiscard]] static constexpr std::string_view name() ENTT_NOEXCEPT {
constexpr auto value = internal::type_name<Type>();
return value;
}
#elif defined ENTT_PRETTY_FUNCTION
[[nodiscard]] static std::string_view name() ENTT_NOEXCEPT {
static const auto value = internal::type_name<Type>();
return value;
}
#else
[[nodiscard]] static constexpr std::string_view name() ENTT_NOEXCEPT {
return internal::type_name<Type>();
}
#endif
};
}
#endif
// #include "../core/type_traits.hpp"
#ifndef ENTT_CORE_TYPE_TRAITS_HPP
#define ENTT_CORE_TYPE_TRAITS_HPP
#include <cstddef>
#include <utility>
#include <type_traits>
// #include "../config/config.h"
// #include "fwd.hpp"
namespace entt {
/**
* @brief Using declaration to be used to _repeat_ the same type a number of
* times equal to the size of a given parameter pack.
* @tparam Type A type to repeat.
*/
template<typename Type, typename>
using unpack_as_t = Type;
/**
* @brief Helper variable template to be used to _repeat_ the same value a
* number of times equal to the size of a given parameter pack.
* @tparam Value A value to repeat.
*/
template<auto Value, typename>
inline constexpr auto unpack_as_v = Value;
/**
* @brief Wraps a static constant.
* @tparam Value A static constant.
*/
template<auto Value>
using integral_constant = std::integral_constant<decltype(Value), Value>;
/**
* @brief Alias template to ease the creation of named values.
* @tparam Value A constant value at least convertible to `id_type`.
*/
template<id_type Value>
using tag = integral_constant<Value>;
/**
* @brief Utility class to disambiguate overloaded functions.
* @tparam N Number of choices available.
*/
template<std::size_t N>
struct choice_t
// Unfortunately, doxygen cannot parse such a construct.
/*! @cond TURN_OFF_DOXYGEN */
: choice_t<N-1>
/*! @endcond */
{};
/*! @copybrief choice_t */
template<>
struct choice_t<0> {};
/**
* @brief Variable template for the choice trick.
* @tparam N Number of choices available.
*/
template<std::size_t N>
inline constexpr choice_t<N> choice{};
/*! @brief A class to use to push around lists of types, nothing more. */
template<typename...>
struct type_list {};
/*! @brief Primary template isn't defined on purpose. */
template<typename>
struct type_list_size;
/**
* @brief Compile-time number of elements in a type list.
* @tparam Type Types provided by the type list.
*/
template<typename... Type>
struct type_list_size<type_list<Type...>>
: std::integral_constant<std::size_t, sizeof...(Type)>
{};
/**
* @brief Helper variable template.
* @tparam List Type list.
*/
template<class List>
inline constexpr auto type_list_size_v = type_list_size<List>::value;
/*! @brief Primary template isn't defined on purpose. */
template<typename...>
struct type_list_cat;
/*! @brief Concatenates multiple type lists. */
template<>
struct type_list_cat<> {
/*! @brief A type list composed by the types of all the type lists. */
using type = type_list<>;
};
/**
* @brief Concatenates multiple type lists.
* @tparam Type Types provided by the first type list.
* @tparam Other Types provided by the second type list.
* @tparam List Other type lists, if any.
*/
template<typename... Type, typename... Other, typename... List>
struct type_list_cat<type_list<Type...>, type_list<Other...>, List...> {
/*! @brief A type list composed by the types of all the type lists. */
using type = typename type_list_cat<type_list<Type..., Other...>, List...>::type;
};
/**
* @brief Concatenates multiple type lists.
* @tparam Type Types provided by the type list.
*/
template<typename... Type>
struct type_list_cat<type_list<Type...>> {
/*! @brief A type list composed by the types of all the type lists. */
using type = type_list<Type...>;
};
/**
* @brief Helper type.
* @tparam List Type lists to concatenate.
*/
template<typename... List>
using type_list_cat_t = typename type_list_cat<List...>::type;
/*! @brief Primary template isn't defined on purpose. */
template<typename>
struct type_list_unique;
/**
* @brief Removes duplicates types from a type list.
* @tparam Type One of the types provided by the given type list.
* @tparam Other The other types provided by the given type list.
*/
template<typename Type, typename... Other>
struct type_list_unique<type_list<Type, Other...>> {
/*! @brief A type list without duplicate types. */
using type = std::conditional_t<
std::disjunction_v<std::is_same<Type, Other>...>,
typename type_list_unique<type_list<Other...>>::type,
type_list_cat_t<type_list<Type>, typename type_list_unique<type_list<Other...>>::type>
>;
};
/*! @brief Removes duplicates types from a type list. */
template<>
struct type_list_unique<type_list<>> {
/*! @brief A type list without duplicate types. */
using type = type_list<>;
};
/**
* @brief Helper type.
* @tparam Type A type list.
*/
template<typename Type>
using type_list_unique_t = typename type_list_unique<Type>::type;
/**
* @brief Provides the member constant `value` to true if a given type is
* equality comparable, false otherwise.
* @tparam Type Potentially equality comparable type.
*/
template<typename Type, typename = std::void_t<>>
struct is_equality_comparable: std::false_type {};
/*! @copydoc is_equality_comparable */
template<typename Type>
struct is_equality_comparable<Type, std::void_t<decltype(std::declval<Type>() == std::declval<Type>())>>
: std::true_type
{};
/**
* @brief Helper variable template.
* @tparam Type Potentially equality comparable type.
*/
template<class Type>
inline constexpr auto is_equality_comparable_v = is_equality_comparable<Type>::value;
/**
* @brief Provides the member constant `value` to true if a given type is empty
* and the empty type optimization is enabled, false otherwise.
* @tparam Type Potential empty type.
*/
template<typename Type, typename = void>
struct is_eto_eligible
: ENTT_IS_EMPTY(Type)
{};
/**
* @brief Helper variable template.
* @tparam Type Potential empty type.
*/
template<typename Type>
inline constexpr auto is_eto_eligible_v = is_eto_eligible<Type>::value;
/**
* @brief Extracts the class of a non-static member object or function.
* @tparam Member A pointer to a non-static member object or function.
*/
template<typename Member>
class member_class {
static_assert(std::is_member_pointer_v<Member>, "Invalid pointer type to non-static member object or function");
template<typename Class, typename Ret, typename... Args>
static Class * clazz(Ret(Class:: *)(Args...));
template<typename Class, typename Ret, typename... Args>
static Class * clazz(Ret(Class:: *)(Args...) const);
template<typename Class, typename Type>
static Class * clazz(Type Class:: *);
public:
/*! @brief The class of the given non-static member object or function. */
using type = std::remove_pointer_t<decltype(clazz(std::declval<Member>()))>;
};
/**
* @brief Helper type.
* @tparam Member A pointer to a non-static member object or function.
*/
template<typename Member>
using member_class_t = typename member_class<Member>::type;
}
#endif
// #include "../signal/sigh.hpp"
#ifndef ENTT_SIGNAL_SIGH_HPP
#define ENTT_SIGNAL_SIGH_HPP
#include <vector>
#include <utility>
#include <iterator>
#include <algorithm>
#include <functional>
#include <type_traits>
// #include "../config/config.h"
#ifndef ENTT_CONFIG_CONFIG_H
#define ENTT_CONFIG_CONFIG_H
#ifndef ENTT_NOEXCEPT
# define ENTT_NOEXCEPT noexcept
#endif
#ifndef ENTT_HS_SUFFIX
# define ENTT_HS_SUFFIX _hs
#endif
#ifndef ENTT_HWS_SUFFIX
# define ENTT_HWS_SUFFIX _hws
#endif
#ifndef ENTT_USE_ATOMIC
# define ENTT_MAYBE_ATOMIC(Type) Type
#else
# include <atomic>
# define ENTT_MAYBE_ATOMIC(Type) std::atomic<Type>
#endif
#ifndef ENTT_ID_TYPE
# include <cstdint>
# define ENTT_ID_TYPE std::uint32_t
#endif
#ifndef ENTT_PAGE_SIZE
# define ENTT_PAGE_SIZE 32768
#endif
#ifndef ENTT_ASSERT
# include <cassert>
# define ENTT_ASSERT(condition) assert(condition)
#endif
#ifndef ENTT_NO_ETO
# include <type_traits>
# define ENTT_IS_EMPTY(Type) std::is_empty<Type>
#else
# include <type_traits>
# define ENTT_IS_EMPTY(Type) std::false_type
#endif
#ifndef ENTT_STANDARD_CPP
# if defined __clang__ || (defined __GNUC__ && __GNUC__ > 8)
# define ENTT_PRETTY_FUNCTION_CONSTEXPR
# define ENTT_PRETTY_FUNCTION __PRETTY_FUNCTION__
# define ENTT_PRETTY_FUNCTION_PREFIX '='
# define ENTT_PRETTY_FUNCTION_SUFFIX ']'
# elif defined __GNUC__
# define ENTT_PRETTY_FUNCTION __PRETTY_FUNCTION__
# define ENTT_PRETTY_FUNCTION_PREFIX '='
# define ENTT_PRETTY_FUNCTION_SUFFIX ']'
# elif defined _MSC_VER
# define ENTT_PRETTY_FUNCTION_CONSTEXPR
# define ENTT_PRETTY_FUNCTION __FUNCSIG__
# define ENTT_PRETTY_FUNCTION_PREFIX '<'
# define ENTT_PRETTY_FUNCTION_SUFFIX '>'
# endif
#endif
#ifndef ENTT_STANDALONE
# define ENTT_FAST_PATH(...) false
#else
# define ENTT_FAST_PATH(Cond) Cond
#endif
#endif
// #include "delegate.hpp"
#ifndef ENTT_SIGNAL_DELEGATE_HPP
#define ENTT_SIGNAL_DELEGATE_HPP
#include <tuple>
#include <cstddef>
#include <utility>
#include <functional>
#include <type_traits>
// #include "../config/config.h"
namespace entt {
/**
* @cond TURN_OFF_DOXYGEN
* Internal details not to be documented.
*/
namespace internal {
template<typename Ret, typename... Args>
auto function_pointer(Ret(*)(Args...)) -> Ret(*)(Args...);
template<typename Ret, typename Type, typename... Args, typename Other>
auto function_pointer(Ret(*)(Type, Args...), Other &&) -> Ret(*)(Args...);
template<typename Class, typename Ret, typename... Args, typename... Other>
auto function_pointer(Ret(Class:: *)(Args...), Other &&...) -> Ret(*)(Args...);
template<typename Class, typename Ret, typename... Args, typename... Other>
auto function_pointer(Ret(Class:: *)(Args...) const, Other &&...) -> Ret(*)(Args...);
template<typename Class, typename Type, typename... Other>
auto function_pointer(Type Class:: *, Other &&...) -> Type(*)();
template<typename... Type>
using function_pointer_t = decltype(internal::function_pointer(std::declval<Type>()...));
template<typename... Class, typename Ret, typename... Args>
[[nodiscard]] constexpr auto index_sequence_for(Ret(*)(Args...)) {
return std::index_sequence_for<Class..., Args...>{};
}
}
/**
* Internal details not to be documented.
* @endcond
*/
/*! @brief Used to wrap a function or a member of a specified type. */
template<auto>
struct connect_arg_t {};
/*! @brief Constant of type connect_arg_t used to disambiguate calls. */
template<auto Func>
inline constexpr connect_arg_t<Func> connect_arg{};
/**
* @brief Basic delegate implementation.
*
* Primary template isn't defined on purpose. All the specializations give a
* compile-time error unless the template parameter is a function type.
*/
template<typename>
class delegate;
/**
* @brief Utility class to use to send around functions and members.
*
* Unmanaged delegate for function pointers and members. Users of this class are
* in charge of disconnecting instances before deleting them.
*
* A delegate can be used as a general purpose invoker without memory overhead
* for free functions possibly with payloads and bound or unbound members.
*
* @tparam Ret Return type of a function type.
* @tparam Args Types of arguments of a function type.
*/
template<typename Ret, typename... Args>
class delegate<Ret(Args...)> {
template<auto Candidate, std::size_t... Index>
[[nodiscard]] auto wrap(std::index_sequence<Index...>) ENTT_NOEXCEPT {
return [](const void *, Args... args) -> Ret {
[[maybe_unused]] const auto arguments = std::forward_as_tuple(std::forward<Args>(args)...);
return Ret(std::invoke(Candidate, std::forward<std::tuple_element_t<Index, std::tuple<Args...>>>(std::get<Index>(arguments))...));
};
}
template<auto Candidate, typename Type, std::size_t... Index>
[[nodiscard]] auto wrap(Type &, std::index_sequence<Index...>) ENTT_NOEXCEPT {
return [](const void *payload, Args... args) -> Ret {
[[maybe_unused]] const auto arguments = std::forward_as_tuple(std::forward<Args>(args)...);
Type *curr = static_cast<Type *>(const_cast<std::conditional_t<std::is_const_v<Type>, const void *, void *>>(payload));
return Ret(std::invoke(Candidate, *curr, std::forward<std::tuple_element_t<Index, std::tuple<Args...>>>(std::get<Index>(arguments))...));
};
}
template<auto Candidate, typename Type, std::size_t... Index>
[[nodiscard]] auto wrap(Type *, std::index_sequence<Index...>) ENTT_NOEXCEPT {
return [](const void *payload, Args... args) -> Ret {
[[maybe_unused]] const auto arguments = std::forward_as_tuple(std::forward<Args>(args)...);
Type *curr = static_cast<Type *>(const_cast<std::conditional_t<std::is_const_v<Type>, const void *, void *>>(payload));
return Ret(std::invoke(Candidate, curr, std::forward<std::tuple_element_t<Index, std::tuple<Args...>>>(std::get<Index>(arguments))...));
};
}
public:
/*! @brief Function type of the contained target. */
using function_type = Ret(const void *, Args...);
/*! @brief Function type of the delegate. */
using type = Ret(Args...);
/*! @brief Return type of the delegate. */
using result_type = Ret;
/*! @brief Default constructor. */
delegate() ENTT_NOEXCEPT
: fn{nullptr}, data{nullptr}
{}
/**
* @brief Constructs a delegate and connects a free function or an unbound
* member.
* @tparam Candidate Function or member to connect to the delegate.
*/
template<auto Candidate>
delegate(connect_arg_t<Candidate>) ENTT_NOEXCEPT {
connect<Candidate>();
}
/**
* @brief Constructs a delegate and connects a free function with payload or
* a bound member.
* @tparam Candidate Function or member to connect to the delegate.
* @tparam Type Type of class or type of payload.
* @param value_or_instance A valid object that fits the purpose.
*/
template<auto Candidate, typename Type>
delegate(connect_arg_t<Candidate>, Type &&value_or_instance) ENTT_NOEXCEPT {
connect<Candidate>(std::forward<Type>(value_or_instance));
}
/**
* @brief Constructs a delegate and connects an user defined function with
* optional payload.
* @param function Function to connect to the delegate.
* @param payload User defined arbitrary data.
*/
delegate(function_type *function, const void *payload = nullptr) ENTT_NOEXCEPT {
connect(function, payload);
}
/**
* @brief Connects a free function or an unbound member to a delegate.
* @tparam Candidate Function or member to connect to the delegate.
*/
template<auto Candidate>
void connect() ENTT_NOEXCEPT {
data = nullptr;
if constexpr(std::is_invocable_r_v<Ret, decltype(Candidate), Args...>) {
fn = [](const void *, Args... args) -> Ret {
return Ret(std::invoke(Candidate, std::forward<Args>(args)...));
};
} else if constexpr(std::is_member_pointer_v<decltype(Candidate)>) {
fn = wrap<Candidate>(internal::index_sequence_for<std::tuple_element_t<0, std::tuple<Args...>>>(internal::function_pointer_t<decltype(Candidate)>{}));
} else {
fn = wrap<Candidate>(internal::index_sequence_for(internal::function_pointer_t<decltype(Candidate)>{}));
}
}
/**
* @brief Connects a free function with payload or a bound member to a
* delegate.
*
* The delegate isn't responsible for the connected object or the payload.
* Users must always guarantee that the lifetime of the instance overcomes
* the one of the delegate.<br/>
* When used to connect a free function with payload, its signature must be
* such that the instance is the first argument before the ones used to
* define the delegate itself.
*
* @tparam Candidate Function or member to connect to the delegate.
* @tparam Type Type of class or type of payload.
* @param value_or_instance A valid reference that fits the purpose.
*/
template<auto Candidate, typename Type>
void connect(Type &value_or_instance) ENTT_NOEXCEPT {
data = &value_or_instance;
if constexpr(std::is_invocable_r_v<Ret, decltype(Candidate), Type &, Args...>) {
fn = [](const void *payload, Args... args) -> Ret {
Type *curr = static_cast<Type *>(const_cast<std::conditional_t<std::is_const_v<Type>, const void *, void *>>(payload));
return Ret(std::invoke(Candidate, *curr, std::forward<Args>(args)...));
};
} else {
fn = wrap<Candidate>(value_or_instance, internal::index_sequence_for(internal::function_pointer_t<decltype(Candidate), Type>{}));
}
}
/**
* @brief Connects a free function with payload or a bound member to a
* delegate.
*
* @sa connect(Type &)
*
* @tparam Candidate Function or member to connect to the delegate.
* @tparam Type Type of class or type of payload.
* @param value_or_instance A valid pointer that fits the purpose.
*/
template<auto Candidate, typename Type>
void connect(Type *value_or_instance) ENTT_NOEXCEPT {
data = value_or_instance;
if constexpr(std::is_invocable_r_v<Ret, decltype(Candidate), Type *, Args...>) {
fn = [](const void *payload, Args... args) -> Ret {
Type *curr = static_cast<Type *>(const_cast<std::conditional_t<std::is_const_v<Type>, const void *, void *>>(payload));
return Ret(std::invoke(Candidate, curr, std::forward<Args>(args)...));
};
} else {
fn = wrap<Candidate>(value_or_instance, internal::index_sequence_for(internal::function_pointer_t<decltype(Candidate), Type>{}));
}
}
/**
* @brief Connects an user defined function with optional payload to a
* delegate.
*
* The delegate isn't responsible for the connected object or the payload.
* Users must always guarantee that the lifetime of an instance overcomes
* the one of the delegate.<br/>
* The payload is returned as the first argument to the target function in
* all cases.
*
* @param function Function to connect to the delegate.
* @param payload User defined arbitrary data.
*/
void connect(function_type *function, const void *payload = nullptr) ENTT_NOEXCEPT {
fn = function;
data = payload;
}
/**
* @brief Resets a delegate.
*
* After a reset, a delegate cannot be invoked anymore.
*/
void reset() ENTT_NOEXCEPT {
fn = nullptr;
data = nullptr;
}
/**
* @brief Returns the instance or the payload linked to a delegate, if any.
* @return An opaque pointer to the underlying data.
*/
[[nodiscard]] const void * instance() const ENTT_NOEXCEPT {
return data;
}
/**
* @brief Triggers a delegate.
*
* The delegate invokes the underlying function and returns the result.
*
* @warning
* Attempting to trigger an invalid delegate results in undefined
* behavior.<br/>
* An assertion will abort the execution at runtime in debug mode if the
* delegate has not yet been set.
*
* @param args Arguments to use to invoke the underlying function.
* @return The value returned by the underlying function.
*/
Ret operator()(Args... args) const {
ENTT_ASSERT(fn);
return fn(data, std::forward<Args>(args)...);
}
/**
* @brief Checks whether a delegate actually stores a listener.
* @return False if the delegate is empty, true otherwise.
*/
[[nodiscard]] explicit operator bool() const ENTT_NOEXCEPT {
// no need to test also data
return !(fn == nullptr);
}
/**
* @brief Compares the contents of two delegates.
* @param other Delegate with which to compare.
* @return False if the two contents differ, true otherwise.
*/
[[nodiscard]] bool operator==(const delegate<Ret(Args...)> &other) const ENTT_NOEXCEPT {
return fn == other.fn && data == other.data;
}
private:
function_type *fn;
const void *data;
};
/**
* @brief Compares the contents of two delegates.
* @tparam Ret Return type of a function type.
* @tparam Args Types of arguments of a function type.
* @param lhs A valid delegate object.
* @param rhs A valid delegate object.
* @return True if the two contents differ, false otherwise.
*/
template<typename Ret, typename... Args>
[[nodiscard]] bool operator!=(const delegate<Ret(Args...)> &lhs, const delegate<Ret(Args...)> &rhs) ENTT_NOEXCEPT {
return !(lhs == rhs);
}
/**
* @brief Deduction guide.
* @tparam Candidate Function or member to connect to the delegate.
*/
template<auto Candidate>
delegate(connect_arg_t<Candidate>) ENTT_NOEXCEPT
-> delegate<std::remove_pointer_t<internal::function_pointer_t<decltype(Candidate)>>>;
/**
* @brief Deduction guide.
* @tparam Candidate Function or member to connect to the delegate.
* @tparam Type Type of class or type of payload.
*/
template<auto Candidate, typename Type>
delegate(connect_arg_t<Candidate>, Type &&) ENTT_NOEXCEPT
-> delegate<std::remove_pointer_t<internal::function_pointer_t<decltype(Candidate), Type>>>;
/*! @brief Deduction guide. */
template<typename Ret, typename... Args>
delegate(Ret(*)(const void *, Args...), const void * = nullptr) ENTT_NOEXCEPT
-> delegate<Ret(Args...)>;
}
#endif
// #include "fwd.hpp"
#ifndef ENTT_SIGNAL_FWD_HPP
#define ENTT_SIGNAL_FWD_HPP
namespace entt {
template<typename>
class delegate;
class dispatcher;
template<typename>
class emitter;
class connection;
struct scoped_connection;
template<typename>
class sink;
template<typename>
class sigh;
}
#endif
namespace entt {
/**
* @brief Sink class.
*
* Primary template isn't defined on purpose. All the specializations give a
* compile-time error unless the template parameter is a function type.
*
* @tparam Function A valid function type.
*/
template<typename Function>
class sink;
/**
* @brief Unmanaged signal handler.
*
* Primary template isn't defined on purpose. All the specializations give a
* compile-time error unless the template parameter is a function type.
*
* @tparam Function A valid function type.
*/
template<typename Function>
class sigh;
/**
* @brief Unmanaged signal handler.
*
* It works directly with references to classes and pointers to member functions
* as well as pointers to free functions. Users of this class are in charge of
* disconnecting instances before deleting them.
*
* This class serves mainly two purposes:
*
* * Creating signals to use later to notify a bunch of listeners.
* * Collecting results from a set of functions like in a voting system.
*
* @tparam Ret Return type of a function type.
* @tparam Args Types of arguments of a function type.
*/
template<typename Ret, typename... Args>
class sigh<Ret(Args...)> {
/*! @brief A sink is allowed to modify a signal. */
friend class sink<Ret(Args...)>;
public:
/*! @brief Unsigned integer type. */
using size_type = std::size_t;
/*! @brief Sink type. */
using sink_type = sink<Ret(Args...)>;
/**
* @brief Instance type when it comes to connecting member functions.
* @tparam Class Type of class to which the member function belongs.
*/
template<typename Class>
using instance_type = Class *;
/**
* @brief Number of listeners connected to the signal.
* @return Number of listeners currently connected.
*/
[[nodiscard]] size_type size() const ENTT_NOEXCEPT {
return calls.size();
}
/**
* @brief Returns false if at least a listener is connected to the signal.
* @return True if the signal has no listeners connected, false otherwise.
*/
[[nodiscard]] bool empty() const ENTT_NOEXCEPT {
return calls.empty();
}
/**
* @brief Triggers a signal.
*
* All the listeners are notified. Order isn't guaranteed.
*
* @param args Arguments to use to invoke listeners.
*/
void publish(Args... args) const {
for(auto &&call: std::as_const(calls)) {
call(args...);
}
}
/**
* @brief Collects return values from the listeners.
*
* The collector must expose a call operator with the following properties:
*
* * The return type is either `void` or such that it's convertible to
* `bool`. In the second case, a true value will stop the iteration.
* * The list of parameters is empty if `Ret` is `void`, otherwise it
* contains a single element such that `Ret` is convertible to it.
*
* @tparam Func Type of collector to use, if any.
* @param func A valid function object.
* @param args Arguments to use to invoke listeners.
*/
template<typename Func>
void collect(Func func, Args... args) const {
for(auto &&call: calls) {
if constexpr(std::is_void_v<Ret>) {
if constexpr(std::is_invocable_r_v<bool, Func>) {
call(args...);
if(func()) { break; }
} else {
call(args...);
func();
}
} else {
if constexpr(std::is_invocable_r_v<bool, Func, Ret>) {
if(func(call(args...))) { break; }
} else {
func(call(args...));
}
}
}
}
private:
std::vector<delegate<Ret(Args...)>> calls;
};
/**
* @brief Connection class.
*
* Opaque object the aim of which is to allow users to release an already
* estabilished connection without having to keep a reference to the signal or
* the sink that generated it.
*/
class connection {
/*! @brief A sink is allowed to create connection objects. */
template<typename>
friend class sink;
connection(delegate<void(void *)> fn, void *ref)
: disconnect{fn}, signal{ref}
{}
public:
/*! @brief Default constructor. */
connection() = default;
/**
* @brief Checks whether a connection is properly initialized.
* @return True if the connection is properly initialized, false otherwise.
*/
[[nodiscard]] explicit operator bool() const ENTT_NOEXCEPT {
return static_cast<bool>(disconnect);
}
/*! @brief Breaks the connection. */
void release() {
if(disconnect) {
disconnect(signal);
disconnect.reset();
}
}
private:
delegate<void(void *)> disconnect;
void *signal{};
};
/**
* @brief Scoped connection class.
*
* Opaque object the aim of which is to allow users to release an already
* estabilished connection without having to keep a reference to the signal or
* the sink that generated it.<br/>
* A scoped connection automatically breaks the link between the two objects
* when it goes out of scope.
*/
struct scoped_connection {
/*! @brief Default constructor. */
scoped_connection() = default;
/**
* @brief Constructs a scoped connection from a basic connection.
* @param other A valid connection object.
*/
scoped_connection(const connection &other)
: conn{other}
{}
/*! @brief Default copy constructor, deleted on purpose. */
scoped_connection(const scoped_connection &) = delete;
/*! @brief Automatically breaks the link on destruction. */
~scoped_connection() {
conn.release();
}
/**
* @brief Default copy assignment operator, deleted on purpose.
* @return This scoped connection.
*/
scoped_connection & operator=(const scoped_connection &) = delete;
/**
* @brief Acquires a connection.
* @param other The connection object to acquire.
* @return This scoped connection.
*/
scoped_connection & operator=(connection other) {
conn = std::move(other);
return *this;
}
/**
* @brief Checks whether a scoped connection is properly initialized.
* @return True if the connection is properly initialized, false otherwise.
*/
[[nodiscard]] explicit operator bool() const ENTT_NOEXCEPT {
return static_cast<bool>(conn);
}
/*! @brief Breaks the connection. */
void release() {
conn.release();
}
private:
connection conn;
};
/**
* @brief Sink class.
*
* A sink is used to connect listeners to signals and to disconnect them.<br/>
* The function type for a listener is the one of the signal to which it
* belongs.
*
* The clear separation between a signal and a sink permits to store the former
* as private data member without exposing the publish functionality to the
* users of the class.
*
* @warning
* Lifetime of a sink must not overcome that of the signal to which it refers.
* In any other case, attempting to use a sink results in undefined behavior.
*
* @tparam Ret Return type of a function type.
* @tparam Args Types of arguments of a function type.
*/
template<typename Ret, typename... Args>
class sink<Ret(Args...)> {
using signal_type = sigh<Ret(Args...)>;
using difference_type = typename std::iterator_traits<typename decltype(signal_type::calls)::iterator>::difference_type;
template<auto Candidate, typename Type>
static void release(Type value_or_instance, void *signal) {
sink{*static_cast<signal_type *>(signal)}.disconnect<Candidate>(value_or_instance);
}
template<auto Candidate>
static void release(void *signal) {
sink{*static_cast<signal_type *>(signal)}.disconnect<Candidate>();
}
public:
/**
* @brief Constructs a sink that is allowed to modify a given signal.
* @param ref A valid reference to a signal object.
*/
sink(sigh<Ret(Args...)> &ref) ENTT_NOEXCEPT
: offset{},
signal{&ref}
{}
/**
* @brief Returns false if at least a listener is connected to the sink.
* @return True if the sink has no listeners connected, false otherwise.
*/
[[nodiscard]] bool empty() const ENTT_NOEXCEPT {
return signal->calls.empty();
}
/**
* @brief Returns a sink that connects before a given free function or an
* unbound member.
* @tparam Function A valid free function pointer.
* @return A properly initialized sink object.
*/
template<auto Function>
[[nodiscard]] sink before() {
delegate<Ret(Args...)> call{};
call.template connect<Function>();
const auto &calls = signal->calls;
const auto it = std::find(calls.cbegin(), calls.cend(), std::move(call));
sink other{*this};
other.offset = std::distance(it, calls.cend());
return other;
}
/**
* @brief Returns a sink that connects before a free function with payload
* or a bound member.
* @tparam Candidate Member or free function to look for.
* @tparam Type Type of class or type of payload.
* @param value_or_instance A valid object that fits the purpose.
* @return A properly initialized sink object.
*/
template<auto Candidate, typename Type>
[[nodiscard]] sink before(Type &&value_or_instance) {
delegate<Ret(Args...)> call{};
call.template connect<Candidate>(value_or_instance);
const auto &calls = signal->calls;
const auto it = std::find(calls.cbegin(), calls.cend(), std::move(call));
sink other{*this};
other.offset = std::distance(it, calls.cend());
return other;
}
/**
* @brief Returns a sink that connects before a given instance or specific
* payload.
* @tparam Type Type of class or type of payload.
* @param value_or_instance A valid object that fits the purpose.
* @return A properly initialized sink object.
*/
template<typename Type>
[[nodiscard]] sink before(Type &value_or_instance) {
return before(&value_or_instance);
}
/**
* @brief Returns a sink that connects before a given instance or specific
* payload.
* @tparam Type Type of class or type of payload.
* @param value_or_instance A valid pointer that fits the purpose.
* @return A properly initialized sink object.
*/
template<typename Type>
[[nodiscard]] sink before(Type *value_or_instance) {
sink other{*this};
if(value_or_instance) {
const auto &calls = signal->calls;
const auto it = std::find_if(calls.cbegin(), calls.cend(), [value_or_instance](const auto &delegate) {
return delegate.instance() == value_or_instance;
});
other.offset = std::distance(it, calls.cend());
}
return other;
}
/**
* @brief Returns a sink that connects before anything else.
* @return A properly initialized sink object.
*/
[[nodiscard]] sink before() {
sink other{*this};
other.offset = signal->calls.size();
return other;
}
/**
* @brief Connects a free function or an unbound member to a signal.
*
* The signal handler performs checks to avoid multiple connections for the
* same function.
*
* @tparam Candidate Function or member to connect to the signal.
* @return A properly initialized connection object.
*/
template<auto Candidate>
connection connect() {
disconnect<Candidate>();
delegate<Ret(Args...)> call{};
call.template connect<Candidate>();
signal->calls.insert(signal->calls.end() - offset, std::move(call));
delegate<void(void *)> conn{};
conn.template connect<&release<Candidate>>();
return { std::move(conn), signal };
}
/**
* @brief Connects a free function with payload or a bound member to a
* signal.
*
* The signal isn't responsible for the connected object or the payload.
* Users must always guarantee that the lifetime of the instance overcomes
* the one of the signal. On the other side, the signal handler performs
* checks to avoid multiple connections for the same function.<br/>
* When used to connect a free function with payload, its signature must be
* such that the instance is the first argument before the ones used to
* define the signal itself.
*
* @tparam Candidate Function or member to connect to the signal.
* @tparam Type Type of class or type of payload.
* @param value_or_instance A valid object that fits the purpose.
* @return A properly initialized connection object.
*/
template<auto Candidate, typename Type>
connection connect(Type &&value_or_instance) {
disconnect<Candidate>(value_or_instance);
delegate<Ret(Args...)> call{};
call.template connect<Candidate>(value_or_instance);
signal->calls.insert(signal->calls.end() - offset, std::move(call));
delegate<void(void *)> conn{};
conn.template connect<&release<Candidate, Type>>(value_or_instance);
return { std::move(conn), signal };
}
/**
* @brief Disconnects a free function or an unbound member from a signal.
* @tparam Candidate Function or member to disconnect from the signal.
*/
template<auto Candidate>
void disconnect() {
auto &calls = signal->calls;
delegate<Ret(Args...)> call{};
call.template connect<Candidate>();
calls.erase(std::remove(calls.begin(), calls.end(), std::move(call)), calls.end());
}
/**
* @brief Disconnects a free function with payload or a bound member from a
* signal.
* @tparam Candidate Function or member to disconnect from the signal.
* @tparam Type Type of class or type of payload.
* @param value_or_instance A valid object that fits the purpose.
*/
template<auto Candidate, typename Type>
void disconnect(Type &&value_or_instance) {
auto &calls = signal->calls;
delegate<Ret(Args...)> call{};
call.template connect<Candidate>(value_or_instance);
calls.erase(std::remove(calls.begin(), calls.end(), std::move(call)), calls.end());
}
/**
* @brief Disconnects free functions with payload or bound members from a
* signal.
* @tparam Type Type of class or type of payload.
* @param value_or_instance A valid object that fits the purpose.
*/
template<typename Type>
void disconnect(Type &value_or_instance) {
disconnect(&value_or_instance);
}
/**
* @brief Disconnects free functions with payload or bound members from a
* signal.
* @tparam Type Type of class or type of payload.
* @param value_or_instance A valid object that fits the purpose.
*/
template<typename Type>
void disconnect(Type *value_or_instance) {
if(value_or_instance) {
auto &calls = signal->calls;
calls.erase(std::remove_if(calls.begin(), calls.end(), [value_or_instance](const auto &delegate) {
return delegate.instance() == value_or_instance;
}), calls.end());
}
}
/*! @brief Disconnects all the listeners from a signal. */
void disconnect() {
signal->calls.clear();
}
private:
difference_type offset;
signal_type *signal;
};
/**
* @brief Deduction guide.
*
* It allows to deduce the function type of a sink directly from the signal it
* refers to.
*
* @tparam Ret Return type of a function type.
* @tparam Args Types of arguments of a function type.
*/
template<typename Ret, typename... Args>
sink(sigh<Ret(Args...)> &) ENTT_NOEXCEPT -> sink<Ret(Args...)>;
}
#endif
// #include "entity.hpp"
#ifndef ENTT_ENTITY_ENTITY_HPP
#define ENTT_ENTITY_ENTITY_HPP
#include <cstddef>
#include <cstdint>
#include <type_traits>
// #include "../config/config.h"
namespace entt {
/**
* @brief Entity traits.
*
* Primary template isn't defined on purpose. All the specializations give a
* compile-time error unless the template parameter is an accepted entity type.
*/
template<typename, typename = void>
struct entt_traits;
/**
* @brief Entity traits for enumeration types.
* @tparam Type The type to check.
*/
template<typename Type>
struct entt_traits<Type, std::enable_if_t<std::is_enum_v<Type>>>
: entt_traits<std::underlying_type_t<Type>>
{};
/**
* @brief Entity traits for a 16 bits entity identifier.
*
* A 16 bits entity identifier guarantees:
*
* * 12 bits for the entity number (up to 4k entities).
* * 4 bit for the version (resets in [0-15]).
*/
template<>
struct entt_traits<std::uint16_t> {
/*! @brief Underlying entity type. */
using entity_type = std::uint16_t;
/*! @brief Underlying version type. */
using version_type = std::uint8_t;
/*! @brief Difference type. */
using difference_type = std::int16_t;
/*! @brief Mask to use to get the entity number out of an identifier. */
static constexpr entity_type entity_mask = 0xFFF;
/*! @brief Mask to use to get the version out of an identifier. */
static constexpr entity_type version_mask = 0xF;
/*! @brief Extent of the entity number within an identifier. */
static constexpr std::size_t entity_shift = 12u;
};
/**
* @brief Entity traits for a 32 bits entity identifier.
*
* A 32 bits entity identifier guarantees:
*
* * 20 bits for the entity number (suitable for almost all the games).
* * 12 bit for the version (resets in [0-4095]).
*/
template<>
struct entt_traits<std::uint32_t> {
/*! @brief Underlying entity type. */
using entity_type = std::uint32_t;
/*! @brief Underlying version type. */
using version_type = std::uint16_t;
/*! @brief Difference type. */
using difference_type = std::int32_t;
/*! @brief Mask to use to get the entity number out of an identifier. */
static constexpr entity_type entity_mask = 0xFFFFF;
/*! @brief Mask to use to get the version out of an identifier. */
static constexpr entity_type version_mask = 0xFFF;
/*! @brief Extent of the entity number within an identifier. */
static constexpr std::size_t entity_shift = 20u;
};
/**
* @brief Entity traits for a 64 bits entity identifier.
*
* A 64 bits entity identifier guarantees:
*
* * 32 bits for the entity number (an indecently large number).
* * 32 bit for the version (an indecently large number).
*/
template<>
struct entt_traits<std::uint64_t> {
/*! @brief Underlying entity type. */
using entity_type = std::uint64_t;
/*! @brief Underlying version type. */
using version_type = std::uint32_t;
/*! @brief Difference type. */
using difference_type = std::int64_t;
/*! @brief Mask to use to get the entity number out of an identifier. */
static constexpr entity_type entity_mask = 0xFFFFFFFF;
/*! @brief Mask to use to get the version out of an identifier. */
static constexpr entity_type version_mask = 0xFFFFFFFF;
/*! @brief Extent of the entity number within an identifier. */
static constexpr std::size_t entity_shift = 32u;
};
/**
* @brief Converts an entity type to its underlying type.
* @tparam Entity The value type.
* @param entity The value to convert.
* @return The integral representation of the given value.
*/
template<typename Entity>
[[nodiscard]] constexpr auto to_integral(const Entity entity) ENTT_NOEXCEPT {
return static_cast<typename entt_traits<Entity>::entity_type>(entity);
}
/*! @brief Null object for all entity identifiers. */
struct null_t {
/**
* @brief Converts the null object to identifiers of any type.
* @tparam Entity Type of entity identifier.
* @return The null representation for the given identifier.
*/
template<typename Entity>
[[nodiscard]] constexpr operator Entity() const ENTT_NOEXCEPT {
return Entity{entt_traits<Entity>::entity_mask};
}
/**
* @brief Compares two null objects.
* @return True in all cases.
*/
[[nodiscard]] constexpr bool operator==(null_t) const ENTT_NOEXCEPT {
return true;
}
/**
* @brief Compares two null objects.
* @return False in all cases.
*/
[[nodiscard]] constexpr bool operator!=(null_t) const ENTT_NOEXCEPT {
return false;
}
/**
* @brief Compares a null object and an entity identifier of any type.
* @tparam Entity Type of entity identifier.
* @param entity Entity identifier with which to compare.
* @return False if the two elements differ, true otherwise.
*/
template<typename Entity>
[[nodiscard]] constexpr bool operator==(const Entity entity) const ENTT_NOEXCEPT {
return (to_integral(entity) & entt_traits<Entity>::entity_mask) == to_integral(static_cast<Entity>(*this));
}
/**
* @brief Compares a null object and an entity identifier of any type.
* @tparam Entity Type of entity identifier.
* @param entity Entity identifier with which to compare.
* @return True if the two elements differ, false otherwise.
*/
template<typename Entity>
[[nodiscard]] constexpr bool operator!=(const Entity entity) const ENTT_NOEXCEPT {
return !(entity == *this);
}
};
/**
* @brief Compares a null object and an entity identifier of any type.
* @tparam Entity Type of entity identifier.
* @param entity Entity identifier with which to compare.
* @param other A null object yet to be converted.
* @return False if the two elements differ, true otherwise.
*/
template<typename Entity>
[[nodiscard]] constexpr bool operator==(const Entity entity, null_t other) ENTT_NOEXCEPT {
return other.operator==(entity);
}
/**
* @brief Compares a null object and an entity identifier of any type.
* @tparam Entity Type of entity identifier.
* @param entity Entity identifier with which to compare.
* @param other A null object yet to be converted.
* @return True if the two elements differ, false otherwise.
*/
template<typename Entity>
[[nodiscard]] constexpr bool operator!=(const Entity entity, null_t other) ENTT_NOEXCEPT {
return !(other == entity);
}
/**
* Internal details not to be documented.
* @endcond
*/
/**
* @brief Compile-time constant for null entities.
*
* There exist implicit conversions from this variable to entity identifiers of
* any allowed type. Similarly, there exist comparision operators between the
* null entity and any other entity identifier.
*/
inline constexpr null_t null{};
}
#endif
// #include "fwd.hpp"
#ifndef ENTT_ENTITY_FWD_HPP
#define ENTT_ENTITY_FWD_HPP
// #include "../core/fwd.hpp"
namespace entt {
template <typename>
class basic_registry;
template<typename...>
class basic_view;
template<typename>
class basic_runtime_view;
template<typename...>
class basic_group;
template<typename>
class basic_observer;
template <typename>
struct basic_actor;
template<typename>
struct basic_handle;
template<typename>
class basic_snapshot;
template<typename>
class basic_snapshot_loader;
template<typename>
class basic_continuous_loader;
/*! @brief Default entity identifier. */
enum class entity: id_type {};
/*! @brief Alias declaration for the most common use case. */
using registry = basic_registry<entity>;
/*! @brief Alias declaration for the most common use case. */
using observer = basic_observer<entity>;
/*! @brief Alias declaration for the most common use case. */
using actor [[deprecated("Consider using the handle class instead")]] = basic_actor<entity>;
/*! @brief Alias declaration for the most common use case. */
using handle = basic_handle<entity>;
/*! @brief Alias declaration for the most common use case. */
using const_handle = basic_handle<const entity>;
/*! @brief Alias declaration for the most common use case. */
using snapshot = basic_snapshot<entity>;
/*! @brief Alias declaration for the most common use case. */
using snapshot_loader = basic_snapshot_loader<entity>;
/*! @brief Alias declaration for the most common use case. */
using continuous_loader = basic_continuous_loader<entity>;
/**
* @brief Alias declaration for the most common use case.
* @tparam Types Types of components iterated by the view.
*/
template<typename... Types>
using view = basic_view<entity, Types...>;
/*! @brief Alias declaration for the most common use case. */
using runtime_view = basic_runtime_view<entity>;
/**
* @brief Alias declaration for the most common use case.
* @tparam Types Types of components iterated by the group.
*/
template<typename... Types>
using group = basic_group<entity, Types...>;
}
#endif
// #include "group.hpp"
#ifndef ENTT_ENTITY_GROUP_HPP
#define ENTT_ENTITY_GROUP_HPP
#include <tuple>
#include <utility>
#include <type_traits>
// #include "../config/config.h"
// #include "../core/type_traits.hpp"
// #include "entity.hpp"
// #include "fwd.hpp"
// #include "pool.hpp"
#ifndef ENTT_ENTITY_POOL_HPP
#define ENTT_ENTITY_POOL_HPP
#include <type_traits>
// #include "storage.hpp"
#ifndef ENTT_ENTITY_STORAGE_HPP
#define ENTT_ENTITY_STORAGE_HPP
#include <algorithm>
#include <iterator>
#include <utility>
#include <vector>
#include <cstddef>
#include <type_traits>
// #include "../config/config.h"
// #include "../core/algorithm.hpp"
// #include "../core/type_traits.hpp"
// #include "entity.hpp"
// #include "sparse_set.hpp"
#ifndef ENTT_ENTITY_SPARSE_SET_HPP
#define ENTT_ENTITY_SPARSE_SET_HPP
#include <iterator>
#include <utility>
#include <vector>
#include <memory>
#include <cstddef>
#include <type_traits>
// #include "../config/config.h"
// #include "../core/algorithm.hpp"
// #include "entity.hpp"
// #include "fwd.hpp"
namespace entt {
/**
* @brief Basic sparse set implementation.
*
* Sparse set or packed array or whatever is the name users give it.<br/>
* Two arrays: an _external_ one and an _internal_ one; a _sparse_ one and a
* _packed_ one; one used for direct access through contiguous memory, the other
* one used to get the data through an extra level of indirection.<br/>
* This is largely used by the registry to offer users the fastest access ever
* to the components. Views and groups in general are almost entirely designed
* around sparse sets.
*
* This type of data structure is widely documented in the literature and on the
* web. This is nothing more than a customized implementation suitable for the
* purpose of the framework.
*
* @note
* Internal data structures arrange elements to maximize performance. There are
* no guarantees that entities are returned in the insertion order when iterate
* a sparse set. Do not make assumption on the order in any case.
*
* @tparam Entity A valid entity type (see entt_traits for more details).
*/
template<typename Entity>
class sparse_set {
static_assert(ENTT_PAGE_SIZE && ((ENTT_PAGE_SIZE & (ENTT_PAGE_SIZE - 1)) == 0), "ENTT_PAGE_SIZE must be a power of two");
static constexpr auto entt_per_page = ENTT_PAGE_SIZE / sizeof(Entity);
using traits_type = entt_traits<Entity>;
using page_type = std::unique_ptr<Entity[]>;
class sparse_set_iterator final {
friend class sparse_set<Entity>;
using packed_type = std::vector<Entity>;
using index_type = typename traits_type::difference_type;
sparse_set_iterator(const packed_type &ref, const index_type idx) ENTT_NOEXCEPT
: packed{&ref}, index{idx}
{}
public:
using difference_type = index_type;
using value_type = Entity;
using pointer = const value_type *;
using reference = const value_type &;
using iterator_category = std::random_access_iterator_tag;
sparse_set_iterator() ENTT_NOEXCEPT = default;
sparse_set_iterator & operator++() ENTT_NOEXCEPT {
return --index, *this;
}
sparse_set_iterator operator++(int) ENTT_NOEXCEPT {
iterator orig = *this;
return ++(*this), orig;
}
sparse_set_iterator & operator--() ENTT_NOEXCEPT {
return ++index, *this;
}
sparse_set_iterator operator--(int) ENTT_NOEXCEPT {
sparse_set_iterator orig = *this;
return operator--(), orig;
}
sparse_set_iterator & operator+=(const difference_type value) ENTT_NOEXCEPT {
index -= value;
return *this;
}
sparse_set_iterator operator+(const difference_type value) const ENTT_NOEXCEPT {
sparse_set_iterator copy = *this;
return (copy += value);
}
sparse_set_iterator & operator-=(const difference_type value) ENTT_NOEXCEPT {
return (*this += -value);
}
sparse_set_iterator operator-(const difference_type value) const ENTT_NOEXCEPT {
return (*this + -value);
}
difference_type operator-(const sparse_set_iterator &other) const ENTT_NOEXCEPT {
return other.index - index;
}
[[nodiscard]] reference operator[](const difference_type value) const {
const auto pos = size_type(index-value-1u);
return (*packed)[pos];
}
[[nodiscard]] bool operator==(const sparse_set_iterator &other) const ENTT_NOEXCEPT {
return other.index == index;
}
[[nodiscard]] bool operator!=(const sparse_set_iterator &other) const ENTT_NOEXCEPT {
return !(*this == other);
}
[[nodiscard]] bool operator<(const sparse_set_iterator &other) const ENTT_NOEXCEPT {
return index > other.index;
}
[[nodiscard]] bool operator>(const sparse_set_iterator &other) const ENTT_NOEXCEPT {
return index < other.index;
}
[[nodiscard]] bool operator<=(const sparse_set_iterator &other) const ENTT_NOEXCEPT {
return !(*this > other);
}
[[nodiscard]] bool operator>=(const sparse_set_iterator &other) const ENTT_NOEXCEPT {
return !(*this < other);
}
[[nodiscard]] pointer operator->() const {
const auto pos = size_type(index-1u);
return &(*packed)[pos];
}
[[nodiscard]] reference operator*() const {
return *operator->();
}
private:
const packed_type *packed;
index_type index;
};
[[nodiscard]] auto page(const Entity entt) const ENTT_NOEXCEPT {
return size_type{(to_integral(entt) & traits_type::entity_mask) / entt_per_page};
}
[[nodiscard]] auto offset(const Entity entt) const ENTT_NOEXCEPT {
return size_type{to_integral(entt) & (entt_per_page - 1)};
}
[[nodiscard]] page_type & assure(const std::size_t pos) {
if(!(pos < sparse.size())) {
sparse.resize(pos+1);
}
if(!sparse[pos]) {
sparse[pos].reset(new entity_type[entt_per_page]);
// null is safe in all cases for our purposes
for(auto *first = sparse[pos].get(), *last = first + entt_per_page; first != last; ++first) {
*first = null;
}
}
return sparse[pos];
}
public:
/*! @brief Underlying entity identifier. */
using entity_type = Entity;
/*! @brief Unsigned integer type. */
using size_type = std::size_t;
/*! @brief Random access iterator type. */
using iterator = sparse_set_iterator;
/*! @brief Reverse iterator type. */
using reverse_iterator = const entity_type *;
/*! @brief Default constructor. */
sparse_set() = default;
/*! @brief Default move constructor. */
sparse_set(sparse_set &&) = default;
/*! @brief Default destructor. */
virtual ~sparse_set() = default;
/*! @brief Default move assignment operator. @return This sparse set. */
sparse_set & operator=(sparse_set &&) = default;
/**
* @brief Increases the capacity of a sparse set.
*
* If the new capacity is greater than the current capacity, new storage is
* allocated, otherwise the method does nothing.
*
* @param cap Desired capacity.
*/
void reserve(const size_type cap) {
packed.reserve(cap);
}
/**
* @brief Returns the number of elements that a sparse set has currently
* allocated space for.
* @return Capacity of the sparse set.
*/
[[nodiscard]] size_type capacity() const ENTT_NOEXCEPT {
return packed.capacity();
}
/*! @brief Requests the removal of unused capacity. */
void shrink_to_fit() {
// conservative approach
if(packed.empty()) {
sparse.clear();
}
sparse.shrink_to_fit();
packed.shrink_to_fit();
}
/**
* @brief Returns the extent of a sparse set.
*
* The extent of a sparse set is also the size of the internal sparse array.
* There is no guarantee that the internal packed array has the same size.
* Usually the size of the internal sparse array is equal or greater than
* the one of the internal packed array.
*
* @return Extent of the sparse set.
*/
[[nodiscard]] size_type extent() const ENTT_NOEXCEPT {
return sparse.size() * entt_per_page;
}
/**
* @brief Returns the number of elements in a sparse set.
*
* The number of elements is also the size of the internal packed array.
* There is no guarantee that the internal sparse array has the same size.
* Usually the size of the internal sparse array is equal or greater than
* the one of the internal packed array.
*
* @return Number of elements.
*/
[[nodiscard]] size_type size() const ENTT_NOEXCEPT {
return packed.size();
}
/**
* @brief Checks whether a sparse set is empty.
* @return True if the sparse set is empty, false otherwise.
*/
[[nodiscard]] bool empty() const ENTT_NOEXCEPT {
return packed.empty();
}
/**
* @brief Direct access to the internal packed array.
*
* The returned pointer is such that range `[data(), data() + size()]` is
* always a valid range, even if the container is empty.
*
* @note
* Entities are in the reverse order as returned by the `begin`/`end`
* iterators.
*
* @return A pointer to the internal packed array.
*/
[[nodiscard]] const entity_type * data() const ENTT_NOEXCEPT {
return packed.data();
}
/**
* @brief Returns an iterator to the beginning.
*
* The returned iterator points to the first entity of the internal packed
* array. If the sparse set is empty, the returned iterator will be equal to
* `end()`.
*
* @return An iterator to the first entity of the internal packed array.
*/
[[nodiscard]] iterator begin() const ENTT_NOEXCEPT {
const typename traits_type::difference_type pos = packed.size();
return iterator{packed, pos};
}
/**
* @brief Returns an iterator to the end.
*
* The returned iterator points to the element following the last entity in
* the internal packed array. Attempting to dereference the returned
* iterator results in undefined behavior.
*
* @return An iterator to the element following the last entity of the
* internal packed array.
*/
[[nodiscard]] iterator end() const ENTT_NOEXCEPT {
return iterator{packed, {}};
}
/**
* @brief Returns a reverse iterator to the beginning.
*
* The returned iterator points to the first entity of the reversed internal
* packed array. If the sparse set is empty, the returned iterator will be
* equal to `rend()`.
*
* @return An iterator to the first entity of the reversed internal packed
* array.
*/
[[nodiscard]] reverse_iterator rbegin() const ENTT_NOEXCEPT {
return packed.data();
}
/**
* @brief Returns a reverse iterator to the end.
*
* The returned iterator points to the element following the last entity in
* the reversed internal packed array. Attempting to dereference the
* returned iterator results in undefined behavior.
*
* @return An iterator to the element following the last entity of the
* reversed internal packed array.
*/
[[nodiscard]] reverse_iterator rend() const ENTT_NOEXCEPT {
return rbegin() + packed.size();
}
/**
* @brief Finds an entity.
* @param entt A valid entity identifier.
* @return An iterator to the given entity if it's found, past the end
* iterator otherwise.
*/
[[nodiscard]] iterator find(const entity_type entt) const {
return contains(entt) ? --(end() - index(entt)) : end();
}
/**
* @brief Checks if a sparse set contains an entity.
* @param entt A valid entity identifier.
* @return True if the sparse set contains the entity, false otherwise.
*/
[[nodiscard]] bool contains(const entity_type entt) const {
const auto curr = page(entt);
// testing against null permits to avoid accessing the packed array
return (curr < sparse.size() && sparse[curr] && sparse[curr][offset(entt)] != null);
}
/**
* @brief Returns the position of an entity in a sparse set.
*
* @warning
* Attempting to get the position of an entity that doesn't belong to the
* sparse set results in undefined behavior.<br/>
* An assertion will abort the execution at runtime in debug mode if the
* sparse set doesn't contain the given entity.
*
* @param entt A valid entity identifier.
* @return The position of the entity in the sparse set.
*/
[[nodiscard]] size_type index(const entity_type entt) const {
ENTT_ASSERT(contains(entt));
return size_type{to_integral(sparse[page(entt)][offset(entt)])};
}
/**
* @brief Assigns an entity to a sparse set.
*
* @warning
* Attempting to assign an entity that already belongs to the sparse set
* results in undefined behavior.<br/>
* An assertion will abort the execution at runtime in debug mode if the
* sparse set already contains the given entity.
*
* @param entt A valid entity identifier.
*/
void emplace(const entity_type entt) {
ENTT_ASSERT(!contains(entt));
assure(page(entt))[offset(entt)] = entity_type(static_cast<typename traits_type::entity_type>(packed.size()));
packed.push_back(entt);
}
/**
* @brief Assigns one or more entities to a sparse set.
*
* @warning
* Attempting to assign an entity that already belongs to the sparse set
* results in undefined behavior.<br/>
* An assertion will abort the execution at runtime in debug mode if the
* sparse set already contains the given entity.
*
* @tparam It Type of input iterator.
* @param first An iterator to the first element of the range of entities.
* @param last An iterator past the last element of the range of entities.
*/
template<typename It>
void insert(It first, It last) {
auto next = static_cast<typename traits_type::entity_type>(packed.size());
packed.insert(packed.end(), first, last);
while(first != last) {
const auto entt = *(first++);
ENTT_ASSERT(!contains(entt));
assure(page(entt))[offset(entt)] = entity_type(next++);
}
}
/**
* @brief Removes an entity from a sparse set.
*
* @warning
* Attempting to remove an entity that doesn't belong to the sparse set
* results in undefined behavior.<br/>
* An assertion will abort the execution at runtime in debug mode if the
* sparse set doesn't contain the given entity.
*
* @param entt A valid entity identifier.
*/
void erase(const entity_type entt) {
ENTT_ASSERT(contains(entt));
const auto curr = page(entt);
const auto pos = offset(entt);
packed[size_type{to_integral(sparse[curr][pos])}] = packed.back();
sparse[page(packed.back())][offset(packed.back())] = sparse[curr][pos];
sparse[curr][pos] = null;
packed.pop_back();
}
/**
* @brief Swaps two entities in the internal packed array.
*
* For what it's worth, this function affects both the internal sparse array
* and the internal packed array. Users should not care of that anyway.
*
* @warning
* Attempting to swap entities that don't belong to the sparse set results
* in undefined behavior.<br/>
* An assertion will abort the execution at runtime in debug mode if the
* sparse set doesn't contain the given entities.
*
* @param lhs A valid entity identifier.
* @param rhs A valid entity identifier.
*/
virtual void swap(const entity_type lhs, const entity_type rhs) {
auto &from = sparse[page(lhs)][offset(lhs)];
auto &to = sparse[page(rhs)][offset(rhs)];
std::swap(packed[size_type{to_integral(from)}], packed[size_type{to_integral(to)}]);
std::swap(from, to);
}
/**
* @brief Sort elements according to the given comparison function.
*
* Sort the elements so that iterating the range with a couple of iterators
* returns them in the expected order. See `begin` and `end` for more
* details.
*
* The comparison function object must return `true` if the first element
* is _less_ than the second one, `false` otherwise. The signature of the
* comparison function should be equivalent to the following:
*
* @code{.cpp}
* bool(const Entity, const Entity);
* @endcode
*
* Moreover, the comparison function object shall induce a
* _strict weak ordering_ on the values.
*
* The sort function oject must offer a member function template
* `operator()` that accepts three arguments:
*
* * An iterator to the first element of the range to sort.
* * An iterator past the last element of the range to sort.
* * A comparison function to use to compare the elements.
*
* @tparam Compare Type of comparison function object.
* @tparam Sort Type of sort function object.
* @tparam Args Types of arguments to forward to the sort function object.
* @param first An iterator to the first element of the range to sort.
* @param last An iterator past the last element of the range to sort.
* @param compare A valid comparison function object.
* @param algo A valid sort function object.
* @param args Arguments to forward to the sort function object, if any.
*/
template<typename Compare, typename Sort = std_sort, typename... Args>
void sort(iterator first, iterator last, Compare compare, Sort algo = Sort{}, Args &&... args) {
ENTT_ASSERT(!(last < first));
ENTT_ASSERT(!(last > end()));
const auto length = std::distance(first, last);
const auto skip = std::distance(last, end());
const auto to = packed.rend() - skip;
const auto from = to - length;
algo(from, to, std::move(compare), std::forward<Args>(args)...);
for(size_type pos = skip, end = skip+length; pos < end; ++pos) {
sparse[page(packed[pos])][offset(packed[pos])] = entity_type(static_cast<typename traits_type::entity_type>(pos));
}
}
/**
* @brief Sort elements according to the given comparison function.
*
* @sa sort
*
* This function is a slightly slower version of `sort` that invokes the
* caller to indicate which entities are swapped.<br/>
* It's recommended when the caller wants to sort its own data structures to
* align them with the order induced in the sparse set.
*
* The signature of the callback should be equivalent to the following:
*
* @code{.cpp}
* bool(const Entity, const Entity);
* @endcode
*
* @tparam Apply Type of function object to invoke to notify the caller.
* @tparam Compare Type of comparison function object.
* @tparam Sort Type of sort function object.
* @tparam Args Types of arguments to forward to the sort function object.
* @param first An iterator to the first element of the range to sort.
* @param last An iterator past the last element of the range to sort.
* @param apply A valid function object to use as a callback.
* @param compare A valid comparison function object.
* @param algo A valid sort function object.
* @param args Arguments to forward to the sort function object, if any.
*/
template<typename Apply, typename Compare, typename Sort = std_sort, typename... Args>
void arrange(iterator first, iterator last, Apply apply, Compare compare, Sort algo = Sort{}, Args &&... args) {
ENTT_ASSERT(!(last < first));
ENTT_ASSERT(!(last > end()));
const auto length = std::distance(first, last);
const auto skip = std::distance(last, end());
const auto to = packed.rend() - skip;
const auto from = to - length;
algo(from, to, std::move(compare), std::forward<Args>(args)...);
for(size_type pos = skip, end = skip+length; pos < end; ++pos) {
auto curr = pos;
auto next = index(packed[curr]);
while(curr != next) {
apply(packed[curr], packed[next]);
sparse[page(packed[curr])][offset(packed[curr])] = entity_type(static_cast<typename traits_type::entity_type>(curr));
curr = next;
next = index(packed[curr]);
}
}
}
/**
* @brief Sort entities according to their order in another sparse set.
*
* Entities that are part of both the sparse sets are ordered internally
* according to the order they have in `other`. All the other entities goes
* to the end of the list and there are no guarantees on their order.<br/>
* In other terms, this function can be used to impose the same order on two
* sets by using one of them as a master and the other one as a slave.
*
* Iterating the sparse set with a couple of iterators returns elements in
* the expected order after a call to `respect`. See `begin` and `end` for
* more details.
*
* @param other The sparse sets that imposes the order of the entities.
*/
void respect(const sparse_set &other) {
const auto to = other.end();
auto from = other.begin();
size_type pos = packed.size() - 1;
while(pos && from != to) {
if(contains(*from)) {
if(*from != packed[pos]) {
swap(packed[pos], *from);
}
--pos;
}
++from;
}
}
/**
* @brief Clears a sparse set.
*/
void clear() ENTT_NOEXCEPT {
sparse.clear();
packed.clear();
}
private:
std::vector<page_type> sparse;
std::vector<entity_type> packed;
};
}
#endif
namespace entt {
/**
* @brief Basic storage implementation.
*
* This class is a refinement of a sparse set that associates an object to an
* entity. The main purpose of this class is to extend sparse sets to store
* components in a registry. It guarantees fast access both to the elements and
* to the entities.
*
* @note
* Entities and objects have the same order. It's guaranteed both in case of raw
* access (either to entities or objects) and when using random or input access
* iterators.
*
* @note
* Internal data structures arrange elements to maximize performance. There are
* no guarantees that objects are returned in the insertion order when iterate
* a storage. Do not make assumption on the order in any case.
*
* @warning
* Empty types aren't explicitly instantiated. Therefore, many of the functions
* normally available for non-empty types will not be available for empty ones.
*
* @sa sparse_set<Entity>
*
* @tparam Entity A valid entity type (see entt_traits for more details).
* @tparam Type Type of objects assigned to the entities.
*/
template<typename Entity, typename Type, typename = std::void_t<>>
class storage: public sparse_set<Entity> {
static_assert(std::is_move_constructible_v<Type> && std::is_move_assignable_v<Type>, "The managed type must be at least move constructible and assignable");
using underlying_type = sparse_set<Entity>;
using traits_type = entt_traits<Entity>;
template<bool Const>
class storage_iterator final {
friend class storage<Entity, Type>;
using instance_type = std::conditional_t<Const, const std::vector<Type>, std::vector<Type>>;
using index_type = typename traits_type::difference_type;
storage_iterator(instance_type &ref, const index_type idx) ENTT_NOEXCEPT
: instances{&ref}, index{idx}
{}
public:
using difference_type = index_type;
using value_type = Type;
using pointer = std::conditional_t<Const, const value_type *, value_type *>;
using reference = std::conditional_t<Const, const value_type &, value_type &>;
using iterator_category = std::random_access_iterator_tag;
storage_iterator() ENTT_NOEXCEPT = default;
storage_iterator & operator++() ENTT_NOEXCEPT {
return --index, *this;
}
storage_iterator operator++(int) ENTT_NOEXCEPT {
storage_iterator orig = *this;
return ++(*this), orig;
}
storage_iterator & operator--() ENTT_NOEXCEPT {
return ++index, *this;
}
storage_iterator operator--(int) ENTT_NOEXCEPT {
storage_iterator orig = *this;
return operator--(), orig;
}
storage_iterator & operator+=(const difference_type value) ENTT_NOEXCEPT {
index -= value;
return *this;
}
storage_iterator operator+(const difference_type value) const ENTT_NOEXCEPT {
storage_iterator copy = *this;
return (copy += value);
}
storage_iterator & operator-=(const difference_type value) ENTT_NOEXCEPT {
return (*this += -value);
}
storage_iterator operator-(const difference_type value) const ENTT_NOEXCEPT {
return (*this + -value);
}
difference_type operator-(const storage_iterator &other) const ENTT_NOEXCEPT {
return other.index - index;
}
[[nodiscard]] reference operator[](const difference_type value) const ENTT_NOEXCEPT {
const auto pos = size_type(index-value-1);
return (*instances)[pos];
}
[[nodiscard]] bool operator==(const storage_iterator &other) const ENTT_NOEXCEPT {
return other.index == index;
}
[[nodiscard]] bool operator!=(const storage_iterator &other) const ENTT_NOEXCEPT {
return !(*this == other);
}
[[nodiscard]] bool operator<(const storage_iterator &other) const ENTT_NOEXCEPT {
return index > other.index;
}
[[nodiscard]] bool operator>(const storage_iterator &other) const ENTT_NOEXCEPT {
return index < other.index;
}
[[nodiscard]] bool operator<=(const storage_iterator &other) const ENTT_NOEXCEPT {
return !(*this > other);
}
[[nodiscard]] bool operator>=(const storage_iterator &other) const ENTT_NOEXCEPT {
return !(*this < other);
}
[[nodiscard]] pointer operator->() const ENTT_NOEXCEPT {
const auto pos = size_type(index-1u);
return &(*instances)[pos];
}
[[nodiscard]] reference operator*() const ENTT_NOEXCEPT {
return *operator->();
}
private:
instance_type *instances;
index_type index;
};
public:
/*! @brief Type of the objects associated with the entities. */
using object_type = Type;
/*! @brief Underlying entity identifier. */
using entity_type = Entity;
/*! @brief Unsigned integer type. */
using size_type = std::size_t;
/*! @brief Random access iterator type. */
using iterator = storage_iterator<false>;
/*! @brief Constant random access iterator type. */
using const_iterator = storage_iterator<true>;
/*! @brief Reverse iterator type. */
using reverse_iterator = Type *;
/*! @brief Constant reverse iterator type. */
using const_reverse_iterator = const Type *;
/**
* @brief Increases the capacity of a storage.
*
* If the new capacity is greater than the current capacity, new storage is
* allocated, otherwise the method does nothing.
*
* @param cap Desired capacity.
*/
void reserve(const size_type cap) {
underlying_type::reserve(cap);
instances.reserve(cap);
}
/*! @brief Requests the removal of unused capacity. */
void shrink_to_fit() {
underlying_type::shrink_to_fit();
instances.shrink_to_fit();
}
/**
* @brief Direct access to the array of objects.
*
* The returned pointer is such that range `[raw(), raw() + size()]` is
* always a valid range, even if the container is empty.
*
* @note
* Objects are in the reverse order as returned by the `begin`/`end`
* iterators.
*
* @return A pointer to the array of objects.
*/
[[nodiscard]] const object_type * raw() const ENTT_NOEXCEPT {
return instances.data();
}
/*! @copydoc raw */
[[nodiscard]] object_type * raw() ENTT_NOEXCEPT {
return const_cast<object_type *>(std::as_const(*this).raw());
}
/**
* @brief Returns an iterator to the beginning.
*
* The returned iterator points to the first instance of the internal array.
* If the storage is empty, the returned iterator will be equal to `end()`.
*
* @return An iterator to the first instance of the internal array.
*/
[[nodiscard]] const_iterator cbegin() const ENTT_NOEXCEPT {
const typename traits_type::difference_type pos = underlying_type::size();
return const_iterator{instances, pos};
}
/*! @copydoc cbegin */
[[nodiscard]] const_iterator begin() const ENTT_NOEXCEPT {
return cbegin();
}
/*! @copydoc begin */
[[nodiscard]] iterator begin() ENTT_NOEXCEPT {
const typename traits_type::difference_type pos = underlying_type::size();
return iterator{instances, pos};
}
/**
* @brief Returns an iterator to the end.
*
* The returned iterator points to the element following the last instance
* of the internal array. Attempting to dereference the returned iterator
* results in undefined behavior.
*
* @return An iterator to the element following the last instance of the
* internal array.
*/
[[nodiscard]] const_iterator cend() const ENTT_NOEXCEPT {
return const_iterator{instances, {}};
}
/*! @copydoc cend */
[[nodiscard]] const_iterator end() const ENTT_NOEXCEPT {
return cend();
}
/*! @copydoc end */
[[nodiscard]] iterator end() ENTT_NOEXCEPT {
return iterator{instances, {}};
}
/**
* @brief Returns a reverse iterator to the beginning.
*
* The returned iterator points to the first instance of the reversed
* internal array. If the storage is empty, the returned iterator will be
* equal to `rend()`.
*
* @return An iterator to the first instance of the reversed internal array.
*/
[[nodiscard]] const_reverse_iterator crbegin() const ENTT_NOEXCEPT {
return instances.data();
}
/*! @copydoc crbegin */
[[nodiscard]] const_reverse_iterator rbegin() const ENTT_NOEXCEPT {
return crbegin();
}
/*! @copydoc rbegin */
[[nodiscard]] reverse_iterator rbegin() ENTT_NOEXCEPT {
return instances.data();
}
/**
* @brief Returns a reverse iterator to the end.
*
* The returned iterator points to the element following the last instance
* of the reversed internal array. Attempting to dereference the returned
* iterator results in undefined behavior.
*
* @return An iterator to the element following the last instance of the
* reversed internal array.
*/
[[nodiscard]] const_reverse_iterator crend() const ENTT_NOEXCEPT {
return crbegin() + instances.size();
}
/*! @copydoc crend */
[[nodiscard]] const_reverse_iterator rend() const ENTT_NOEXCEPT {
return crend();
}
/*! @copydoc rend */
[[nodiscard]] reverse_iterator rend() ENTT_NOEXCEPT {
return rbegin() + instances.size();
}
/**
* @brief Returns the object associated with an entity.
*
* @warning
* Attempting to use an entity that doesn't belong to the storage results in
* undefined behavior.<br/>
* An assertion will abort the execution at runtime in debug mode if the
* storage doesn't contain the given entity.
*
* @param entt A valid entity identifier.
* @return The object associated with the entity.
*/
[[nodiscard]] const object_type & get(const entity_type entt) const {
return instances[underlying_type::index(entt)];
}
/*! @copydoc get */
[[nodiscard]] object_type & get(const entity_type entt) {
return const_cast<object_type &>(std::as_const(*this).get(entt));
}
/**
* @brief Returns a pointer to the object associated with an entity, if any.
* @param entt A valid entity identifier.
* @return The object associated with the entity, if any.
*/
[[nodiscard]] const object_type * try_get(const entity_type entt) const {
return underlying_type::contains(entt) ? (instances.data() + underlying_type::index(entt)) : nullptr;
}
/*! @copydoc try_get */
[[nodiscard]] object_type * try_get(const entity_type entt) {
return const_cast<object_type *>(std::as_const(*this).try_get(entt));
}
/**
* @brief Assigns an entity to a storage and constructs its object.
*
* This version accept both types that can be constructed in place directly
* and types like aggregates that do not work well with a placement new as
* performed usually under the hood during an _emplace back_.
*
* @warning
* Attempting to use an entity that already belongs to the storage results
* in undefined behavior.<br/>
* An assertion will abort the execution at runtime in debug mode if the
* storage already contains the given entity.
*
* @tparam Args Types of arguments to use to construct the object.
* @param entt A valid entity identifier.
* @param args Parameters to use to construct an object for the entity.
*/
template<typename... Args>
void emplace(const entity_type entt, Args &&... args) {
if constexpr(std::is_aggregate_v<object_type>) {
instances.push_back(Type{std::forward<Args>(args)...});
} else {
instances.emplace_back(std::forward<Args>(args)...);
}
// entity goes after component in case constructor throws
underlying_type::emplace(entt);
}
/**
* @brief Assigns one or more entities to a storage and constructs their
* objects from a given instance.
*
* @warning
* Attempting to assign an entity that already belongs to the storage
* results in undefined behavior.<br/>
* An assertion will abort the execution at runtime in debug mode if the
* storage already contains the given entity.
*
* @tparam It Type of input iterator.
* @param first An iterator to the first element of the range of entities.
* @param last An iterator past the last element of the range of entities.
* @param value An instance of the object to construct.
*/
template<typename It>
void insert(It first, It last, const object_type &value = {}) {
instances.insert(instances.end(), std::distance(first, last), value);
// entities go after components in case constructors throw
underlying_type::insert(first, last);
}
/**
* @brief Assigns one or more entities to a storage and constructs their
* objects from a given range.
*
* @sa construct
*
* @tparam EIt Type of input iterator.
* @tparam CIt Type of input iterator.
* @param first An iterator to the first element of the range of entities.
* @param last An iterator past the last element of the range of entities.
* @param from An iterator to the first element of the range of objects.
* @param to An iterator past the last element of the range of objects.
*/
template<typename EIt, typename CIt>
void insert(EIt first, EIt last, CIt from, CIt to) {
instances.insert(instances.end(), from, to);
// entities go after components in case constructors throw
underlying_type::insert(first, last);
}
/**
* @brief Removes an entity from a storage and destroys its object.
*
* @warning
* Attempting to use an entity that doesn't belong to the storage results in
* undefined behavior.<br/>
* An assertion will abort the execution at runtime in debug mode if the
* storage doesn't contain the given entity.
*
* @param entt A valid entity identifier.
*/
void erase(const entity_type entt) {
auto other = std::move(instances.back());
instances[underlying_type::index(entt)] = std::move(other);
instances.pop_back();
underlying_type::erase(entt);
}
/**
* @brief Swaps entities and objects in the internal packed arrays.
*
* @warning
* Attempting to swap entities that don't belong to the sparse set results
* in undefined behavior.<br/>
* An assertion will abort the execution at runtime in debug mode if the
* sparse set doesn't contain the given entities.
*
* @param lhs A valid entity identifier.
* @param rhs A valid entity identifier.
*/
void swap(const entity_type lhs, const entity_type rhs) override {
std::swap(instances[underlying_type::index(lhs)], instances[underlying_type::index(rhs)]);
underlying_type::swap(lhs, rhs);
}
/**
* @brief Sort elements according to the given comparison function.
*
* Sort the elements so that iterating the range with a couple of iterators
* returns them in the expected order. See `begin` and `end` for more
* details.
*
* The comparison function object must return `true` if the first element
* is _less_ than the second one, `false` otherwise. The signature of the
* comparison function should be equivalent to one of the following:
*
* @code{.cpp}
* bool(const Entity, const Entity);
* bool(const Type &, const Type &);
* @endcode
*
* Moreover, the comparison function object shall induce a
* _strict weak ordering_ on the values.
*
* The sort function oject must offer a member function template
* `operator()` that accepts three arguments:
*
* * An iterator to the first element of the range to sort.
* * An iterator past the last element of the range to sort.
* * A comparison function to use to compare the elements.
*
* @warning
* Empty types are never instantiated. Therefore, only comparison function
* objects that require to return entities rather than components are
* accepted.
*
* @tparam Compare Type of comparison function object.
* @tparam Sort Type of sort function object.
* @tparam Args Types of arguments to forward to the sort function object.
* @param first An iterator to the first element of the range to sort.
* @param last An iterator past the last element of the range to sort.
* @param compare A valid comparison function object.
* @param algo A valid sort function object.
* @param args Arguments to forward to the sort function object, if any.
*/
template<typename Compare, typename Sort = std_sort, typename... Args>
void sort(iterator first, iterator last, Compare compare, Sort algo = Sort{}, Args &&... args) {
ENTT_ASSERT(!(last < first));
ENTT_ASSERT(!(last > end()));
const auto from = underlying_type::begin() + std::distance(begin(), first);
const auto to = from + std::distance(first, last);
const auto apply = [this](const auto lhs, const auto rhs) {
std::swap(instances[underlying_type::index(lhs)], instances[underlying_type::index(rhs)]);
};
if constexpr(std::is_invocable_v<Compare, const object_type &, const object_type &>) {
underlying_type::arrange(from, to, std::move(apply), [this, compare = std::move(compare)](const auto lhs, const auto rhs) {
return compare(std::as_const(instances[underlying_type::index(lhs)]), std::as_const(instances[underlying_type::index(rhs)]));
}, std::move(algo), std::forward<Args>(args)...);
} else {
underlying_type::arrange(from, to, std::move(apply), std::move(compare), std::move(algo), std::forward<Args>(args)...);
}
}
/*! @brief Clears a storage. */
void clear() {
underlying_type::clear();
instances.clear();
}
private:
std::vector<object_type> instances;
};
/*! @copydoc storage */
template<typename Entity, typename Type>
class storage<Entity, Type, std::enable_if_t<is_eto_eligible_v<Type>>>: public sparse_set<Entity> {
using underlying_type = sparse_set<Entity>;
public:
/*! @brief Type of the objects associated with the entities. */
using object_type = Type;
/*! @brief Underlying entity identifier. */
using entity_type = Entity;
/*! @brief Unsigned integer type. */
using size_type = std::size_t;
/**
* @brief Assigns an entity to a storage and constructs its object.
*
* @warning
* Attempting to use an entity that already belongs to the storage results
* in undefined behavior.<br/>
* An assertion will abort the execution at runtime in debug mode if the
* storage already contains the given entity.
*
* @tparam Args Types of arguments to use to construct the object.
* @param entt A valid entity identifier.
* @param args Parameters to use to construct an object for the entity.
*/
template<typename... Args>
void emplace(const entity_type entt, Args &&... args) {
[[maybe_unused]] object_type instance{std::forward<Args>(args)...};
underlying_type::emplace(entt);
}
/**
* @brief Assigns one or more entities to a storage.
*
* @warning
* Attempting to assign an entity that already belongs to the storage
* results in undefined behavior.<br/>
* An assertion will abort the execution at runtime in debug mode if the
* storage already contains the given entity.
*
* @tparam It Type of input iterator.
* @param first An iterator to the first element of the range of entities.
* @param last An iterator past the last element of the range of entities.
*/
template<typename It>
void insert(It first, It last, const object_type & = {}) {
underlying_type::insert(first, last);
}
};
}
#endif
namespace entt {
/**
* @brief Applies component-to-pool conversion and defines the resulting type as
* the member typedef type.
*
* Formally:
*
* * If the component type is a non-const one, the member typedef type is the
* declared storage type.
* * If the component type is a const one, the member typedef type is the
* declared storage type, except it has a const-qualifier added.
*
* @tparam Entity A valid entity type (see entt_traits for more details).
* @tparam Type Type of objects assigned to the entities.
*/
template<typename Entity, typename Type, typename = void>
struct pool {
/*! @brief Resulting type after component-to-pool conversion. */
using type = storage<Entity, Type>;
};
/*! @copydoc pool */
template<typename Entity, typename Type>
struct pool<Entity, const Type> {
/*! @brief Resulting type after component-to-pool conversion. */
using type = std::add_const_t<typename pool<Entity, std::remove_const_t<Type>>::type>;
};
/**
* @brief Alias declaration to use to make component-to-pool conversions.
* @tparam Entity A valid entity type (see entt_traits for more details).
* @tparam Type Type of objects assigned to the entities.
*/
template<typename Entity, typename Type>
using pool_t = typename pool<Entity, Type>::type;
}
#endif
// #include "sparse_set.hpp"
// #include "utility.hpp"
#ifndef ENTT_ENTITY_UTILITY_HPP
#define ENTT_ENTITY_UTILITY_HPP
// #include "../core/type_traits.hpp"
namespace entt {
/**
* @brief Alias for exclusion lists.
* @tparam Type List of types.
*/
template<typename... Type>
struct exclude_t: type_list<Type...> {};
/**
* @brief Variable template for exclusion lists.
* @tparam Type List of types.
*/
template<typename... Type>
inline constexpr exclude_t<Type...> exclude{};
/**
* @brief Alias for lists of observed components.
* @tparam Type List of types.
*/
template<typename... Type>
struct get_t: type_list<Type...>{};
/**
* @brief Variable template for lists of observed components.
* @tparam Type List of types.
*/
template<typename... Type>
inline constexpr get_t<Type...> get{};
}
#endif
namespace entt {
/**
* @brief Group.
*
* Primary template isn't defined on purpose. All the specializations give a
* compile-time error, but for a few reasonable cases.
*/
template<typename...>
class basic_group;
/**
* @brief Non-owning group.
*
* A non-owning group returns all entities and only the entities that have at
* least the given components. Moreover, it's guaranteed that the entity list
* is tightly packed in memory for fast iterations.
*
* @b Important
*
* Iterators aren't invalidated if:
*
* * New instances of the given components are created and assigned to entities.
* * The entity currently pointed is modified (as an example, if one of the
* given components is removed from the entity to which the iterator points).
* * The entity currently pointed is destroyed.
*
* In all other cases, modifying the pools iterated by the group in any way
* invalidates all the iterators and using them results in undefined behavior.
*
* @note
* Groups share references to the underlying data structures of the registry
* that generated them. Therefore any change to the entities and to the
* components made by means of the registry are immediately reflected by all the
* groups.<br/>
* Moreover, sorting a non-owning group affects all the instances of the same
* group (it means that users don't have to call `sort` on each instance to sort
* all of them because they _share_ entities and components).
*
* @warning
* Lifetime of a group must not overcome that of the registry that generated it.
* In any other case, attempting to use a group results in undefined behavior.
*
* @tparam Entity A valid entity type (see entt_traits for more details).
* @tparam Exclude Types of components used to filter the group.
* @tparam Get Type of components observed by the group.
*/
template<typename Entity, typename... Exclude, typename... Get>
class basic_group<Entity, exclude_t<Exclude...>, get_t<Get...>> {
/*! @brief A registry is allowed to create groups. */
friend class basic_registry<Entity>;
template<typename Component>
using pool_type = pool_t<Entity, Component>;
class group_proxy {
friend class basic_group<Entity, exclude_t<Exclude...>, get_t<Get...>>;
class proxy_iterator {
friend class group_proxy;
using it_type = typename sparse_set<Entity>::iterator;
using ref_type = decltype(std::tuple_cat(std::declval<std::conditional_t<is_eto_eligible_v<Get>, std::tuple<>, std::tuple<pool_type<Get> *>>>()...));
proxy_iterator(it_type from, ref_type ref) ENTT_NOEXCEPT
: it{from},
pools{ref}
{}
public:
using difference_type = std::ptrdiff_t;
using value_type = decltype(std::tuple_cat(
std::declval<std::tuple<Entity>>(),
std::declval<std::conditional_t<is_eto_eligible_v<Get>, std::tuple<>, std::tuple<Get>>>()...
));
using pointer = void;
using reference = decltype(std::tuple_cat(
std::declval<std::tuple<Entity>>(),
std::declval<std::conditional_t<is_eto_eligible_v<Get>, std::tuple<>, std::tuple<Get &>>>()...
));
using iterator_category = std::input_iterator_tag;
proxy_iterator & operator++() ENTT_NOEXCEPT {
return ++it, *this;
}
proxy_iterator operator++(int) ENTT_NOEXCEPT {
proxy_iterator orig = *this;
return ++(*this), orig;
}
[[nodiscard]] reference operator*() const ENTT_NOEXCEPT {
return std::apply([entt = *it](auto *... cpool) { return reference{entt, cpool->get(entt)...}; }, pools);
}
[[nodiscard]] bool operator==(const proxy_iterator &other) const ENTT_NOEXCEPT {
return other.it == it;
}
[[nodiscard]] bool operator!=(const proxy_iterator &other) const ENTT_NOEXCEPT {
return !(*this == other);
}
private:
it_type it{};
ref_type pools{};
};
group_proxy(const sparse_set<Entity> &ref, std::tuple<pool_type<Get> *...> gpools)
: handler{&ref},
pools{gpools}
{}
public:
using iterator = proxy_iterator;
[[nodiscard]] iterator begin() const ENTT_NOEXCEPT {
return proxy_iterator{handler->begin(), std::tuple_cat([](auto *cpool) {
if constexpr(is_eto_eligible_v<typename std::decay_t<decltype(*cpool)>::object_type>) {
return std::make_tuple();
} else {
return std::make_tuple(cpool);
}
}(std::get<pool_type<Get> *>(pools))...)};
}
[[nodiscard]] iterator end() const ENTT_NOEXCEPT {
return proxy_iterator{handler->end(), std::tuple_cat([](auto *cpool) {
if constexpr(is_eto_eligible_v<typename std::decay_t<decltype(*cpool)>::object_type>) {
return std::make_tuple();
} else {
return std::make_tuple(cpool);
}
}(std::get<pool_type<Get> *>(pools))...)};
}
private:
const sparse_set<Entity> *handler;
std::tuple<pool_type<Get> *...> pools;
};
basic_group(sparse_set<Entity> &ref, pool_type<Get> &... gpool) ENTT_NOEXCEPT
: handler{&ref},
pools{&gpool...}
{}
template<typename Func, typename... Weak>
void traverse(Func func, type_list<Weak...>) const {
for(const auto entt: *handler) {
if constexpr(std::is_invocable_v<Func, decltype(get<Weak>({}))...>) {
func(std::get<pool_type<Weak> *>(pools)->get(entt)...);
} else {
func(entt, std::get<pool_type<Weak> *>(pools)->get(entt)...);
}
}
}
public:
/*! @brief Underlying entity identifier. */
using entity_type = Entity;
/*! @brief Unsigned integer type. */
using size_type = std::size_t;
/*! @brief Random access iterator type. */
using iterator = typename sparse_set<Entity>::iterator;
/*! @brief Reversed iterator type. */
using reverse_iterator = typename sparse_set<Entity>::reverse_iterator;
/**
* @brief Returns the number of existing components of the given type.
* @tparam Component Type of component of which to return the size.
* @return Number of existing components of the given type.
*/
template<typename Component>
[[nodiscard]] size_type size() const ENTT_NOEXCEPT {
return std::get<pool_type<Component> *>(pools)->size();
}
/**
* @brief Returns the number of entities that have the given components.
* @return Number of entities that have the given components.
*/
[[nodiscard]] size_type size() const ENTT_NOEXCEPT {
return handler->size();
}
/**
* @brief Returns the number of elements that a group has currently
* allocated space for.
* @return Capacity of the group.
*/
[[nodiscard]] size_type capacity() const ENTT_NOEXCEPT {
return handler->capacity();
}
/*! @brief Requests the removal of unused capacity. */
void shrink_to_fit() {
handler->shrink_to_fit();
}
/**
* @brief Checks whether a group or some pools are empty.
* @tparam Component Types of components in which one is interested.
* @return True if the group or the pools are empty, false otherwise.
*/
template<typename... Component>
[[nodiscard]] bool empty() const ENTT_NOEXCEPT {
if constexpr(sizeof...(Component) == 0) {
return handler->empty();
} else {
return (std::get<pool_type<Component> *>(pools)->empty() && ...);
}
}
/**
* @brief Direct access to the list of components of a given pool.
*
* The returned pointer is such that range
* `[raw<Component>(), raw<Component>() + size<Component>()]` is always a
* valid range, even if the container is empty.
*
* @note
* Components are in the reverse order as returned by the `begin`/`end`
* iterators.
*
* @tparam Component Type of component in which one is interested.
* @return A pointer to the array of components.
*/
template<typename Component>
[[nodiscard]] Component * raw() const ENTT_NOEXCEPT {
return std::get<pool_type<Component> *>(pools)->raw();
}
/**
* @brief Direct access to the list of entities of a given pool.
*
* The returned pointer is such that range
* `[data<Component>(), data<Component>() + size<Component>()]` is always a
* valid range, even if the container is empty.
*
* @note
* Entities are in the reverse order as returned by the `begin`/`end`
* iterators.
*
* @tparam Component Type of component in which one is interested.
* @return A pointer to the array of entities.
*/
template<typename Component>
[[nodiscard]] const entity_type * data() const ENTT_NOEXCEPT {
return std::get<pool_type<Component> *>(pools)->data();
}
/**
* @brief Direct access to the list of entities.
*
* The returned pointer is such that range `[data(), data() + size()]` is
* always a valid range, even if the container is empty.
*
* @note
* Entities are in the reverse order as returned by the `begin`/`end`
* iterators.
*
* @return A pointer to the array of entities.
*/
[[nodiscard]] const entity_type * data() const ENTT_NOEXCEPT {
return handler->data();
}
/**
* @brief Returns an iterator to the first entity of the group.
*
* The returned iterator points to the first entity of the group. If the
* group is empty, the returned iterator will be equal to `end()`.
*
* @note
* Iterators stay true to the order imposed to the underlying data
* structures.
*
* @return An iterator to the first entity of the group.
*/
[[nodiscard]] iterator begin() const ENTT_NOEXCEPT {
return handler->begin();
}
/**
* @brief Returns an iterator that is past the last entity of the group.
*
* The returned iterator points to the entity following the last entity of
* the group. Attempting to dereference the returned iterator results in
* undefined behavior.
*
* @note
* Iterators stay true to the order imposed to the underlying data
* structures.
*
* @return An iterator to the entity following the last entity of the
* group.
*/
[[nodiscard]] iterator end() const ENTT_NOEXCEPT {
return handler->end();
}
/**
* @brief Returns an iterator to the first entity of the reversed group.
*
* The returned iterator points to the first entity of the reversed group.
* If the group is empty, the returned iterator will be equal to `rend()`.
*
* @note
* Iterators stay true to the order imposed to the underlying data
* structures.
*
* @return An iterator to the first entity of the reversed group.
*/
[[nodiscard]] reverse_iterator rbegin() const ENTT_NOEXCEPT {
return handler->rbegin();
}
/**
* @brief Returns an iterator that is past the last entity of the reversed
* group.
*
* The returned iterator points to the entity following the last entity of
* the reversed group. Attempting to dereference the returned iterator
* results in undefined behavior.
*
* @note
* Iterators stay true to the order imposed to the underlying data
* structures.
*
* @return An iterator to the entity following the last entity of the
* reversed group.
*/
[[nodiscard]] reverse_iterator rend() const ENTT_NOEXCEPT {
return handler->rend();
}
/**
* @brief Returns the first entity of the group, if any.
* @return The first entity of the group if one exists, the null entity
* otherwise.
*/
[[nodiscard]] entity_type front() const {
const auto it = begin();
return it != end() ? *it : null;
}
/**
* @brief Returns the last entity of the group, if any.
* @return The last entity of the group if one exists, the null entity
* otherwise.
*/
[[nodiscard]] entity_type back() const {
const auto it = rbegin();
return it != rend() ? *it : null;
}
/**
* @brief Finds an entity.
* @param entt A valid entity identifier.
* @return An iterator to the given entity if it's found, past the end
* iterator otherwise.
*/
[[nodiscard]] iterator find(const entity_type entt) const {
const auto it = handler->find(entt);
return it != end() && *it == entt ? it : end();
}
/**
* @brief Returns the identifier that occupies the given position.
* @param pos Position of the element to return.
* @return The identifier that occupies the given position.
*/
[[nodiscard]] entity_type operator[](const size_type pos) const {
return begin()[pos];
}
/**
* @brief Checks if a group contains an entity.
* @param entt A valid entity identifier.
* @return True if the group contains the given entity, false otherwise.
*/
[[nodiscard]] bool contains(const entity_type entt) const {
return handler->contains(entt);
}
/**
* @brief Returns the components assigned to the given entity.
*
* Prefer this function instead of `registry::get` during iterations. It has
* far better performance than its counterpart.
*
* @warning
* Attempting to use an invalid component type results in a compilation
* error. Attempting to use an entity that doesn't belong to the group
* results in undefined behavior.<br/>
* An assertion will abort the execution at runtime in debug mode if the
* group doesn't contain the given entity.
*
* @tparam Component Types of components to get.
* @param entt A valid entity identifier.
* @return The components assigned to the entity.
*/
template<typename... Component>
[[nodiscard]] decltype(auto) get([[maybe_unused]] const entity_type entt) const {
ENTT_ASSERT(contains(entt));
if constexpr(sizeof...(Component) == 1) {
return (std::get<pool_type<Component> *>(pools)->get(entt), ...);
} else {
return std::tuple<decltype(get<Component>({}))...>{get<Component>(entt)...};
}
}
/**
* @brief Iterates entities and components and applies the given function
* object to them.
*
* The function object is invoked for each entity. It is provided with the
* entity itself and a set of references to non-empty components. The
* _constness_ of the components is as requested.<br/>
* The signature of the function must be equivalent to one of the following
* forms:
*
* @code{.cpp}
* void(const entity_type, Type &...);
* void(Type &...);
* @endcode
*
* @note
* Empty types aren't explicitly instantiated and therefore they are never
* returned during iterations.
*
* @tparam Func Type of the function object to invoke.
* @param func A valid function object.
*/
template<typename Func>
void each(Func func) const {
using get_type_list = type_list_cat_t<std::conditional_t<is_eto_eligible_v<Get>, type_list<>, type_list<Get>>...>;
traverse(std::move(func), get_type_list{});
}
/**
* @brief Returns an iterable object to use to _visit_ the group.
*
* The iterable object returns tuples that contain the current entity and a
* set of references to its non-empty components. The _constness_ of the
* components is as requested.
*
* @note
* Empty types aren't explicitly instantiated and therefore they are never
* returned during iterations.
*
* @return An iterable object to use to _visit_ the group.
*/
[[nodiscard]] auto proxy() const ENTT_NOEXCEPT {
return group_proxy{*handler, pools};
}
/**
* @brief Sort a group according to the given comparison function.
*
* Sort the group so that iterating it with a couple of iterators returns
* entities and components in the expected order. See `begin` and `end` for
* more details.
*
* The comparison function object must return `true` if the first element
* is _less_ than the second one, `false` otherwise. The signature of the
* comparison function should be equivalent to one of the following:
*
* @code{.cpp}
* bool(std::tuple<Component &...>, std::tuple<Component &...>);
* bool(const Component &..., const Component &...);
* bool(const Entity, const Entity);
* @endcode
*
* Where `Component` are such that they are iterated by the group.<br/>
* Moreover, the comparison function object shall induce a
* _strict weak ordering_ on the values.
*
* The sort function oject must offer a member function template
* `operator()` that accepts three arguments:
*
* * An iterator to the first element of the range to sort.
* * An iterator past the last element of the range to sort.
* * A comparison function to use to compare the elements.
*
* @tparam Component Optional types of components to compare.
* @tparam Compare Type of comparison function object.
* @tparam Sort Type of sort function object.
* @tparam Args Types of arguments to forward to the sort function object.
* @param compare A valid comparison function object.
* @param algo A valid sort function object.
* @param args Arguments to forward to the sort function object, if any.
*/
template<typename... Component, typename Compare, typename Sort = std_sort, typename... Args>
void sort(Compare compare, Sort algo = Sort{}, Args &&... args) {
if constexpr(sizeof...(Component) == 0) {
static_assert(std::is_invocable_v<Compare, const entity_type, const entity_type>, "Invalid comparison function");
handler->sort(handler->begin(), handler->end(), std::move(compare), std::move(algo), std::forward<Args>(args)...);
} else if constexpr(sizeof...(Component) == 1) {
handler->sort(handler->begin(), handler->end(), [this, compare = std::move(compare)](const entity_type lhs, const entity_type rhs) {
return compare((std::get<pool_type<Component> *>(pools)->get(lhs), ...), (std::get<pool_type<Component> *>(pools)->get(rhs), ...));
}, std::move(algo), std::forward<Args>(args)...);
} else {
handler->sort(handler->begin(), handler->end(), [this, compare = std::move(compare)](const entity_type lhs, const entity_type rhs) {
return compare(std::tuple<decltype(get<Component>({}))...>{std::get<pool_type<Component> *>(pools)->get(lhs)...}, std::tuple<decltype(get<Component>({}))...>{std::get<pool_type<Component> *>(pools)->get(rhs)...});
}, std::move(algo), std::forward<Args>(args)...);
}
}
/**
* @brief Sort the shared pool of entities according to the given component.
*
* Non-owning groups of the same type share with the registry a pool of
* entities with its own order that doesn't depend on the order of any pool
* of components. Users can order the underlying data structure so that it
* respects the order of the pool of the given component.
*
* @note
* The shared pool of entities and thus its order is affected by the changes
* to each and every pool that it tracks. Therefore changes to those pools
* can quickly ruin the order imposed to the pool of entities shared between
* the non-owning groups.
*
* @tparam Component Type of component to use to impose the order.
*/
template<typename Component>
void sort() const {
handler->respect(*std::get<pool_type<Component> *>(pools));
}
private:
sparse_set<entity_type> *handler;
const std::tuple<pool_type<Get> *...> pools;
};
/**
* @brief Owning group.
*
* Owning groups return all entities and only the entities that have at least
* the given components. Moreover:
*
* * It's guaranteed that the entity list is tightly packed in memory for fast
* iterations.
* * It's guaranteed that the lists of owned components are tightly packed in
* memory for even faster iterations and to allow direct access.
* * They stay true to the order of the owned components and all instances have
* the same order in memory.
*
* The more types of components are owned by a group, the faster it is to
* iterate them.
*
* @b Important
*
* Iterators aren't invalidated if:
*
* * New instances of the given components are created and assigned to entities.
* * The entity currently pointed is modified (as an example, if one of the
* given components is removed from the entity to which the iterator points).
* * The entity currently pointed is destroyed.
*
* In all other cases, modifying the pools iterated by the group in any way
* invalidates all the iterators and using them results in undefined behavior.
*
* @note
* Groups share references to the underlying data structures of the registry
* that generated them. Therefore any change to the entities and to the
* components made by means of the registry are immediately reflected by all the
* groups.
* Moreover, sorting an owning group affects all the instance of the same group
* (it means that users don't have to call `sort` on each instance to sort all
* of them because they share the underlying data structure).
*
* @warning
* Lifetime of a group must not overcome that of the registry that generated it.
* In any other case, attempting to use a group results in undefined behavior.
*
* @tparam Entity A valid entity type (see entt_traits for more details).
* @tparam Exclude Types of components used to filter the group.
* @tparam Get Types of components observed by the group.
* @tparam Owned Types of components owned by the group.
*/
template<typename Entity, typename... Exclude, typename... Get, typename... Owned>
class basic_group<Entity, exclude_t<Exclude...>, get_t<Get...>, Owned...> {
/*! @brief A registry is allowed to create groups. */
friend class basic_registry<Entity>;
template<typename Component>
using pool_type = pool_t<Entity, Component>;
template<typename Component>
using component_iterator = decltype(std::declval<pool_type<Component>>().begin());
class group_proxy {
friend class basic_group<Entity, exclude_t<Exclude...>, get_t<Get...>, Owned...>;
class proxy_iterator {
friend class group_proxy;
using it_type = typename sparse_set<Entity>::iterator;
using owned_type = decltype(std::tuple_cat(std::declval<std::conditional_t<is_eto_eligible_v<Owned>, std::tuple<>, std::tuple<component_iterator<Owned>>>>()...));
using get_type = decltype(std::tuple_cat(std::declval<std::conditional_t<is_eto_eligible_v<Get>, std::tuple<>, std::tuple<pool_type<Get> *>>>()...));
proxy_iterator(it_type from, owned_type oref, get_type gref) ENTT_NOEXCEPT
: it{from},
owned{oref},
get{gref}
{}
public:
using difference_type = std::ptrdiff_t;
using value_type = decltype(std::tuple_cat(
std::declval<std::tuple<Entity>>(),
std::declval<std::conditional_t<is_eto_eligible_v<Owned>, std::tuple<>, std::tuple<Owned>>>()...,
std::declval<std::conditional_t<is_eto_eligible_v<Get>, std::tuple<>, std::tuple<Get>>>()...
));
using pointer = void;
using reference = decltype(std::tuple_cat(
std::declval<std::tuple<Entity>>(),
std::declval<std::conditional_t<is_eto_eligible_v<Owned>, std::tuple<>, std::tuple<Owned &>>>()...,
std::declval<std::conditional_t<is_eto_eligible_v<Get>, std::tuple<>, std::tuple<Get &>>>()...
));
using iterator_category = std::input_iterator_tag;
proxy_iterator & operator++() ENTT_NOEXCEPT {
return ++it, std::apply([](auto &&... curr) { (++curr, ...); }, owned), *this;
}
proxy_iterator operator++(int) ENTT_NOEXCEPT {
proxy_iterator orig = *this;
return ++(*this), orig;
}
[[nodiscard]] reference operator*() const ENTT_NOEXCEPT {
return std::tuple_cat(
std::make_tuple(*it),
std::apply([](auto &&... curr) { return std::forward_as_tuple(*curr...); }, owned),
std::apply([entt = *it](auto &&... curr) { return std::forward_as_tuple(curr->get(entt)...); }, get)
);
}
[[nodiscard]] bool operator==(const proxy_iterator &other) const ENTT_NOEXCEPT {
return other.it == it;
}
[[nodiscard]] bool operator!=(const proxy_iterator &other) const ENTT_NOEXCEPT {
return !(*this == other);
}
private:
it_type it{};
owned_type owned{};
get_type get{};
};
group_proxy(std::tuple<pool_type<Owned> *..., pool_type<Get> *...> cpools, const std::size_t &extent)
: pools{cpools},
length{&extent}
{}
public:
using iterator = proxy_iterator;
[[nodiscard]] iterator begin() const ENTT_NOEXCEPT {
return proxy_iterator{
std::get<0>(pools)->sparse_set<Entity>::end() - *length,
std::tuple_cat([length = *length](auto *cpool) {
if constexpr(is_eto_eligible_v<typename std::decay_t<decltype(*cpool)>::object_type>) {
return std::make_tuple();
} else {
return std::make_tuple(cpool->end() - length);
}
}(std::get<pool_type<Owned> *>(pools))...),
std::tuple_cat([](auto *cpool) {
if constexpr(is_eto_eligible_v<typename std::decay_t<decltype(*cpool)>::object_type>) {
return std::make_tuple();
} else {
return std::make_tuple(cpool);
}
}(std::get<pool_type<Get> *>(pools))...)
};
}
[[nodiscard]] iterator end() const ENTT_NOEXCEPT {
return proxy_iterator{
std::get<0>(pools)->sparse_set<Entity>::end(),
std::tuple_cat([](auto *cpool) {
if constexpr(is_eto_eligible_v<typename std::decay_t<decltype(*cpool)>::object_type>) {
return std::make_tuple();
} else {
return std::make_tuple(cpool->end());
}
}(std::get<pool_type<Owned> *>(pools))...),
std::tuple_cat([](auto *cpool) {
if constexpr(is_eto_eligible_v<typename std::decay_t<decltype(*cpool)>::object_type>) {
return std::make_tuple();
} else {
return std::make_tuple(cpool);
}
}(std::get<pool_type<Get> *>(pools))...)
};
}
private:
const std::tuple<pool_type<Owned> *..., pool_type<Get> *...> pools;
const std::size_t *length;
};
basic_group(const std::size_t &extent, pool_type<Owned> &... opool, pool_type<Get> &... gpool) ENTT_NOEXCEPT
: pools{&opool..., &gpool...},
length{&extent}
{}
template<typename Func, typename... Strong, typename... Weak>
void traverse(Func func, type_list<Strong...>, type_list<Weak...>) const {
[[maybe_unused]] auto it = std::make_tuple((std::get<pool_type<Strong> *>(pools)->end() - *length)...);
[[maybe_unused]] auto data = std::get<0>(pools)->sparse_set<entity_type>::end() - *length;
for(auto next = *length; next; --next) {
if constexpr(std::is_invocable_v<Func, decltype(get<Strong>({}))..., decltype(get<Weak>({}))...>) {
if constexpr(sizeof...(Weak) == 0) {
func(*(std::get<component_iterator<Strong>>(it)++)...);
} else {
const auto entt = *(data++);
func(*(std::get<component_iterator<Strong>>(it)++)..., std::get<pool_type<Weak> *>(pools)->get(entt)...);
}
} else {
const auto entt = *(data++);
func(entt, *(std::get<component_iterator<Strong>>(it)++)..., std::get<pool_type<Weak> *>(pools)->get(entt)...);
}
}
}
public:
/*! @brief Underlying entity identifier. */
using entity_type = Entity;
/*! @brief Unsigned integer type. */
using size_type = std::size_t;
/*! @brief Random access iterator type. */
using iterator = typename sparse_set<Entity>::iterator;
/*! @brief Reversed iterator type. */
using reverse_iterator = typename sparse_set<Entity>::reverse_iterator;
/**
* @brief Returns the number of existing components of the given type.
* @tparam Component Type of component of which to return the size.
* @return Number of existing components of the given type.
*/
template<typename Component>
[[nodiscard]] size_type size() const ENTT_NOEXCEPT {
return std::get<pool_type<Component> *>(pools)->size();
}
/**
* @brief Returns the number of entities that have the given components.
* @return Number of entities that have the given components.
*/
[[nodiscard]] size_type size() const ENTT_NOEXCEPT {
return *length;
}
/**
* @brief Checks whether a group or some pools are empty.
* @tparam Component Types of components in which one is interested.
* @return True if the group or the pools are empty, false otherwise.
*/
template<typename... Component>
[[nodiscard]] bool empty() const ENTT_NOEXCEPT {
if constexpr(sizeof...(Component) == 0) {
return !*length;
} else {
return (std::get<pool_type<Component> *>(pools)->empty() && ...);
}
}
/**
* @brief Direct access to the list of components of a given pool.
*
* The returned pointer is such that range
* `[raw<Component>(), raw<Component>() + size<Component>()]` is always a
* valid range, even if the container is empty.<br/>
* Moreover, in case the group owns the given component, the range
* `[raw<Component>(), raw<Component>() + size()]` is such that it contains
* the instances that are part of the group itself.
*
* @note
* Components are in the reverse order as returned by the `begin`/`end`
* iterators.
*
* @tparam Component Type of component in which one is interested.
* @return A pointer to the array of components.
*/
template<typename Component>
[[nodiscard]] Component * raw() const ENTT_NOEXCEPT {
return std::get<pool_type<Component> *>(pools)->raw();
}
/**
* @brief Direct access to the list of entities of a given pool.
*
* The returned pointer is such that range
* `[data<Component>(), data<Component>() + size<Component>()]` is always a
* valid range, even if the container is empty.<br/>
* Moreover, in case the group owns the given component, the range
* `[data<Component>(), data<Component>() + size()]` is such that it
* contains the entities that are part of the group itself.
*
* @note
* Entities are in the reverse order as returned by the `begin`/`end`
* iterators.
*
* @tparam Component Type of component in which one is interested.
* @return A pointer to the array of entities.
*/
template<typename Component>
[[nodiscard]] const entity_type * data() const ENTT_NOEXCEPT {
return std::get<pool_type<Component> *>(pools)->data();
}
/**
* @brief Direct access to the list of entities.
*
* The returned pointer is such that range `[data(), data() + size()]` is
* always a valid range, even if the container is empty.
*
* @note
* Entities are in the reverse order as returned by the `begin`/`end`
* iterators.
*
* @return A pointer to the array of entities.
*/
[[nodiscard]] const entity_type * data() const ENTT_NOEXCEPT {
return std::get<0>(pools)->data();
}
/**
* @brief Returns an iterator to the first entity of the group.
*
* The returned iterator points to the first entity of the group. If the
* group is empty, the returned iterator will be equal to `end()`.
*
* @note
* Iterators stay true to the order imposed to the underlying data
* structures.
*
* @return An iterator to the first entity of the group.
*/
[[nodiscard]] iterator begin() const ENTT_NOEXCEPT {
return std::get<0>(pools)->sparse_set<entity_type>::end() - *length;
}
/**
* @brief Returns an iterator that is past the last entity of the group.
*
* The returned iterator points to the entity following the last entity of
* the group. Attempting to dereference the returned iterator results in
* undefined behavior.
*
* @note
* Iterators stay true to the order imposed to the underlying data
* structures.
*
* @return An iterator to the entity following the last entity of the
* group.
*/
[[nodiscard]] iterator end() const ENTT_NOEXCEPT {
return std::get<0>(pools)->sparse_set<entity_type>::end();
}
/**
* @brief Returns an iterator to the first entity of the reversed group.
*
* The returned iterator points to the first entity of the reversed group.
* If the group is empty, the returned iterator will be equal to `rend()`.
*
* @note
* Iterators stay true to the order imposed to the underlying data
* structures.
*
* @return An iterator to the first entity of the reversed group.
*/
[[nodiscard]] reverse_iterator rbegin() const ENTT_NOEXCEPT {
return std::get<0>(pools)->sparse_set<entity_type>::rbegin();
}
/**
* @brief Returns an iterator that is past the last entity of the reversed
* group.
*
* The returned iterator points to the entity following the last entity of
* the reversed group. Attempting to dereference the returned iterator
* results in undefined behavior.
*
* @note
* Iterators stay true to the order imposed to the underlying data
* structures.
*
* @return An iterator to the entity following the last entity of the
* reversed group.
*/
[[nodiscard]] reverse_iterator rend() const ENTT_NOEXCEPT {
return std::get<0>(pools)->sparse_set<entity_type>::rbegin() + *length;
}
/**
* @brief Returns the first entity of the group, if any.
* @return The first entity of the group if one exists, the null entity
* otherwise.
*/
[[nodiscard]] entity_type front() const {
const auto it = begin();
return it != end() ? *it : null;
}
/**
* @brief Returns the last entity of the group, if any.
* @return The last entity of the group if one exists, the null entity
* otherwise.
*/
[[nodiscard]] entity_type back() const {
const auto it = rbegin();
return it != rend() ? *it : null;
}
/**
* @brief Finds an entity.
* @param entt A valid entity identifier.
* @return An iterator to the given entity if it's found, past the end
* iterator otherwise.
*/
[[nodiscard]] iterator find(const entity_type entt) const {
const auto it = std::get<0>(pools)->find(entt);
return it != end() && it >= begin() && *it == entt ? it : end();
}
/**
* @brief Returns the identifier that occupies the given position.
* @param pos Position of the element to return.
* @return The identifier that occupies the given position.
*/
[[nodiscard]] entity_type operator[](const size_type pos) const {
return begin()[pos];
}
/**
* @brief Checks if a group contains an entity.
* @param entt A valid entity identifier.
* @return True if the group contains the given entity, false otherwise.
*/
[[nodiscard]] bool contains(const entity_type entt) const {
return std::get<0>(pools)->contains(entt) && (std::get<0>(pools)->index(entt) < (*length));
}
/**
* @brief Returns the components assigned to the given entity.
*
* Prefer this function instead of `registry::get` during iterations. It has
* far better performance than its counterpart.
*
* @warning
* Attempting to use an invalid component type results in a compilation
* error. Attempting to use an entity that doesn't belong to the group
* results in undefined behavior.<br/>
* An assertion will abort the execution at runtime in debug mode if the
* group doesn't contain the given entity.
*
* @tparam Component Types of components to get.
* @param entt A valid entity identifier.
* @return The components assigned to the entity.
*/
template<typename... Component>
[[nodiscard]] decltype(auto) get([[maybe_unused]] const entity_type entt) const {
ENTT_ASSERT(contains(entt));
if constexpr(sizeof...(Component) == 1) {
return (std::get<pool_type<Component> *>(pools)->get(entt), ...);
} else {
return std::tuple<decltype(get<Component>({}))...>{get<Component>(entt)...};
}
}
/**
* @brief Iterates entities and components and applies the given function
* object to them.
*
* The function object is invoked for each entity. It is provided with the
* entity itself and a set of references to non-empty components. The
* _constness_ of the components is as requested.<br/>
* The signature of the function must be equivalent to one of the following
* forms:
*
* @code{.cpp}
* void(const entity_type, Type &...);
* void(Type &...);
* @endcode
*
* @note
* Empty types aren't explicitly instantiated and therefore they are never
* returned during iterations.
*
* @tparam Func Type of the function object to invoke.
* @param func A valid function object.
*/
template<typename Func>
void each(Func func) const {
using owned_type_list = type_list_cat_t<std::conditional_t<is_eto_eligible_v<Owned>, type_list<>, type_list<Owned>>...>;
using get_type_list = type_list_cat_t<std::conditional_t<is_eto_eligible_v<Get>, type_list<>, type_list<Get>>...>;
traverse(std::move(func), owned_type_list{}, get_type_list{});
}
/**
* @brief Returns an iterable object to use to _visit_ the group.
*
* The iterable object returns tuples that contain the current entity and a
* set of references to its non-empty components. The _constness_ of the
* components is as requested.
*
* @note
* Empty types aren't explicitly instantiated and therefore they are never
* returned during iterations.
*
* @return An iterable object to use to _visit_ the group.
*/
[[nodiscard]] auto proxy() const ENTT_NOEXCEPT {
return group_proxy{pools, *length};
}
/**
* @brief Sort a group according to the given comparison function.
*
* Sort the group so that iterating it with a couple of iterators returns
* entities and components in the expected order. See `begin` and `end` for
* more details.
*
* The comparison function object must return `true` if the first element
* is _less_ than the second one, `false` otherwise. The signature of the
* comparison function should be equivalent to one of the following:
*
* @code{.cpp}
* bool(std::tuple<Component &...>, std::tuple<Component &...>);
* bool(const Component &, const Component &);
* bool(const Entity, const Entity);
* @endcode
*
* Where `Component` are either owned types or not but still such that they
* are iterated by the group.<br/>
* Moreover, the comparison function object shall induce a
* _strict weak ordering_ on the values.
*
* The sort function oject must offer a member function template
* `operator()` that accepts three arguments:
*
* * An iterator to the first element of the range to sort.
* * An iterator past the last element of the range to sort.
* * A comparison function to use to compare the elements.
*
* @tparam Component Optional types of components to compare.
* @tparam Compare Type of comparison function object.
* @tparam Sort Type of sort function object.
* @tparam Args Types of arguments to forward to the sort function object.
* @param compare A valid comparison function object.
* @param algo A valid sort function object.
* @param args Arguments to forward to the sort function object, if any.
*/
template<typename... Component, typename Compare, typename Sort = std_sort, typename... Args>
void sort(Compare compare, Sort algo = Sort{}, Args &&... args) {
auto *cpool = std::get<0>(pools);
if constexpr(sizeof...(Component) == 0) {
static_assert(std::is_invocable_v<Compare, const entity_type, const entity_type>, "Invalid comparison function");
cpool->sort(cpool->end()-*length, cpool->end(), std::move(compare), std::move(algo), std::forward<Args>(args)...);
} else if constexpr(sizeof...(Component) == 1) {
cpool->sort(cpool->end()-*length, cpool->end(), [this, compare = std::move(compare)](const entity_type lhs, const entity_type rhs) {
return compare((std::get<pool_type<Component> *>(pools)->get(lhs), ...), (std::get<pool_type<Component> *>(pools)->get(rhs), ...));
}, std::move(algo), std::forward<Args>(args)...);
} else {
cpool->sort(cpool->end()-*length, cpool->end(), [this, compare = std::move(compare)](const entity_type lhs, const entity_type rhs) {
return compare(std::tuple<decltype(get<Component>({}))...>{std::get<pool_type<Component> *>(pools)->get(lhs)...}, std::tuple<decltype(get<Component>({}))...>{std::get<pool_type<Component> *>(pools)->get(rhs)...});
}, std::move(algo), std::forward<Args>(args)...);
}
[this](auto *head, auto *... other) {
for(auto next = *length; next; --next) {
const auto pos = next - 1;
[[maybe_unused]] const auto entt = head->data()[pos];
(other->swap(other->data()[pos], entt), ...);
}
}(std::get<pool_type<Owned> *>(pools)...);
}
private:
const std::tuple<pool_type<Owned> *..., pool_type<Get> *...> pools;
const size_type *length;
};
}
#endif
// #include "runtime_view.hpp"
#ifndef ENTT_ENTITY_RUNTIME_VIEW_HPP
#define ENTT_ENTITY_RUNTIME_VIEW_HPP
#include <iterator>
#include <vector>
#include <utility>
#include <algorithm>
#include <type_traits>
// #include "../config/config.h"
// #include "sparse_set.hpp"
// #include "fwd.hpp"
namespace entt {
/**
* @brief Runtime view.
*
* Runtime views iterate over those entities that have at least all the given
* components in their bags. During initialization, a runtime view looks at the
* number of entities available for each component and picks up a reference to
* the smallest set of candidate entities in order to get a performance boost
* when iterate.<br/>
* Order of elements during iterations are highly dependent on the order of the
* underlying data structures. See sparse_set and its specializations for more
* details.
*
* @b Important
*
* Iterators aren't invalidated if:
*
* * New instances of the given components are created and assigned to entities.
* * The entity currently pointed is modified (as an example, if one of the
* given components is removed from the entity to which the iterator points).
* * The entity currently pointed is destroyed.
*
* In all the other cases, modifying the pools of the given components in any
* way invalidates all the iterators and using them results in undefined
* behavior.
*
* @note
* Views share references to the underlying data structures of the registry that
* generated them. Therefore any change to the entities and to the components
* made by means of the registry are immediately reflected by the views, unless
* a pool was missing when the view was built (in this case, the view won't
* have a valid reference and won't be updated accordingly).
*
* @warning
* Lifetime of a view must not overcome that of the registry that generated it.
* In any other case, attempting to use a view results in undefined behavior.
*
* @tparam Entity A valid entity type (see entt_traits for more details).
*/
template<typename Entity>
class basic_runtime_view {
/*! @brief A registry is allowed to create views. */
friend class basic_registry<Entity>;
using underlying_iterator = typename sparse_set<Entity>::iterator;
class view_iterator final {
friend class basic_runtime_view<Entity>;
view_iterator(const std::vector<const sparse_set<Entity> *> &cpools, const std::vector<const sparse_set<Entity> *> &ignore, underlying_iterator curr) ENTT_NOEXCEPT
: pools{&cpools},
filter{&ignore},
it{curr}
{
if(it != (*pools)[0]->end() && !valid()) {
++(*this);
}
}
[[nodiscard]] bool valid() const {
return std::all_of(pools->begin()++, pools->end(), [entt = *it](const auto *curr) { return curr->contains(entt); })
&& std::none_of(filter->cbegin(), filter->cend(), [entt = *it](const auto *curr) { return curr && curr->contains(entt); });
}
public:
using difference_type = typename underlying_iterator::difference_type;
using value_type = typename underlying_iterator::value_type;
using pointer = typename underlying_iterator::pointer;
using reference = typename underlying_iterator::reference;
using iterator_category = std::bidirectional_iterator_tag;
view_iterator() ENTT_NOEXCEPT = default;
view_iterator & operator++() {
while(++it != (*pools)[0]->end() && !valid());
return *this;
}
view_iterator operator++(int) {
view_iterator orig = *this;
return ++(*this), orig;
}
view_iterator & operator--() ENTT_NOEXCEPT {
while(--it != (*pools)[0]->begin() && !valid());
return *this;
}
view_iterator operator--(int) ENTT_NOEXCEPT {
view_iterator orig = *this;
return operator--(), orig;
}
[[nodiscard]] bool operator==(const view_iterator &other) const ENTT_NOEXCEPT {
return other.it == it;
}
[[nodiscard]] bool operator!=(const view_iterator &other) const ENTT_NOEXCEPT {
return !(*this == other);
}
[[nodiscard]] pointer operator->() const {
return it.operator->();
}
[[nodiscard]] reference operator*() const {
return *operator->();
}
private:
const std::vector<const sparse_set<Entity> *> *pools;
const std::vector<const sparse_set<Entity> *> *filter;
underlying_iterator it;
};
basic_runtime_view(std::vector<const sparse_set<Entity> *> cpools, std::vector<const sparse_set<Entity> *> epools) ENTT_NOEXCEPT
: pools{std::move(cpools)},
filter{std::move(epools)}
{
const auto it = std::min_element(pools.begin(), pools.end(), [](const auto *lhs, const auto *rhs) {
return (!lhs && rhs) || (lhs && rhs && lhs->size() < rhs->size());
});
// brings the best candidate (if any) on front of the vector
std::rotate(pools.begin(), it, pools.end());
}
[[nodiscard]] bool valid() const {
return !pools.empty() && pools.front();
}
public:
/*! @brief Underlying entity identifier. */
using entity_type = Entity;
/*! @brief Unsigned integer type. */
using size_type = std::size_t;
/*! @brief Bidirectional iterator type. */
using iterator = view_iterator;
/**
* @brief Estimates the number of entities that have the given components.
* @return Estimated number of entities that have the given components.
*/
[[nodiscard]] size_type size() const {
return valid() ? pools.front()->size() : size_type{};
}
/**
* @brief Checks if the view is definitely empty.
* @return True if the view is definitely empty, false otherwise.
*/
[[nodiscard]] bool empty() const {
return !valid() || pools.front()->empty();
}
/**
* @brief Returns an iterator to the first entity that has the given
* components.
*
* The returned iterator points to the first entity that has the given
* components. If the view is empty, the returned iterator will be equal to
* `end()`.
*
* @note
* Iterators stay true to the order imposed to the underlying data
* structures.
*
* @return An iterator to the first entity that has the given components.
*/
[[nodiscard]] iterator begin() const {
return valid() ? iterator{pools, filter, pools[0]->begin()} : iterator{};
}
/**
* @brief Returns an iterator that is past the last entity that has the
* given components.
*
* The returned iterator points to the entity following the last entity that
* has the given components. Attempting to dereference the returned iterator
* results in undefined behavior.
*
* @note
* Iterators stay true to the order imposed to the underlying data
* structures.
*
* @return An iterator to the entity following the last entity that has the
* given components.
*/
[[nodiscard]] iterator end() const {
return valid() ? iterator{pools, filter, pools[0]->end()} : iterator{};
}
/**
* @brief Checks if a view contains an entity.
* @param entt A valid entity identifier.
* @return True if the view contains the given entity, false otherwise.
*/
[[nodiscard]] bool contains(const entity_type entt) const {
return valid() && std::all_of(pools.cbegin(), pools.cend(), [entt](const auto *curr) { return curr->contains(entt); })
&& std::none_of(filter.cbegin(), filter.cend(), [entt](const auto *curr) { return curr && curr->contains(entt); });
}
/**
* @brief Iterates entities and applies the given function object to them.
*
* The function object is invoked for each entity. It is provided only with
* the entity itself. To get the components, users can use the registry with
* which the view was built.<br/>
* The signature of the function should be equivalent to the following:
*
* @code{.cpp}
* void(const entity_type);
* @endcode
*
* @tparam Func Type of the function object to invoke.
* @param func A valid function object.
*/
template<typename Func>
void each(Func func) const {
for(const auto entity: *this) {
func(entity);
}
}
private:
std::vector<const sparse_set<Entity> *> pools;
std::vector<const sparse_set<Entity> *> filter;
};
}
#endif
// #include "sparse_set.hpp"
// #include "storage.hpp"
// #include "utility.hpp"
// #include "view.hpp"
#ifndef ENTT_ENTITY_VIEW_HPP
#define ENTT_ENTITY_VIEW_HPP
#include <iterator>
#include <array>
#include <tuple>
#include <utility>
#include <algorithm>
#include <type_traits>
// #include "../config/config.h"
// #include "../core/type_traits.hpp"
// #include "entity.hpp"
// #include "fwd.hpp"
// #include "pool.hpp"
// #include "sparse_set.hpp"
// #include "utility.hpp"
namespace entt {
/**
* @brief View.
*
* Primary template isn't defined on purpose. All the specializations give a
* compile-time error, but for a few reasonable cases.
*/
template<typename...>
class basic_view;
/**
* @brief Multi component view.
*
* Multi component views iterate over those entities that have at least all the
* given components in their bags. During initialization, a multi component view
* looks at the number of entities available for each component and uses the
* smallest set in order to get a performance boost when iterate.
*
* @b Important
*
* Iterators aren't invalidated if:
*
* * New instances of the given components are created and assigned to entities.
* * The entity currently pointed is modified (as an example, if one of the
* given components is removed from the entity to which the iterator points).
* * The entity currently pointed is destroyed.
*
* In all other cases, modifying the pools iterated by the view in any way
* invalidates all the iterators and using them results in undefined behavior.
*
* @note
* Views share references to the underlying data structures of the registry that
* generated them. Therefore any change to the entities and to the components
* made by means of the registry are immediately reflected by views.
*
* @warning
* Lifetime of a view must not overcome that of the registry that generated it.
* In any other case, attempting to use a view results in undefined behavior.
*
* @tparam Entity A valid entity type (see entt_traits for more details).
* @tparam Exclude Types of components used to filter the view.
* @tparam Component Types of components iterated by the view.
*/
template<typename Entity, typename... Exclude, typename... Component>
class basic_view<Entity, exclude_t<Exclude...>, Component...> {
/*! @brief A registry is allowed to create views. */
friend class basic_registry<Entity>;
template<typename Comp>
using pool_type = pool_t<Entity, Comp>;
template<typename Comp>
using component_iterator = decltype(std::declval<pool_type<Comp>>().begin());
using unchecked_type = std::array<const sparse_set<Entity> *, (sizeof...(Component) - 1)>;
using filter_type = std::array<const sparse_set<Entity> *, sizeof...(Exclude)>;
template<typename It>
class view_iterator final {
friend class basic_view<Entity, exclude_t<Exclude...>, Component...>;
view_iterator(It from, It to, It curr, unchecked_type other, filter_type ignore) ENTT_NOEXCEPT
: first{from},
last{to},
it{curr},
unchecked{other},
filter{ignore}
{
if(it != last && !valid()) {
++(*this);
}
}
[[nodiscard]] bool valid() const {
return std::all_of(unchecked.cbegin(), unchecked.cend(), [entt = *it](const sparse_set<Entity> *curr) { return curr->contains(entt); })
&& (sizeof...(Exclude) == 0 || std::none_of(filter.cbegin(), filter.cend(), [entt = *it](const sparse_set<Entity> *cpool) { return cpool->contains(entt); }));
}
public:
using difference_type = typename std::iterator_traits<It>::difference_type;
using value_type = typename std::iterator_traits<It>::value_type;
using pointer = typename std::iterator_traits<It>::pointer;
using reference = typename std::iterator_traits<It>::reference;
using iterator_category = std::bidirectional_iterator_tag;
view_iterator() ENTT_NOEXCEPT = default;
view_iterator & operator++() {
while(++it != last && !valid());
return *this;
}
view_iterator operator++(int) {
view_iterator orig = *this;
return ++(*this), orig;
}
view_iterator & operator--() ENTT_NOEXCEPT {
while(--it != first && !valid());
return *this;
}
view_iterator operator--(int) ENTT_NOEXCEPT {
view_iterator orig = *this;
return operator--(), orig;
}
[[nodiscard]] bool operator==(const view_iterator &other) const ENTT_NOEXCEPT {
return other.it == it;
}
[[nodiscard]] bool operator!=(const view_iterator &other) const ENTT_NOEXCEPT {
return !(*this == other);
}
[[nodiscard]] pointer operator->() const {
return &*it;
}
[[nodiscard]] reference operator*() const {
return *operator->();
}
private:
It first;
It last;
It it;
unchecked_type unchecked;
filter_type filter;
};
class view_proxy {
friend class basic_view<Entity, exclude_t<Exclude...>, Component...>;
using proxy_view_iterator = view_iterator<typename sparse_set<Entity>::iterator>;
class proxy_iterator {
friend class view_proxy;
using ref_type = decltype(std::tuple_cat(std::declval<std::conditional_t<is_eto_eligible_v<Component>, std::tuple<>, std::tuple<pool_type<Component> *>>>()...));
proxy_iterator(proxy_view_iterator from, ref_type ref) ENTT_NOEXCEPT
: it{from},
pools{ref}
{}
public:
using difference_type = std::ptrdiff_t;
using value_type = decltype(std::tuple_cat(
std::declval<std::tuple<Entity>>(),
std::declval<std::conditional_t<is_eto_eligible_v<Component>, std::tuple<>, std::tuple<Component>>>()...
));
using pointer = void;
using reference = decltype(std::tuple_cat(
std::declval<std::tuple<Entity>>(),
std::declval<std::conditional_t<is_eto_eligible_v<Component>, std::tuple<>, std::tuple<Component &>>>()...
));
using iterator_category = std::input_iterator_tag;
proxy_iterator & operator++() ENTT_NOEXCEPT {
return ++it, *this;
}
proxy_iterator operator++(int) ENTT_NOEXCEPT {
proxy_iterator orig = *this;
return ++(*this), orig;
}
[[nodiscard]] reference operator*() const ENTT_NOEXCEPT {
return std::apply([entt = *it](auto *... cpool) { return reference{entt, cpool->get(entt)...}; }, pools);
}
[[nodiscard]] bool operator==(const proxy_iterator &other) const ENTT_NOEXCEPT {
return other.it == it;
}
[[nodiscard]] bool operator!=(const proxy_iterator &other) const ENTT_NOEXCEPT {
return !(*this == other);
}
private:
proxy_view_iterator it{};
const ref_type pools{};
};
view_proxy(proxy_view_iterator from, proxy_view_iterator to, std::tuple<pool_type<Component> *...> ref)
: first{from},
last{to},
pools{ref}
{}
public:
using iterator = proxy_iterator;
[[nodiscard]] iterator begin() const ENTT_NOEXCEPT {
return proxy_iterator{first, std::tuple_cat([](auto *cpool) {
if constexpr(is_eto_eligible_v<typename std::decay_t<decltype(*cpool)>::object_type>) {
return std::make_tuple();
} else {
return std::make_tuple(cpool);
}
}(std::get<pool_type<Component> *>(pools))...)};
}
[[nodiscard]] iterator end() const ENTT_NOEXCEPT {
return proxy_iterator{last, std::tuple_cat([](auto *cpool) {
if constexpr(is_eto_eligible_v<typename std::decay_t<decltype(*cpool)>::object_type>) {
return std::make_tuple();
} else {
return std::make_tuple(cpool);
}
}(std::get<pool_type<Component> *>(pools))...)};
}
private:
proxy_view_iterator first;
proxy_view_iterator last;
const std::tuple<pool_type<Component> *...> pools;
};
basic_view(pool_type<Component> &... component, unpack_as_t<const sparse_set<Entity>, Exclude> &... epool) ENTT_NOEXCEPT
: pools{&component...},
view{candidate()},
filter{&epool...}
{}
[[nodiscard]] const sparse_set<Entity> * candidate() const ENTT_NOEXCEPT {
return (std::min)({ static_cast<const sparse_set<Entity> *>(std::get<pool_type<Component> *>(pools))... }, [](const auto *lhs, const auto *rhs) {
return lhs->size() < rhs->size();
});
}
[[nodiscard]] unchecked_type unchecked(const sparse_set<Entity> *cpool) const {
std::size_t pos{};
unchecked_type other{};
((std::get<pool_type<Component> *>(pools) == cpool ? nullptr : (other[pos] = std::get<pool_type<Component> *>(pools), other[pos++])), ...);
return other;
}
template<typename Comp, typename Other>
[[nodiscard]] decltype(auto) get([[maybe_unused]] component_iterator<Comp> &it, [[maybe_unused]] pool_type<Other> *cpool, [[maybe_unused]] const Entity entt) const {
if constexpr(std::is_same_v<Comp, Other>) {
return *it;
} else {
return cpool->get(entt);
}
}
template<typename Comp, typename Func, typename... Type>
void traverse(Func func, type_list<Type...>) const {
if constexpr(std::disjunction_v<std::is_same<Comp, Type>...>) {
auto it = std::get<pool_type<Comp> *>(pools)->begin();
for(const auto entt: static_cast<const sparse_set<entity_type> &>(*std::get<pool_type<Comp> *>(pools))) {
if(((std::is_same_v<Comp, Component> || std::get<pool_type<Component> *>(pools)->contains(entt)) && ...)
&& (sizeof...(Exclude) == 0 || std::none_of(filter.cbegin(), filter.cend(), [entt](const sparse_set<Entity> *cpool) { return cpool->contains(entt); })))
{
if constexpr(std::is_invocable_v<Func, decltype(get<Type>({}))...>) {
func(get<Comp, Type>(it, std::get<pool_type<Type> *>(pools), entt)...);
} else {
func(entt, get<Comp, Type>(it, std::get<pool_type<Type> *>(pools), entt)...);
}
}
++it;
}
} else {
for(const auto entt: static_cast<const sparse_set<entity_type> &>(*std::get<pool_type<Comp> *>(pools))) {
if(((std::is_same_v<Comp, Component> || std::get<pool_type<Component> *>(pools)->contains(entt)) && ...)
&& (sizeof...(Exclude) == 0 || std::none_of(filter.cbegin(), filter.cend(), [entt](const sparse_set<Entity> *cpool) { return cpool->contains(entt); })))
{
if constexpr(std::is_invocable_v<Func, decltype(get<Type>({}))...>) {
func(std::get<pool_type<Type> *>(pools)->get(entt)...);
} else {
func(entt, std::get<pool_type<Type> *>(pools)->get(entt)...);
}
}
}
}
}
template<typename Func, typename... Type>
void iterate(Func func, type_list<Type...>) const {
const auto last = view->data() + view->size();
auto first = view->data();
while(first != last) {
if((std::get<pool_type<Component> *>(pools)->contains(*first) && ...)
&& (sizeof...(Exclude) == 0 || std::none_of(filter.cbegin(), filter.cend(), [entt = *first](const sparse_set<Entity> *cpool) { return cpool->contains(entt); })))
{
const auto base = *(first++);
const auto chunk = (std::min)({ (std::get<pool_type<Component> *>(pools)->size() - std::get<pool_type<Component> *>(pools)->index(base))... });
size_type length{};
for(++length;
length < chunk
&& ((*(std::get<pool_type<Component> *>(pools)->data() + std::get<pool_type<Component> *>(pools)->index(base) + length) == *first) && ...)
&& (sizeof...(Exclude) == 0 || std::none_of(filter.cbegin(), filter.cend(), [entt = *first](const sparse_set<Entity> *cpool) { return cpool->contains(entt); }));
++length, ++first);
func(view->data() + view->index(base), (std::get<pool_type<Type> *>(pools)->raw() + std::get<pool_type<Type> *>(pools)->index(base))..., length);
} else {
++first;
}
}
}
public:
/*! @brief Underlying entity identifier. */
using entity_type = Entity;
/*! @brief Unsigned integer type. */
using size_type = std::size_t;
/*! @brief Bidirectional iterator type. */
using iterator = view_iterator<typename sparse_set<entity_type>::iterator>;
/*! @brief Reverse iterator type. */
using reverse_iterator = view_iterator<typename sparse_set<entity_type>::reverse_iterator>;
/**
* @brief Returns the number of existing components of the given type.
*
* This isn't the number of entities iterated by the view.
*
* @tparam Comp Type of component of which to return the size.
* @return Number of existing components of the given type.
*/
template<typename Comp>
[[nodiscard]] size_type size() const ENTT_NOEXCEPT {
return std::get<pool_type<Comp> *>(pools)->size();
}
/**
* @brief Estimates the number of entities iterated by the view.
* @return Estimated number of entities iterated by the view.
*/
[[nodiscard]] size_type size() const ENTT_NOEXCEPT {
return (std::min)({ std::get<pool_type<Component> *>(pools)->size()... });
}
/**
* @brief Checks whether a view or some pools are empty.
*
* The view is definitely empty if one of the pools it uses is empty. In all
* other cases, the view may be empty and not return entities even if this
* function returns false.
*
* @tparam Comp Types of components in which one is interested.
* @return True if the view or the pools are empty, false otherwise.
*/
template<typename... Comp>
[[nodiscard]] bool empty() const ENTT_NOEXCEPT {
if constexpr(sizeof...(Comp) == 0) {
return (std::get<pool_type<Component> *>(pools)->empty() || ...);
} else {
return (std::get<pool_type<Comp> *>(pools)->empty() && ...);
}
}
/**
* @brief Direct access to the list of components of a given pool.
*
* The returned pointer is such that range
* `[raw<Comp>(), raw<Comp>() + size<Comp>()]` is always a valid range, even
* if the container is empty.
*
* @note
* Components are in the reverse order as returned by the `begin`/`end`
* iterators.
*
* @tparam Comp Type of component in which one is interested.
* @return A pointer to the array of components.
*/
template<typename Comp>
[[nodiscard]] Comp * raw() const ENTT_NOEXCEPT {
return std::get<pool_type<Comp> *>(pools)->raw();
}
/**
* @brief Direct access to the list of entities of a given pool.
*
* The returned pointer is such that range
* `[data<Comp>(), data<Comp>() + size<Comp>()]` is always a valid range,
* even if the container is empty.
*
* @note
* Entities are in the reverse order as returned by the `begin`/`end`
* iterators.
*
* @tparam Comp Type of component in which one is interested.
* @return A pointer to the array of entities.
*/
template<typename Comp>
[[nodiscard]] const entity_type * data() const ENTT_NOEXCEPT {
return std::get<pool_type<Comp> *>(pools)->data();
}
/**
* @brief Returns an iterator to the first entity of the view.
*
* The returned iterator points to the first entity of the view. If the view
* is empty, the returned iterator will be equal to `end()`.
*
* @note
* Iterators stay true to the order imposed to the underlying data
* structures.
*
* @return An iterator to the first entity of the view.
*/
[[nodiscard]] iterator begin() const {
return iterator{view->begin(), view->end(), view->begin(), unchecked(view), filter};
}
/**
* @brief Returns an iterator that is past the last entity of the view.
*
* The returned iterator points to the entity following the last entity of
* the view. Attempting to dereference the returned iterator results in
* undefined behavior.
*
* @note
* Iterators stay true to the order imposed to the underlying data
* structures.
*
* @return An iterator to the entity following the last entity of the view.
*/
[[nodiscard]] iterator end() const {
return iterator{view->begin(), view->end(), view->end(), unchecked(view), filter};
}
/**
* @brief Returns an iterator to the first entity of the reversed view.
*
* The returned iterator points to the first entity of the reversed view. If
* the view is empty, the returned iterator will be equal to `rend()`.
*
* @note
* Iterators stay true to the order imposed to the underlying data
* structures.
*
* @return An iterator to the first entity of the reversed view.
*/
[[nodiscard]] reverse_iterator rbegin() const {
return reverse_iterator{view->rbegin(), view->rend(), view->rbegin(), unchecked(view), filter};
}
/**
* @brief Returns an iterator that is past the last entity of the reversed
* view.
*
* The returned iterator points to the entity following the last entity of
* the reversed view. Attempting to dereference the returned iterator
* results in undefined behavior.
*
* @note
* Iterators stay true to the order imposed to the underlying data
* structures.
*
* @return An iterator to the entity following the last entity of the
* reversed view.
*/
[[nodiscard]] reverse_iterator rend() const {
return reverse_iterator{view->rbegin(), view->rend(), view->rend(), unchecked(view), filter};
}
/**
* @brief Returns the first entity of the view, if any.
* @return The first entity of the view if one exists, the null entity
* otherwise.
*/
[[nodiscard]] entity_type front() const {
const auto it = begin();
return it != end() ? *it : null;
}
/**
* @brief Returns the last entity of the view, if any.
* @return The last entity of the view if one exists, the null entity
* otherwise.
*/
[[nodiscard]] entity_type back() const {
const auto it = rbegin();
return it != rend() ? *it : null;
}
/**
* @brief Finds an entity.
* @param entt A valid entity identifier.
* @return An iterator to the given entity if it's found, past the end
* iterator otherwise.
*/
[[nodiscard]] iterator find(const entity_type entt) const {
iterator it{view->begin(), view->end(), view->find(entt), unchecked(view), filter};
return (it != end() && *it == entt) ? it : end();
}
/**
* @brief Checks if a view contains an entity.
* @param entt A valid entity identifier.
* @return True if the view contains the given entity, false otherwise.
*/
[[nodiscard]] bool contains(const entity_type entt) const {
return (std::get<pool_type<Component> *>(pools)->contains(entt) && ...)
&& (sizeof...(Exclude) == 0 || std::none_of(filter.begin(), filter.end(), [entt](const auto *cpool) { return cpool->contains(entt); }));
}
/**
* @brief Returns the components assigned to the given entity.
*
* Prefer this function instead of `registry::get` during iterations. It has
* far better performance than its counterpart.
*
* @warning
* Attempting to use an invalid component type results in a compilation
* error. Attempting to use an entity that doesn't belong to the view
* results in undefined behavior.<br/>
* An assertion will abort the execution at runtime in debug mode if the
* view doesn't contain the given entity.
*
* @tparam Comp Types of components to get.
* @param entt A valid entity identifier.
* @return The components assigned to the entity.
*/
template<typename... Comp>
[[nodiscard]] decltype(auto) get([[maybe_unused]] const entity_type entt) const {
ENTT_ASSERT(contains(entt));
if constexpr(sizeof...(Comp) == 0) {
static_assert(sizeof...(Component) == 1, "Invalid component type");
return (std::get<pool_type<Component> *>(pools)->get(entt), ...);
} else if constexpr(sizeof...(Comp) == 1) {
return (std::get<pool_type<Comp> *>(pools)->get(entt), ...);
} else {
return std::tuple<decltype(get<Comp>({}))...>{get<Comp>(entt)...};
}
}
/**
* @brief Iterates entities and components and applies the given function
* object to them.
*
* The function object is invoked for each entity. It is provided with the
* entity itself and a set of references to non-empty components. The
* _constness_ of the components is as requested.<br/>
* The signature of the function must be equivalent to one of the following
* forms:
*
* @code{.cpp}
* void(const entity_type, Type &...);
* void(Type &...);
* @endcode
*
* @note
* Empty types aren't explicitly instantiated and therefore they are never
* returned during iterations.
*
* @tparam Func Type of the function object to invoke.
* @param func A valid function object.
*/
template<typename Func>
void each(Func func) const {
view = candidate();
((std::get<pool_type<Component> *>(pools) == view ? each<Component>(std::move(func)) : void()), ...);
}
/**
* @brief Iterates entities and components and applies the given function
* object to them.
*
* The pool of the suggested component is used to lead the iterations. The
* returned entities will therefore respect the order of the pool associated
* with that type.<br/>
* It is no longer guaranteed that the performance is the best possible, but
* there will be greater control over the order of iteration.
*
* @sa each
*
* @tparam Comp Type of component to use to enforce the iteration order.
* @tparam Func Type of the function object to invoke.
* @param func A valid function object.
*/
template<typename Comp, typename Func>
void each(Func func) const {
using non_empty_type = type_list_cat_t<std::conditional_t<is_eto_eligible_v<Component>, type_list<>, type_list<Component>>...>;
traverse<Comp>(std::move(func), non_empty_type{});
}
/**
* @brief Returns an iterable object to use to _visit_ the view.
*
* The iterable object returns tuples that contain the current entity and a
* set of references to its non-empty components. The _constness_ of the
* components is as requested.
*
* @note
* Empty types aren't explicitly instantiated and therefore they are never
* returned during iterations.
*
* @return An iterable object to use to _visit_ the view.
*/
[[nodiscard]] auto proxy() const ENTT_NOEXCEPT {
view = candidate();
return view_proxy{begin(), end(), pools};
}
/**
* @brief Returns an iterable object to use to _visit_ the view.
*
* The pool of the suggested component is used to lead the iterations. The
* returned elements will therefore respect the order of the pool associated
* with that type.<br/>
* It is no longer guaranteed that the performance is the best possible, but
* there will be greater control over the order of iteration.
*
* @sa each
*
* @tparam Comp Type of component to use to enforce the iteration order.
* @return An iterable object to use to _visit_ the view.
*/
template<typename Comp>
[[nodiscard]] auto proxy() const ENTT_NOEXCEPT {
const sparse_set<entity_type> *cpool = std::get<pool_type<Comp> *>(pools);
iterator first{cpool->begin(), cpool->end(), cpool->begin(), unchecked(cpool), filter};
iterator last{cpool->begin(), cpool->end(), cpool->end(), unchecked(cpool), filter};
return view_proxy{std::move(first), std::move(last), pools};
}
/**
* @brief Chunked iteration for entities and components
*
* Chunked iteration tries to spot chunks in the sets of entities and
* components and return them one at a time along with their sizes.<br/>
* This type of iteration is intended where it's known a priori that the
* creation of entities and components takes place in chunk, which is
* actually quite common. In this case, various optimizations can be applied
* downstream to obtain even better performances from the views.
*
* The signature of the function must be equivalent to the following:
*
* @code{.cpp}
* void(const entity_type *, Type *..., size_type);
* @endcode
*
* The arguments are as follows:
*
* * A pointer to the entities belonging to the chunk.
* * Pointers to the components associated with the returned entities.
* * The length of the chunk.
*
* Note that the callback can be invoked 0 or more times and no guarantee is
* given on the order of the elements.
*
* @note
* Empty types aren't explicitly instantiated and therefore they are never
* returned during iterations.
*
* @tparam Func Type of the function object to invoke.
* @param func A valid function object.
*/
template<typename Func>
void chunked(Func func) const {
using non_empty_type = type_list_cat_t<std::conditional_t<is_eto_eligible_v<Component>, type_list<>, type_list<Component>>...>;
view = candidate();
iterate(std::move(func), non_empty_type{});
}
private:
const std::tuple<pool_type<Component> *...> pools;
mutable const sparse_set<entity_type>* view;
filter_type filter;
};
/**
* @brief Single component view specialization.
*
* Single component views are specialized in order to get a boost in terms of
* performance. This kind of views can access the underlying data structure
* directly and avoid superfluous checks.
*
* @b Important
*
* Iterators aren't invalidated if:
*
* * New instances of the given component are created and assigned to entities.
* * The entity currently pointed is modified (as an example, the given
* component is removed from the entity to which the iterator points).
* * The entity currently pointed is destroyed.
*
* In all other cases, modifying the pool iterated by the view in any way
* invalidates all the iterators and using them results in undefined behavior.
*
* @note
* Views share a reference to the underlying data structure of the registry that
* generated them. Therefore any change to the entities and to the components
* made by means of the registry are immediately reflected by views.
*
* @warning
* Lifetime of a view must not overcome that of the registry that generated it.
* In any other case, attempting to use a view results in undefined behavior.
*
* @tparam Entity A valid entity type (see entt_traits for more details).
* @tparam Component Type of component iterated by the view.
*/
template<typename Entity, typename Component>
class basic_view<Entity, exclude_t<>, Component> {
/*! @brief A registry is allowed to create views. */
friend class basic_registry<Entity>;
using pool_type = pool_t<Entity, Component>;
class view_proxy {
friend class basic_view<Entity, exclude_t<>, Component>;
class proxy_iterator {
friend class view_proxy;
using it_type = std::conditional_t<
is_eto_eligible_v<Component>,
std::tuple<typename sparse_set<Entity>::iterator>,
std::tuple<typename sparse_set<Entity>::iterator, decltype(std::declval<pool_type>().begin())>
>;
proxy_iterator(it_type from) ENTT_NOEXCEPT
: it{from}
{}
public:
using difference_type = std::ptrdiff_t;
using value_type = std::conditional_t<is_eto_eligible_v<Component>, std::tuple<Entity>, std::tuple<Entity, Component>>;
using pointer = void;
using reference = std::conditional_t<is_eto_eligible_v<Component>, std::tuple<Entity>, std::tuple<Entity, Component &>>;
using iterator_category = std::input_iterator_tag;
proxy_iterator & operator++() ENTT_NOEXCEPT {
return std::apply([](auto &&... curr) { (++curr, ...); }, it), *this;
}
proxy_iterator operator++(int) ENTT_NOEXCEPT {
proxy_iterator orig = *this;
return ++(*this), orig;
}
[[nodiscard]] reference operator*() const ENTT_NOEXCEPT {
return std::apply([](auto &&... curr) { return reference{*curr...}; }, it);
}
[[nodiscard]] bool operator==(const proxy_iterator &other) const ENTT_NOEXCEPT {
return std::get<0>(other.it) == std::get<0>(it);
}
[[nodiscard]] bool operator!=(const proxy_iterator &other) const ENTT_NOEXCEPT {
return !(*this == other);
}
private:
it_type it{};
};
view_proxy(pool_type &ref)
: pool{&ref}
{}
public:
using iterator = proxy_iterator;
[[nodiscard]] iterator begin() const ENTT_NOEXCEPT {
if constexpr(is_eto_eligible_v<Component>) {
return proxy_iterator{std::make_tuple(pool->sparse_set<entity_type>::begin())};
} else {
return proxy_iterator{std::make_tuple(pool->sparse_set<entity_type>::begin(), pool->begin())};
}
}
[[nodiscard]] iterator end() const ENTT_NOEXCEPT {
if constexpr(is_eto_eligible_v<Component>) {
return proxy_iterator{std::make_tuple(pool->sparse_set<entity_type>::end())};
} else {
return proxy_iterator{std::make_tuple(pool->sparse_set<entity_type>::end(), pool->end())};
}
}
private:
pool_type *pool;
};
basic_view(pool_type &ref) ENTT_NOEXCEPT
: pool{&ref}
{}
public:
/*! @brief Type of component iterated by the view. */
using raw_type = Component;
/*! @brief Underlying entity identifier. */
using entity_type = Entity;
/*! @brief Unsigned integer type. */
using size_type = std::size_t;
/*! @brief Random access iterator type. */
using iterator = typename sparse_set<Entity>::iterator;
/*! @brief Reversed iterator type. */
using reverse_iterator = typename sparse_set<Entity>::reverse_iterator;
/**
* @brief Returns the number of entities that have the given component.
* @return Number of entities that have the given component.
*/
[[nodiscard]] size_type size() const ENTT_NOEXCEPT {
return pool->size();
}
/**
* @brief Checks whether a view is empty.
* @return True if the view is empty, false otherwise.
*/
[[nodiscard]] bool empty() const ENTT_NOEXCEPT {
return pool->empty();
}
/**
* @brief Direct access to the list of components.
*
* The returned pointer is such that range `[raw(), raw() + size()]` is
* always a valid range, even if the container is empty.
*
* @note
* Components are in the reverse order as returned by the `begin`/`end`
* iterators.
*
* @return A pointer to the array of components.
*/
[[nodiscard]] raw_type * raw() const ENTT_NOEXCEPT {
return pool->raw();
}
/**
* @brief Direct access to the list of entities.
*
* The returned pointer is such that range `[data(), data() + size()]` is
* always a valid range, even if the container is empty.
*
* @note
* Entities are in the reverse order as returned by the `begin`/`end`
* iterators.
*
* @return A pointer to the array of entities.
*/
[[nodiscard]] const entity_type * data() const ENTT_NOEXCEPT {
return pool->data();
}
/**
* @brief Returns an iterator to the first entity of the view.
*
* The returned iterator points to the first entity of the view. If the view
* is empty, the returned iterator will be equal to `end()`.
*
* @note
* Iterators stay true to the order imposed to the underlying data
* structures.
*
* @return An iterator to the first entity of the view.
*/
[[nodiscard]] iterator begin() const ENTT_NOEXCEPT {
return pool->sparse_set<Entity>::begin();
}
/**
* @brief Returns an iterator that is past the last entity of the view.
*
* The returned iterator points to the entity following the last entity of
* the view. Attempting to dereference the returned iterator results in
* undefined behavior.
*
* @note
* Iterators stay true to the order imposed to the underlying data
* structures.
*
* @return An iterator to the entity following the last entity of the view.
*/
[[nodiscard]] iterator end() const ENTT_NOEXCEPT {
return pool->sparse_set<Entity>::end();
}
/**
* @brief Returns an iterator to the first entity of the reversed view.
*
* The returned iterator points to the first entity of the reversed view. If
* the view is empty, the returned iterator will be equal to `rend()`.
*
* @note
* Iterators stay true to the order imposed to the underlying data
* structures.
*
* @return An iterator to the first entity of the reversed view.
*/
[[nodiscard]] reverse_iterator rbegin() const ENTT_NOEXCEPT {
return pool->sparse_set<Entity>::rbegin();
}
/**
* @brief Returns an iterator that is past the last entity of the reversed
* view.
*
* The returned iterator points to the entity following the last entity of
* the reversed view. Attempting to dereference the returned iterator
* results in undefined behavior.
*
* @note
* Iterators stay true to the order imposed to the underlying data
* structures.
*
* @return An iterator to the entity following the last entity of the
* reversed view.
*/
[[nodiscard]] reverse_iterator rend() const ENTT_NOEXCEPT {
return pool->sparse_set<Entity>::rend();
}
/**
* @brief Returns the first entity of the view, if any.
* @return The first entity of the view if one exists, the null entity
* otherwise.
*/
[[nodiscard]] entity_type front() const {
const auto it = begin();
return it != end() ? *it : null;
}
/**
* @brief Returns the last entity of the view, if any.
* @return The last entity of the view if one exists, the null entity
* otherwise.
*/
[[nodiscard]] entity_type back() const {
const auto it = rbegin();
return it != rend() ? *it : null;
}
/**
* @brief Finds an entity.
* @param entt A valid entity identifier.
* @return An iterator to the given entity if it's found, past the end
* iterator otherwise.
*/
[[nodiscard]] iterator find(const entity_type entt) const {
const auto it = pool->find(entt);
return it != end() && *it == entt ? it : end();
}
/**
* @brief Returns the identifier that occupies the given position.
* @param pos Position of the element to return.
* @return The identifier that occupies the given position.
*/
[[nodiscard]] entity_type operator[](const size_type pos) const {
return begin()[pos];
}
/**
* @brief Checks if a view contains an entity.
* @param entt A valid entity identifier.
* @return True if the view contains the given entity, false otherwise.
*/
[[nodiscard]] bool contains(const entity_type entt) const {
return pool->contains(entt);
}
/**
* @brief Returns the component assigned to the given entity.
*
* Prefer this function instead of `registry::get` during iterations. It has
* far better performance than its counterpart.
*
* @warning
* Attempting to use an entity that doesn't belong to the view results in
* undefined behavior.<br/>
* An assertion will abort the execution at runtime in debug mode if the
* view doesn't contain the given entity.
*
* @param entt A valid entity identifier.
* @return The component assigned to the entity.
*/
template<typename Comp = Component>
[[nodiscard]] decltype(auto) get(const entity_type entt) const {
static_assert(std::is_same_v<Comp, Component>, "Invalid component type");
ENTT_ASSERT(contains(entt));
return pool->get(entt);
}
/**
* @brief Iterates entities and components and applies the given function
* object to them.
*
* The function object is invoked for each entity. It is provided with the
* entity itself and a reference to the component if it's a non-empty one.
* The _constness_ of the component is as requested.<br/>
* The signature of the function must be equivalent to one of the following
* forms:
*
* @code{.cpp}
* void(const entity_type, Component &);
* void(Component &);
* @endcode
*
* @note
* Empty types aren't explicitly instantiated and therefore they are never
* returned during iterations.
*
* @tparam Func Type of the function object to invoke.
* @param func A valid function object.
*/
template<typename Func>
void each(Func func) const {
if constexpr(is_eto_eligible_v<Component>) {
if constexpr(std::is_invocable_v<Func>) {
for(auto pos = pool->size(); pos; --pos) {
func();
}
} else {
for(const auto entt: *this) {
func(entt);
}
}
} else {
if constexpr(std::is_invocable_v<Func, decltype(get({}))>) {
for(auto &&component: *pool) {
func(component);
}
} else {
auto raw = pool->begin();
for(const auto entt: *this) {
func(entt, *(raw++));
}
}
}
}
/**
* @brief Returns an iterable object to use to _visit_ the view.
*
* The iterable object returns tuples that contain the current entity and a
* reference to its component if it's a non-empty one. The _constness_ of
* the component is as requested.
*
* @note
* Empty types aren't explicitly instantiated and therefore they are never
* returned during iterations.
*
* @return An iterable object to use to _visit_ the view.
*/
[[nodiscard]] auto proxy() const ENTT_NOEXCEPT {
return view_proxy{*pool};
}
private:
pool_type *pool;
};
}
#endif
namespace entt {
/**
* @brief Fast and reliable entity-component system.
*
* The registry is the core class of the entity-component framework.<br/>
* It stores entities and arranges pools of components on a per request basis.
* By means of a registry, users can manage entities and components, then create
* views or groups to iterate them.
*
* @tparam Entity A valid entity type (see entt_traits for more details).
*/
template<typename Entity>
class basic_registry {
using traits_type = entt_traits<Entity>;
template<typename Component>
struct pool_handler final: storage<Entity, Component> {
static_assert(std::is_same_v<Component, std::decay_t<Component>>, "Invalid component type");
[[nodiscard]] auto on_construct() ENTT_NOEXCEPT {
return sink{construction};
}
[[nodiscard]] auto on_update() ENTT_NOEXCEPT {
return sink{update};
}
[[nodiscard]] auto on_destroy() ENTT_NOEXCEPT {
return sink{destruction};
}
template<typename... Args>
decltype(auto) emplace(basic_registry &owner, const Entity entt, Args &&... args) {
storage<entity_type, Component>::emplace(entt, std::forward<Args>(args)...);
construction.publish(owner, entt);
if constexpr(!is_eto_eligible_v<Component>) {
return this->get(entt);
}
}
template<typename It, typename... Args>
void insert(basic_registry &owner, It first, It last, Args &&... args) {
storage<entity_type, Component>::insert(first, last, std::forward<Args>(args)...);
if(!construction.empty()) {
while(first != last) { construction.publish(owner, *(first++)); }
}
}
void remove(basic_registry &owner, const Entity entt) {
destruction.publish(owner, entt);
this->erase(entt);
}
template<typename It>
void remove(basic_registry &owner, It first, It last) {
if(std::distance(first, last) == std::distance(this->begin(), this->end())) {
if(!destruction.empty()) {
while(first != last) { destruction.publish(owner, *(first++)); }
}
this->clear();
} else {
while(first != last) { this->remove(owner, *(first++)); }
}
}
template<typename... Func>
decltype(auto) patch(basic_registry &owner, const Entity entt, [[maybe_unused]] Func &&... func) {
if constexpr(is_eto_eligible_v<Component>) {
update.publish(owner, entt);
} else {
(std::forward<Func>(func)(this->get(entt)), ...);
update.publish(owner, entt);
return this->get(entt);
}
}
decltype(auto) replace(basic_registry &owner, const Entity entt, Component component) {
return patch(owner, entt, [&component](auto &&curr) { curr = std::move(component); });
}
private:
sigh<void(basic_registry &, const Entity)> construction{};
sigh<void(basic_registry &, const Entity)> destruction{};
sigh<void(basic_registry &, const Entity)> update{};
};
struct pool_data {
id_type type_id{};
std::unique_ptr<sparse_set<Entity>> pool{};
void(* remove)(sparse_set<Entity> &, basic_registry &, const Entity){};
};
template<typename...>
struct group_handler;
template<typename... Exclude, typename... Get, typename... Owned>
struct group_handler<exclude_t<Exclude...>, get_t<Get...>, Owned...> {
static_assert(std::conjunction_v<std::is_same<Owned, std::decay_t<Owned>>..., std::is_same<Get, std::decay_t<Get>>..., std::is_same<Exclude, std::decay_t<Exclude>>...>, "One or more component types are invalid");
std::conditional_t<sizeof...(Owned) == 0, sparse_set<Entity>, std::size_t> current{};
template<typename Component>
void maybe_valid_if(basic_registry &owner, const Entity entt) {
[[maybe_unused]] const auto cpools = std::forward_as_tuple(owner.assure<Owned>()...);
const auto is_valid = ((std::is_same_v<Component, Owned> || std::get<pool_handler<Owned> &>(cpools).contains(entt)) && ...)
&& ((std::is_same_v<Component, Get> || owner.assure<Get>().contains(entt)) && ...)
&& ((std::is_same_v<Component, Exclude> || !owner.assure<Exclude>().contains(entt)) && ...);
if constexpr(sizeof...(Owned) == 0) {
if(is_valid && !current.contains(entt)) {
current.emplace(entt);
}
} else {
if(is_valid && !(std::get<0>(cpools).index(entt) < current)) {
const auto pos = current++;
(std::get<pool_handler<Owned> &>(cpools).swap(std::get<pool_handler<Owned> &>(cpools).data()[pos], entt), ...);
}
}
}
void discard_if([[maybe_unused]] basic_registry &owner, const Entity entt) {
if constexpr(sizeof...(Owned) == 0) {
if(current.contains(entt)) {
current.erase(entt);
}
} else {
if(const auto cpools = std::forward_as_tuple(owner.assure<Owned>()...); std::get<0>(cpools).contains(entt) && (std::get<0>(cpools).index(entt) < current)) {
const auto pos = --current;
(std::get<pool_handler<Owned> &>(cpools).swap(std::get<pool_handler<Owned> &>(cpools).data()[pos], entt), ...);
}
}
}
};
struct group_data {
std::size_t size;
std::unique_ptr<void, void(*)(void *)> group;
bool (* owned)(const id_type) ENTT_NOEXCEPT;
bool (* get)(const id_type) ENTT_NOEXCEPT;
bool (* exclude)(const id_type) ENTT_NOEXCEPT;
};
struct variable_data {
id_type type_id;
std::unique_ptr<void, void(*)(void *)> value;
};
template<typename Component>
[[nodiscard]] const pool_handler<Component> & assure() const {
const sparse_set<entity_type> *cpool;
if constexpr(ENTT_FAST_PATH(has_type_index_v<Component>)) {
const auto index = type_index<Component>::value();
if(!(index < pools.size())) {
pools.resize(size_type(index+1u));
}
if(auto &&pdata = pools[index]; !pdata.pool) {
pdata.type_id = type_info<Component>::id();
pdata.pool.reset(new pool_handler<Component>());
pdata.remove = [](sparse_set<entity_type> &target, basic_registry &owner, const entity_type entt) {
static_cast<pool_handler<Component> &>(target).remove(owner, entt);
};
}
cpool = pools[index].pool.get();
} else {
if(const auto it = std::find_if(pools.cbegin(), pools.cend(), [id = type_info<Component>::id()](const auto &pdata) { return id == pdata.type_id; }); it == pools.cend()) {
cpool = pools.emplace_back(pool_data{
type_info<Component>::id(),
std::unique_ptr<sparse_set<entity_type>>{new pool_handler<Component>()},
[](sparse_set<entity_type> &target, basic_registry &owner, const entity_type entt) {
static_cast<pool_handler<Component> &>(target).remove(owner, entt);
}
}).pool.get();
} else {
cpool = it->pool.get();
}
}
return *static_cast<const pool_handler<Component> *>(cpool);
}
template<typename Component>
[[nodiscard]] pool_handler<Component> & assure() {
return const_cast<pool_handler<Component> &>(std::as_const(*this).template assure<Component>());
}
public:
/*! @brief Underlying entity identifier. */
using entity_type = Entity;
/*! @brief Underlying version type. */
using version_type = typename traits_type::version_type;
/*! @brief Unsigned integer type. */
using size_type = std::size_t;
/*! @brief Default constructor. */
basic_registry() = default;
/*! @brief Default move constructor. */
basic_registry(basic_registry &&) = default;
/*! @brief Default move assignment operator. @return This registry. */
basic_registry & operator=(basic_registry &&) = default;
/**
* @brief Prepares a pool for the given type if required.
* @tparam Component Type of component for which to prepare a pool.
*/
template<typename Component>
void prepare() {
// suppress the warning due to the [[nodiscard]] attribute
static_cast<void>(assure<Component>());
}
/**
* @brief Returns the number of existing components of the given type.
* @tparam Component Type of component of which to return the size.
* @return Number of existing components of the given type.
*/
template<typename Component>
[[nodiscard]] size_type size() const {
return assure<Component>().size();
}
/**
* @brief Returns the number of entities created so far.
* @return Number of entities created so far.
*/
[[nodiscard]] size_type size() const ENTT_NOEXCEPT {
return entities.size();
}
/**
* @brief Returns the number of entities still in use.
* @return Number of entities still in use.
*/
[[nodiscard]] size_type alive() const {
auto sz = entities.size();
auto curr = destroyed;
for(; curr != null; --sz) {
curr = entities[to_integral(curr) & traits_type::entity_mask];
}
return sz;
}
/**
* @brief Increases the capacity of the registry or of the pools for the
* given components.
*
* If no components are specified, the capacity of the registry is
* increased, that is the number of entities it contains. Otherwise the
* capacity of the pools for the given components is increased.<br/>
* In both cases, if the new capacity is greater than the current capacity,
* new storage is allocated, otherwise the method does nothing.
*
* @tparam Component Types of components for which to reserve storage.
* @param cap Desired capacity.
*/
template<typename... Component>
void reserve(const size_type cap) {
if constexpr(sizeof...(Component) == 0) {
entities.reserve(cap);
} else {
(assure<Component>().reserve(cap), ...);
}
}
/**
* @brief Returns the capacity of the pool for the given component.
* @tparam Component Type of component in which one is interested.
* @return Capacity of the pool of the given component.
*/
template<typename Component>
[[nodiscard]] size_type capacity() const {
return assure<Component>().capacity();
}
/**
* @brief Returns the number of entities that a registry has currently
* allocated space for.
* @return Capacity of the registry.
*/
[[nodiscard]] size_type capacity() const ENTT_NOEXCEPT {
return entities.capacity();
}
/**
* @brief Requests the removal of unused capacity for the given components.
* @tparam Component Types of components for which to reclaim unused
* capacity.
*/
template<typename... Component>
void shrink_to_fit() {
(assure<Component>().shrink_to_fit(), ...);
}
/**
* @brief Checks whether the registry or the pools of the given components
* are empty.
*
* A registry is considered empty when it doesn't contain entities that are
* still in use.
*
* @tparam Component Types of components in which one is interested.
* @return True if the registry or the pools of the given components are
* empty, false otherwise.
*/
template<typename... Component>
[[nodiscard]] bool empty() const {
if constexpr(sizeof...(Component) == 0) {
return !alive();
} else {
return (assure<Component>().empty() && ...);
}
}
/**
* @brief Direct access to the list of components of a given pool.
*
* The returned pointer is such that range
* `[raw<Component>(), raw<Component>() + size<Component>()]` is always a
* valid range, even if the container is empty.
*
* Components are in the reverse order as imposed by the sorting
* functionalities.
*
* @note
* Empty components aren't explicitly instantiated. Therefore, this function
* isn't available for them. A compilation error will occur if invoked.
*
* @tparam Component Type of component in which one is interested.
* @return A pointer to the array of components of the given type.
*/
template<typename Component>
[[nodiscard]] const Component * raw() const {
return assure<Component>().raw();
}
/*! @copydoc raw */
template<typename Component>
[[nodiscard]] Component * raw() {
return const_cast<Component *>(std::as_const(*this).template raw<Component>());
}
/**
* @brief Direct access to the list of entities of a given pool.
*
* The returned pointer is such that range
* `[data<Component>(), data<Component>() + size<Component>()]` is always a
* valid range, even if the container is empty.
*
* Entities are in the reverse order as imposed by the sorting
* functionalities.
*
* @tparam Component Type of component in which one is interested.
* @return A pointer to the array of entities.
*/
template<typename Component>
[[nodiscard]] const entity_type * data() const {
return assure<Component>().data();
}
/**
* @brief Direct access to the list of entities of a registry.
*
* The returned pointer is such that range `[data(), data() + size()]` is
* always a valid range, even if the container is empty.
*
* @warning
* This list contains both valid and destroyed entities and isn't suitable
* for direct use.
*
* @return A pointer to the array of entities.
*/
[[nodiscard]] const entity_type * data() const ENTT_NOEXCEPT {
return entities.data();
}
/**
* @brief Checks if an entity identifier refers to a valid entity.
* @param entity An entity identifier, either valid or not.
* @return True if the identifier is valid, false otherwise.
*/
[[nodiscard]] bool valid(const entity_type entity) const {
const auto pos = size_type(to_integral(entity) & traits_type::entity_mask);
return (pos < entities.size() && entities[pos] == entity);
}
/**
* @brief Returns the entity identifier without the version.
* @param entity An entity identifier, either valid or not.
* @return The entity identifier without the version.
*/
[[nodiscard]] static entity_type entity(const entity_type entity) ENTT_NOEXCEPT {
return entity_type{to_integral(entity) & traits_type::entity_mask};
}
/**
* @brief Returns the version stored along with an entity identifier.
* @param entity An entity identifier, either valid or not.
* @return The version stored along with the given entity identifier.
*/
[[nodiscard]] static version_type version(const entity_type entity) ENTT_NOEXCEPT {
return version_type(to_integral(entity) >> traits_type::entity_shift);
}
/**
* @brief Returns the actual version for an entity identifier.
*
* @warning
* Attempting to use an entity that doesn't belong to the registry results
* in undefined behavior. An entity belongs to the registry even if it has
* been previously destroyed and/or recycled.<br/>
* An assertion will abort the execution at runtime in debug mode if the
* registry doesn't own the given entity.
*
* @param entity A valid entity identifier.
* @return Actual version for the given entity identifier.
*/
[[nodiscard]] version_type current(const entity_type entity) const {
const auto pos = size_type(to_integral(entity) & traits_type::entity_mask);
ENTT_ASSERT(pos < entities.size());
return version_type(to_integral(entities[pos]) >> traits_type::entity_shift);
}
/**
* @brief Creates a new entity and returns it.
*
* There are two kinds of possible entity identifiers:
*
* * Newly created ones in case no entities have been previously destroyed.
* * Recycled ones with updated versions.
*
* @return A valid entity identifier.
*/
entity_type create() {
entity_type entt;
if(destroyed == null) {
entt = entities.emplace_back(entity_type{static_cast<typename traits_type::entity_type>(entities.size())});
// traits_type::entity_mask is reserved to allow for null identifiers
ENTT_ASSERT(to_integral(entt) < traits_type::entity_mask);
} else {
const auto curr = to_integral(destroyed);
const auto version = to_integral(entities[curr]) & (traits_type::version_mask << traits_type::entity_shift);
destroyed = entity_type{to_integral(entities[curr]) & traits_type::entity_mask};
entt = entities[curr] = entity_type{curr | version};
}
return entt;
}
/**
* @brief Creates a new entity and returns it.
*
* @sa create
*
* If the requested entity isn't in use, the suggested identifier is created
* and returned. Otherwise, a new one will be generated for this purpose.
*
* @param hint A desired entity identifier.
* @return A valid entity identifier.
*/
[[nodiscard]] entity_type create(const entity_type hint) {
ENTT_ASSERT(hint != null);
entity_type entt;
if(const auto req = (to_integral(hint) & traits_type::entity_mask); !(req < entities.size())) {
entities.reserve(req + 1);
for(auto pos = entities.size(); pos < req; ++pos) {
entities.emplace_back(destroyed);
destroyed = entity_type{static_cast<typename traits_type::entity_type>(pos)};
}
entt = entities.emplace_back(hint);
} else if(const auto curr = (to_integral(entities[req]) & traits_type::entity_mask); req == curr) {
entt = create();
} else {
auto *it = &destroyed;
for(; (to_integral(*it) & traits_type::entity_mask) != req; it = &entities[to_integral(*it) & traits_type::entity_mask]);
*it = entity_type{curr | (to_integral(*it) & (traits_type::version_mask << traits_type::entity_shift))};
entt = entities[req] = hint;
}
return entt;
}
/**
* @brief Assigns each element in a range an entity.
*
* @sa create
*
* @tparam It Type of forward iterator.
* @param first An iterator to the first element of the range to generate.
* @param last An iterator past the last element of the range to generate.
*/
template<typename It>
void create(It first, It last) {
std::generate(first, last, [this]() { return create(); });
}
/**
* @brief Assigns entities to an empty registry.
*
* This function is intended for use in conjunction with `raw`.<br/>
* Don't try to inject ranges of randomly generated entities. There is no
* guarantee that a registry will continue to work properly in this case.
*
* @warning
* An assertion will abort the execution at runtime in debug mode if all
* pools aren't empty.
*
* @tparam It Type of input iterator.
* @param first An iterator to the first element of the range of entities.
* @param last An iterator past the last element of the range of entities.
*/
template<typename It>
void assign(It first, It last) {
ENTT_ASSERT(std::all_of(pools.cbegin(), pools.cend(), [](auto &&pdata) { return !pdata.pool || pdata.pool->empty(); }));
entities.assign(first, last);
destroyed = null;
for(std::size_t pos{}, end = entities.size(); pos < end; ++pos) {
if((to_integral(entities[pos]) & traits_type::entity_mask) != pos) {
const auto version = to_integral(entities[pos]) & (traits_type::version_mask << traits_type::entity_shift);
entities[pos] = entity_type{to_integral(destroyed) | version};
destroyed = entity_type{static_cast<typename traits_type::entity_type>(pos)};
}
}
}
/**
* @brief Destroys an entity.
*
* When an entity is destroyed, its version is updated and the identifier
* can be recycled at any time.
*
* @sa remove_all
*
* @param entity A valid entity identifier.
*/
void destroy(const entity_type entity) {
destroy(entity, version_type((to_integral(entity) >> traits_type::entity_shift) + 1));
}
/**
* @brief Destroys an entity.
*
* If the entity isn't already destroyed, the suggested version is used
* instead of the implicitly generated one.
*
* @sa remove_all
*
* @param entity A valid entity identifier.
* @param version A desired version upon destruction.
*/
void destroy(const entity_type entity, const version_type version) {
remove_all(entity);
// lengthens the implicit list of destroyed entities
const auto entt = to_integral(entity) & traits_type::entity_mask;
entities[entt] = entity_type{to_integral(destroyed) | (typename traits_type::entity_type{version} << traits_type::entity_shift)};
destroyed = entity_type{entt};
}
/**
* @brief Destroys all the entities in a range.
*
* @sa destroy
*
* @tparam It Type of input iterator.
* @param first An iterator to the first element of the range of entities.
* @param last An iterator past the last element of the range of entities.
*/
template<typename It>
void destroy(It first, It last) {
while(first != last) { destroy(*(first++)); }
}
/**
* @brief Assigns the given component to an entity.
*
* A new instance of the given component is created and initialized with the
* arguments provided (the component must have a proper constructor or be of
* aggregate type). Then the component is assigned to the given entity.
*
* @warning
* Attempting to use an invalid entity or to assign a component to an entity
* that already owns it results in undefined behavior.<br/>
* An assertion will abort the execution at runtime in debug mode in case of
* invalid entity or if the entity already owns an instance of the given
* component.
*
* @tparam Component Type of component to create.
* @tparam Args Types of arguments to use to construct the component.
* @param entity A valid entity identifier.
* @param args Parameters to use to initialize the component.
* @return A reference to the newly created component.
*/
template<typename Component, typename... Args>
decltype(auto) emplace(const entity_type entity, Args &&... args) {
ENTT_ASSERT(valid(entity));
return assure<Component>().emplace(*this, entity, std::forward<Args>(args)...);
}
/**
* @brief Assigns each entity in a range the given component.
*
* @sa emplace
*
* @tparam Component Type of component to create.
* @tparam It Type of input iterator.
* @param first An iterator to the first element of the range of entities.
* @param last An iterator past the last element of the range of entities.
* @param value An instance of the component to assign.
*/
template<typename Component, typename It>
void insert(It first, It last, const Component &value = {}) {
ENTT_ASSERT(std::all_of(first, last, [this](const auto entity) { return valid(entity); }));
assure<Component>().insert(*this, first, last, value);
}
/**
* @brief Assigns each entity in a range the given components.
*
* @sa emplace
*
* @tparam Component Type of component to create.
* @tparam EIt Type of input iterator.
* @tparam CIt Type of input iterator.
* @param first An iterator to the first element of the range of entities.
* @param last An iterator past the last element of the range of entities.
* @param from An iterator to the first element of the range of components.
* @param to An iterator past the last element of the range of components.
*/
template<typename Component, typename EIt, typename CIt>
void insert(EIt first, EIt last, CIt from, CIt to) {
static_assert(std::is_constructible_v<Component, typename std::iterator_traits<CIt>::value_type>, "Invalid value type");
ENTT_ASSERT(std::all_of(first, last, [this](const auto entity) { return valid(entity); }));
assure<Component>().insert(*this, first, last, from, to);
}
/**
* @brief Assigns or replaces the given component for an entity.
*
* Equivalent to the following snippet (pseudocode):
*
* @code{.cpp}
* auto &component = registry.has<Component>(entity) ? registry.replace<Component>(entity, args...) : registry.emplace<Component>(entity, args...);
* @endcode
*
* Prefer this function anyway because it has slightly better performance.
*
* @warning
* Attempting to use an invalid entity results in undefined behavior.<br/>
* An assertion will abort the execution at runtime in debug mode in case of
* invalid entity.
*
* @tparam Component Type of component to assign or replace.
* @tparam Args Types of arguments to use to construct the component.
* @param entity A valid entity identifier.
* @param args Parameters to use to initialize the component.
* @return A reference to the newly created component.
*/
template<typename Component, typename... Args>
decltype(auto) emplace_or_replace(const entity_type entity, Args &&... args) {
ENTT_ASSERT(valid(entity));
auto &cpool = assure<Component>();
return cpool.contains(entity)
? cpool.replace(*this, entity, Component{std::forward<Args>(args)...})
: cpool.emplace(*this, entity, std::forward<Args>(args)...);
}
/**
* @brief Patches the given component for an entity.
*
* The signature of the functions should be equivalent to the following:
*
* @code{.cpp}
* void(Component &);
* @endcode
*
* @note
* Empty types aren't explicitly instantiated and therefore they are never
* returned. However, this function can be used to trigger an update signal
* for them.
*
* @warning
* Attempting to use an invalid entity or to patch a component of an entity
* that doesn't own it results in undefined behavior.<br/>
* An assertion will abort the execution at runtime in debug mode in case of
* invalid entity or if the entity doesn't own an instance of the given
* component.
*
* @tparam Component Type of component to patch.
* @tparam Func Types of the function objects to invoke.
* @param entity A valid entity identifier.
* @param func Valid function objects.
* @return A reference to the patched component.
*/
template<typename Component, typename... Func>
decltype(auto) patch(const entity_type entity, Func &&... func) {
ENTT_ASSERT(valid(entity));
return assure<Component>().patch(*this, entity, std::forward<Func>(func)...);
}
/**
* @brief Replaces the given component for an entity.
*
* A new instance of the given component is created and initialized with the
* arguments provided (the component must have a proper constructor or be of
* aggregate type). Then the component is assigned to the given entity.
*
* @warning
* Attempting to use an invalid entity or to replace a component of an
* entity that doesn't own it results in undefined behavior.<br/>
* An assertion will abort the execution at runtime in debug mode in case of
* invalid entity or if the entity doesn't own an instance of the given
* component.
*
* @tparam Component Type of component to replace.
* @tparam Args Types of arguments to use to construct the component.
* @param entity A valid entity identifier.
* @param args Parameters to use to initialize the component.
* @return A reference to the component being replaced.
*/
template<typename Component, typename... Args>
decltype(auto) replace(const entity_type entity, Args &&... args) {
return assure<Component>().replace(*this, entity, Component{std::forward<Args>(args)...});
}
/**
* @brief Removes the given components from an entity.
*
* @warning
* Attempting to use an invalid entity or to remove a component from an
* entity that doesn't own it results in undefined behavior.<br/>
* An assertion will abort the execution at runtime in debug mode in case of
* invalid entity or if the entity doesn't own an instance of the given
* component.
*
* @tparam Component Types of components to remove.
* @param entity A valid entity identifier.
*/
template<typename... Component>
void remove(const entity_type entity) {
ENTT_ASSERT(valid(entity));
(assure<Component>().remove(*this, entity), ...);
}
/**
* @brief Removes the given components from all the entities in a range.
*
* @see remove
*
* @tparam Component Types of components to remove.
* @tparam It Type of input iterator.
* @param first An iterator to the first element of the range of entities.
* @param last An iterator past the last element of the range of entities.
*/
template<typename... Component, typename It>
void remove(It first, It last) {
ENTT_ASSERT(std::all_of(first, last, [this](const auto entity) { return valid(entity); }));
(assure<Component>().remove(*this, first, last), ...);
}
/**
* @brief Removes the given components from an entity.
*
* Equivalent to the following snippet (pseudocode):
*
* @code{.cpp}
* if(registry.has<Component>(entity)) { registry.remove<Component>(entity) }
* @endcode
*
* Prefer this function anyway because it has slightly better performance.
*
* @warning
* Attempting to use an invalid entity results in undefined behavior.<br/>
* An assertion will abort the execution at runtime in debug mode in case of
* invalid entity.
*
* @tparam Component Types of components to remove.
* @param entity A valid entity identifier.
* @return The number of components actually removed.
*/
template<typename... Component>
size_type remove_if_exists(const entity_type entity) {
ENTT_ASSERT(valid(entity));
return ([this, entity](auto &&cpool) {
return cpool.contains(entity) ? (cpool.remove(*this, entity), true) : false;
}(assure<Component>()) + ... + size_type{});
}
/**
* @brief Removes all the components from an entity and makes it orphaned.
*
* @warning
* In case there are listeners that observe the destruction of components
* and assign other components to the entity in their bodies, the result of
* invoking this function may not be as expected. In the worst case, it
* could lead to undefined behavior.
*
* @warning
* Attempting to use an invalid entity results in undefined behavior.<br/>
* An assertion will abort the execution at runtime in debug mode in case of
* invalid entity.
*
* @param entity A valid entity identifier.
*/
void remove_all(const entity_type entity) {
ENTT_ASSERT(valid(entity));
for(auto pos = pools.size(); pos; --pos) {
if(auto &pdata = pools[pos-1]; pdata.pool && pdata.pool->contains(entity)) {
pdata.remove(*pdata.pool, *this, entity);
}
}
}
/**
* @brief Checks if an entity has all the given components.
*
* @warning
* Attempting to use an invalid entity results in undefined behavior.<br/>
* An assertion will abort the execution at runtime in debug mode in case of
* invalid entity.
*
* @tparam Component Components for which to perform the check.
* @param entity A valid entity identifier.
* @return True if the entity has all the components, false otherwise.
*/
template<typename... Component>
[[nodiscard]] bool has(const entity_type entity) const {
ENTT_ASSERT(valid(entity));
return (assure<Component>().contains(entity) && ...);
}
/**
* @brief Checks if an entity has at least one of the given components.
*
* @warning
* Attempting to use an invalid entity results in undefined behavior.<br/>
* An assertion will abort the execution at runtime in debug mode in case of
* invalid entity.
*
* @tparam Component Components for which to perform the check.
* @param entity A valid entity identifier.
* @return True if the entity has at least one of the given components,
* false otherwise.
*/
template<typename... Component>
[[nodiscard]] bool any(const entity_type entity) const {
ENTT_ASSERT(valid(entity));
return (assure<Component>().contains(entity) || ...);
}
/**
* @brief Returns references to the given components for an entity.
*
* @warning
* Attempting to use an invalid entity or to get a component from an entity
* that doesn't own it results in undefined behavior.<br/>
* An assertion will abort the execution at runtime in debug mode in case of
* invalid entity or if the entity doesn't own an instance of the given
* component.
*
* @tparam Component Types of components to get.
* @param entity A valid entity identifier.
* @return References to the components owned by the entity.
*/
template<typename... Component>
[[nodiscard]] decltype(auto) get([[maybe_unused]] const entity_type entity) const {
ENTT_ASSERT(valid(entity));
if constexpr(sizeof...(Component) == 1) {
return (assure<Component>().get(entity), ...);
} else {
return std::forward_as_tuple(get<Component>(entity)...);
}
}
/*! @copydoc get */
template<typename... Component>
[[nodiscard]] decltype(auto) get([[maybe_unused]] const entity_type entity) {
ENTT_ASSERT(valid(entity));
if constexpr(sizeof...(Component) == 1) {
return (assure<Component>().get(entity), ...);
} else {
return std::forward_as_tuple(get<Component>(entity)...);
}
}
/**
* @brief Returns a reference to the given component for an entity.
*
* In case the entity doesn't own the component, the parameters provided are
* used to construct it.<br/>
* Equivalent to the following snippet (pseudocode):
*
* @code{.cpp}
* auto &component = registry.has<Component>(entity) ? registry.get<Component>(entity) : registry.emplace<Component>(entity, args...);
* @endcode
*
* Prefer this function anyway because it has slightly better performance.
*
* @warning
* Attempting to use an invalid entity results in undefined behavior.<br/>
* An assertion will abort the execution at runtime in debug mode in case of
* invalid entity.
*
* @tparam Component Type of component to get.
* @tparam Args Types of arguments to use to construct the component.
* @param entity A valid entity identifier.
* @param args Parameters to use to initialize the component.
* @return Reference to the component owned by the entity.
*/
template<typename Component, typename... Args>
[[nodiscard]] decltype(auto) get_or_emplace(const entity_type entity, Args &&... args) {
ENTT_ASSERT(valid(entity));
auto &cpool = assure<Component>();
return cpool.contains(entity) ? cpool.get(entity) : cpool.emplace(*this, entity, std::forward<Args>(args)...);
}
/**
* @brief Returns pointers to the given components for an entity.
*
* @warning
* Attempting to use an invalid entity results in undefined behavior.<br/>
* An assertion will abort the execution at runtime in debug mode in case of
* invalid entity.
*
* @tparam Component Types of components to get.
* @param entity A valid entity identifier.
* @return Pointers to the components owned by the entity.
*/
template<typename... Component>
[[nodiscard]] auto try_get([[maybe_unused]] const entity_type entity) const {
ENTT_ASSERT(valid(entity));
if constexpr(sizeof...(Component) == 1) {
return (assure<Component>().try_get(entity), ...);
} else {
return std::make_tuple(try_get<Component>(entity)...);
}
}
/*! @copydoc try_get */
template<typename... Component>
[[nodiscard]] auto try_get([[maybe_unused]] const entity_type entity) {
ENTT_ASSERT(valid(entity));
if constexpr(sizeof...(Component) == 1) {
return (assure<Component>().try_get(entity), ...);
} else {
return std::make_tuple(try_get<Component>(entity)...);
}
}
/**
* @brief Clears a whole registry or the pools for the given components.
* @tparam Component Types of components to remove from their entities.
*/
template<typename... Component>
void clear() {
if constexpr(sizeof...(Component) == 0) {
// useless this-> used to suppress a warning with clang
each([this](const auto entity) { this->destroy(entity); });
} else {
([this](auto &&cpool) {
cpool.remove(*this, cpool.sparse_set<entity_type>::begin(), cpool.sparse_set<entity_type>::end());
}(assure<Component>()), ...);
}
}
/**
* @brief Iterates all the entities that are still in use.
*
* The function object is invoked for each entity that is still in use.<br/>
* The signature of the function should be equivalent to the following:
*
* @code{.cpp}
* void(const Entity);
* @endcode
*
* This function is fairly slow and should not be used frequently. However,
* it's useful for iterating all the entities still in use, regardless of
* their components.
*
* @tparam Func Type of the function object to invoke.
* @param func A valid function object.
*/
template<typename Func>
void each(Func func) const {
if(destroyed == null) {
for(auto pos = entities.size(); pos; --pos) {
func(entities[pos-1]);
}
} else {
for(auto pos = entities.size(); pos; --pos) {
if(const auto entt = entities[pos - 1]; (to_integral(entt) & traits_type::entity_mask) == (pos - 1)) {
func(entt);
}
}
}
}
/**
* @brief Checks if an entity has components assigned.
* @param entity A valid entity identifier.
* @return True if the entity has no components assigned, false otherwise.
*/
[[nodiscard]] bool orphan(const entity_type entity) const {
ENTT_ASSERT(valid(entity));
return std::none_of(pools.cbegin(), pools.cend(), [entity](auto &&pdata) { return pdata.pool && pdata.pool->contains(entity); });
}
/**
* @brief Iterates orphans and applies them the given function object.
*
* The function object is invoked for each entity that is still in use and
* has no components assigned.<br/>
* The signature of the function should be equivalent to the following:
*
* @code{.cpp}
* void(const Entity);
* @endcode
*
* This function can be very slow and should not be used frequently.
*
* @tparam Func Type of the function object to invoke.
* @param func A valid function object.
*/
template<typename Func>
void orphans(Func func) const {
each([this, &func](const auto entity) {
if(orphan(entity)) {
func(entity);
}
});
}
/**
* @brief Returns a sink object for the given component.
*
* A sink is an opaque object used to connect listeners to components.<br/>
* The sink returned by this function can be used to receive notifications
* whenever a new instance of the given component is created and assigned to
* an entity.
*
* The function type for a listener is equivalent to:
*
* @code{.cpp}
* void(registry<Entity> &, Entity);
* @endcode
*
* Listeners are invoked **after** the component has been assigned to the
* entity.
*
* @sa sink
*
* @tparam Component Type of component of which to get the sink.
* @return A temporary sink object.
*/
template<typename Component>
[[nodiscard]] auto on_construct() {
return assure<Component>().on_construct();
}
/**
* @brief Returns a sink object for the given component.
*
* A sink is an opaque object used to connect listeners to components.<br/>
* The sink returned by this function can be used to receive notifications
* whenever an instance of the given component is explicitly updated.
*
* The function type for a listener is equivalent to:
*
* @code{.cpp}
* void(registry<Entity> &, Entity);
* @endcode
*
* Listeners are invoked **after** the component has been updated.
*
* @sa sink
*
* @tparam Component Type of component of which to get the sink.
* @return A temporary sink object.
*/
template<typename Component>
[[nodiscard]] auto on_update() {
return assure<Component>().on_update();
}
/**
* @brief Returns a sink object for the given component.
*
* A sink is an opaque object used to connect listeners to components.<br/>
* The sink returned by this function can be used to receive notifications
* whenever an instance of the given component is removed from an entity and
* thus destroyed.
*
* The function type for a listener is equivalent to:
*
* @code{.cpp}
* void(registry<Entity> &, Entity);
* @endcode
*
* Listeners are invoked **before** the component has been removed from the
* entity.
*
* @sa sink
*
* @tparam Component Type of component of which to get the sink.
* @return A temporary sink object.
*/
template<typename Component>
[[nodiscard]] auto on_destroy() {
return assure<Component>().on_destroy();
}
/**
* @brief Returns a view for the given components.
*
* This kind of objects are created on the fly and share with the registry
* its internal data structures.<br/>
* Feel free to discard a view after the use. Creating and destroying a view
* is an incredibly cheap operation because they do not require any type of
* initialization.<br/>
* As a rule of thumb, storing a view should never be an option.
*
* Views do their best to iterate the smallest set of candidate entities.
* In particular:
*
* * Single component views are incredibly fast and iterate a packed array
* of entities, all of which has the given component.
* * Multi component views look at the number of entities available for each
* component and pick up a reference to the smallest set of candidates to
* test for the given components.
*
* Views in no way affect the functionalities of the registry nor those of
* the underlying pools.
*
* @note
* Multi component views are pretty fast. However their performance tend to
* degenerate when the number of components to iterate grows up and the most
* of the entities have all the given components.<br/>
* To get a performance boost, consider using a group instead.
*
* @tparam Component Type of components used to construct the view.
* @tparam Exclude Types of components used to filter the view.
* @return A newly created view.
*/
template<typename... Component, typename... Exclude>
[[nodiscard]] basic_view<Entity, exclude_t<Exclude...>, Component...> view(exclude_t<Exclude...> = {}) const {
static_assert(sizeof...(Component) > 0, "Exclusion-only views are not supported");
return { assure<std::decay_t<Component>>()..., assure<Exclude>()... };
}
/*! @copydoc view */
template<typename... Component, typename... Exclude>
[[nodiscard]] basic_view<Entity, exclude_t<Exclude...>, Component...> view(exclude_t<Exclude...> = {}) {
static_assert(sizeof...(Component) > 0, "Exclusion-only views are not supported");
return { assure<std::decay_t<Component>>()..., assure<Exclude>()... };
}
/**
* @brief Returns a runtime view for the given components.
*
* This kind of objects are created on the fly and share with the registry
* its internal data structures.<br/>
* Users should throw away the view after use. Fortunately, creating and
* destroying a runtime view is an incredibly cheap operation because they
* do not require any type of initialization.<br/>
* As a rule of thumb, storing a view should never be an option.
*
* Runtime views are to be used when users want to construct a view from
* some external inputs and don't know at compile-time what are the required
* components.
*
* @tparam ItComp Type of input iterator for the components to use to
* construct the view.
* @tparam ItExcl Type of input iterator for the components to use to filter
* the view.
* @param first An iterator to the first element of the range of components
* to use to construct the view.
* @param last An iterator past the last element of the range of components
* to use to construct the view.
* @param from An iterator to the first element of the range of components
* to use to filter the view.
* @param to An iterator past the last element of the range of components to
* use to filter the view.
* @return A newly created runtime view.
*/
template<typename ItComp, typename ItExcl = id_type *>
[[nodiscard]] basic_runtime_view<Entity> runtime_view(ItComp first, ItComp last, ItExcl from = {}, ItExcl to = {}) const {
std::vector<const sparse_set<Entity> *> component(std::distance(first, last));
std::vector<const sparse_set<Entity> *> filter(std::distance(from, to));
std::transform(first, last, component.begin(), [this](const auto ctype) {
const auto it = std::find_if(pools.cbegin(), pools.cend(), [ctype](auto &&pdata) { return pdata.pool && pdata.type_id == ctype; });
return it == pools.cend() ? nullptr : it->pool.get();
});
std::transform(from, to, filter.begin(), [this](const auto ctype) {
const auto it = std::find_if(pools.cbegin(), pools.cend(), [ctype](auto &&pdata) { return pdata.pool && pdata.type_id == ctype; });
return it == pools.cend() ? nullptr : it->pool.get();
});
return { std::move(component), std::move(filter) };
}
/**
* @brief Returns a group for the given components.
*
* This kind of objects are created on the fly and share with the registry
* its internal data structures.<br/>
* Feel free to discard a group after the use. Creating and destroying a
* group is an incredibly cheap operation because they do not require any
* type of initialization, but for the first time they are requested.<br/>
* As a rule of thumb, storing a group should never be an option.
*
* Groups support exclusion lists and can own types of components. The more
* types are owned by a group, the faster it is to iterate entities and
* components.<br/>
* However, groups also affect some features of the registry such as the
* creation and destruction of components, which will consequently be
* slightly slower (nothing that can be noticed in most cases).
*
* @note
* Pools of components that are owned by a group cannot be sorted anymore.
* The group takes the ownership of the pools and arrange components so as
* to iterate them as fast as possible.
*
* @tparam Owned Types of components owned by the group.
* @tparam Get Types of components observed by the group.
* @tparam Exclude Types of components used to filter the group.
* @return A newly created group.
*/
template<typename... Owned, typename... Get, typename... Exclude>
[[nodiscard]] basic_group<Entity, exclude_t<Exclude...>, get_t<Get...>, Owned...> group(get_t<Get...>, exclude_t<Exclude...> = {}) {
static_assert(sizeof...(Owned) + sizeof...(Get) > 0, "Exclusion-only views are not supported");
static_assert(sizeof...(Owned) + sizeof...(Get) + sizeof...(Exclude) > 1, "Single component groups are not allowed");
using handler_type = group_handler<exclude_t<Exclude...>, get_t<std::decay_t<Get>...>, std::decay_t<Owned>...>;
const auto cpools = std::forward_as_tuple(assure<std::decay_t<Owned>>()..., assure<std::decay_t<Get>>()...);
constexpr auto size = sizeof...(Owned) + sizeof...(Get) + sizeof...(Exclude);
handler_type *handler = nullptr;
if(auto it = std::find_if(groups.cbegin(), groups.cend(), [size](const auto &gdata) {
return gdata.size == size
&& (gdata.owned(type_info<std::decay_t<Owned>>::id()) && ...)
&& (gdata.get(type_info<std::decay_t<Get>>::id()) && ...)
&& (gdata.exclude(type_info<Exclude>::id()) && ...);
}); it != groups.cend())
{
handler = static_cast<handler_type *>(it->group.get());
}
if(!handler) {
group_data candidate = {
size,
{ new handler_type{}, [](void *instance) { delete static_cast<handler_type *>(instance); } },
[]([[maybe_unused]] const id_type ctype) ENTT_NOEXCEPT { return ((ctype == type_info<std::decay_t<Owned>>::id()) || ...); },
[]([[maybe_unused]] const id_type ctype) ENTT_NOEXCEPT { return ((ctype == type_info<std::decay_t<Get>>::id()) || ...); },
[]([[maybe_unused]] const id_type ctype) ENTT_NOEXCEPT { return ((ctype == type_info<Exclude>::id()) || ...); },
};
handler = static_cast<handler_type *>(candidate.group.get());
const void *maybe_valid_if = nullptr;
const void *discard_if = nullptr;
if constexpr(sizeof...(Owned) == 0) {
groups.push_back(std::move(candidate));
} else {
ENTT_ASSERT(std::all_of(groups.cbegin(), groups.cend(), [size](const auto &gdata) {
const auto overlapping = (0u + ... + gdata.owned(type_info<std::decay_t<Owned>>::id()));
const auto sz = overlapping + (0u + ... + gdata.get(type_info<std::decay_t<Get>>::id())) + (0u + ... + gdata.exclude(type_info<Exclude>::id()));
return !overlapping || ((sz == size) || (sz == gdata.size));
}));
const auto next = std::find_if_not(groups.cbegin(), groups.cend(), [size](const auto &gdata) {
return !(0u + ... + gdata.owned(type_info<std::decay_t<Owned>>::id())) || (size > gdata.size);
});
const auto prev = std::find_if(std::make_reverse_iterator(next), groups.crend(), [](const auto &gdata) {
return (0u + ... + gdata.owned(type_info<std::decay_t<Owned>>::id()));
});
maybe_valid_if = (next == groups.cend() ? maybe_valid_if : next->group.get());
discard_if = (prev == groups.crend() ? discard_if : prev->group.get());
groups.insert(next, std::move(candidate));
}
(on_construct<std::decay_t<Owned>>().before(maybe_valid_if).template connect<&handler_type::template maybe_valid_if<std::decay_t<Owned>>>(*handler), ...);
(on_construct<std::decay_t<Get>>().before(maybe_valid_if).template connect<&handler_type::template maybe_valid_if<std::decay_t<Get>>>(*handler), ...);
(on_destroy<Exclude>().before(maybe_valid_if).template connect<&handler_type::template maybe_valid_if<Exclude>>(*handler), ...);
(on_destroy<std::decay_t<Owned>>().before(discard_if).template connect<&handler_type::discard_if>(*handler), ...);
(on_destroy<std::decay_t<Get>>().before(discard_if).template connect<&handler_type::discard_if>(*handler), ...);
(on_construct<Exclude>().before(discard_if).template connect<&handler_type::discard_if>(*handler), ...);
if constexpr(sizeof...(Owned) == 0) {
for(const auto entity: view<Owned..., Get...>(exclude<Exclude...>)) {
handler->current.emplace(entity);
}
} else {
// we cannot iterate backwards because we want to leave behind valid entities in case of owned types
for(auto *first = std::get<0>(cpools).data(), *last = first + std::get<0>(cpools).size(); first != last; ++first) {
handler->template maybe_valid_if<std::tuple_element_t<0, std::tuple<std::decay_t<Owned>...>>>(*this, *first);
}
}
}
if constexpr(sizeof...(Owned) == 0) {
return { handler->current, std::get<pool_handler<std::decay_t<Get>> &>(cpools)... };
} else {
return { handler->current, std::get<pool_handler<std::decay_t<Owned>> &>(cpools)... , std::get<pool_handler<std::decay_t<Get>> &>(cpools)... };
}
}
/**
* @brief Returns a group for the given components.
*
* @sa group
*
* @tparam Owned Types of components owned by the group.
* @tparam Get Types of components observed by the group.
* @tparam Exclude Types of components used to filter the group.
* @return A newly created group.
*/
template<typename... Owned, typename... Get, typename... Exclude>
[[nodiscard]] basic_group<Entity, exclude_t<Exclude...>, get_t<Get...>, Owned...> group(get_t<Get...>, exclude_t<Exclude...> = {}) const {
static_assert(std::conjunction_v<std::is_const<Owned>..., std::is_const<Get>...>, "Invalid non-const type");
return const_cast<basic_registry *>(this)->group<Owned...>(get_t<Get...>{}, exclude<Exclude...>);
}
/**
* @brief Returns a group for the given components.
*
* @sa group
*
* @tparam Owned Types of components owned by the group.
* @tparam Exclude Types of components used to filter the group.
* @return A newly created group.
*/
template<typename... Owned, typename... Exclude>
[[nodiscard]] basic_group<Entity, exclude_t<Exclude...>, get_t<>, Owned...> group(exclude_t<Exclude...> = {}) {
return group<Owned...>(get_t<>{}, exclude<Exclude...>);
}
/**
* @brief Returns a group for the given components.
*
* @sa group
*
* @tparam Owned Types of components owned by the group.
* @tparam Exclude Types of components used to filter the group.
* @return A newly created group.
*/
template<typename... Owned, typename... Exclude>
[[nodiscard]] basic_group<Entity, exclude_t<Exclude...>, get_t<>, Owned...> group(exclude_t<Exclude...> = {}) const {
static_assert(std::conjunction_v<std::is_const<Owned>...>, "Invalid non-const type");
return const_cast<basic_registry *>(this)->group<Owned...>(exclude<Exclude...>);
}
/**
* @brief Checks whether the given components belong to any group.
* @tparam Component Types of components in which one is interested.
* @return True if the pools of the given components are sortable, false
* otherwise.
*/
template<typename... Component>
[[nodiscard]] bool sortable() const {
return std::none_of(groups.cbegin(), groups.cend(), [](auto &&gdata) { return (gdata.owned(type_info<std::decay_t<Component>>::id()) || ...); });
}
/**
* @brief Checks whether a group can be sorted.
* @tparam Owned Types of components owned by the group.
* @tparam Get Types of components observed by the group.
* @tparam Exclude Types of components used to filter the group.
* @return True if the group can be sorted, false otherwise.
*/
template<typename... Owned, typename... Get, typename... Exclude>
[[nodiscard]] bool sortable(const basic_group<Entity, exclude_t<Exclude...>, get_t<Get...>, Owned...> &) ENTT_NOEXCEPT {
constexpr auto size = sizeof...(Owned) + sizeof...(Get) + sizeof...(Exclude);
return std::find_if(groups.cbegin(), groups.cend(), [size](const auto &gdata) {
return (0u + ... + gdata.owned(type_info<std::decay_t<Owned>>::id())) && (size < gdata.size);
}) == groups.cend();
}
/**
* @brief Sorts the pool of entities for the given component.
*
* The order of the elements in a pool is highly affected by assignments
* of components to entities and deletions. Components are arranged to
* maximize the performance during iterations and users should not make any
* assumption on the order.<br/>
* This function can be used to impose an order to the elements in the pool
* of the given component. The order is kept valid until a component of the
* given type is assigned or removed from an entity.
*
* The comparison function object must return `true` if the first element
* is _less_ than the second one, `false` otherwise. The signature of the
* comparison function should be equivalent to one of the following:
*
* @code{.cpp}
* bool(const Entity, const Entity);
* bool(const Component &, const Component &);
* @endcode
*
* Moreover, the comparison function object shall induce a
* _strict weak ordering_ on the values.
*
* The sort function oject must offer a member function template
* `operator()` that accepts three arguments:
*
* * An iterator to the first element of the range to sort.
* * An iterator past the last element of the range to sort.
* * A comparison function to use to compare the elements.
*
* The comparison funtion object received by the sort function object hasn't
* necessarily the type of the one passed along with the other parameters to
* this member function.
*
* @warning
* Pools of components owned by a group cannot be sorted.<br/>
* An assertion will abort the execution at runtime in debug mode in case
* the pool is owned by a group.
*
* @tparam Component Type of components to sort.
* @tparam Compare Type of comparison function object.
* @tparam Sort Type of sort function object.
* @tparam Args Types of arguments to forward to the sort function object.
* @param compare A valid comparison function object.
* @param algo A valid sort function object.
* @param args Arguments to forward to the sort function object, if any.
*/
template<typename Component, typename Compare, typename Sort = std_sort, typename... Args>
void sort(Compare compare, Sort algo = Sort{}, Args &&... args) {
ENTT_ASSERT(sortable<Component>());
auto &cpool = assure<Component>();
cpool.sort(cpool.begin(), cpool.end(), std::move(compare), std::move(algo), std::forward<Args>(args)...);
}
/**
* @brief Sorts two pools of components in the same way.
*
* The order of the elements in a pool is highly affected by assignments
* of components to entities and deletions. Components are arranged to
* maximize the performance during iterations and users should not make any
* assumption on the order.
*
* It happens that different pools of components must be sorted the same way
* because of runtime and/or performance constraints. This function can be
* used to order a pool of components according to the order between the
* entities in another pool of components.
*
* @b How @b it @b works
*
* Being `A` and `B` the two sets where `B` is the master (the one the order
* of which rules) and `A` is the slave (the one to sort), after a call to
* this function an iterator for `A` will return the entities according to
* the following rules:
*
* * All the entities in `A` that are also in `B` are returned first
* according to the order they have in `B`.
* * All the entities in `A` that are not in `B` are returned in no
* particular order after all the other entities.
*
* Any subsequent change to `B` won't affect the order in `A`.
*
* @warning
* Pools of components owned by a group cannot be sorted.<br/>
* An assertion will abort the execution at runtime in debug mode in case
* the pool is owned by a group.
*
* @tparam To Type of components to sort.
* @tparam From Type of components to use to sort.
*/
template<typename To, typename From>
void sort() {
ENTT_ASSERT(sortable<To>());
assure<To>().respect(assure<From>());
}
/**
* @brief Visits an entity and returns the types for its components.
*
* The signature of the function should be equivalent to the following:
*
* @code{.cpp}
* void(const id_type);
* @endcode
*
* Returned identifiers are those of the components owned by the entity.
*
* @sa type_info
*
* @warning
* It's not specified whether a component attached to or removed from the
* given entity during the visit is returned or not to the caller.
*
* @tparam Func Type of the function object to invoke.
* @param entity A valid entity identifier.
* @param func A valid function object.
*/
template<typename Func>
void visit(entity_type entity, Func func) const {
for(auto pos = pools.size(); pos; --pos) {
if(const auto &pdata = pools[pos-1]; pdata.pool && pdata.pool->contains(entity)) {
func(pdata.type_id);
}
}
}
/**
* @brief Visits a registry and returns the types for its components.
*
* The signature of the function should be equivalent to the following:
*
* @code{.cpp}
* void(const id_type);
* @endcode
*
* Returned identifiers are those of the components managed by the registry.
*
* @sa type_info
*
* @warning
* It's not specified whether a component for which a pool is created during
* the visit is returned or not to the caller.
*
* @tparam Func Type of the function object to invoke.
* @param func A valid function object.
*/
template<typename Func>
void visit(Func func) const {
for(auto pos = pools.size(); pos; --pos) {
if(const auto &pdata = pools[pos-1]; pdata.pool) {
func(pdata.type_id);
}
}
}
/**
* @brief Binds an object to the context of the registry.
*
* If the value already exists it is overwritten, otherwise a new instance
* of the given type is created and initialized with the arguments provided.
*
* @tparam Type Type of object to set.
* @tparam Args Types of arguments to use to construct the object.
* @param args Parameters to use to initialize the value.
* @return A reference to the newly created object.
*/
template<typename Type, typename... Args>
Type & set(Args &&... args) {
unset<Type>();
vars.push_back(variable_data{type_info<Type>::id(), { new Type{std::forward<Args>(args)...}, [](void *instance) { delete static_cast<Type *>(instance); } }});
return *static_cast<Type *>(vars.back().value.get());
}
/**
* @brief Unsets a context variable if it exists.
* @tparam Type Type of object to set.
*/
template<typename Type>
void unset() {
vars.erase(std::remove_if(vars.begin(), vars.end(), [](auto &&var) {
return var.type_id == type_info<Type>::id();
}), vars.end());
}
/**
* @brief Binds an object to the context of the registry.
*
* In case the context doesn't contain the given object, the parameters
* provided are used to construct it.
*
* @tparam Type Type of object to set.
* @tparam Args Types of arguments to use to construct the object.
* @param args Parameters to use to initialize the object.
* @return A reference to the object in the context of the registry.
*/
template<typename Type, typename... Args>
[[nodiscard]] Type & ctx_or_set(Args &&... args) {
auto *value = try_ctx<Type>();
return value ? *value : set<Type>(std::forward<Args>(args)...);
}
/**
* @brief Returns a pointer to an object in the context of the registry.
* @tparam Type Type of object to get.
* @return A pointer to the object if it exists in the context of the
* registry, a null pointer otherwise.
*/
template<typename Type>
[[nodiscard]] const Type * try_ctx() const {
auto it = std::find_if(vars.cbegin(), vars.cend(), [](auto &&var) { return var.type_id == type_info<Type>::id(); });
return it == vars.cend() ? nullptr : static_cast<const Type *>(it->value.get());
}
/*! @copydoc try_ctx */
template<typename Type>
[[nodiscard]] Type * try_ctx() {
return const_cast<Type *>(std::as_const(*this).template try_ctx<Type>());
}
/**
* @brief Returns a reference to an object in the context of the registry.
*
* @warning
* Attempting to get a context variable that doesn't exist results in
* undefined behavior.<br/>
* An assertion will abort the execution at runtime in debug mode in case of
* invalid requests.
*
* @tparam Type Type of object to get.
* @return A valid reference to the object in the context of the registry.
*/
template<typename Type>
[[nodiscard]] const Type & ctx() const {
const auto *instance = try_ctx<Type>();
ENTT_ASSERT(instance);
return *instance;
}
/*! @copydoc ctx */
template<typename Type>
[[nodiscard]] Type & ctx() {
return const_cast<Type &>(std::as_const(*this).template ctx<Type>());
}
/**
* @brief Visits a registry and returns the types for its context variables.
*
* The signature of the function should be equivalent to the following:
*
* @code{.cpp}
* void(const id_type);
* @endcode
*
* Returned identifiers are those of the context variables currently set.
*
* @sa type_info
*
* @warning
* It's not specified whether a context variable created during the visit is
* returned or not to the caller.
*
* @tparam Func Type of the function object to invoke.
* @param func A valid function object.
*/
template<typename Func>
void ctx(Func func) const {
for(auto pos = vars.size(); pos; --pos) {
func(vars[pos-1].type_id);
}
}
private:
std::vector<group_data> groups{};
mutable std::vector<pool_data> pools{};
std::vector<entity_type> entities{};
std::vector<variable_data> vars{};
entity_type destroyed{null};
};
}
#endif
// #include "entity.hpp"
// #include "fwd.hpp"
namespace entt {
/**
* @brief Dedicated to those who aren't confident with the
* entity-component-system architecture.
*
* Tiny wrapper around a registry, for all those users that aren't confident
* with entity-component-system architecture and prefer to iterate objects
* directly.
*
* @tparam Entity A valid entity type (see entt_traits for more details).
*/
template<typename Entity>
struct [[deprecated("Consider using the handle class instead")]] basic_actor {
/*! @brief Type of registry used internally. */
using registry_type = basic_registry<Entity>;
/*! @brief Underlying entity identifier. */
using entity_type = Entity;
basic_actor() ENTT_NOEXCEPT
: entt{null}, reg{nullptr}
{}
/**
* @brief Move constructor.
*
* After actor move construction, instances that have been moved from are
* placed in a valid but unspecified state. It's highly discouraged to
* continue using them.
*
* @param other The instance to move from.
*/
basic_actor(basic_actor &&other) ENTT_NOEXCEPT
: entt{other.entt}, reg{other.reg}
{
other.entt = null;
}
/**
* @brief Constructs an actor from a given registry.
* @param ref An instance of the registry class.
*/
explicit basic_actor(registry_type &ref)
: entt{ref.create()}, reg{&ref}
{}
/**
* @brief Constructs an actor from a given entity.
* @param entity A valid entity identifier.
* @param ref An instance of the registry class.
*/
explicit basic_actor(entity_type entity, registry_type &ref) ENTT_NOEXCEPT
: entt{entity}, reg{&ref}
{
ENTT_ASSERT(ref.valid(entity));
}
/*! @brief Default destructor. */
virtual ~basic_actor() {
if(*this) {
reg->destroy(entt);
}
}
/**
* @brief Move assignment operator.
*
* After actor move assignment, instances that have been moved from are
* placed in a valid but unspecified state. It's highly discouraged to
* continue using them.
*
* @param other The instance to move from.
* @return This actor.
*/
basic_actor & operator=(basic_actor &&other) ENTT_NOEXCEPT {
if(this != &other) {
auto tmp{std::move(other)};
std::swap(reg, tmp.reg);
std::swap(entt, tmp.entt);
}
return *this;
}
/**
* @brief Assigns the given component to an actor.
*
* A new instance of the given component is created and initialized with the
* arguments provided (the component must have a proper constructor or be of
* aggregate type). Then the component is assigned to the actor.<br/>
* In case the actor already has a component of the given type, it's
* replaced with the new one.
*
* @tparam Component Type of the component to create.
* @tparam Args Types of arguments to use to construct the component.
* @param args Parameters to use to initialize the component.
* @return A reference to the newly created component.
*/
template<typename Component, typename... Args>
decltype(auto) assign(Args &&... args) {
return reg->template emplace_or_replace<Component>(entt, std::forward<Args>(args)...);
}
/**
* @brief Removes the given component from an actor.
* @tparam Component Type of the component to remove.
*/
template<typename Component>
void remove() {
reg->template remove<Component>(entt);
}
/**
* @brief Checks if an actor has the given components.
* @tparam Component Components for which to perform the check.
* @return True if the actor has all the components, false otherwise.
*/
template<typename... Component>
[[nodiscard]] bool has() const {
return reg->template has<Component...>(entt);
}
/**
* @brief Returns references to the given components for an actor.
* @tparam Component Types of components to get.
* @return References to the components owned by the actor.
*/
template<typename... Component>
[[nodiscard]] decltype(auto) get() const {
return std::as_const(*reg).template get<Component...>(entt);
}
/*! @copydoc get */
template<typename... Component>
[[nodiscard]] decltype(auto) get() {
return reg->template get<Component...>(entt);
}
/**
* @brief Returns pointers to the given components for an actor.
* @tparam Component Types of components to get.
* @return Pointers to the components owned by the actor.
*/
template<typename... Component>
[[nodiscard]] auto try_get() const {
return std::as_const(*reg).template try_get<Component...>(entt);
}
/*! @copydoc try_get */
template<typename... Component>
[[nodiscard]] auto try_get() {
return reg->template try_get<Component...>(entt);
}
/**
* @brief Returns a reference to the underlying registry.
* @return A reference to the underlying registry.
*/
[[nodiscard]] const registry_type & backend() const ENTT_NOEXCEPT {
return *reg;
}
/*! @copydoc backend */
[[nodiscard]] registry_type & backend() ENTT_NOEXCEPT {
return const_cast<registry_type &>(std::as_const(*this).backend());
}
/**
* @brief Returns the entity associated with an actor.
* @return The entity associated with the actor.
*/
[[nodiscard]] entity_type entity() const ENTT_NOEXCEPT {
return entt;
}
/**
* @brief Checks if an actor refers to a valid entity or not.
* @return True if the actor refers to a valid entity, false otherwise.
*/
[[nodiscard]] explicit operator bool() const {
return reg && reg->valid(entt);
}
private:
entity_type entt;
registry_type *reg;
};
}
#endif
// #include "entity/entity.hpp"
// #include "entity/group.hpp"
// #include "entity/handle.hpp"
#ifndef ENTT_ENTITY_HANDLE_HPP
#define ENTT_ENTITY_HANDLE_HPP
// #include "registry.hpp"
namespace entt {
/**
* @brief Non-owning handle to an entity.
*
* Tiny wrapper around a registry and an entity.
*
* @tparam Entity A valid entity type (see entt_traits for more details).
*/
template<typename Entity>
struct basic_handle {
/*! @brief Underlying entity identifier. */
using entity_type = std::remove_const_t<Entity>;
/*! @brief Type of registry accepted by the handle. */
using registry_type = std::conditional_t<
std::is_const_v<Entity>,
const basic_registry<entity_type>,
basic_registry<entity_type>
>;
/**
* @brief Constructs a handle from a given registry and entity.
* @param ref An instance of the registry class.
* @param value An entity identifier.
*/
basic_handle(registry_type &ref, entity_type value = null) ENTT_NOEXCEPT
: reg{&ref}, entt{value}
{}
/**
* @brief Assigns an entity to a handle.
* @param value An entity identifier.
* @return This handle.
*/
basic_handle & operator=(const entity_type value) ENTT_NOEXCEPT {
entt = value;
return *this;
}
/**
* @brief Assigns the null object to a handle.
* @return This handle.
*/
basic_handle & operator=(null_t) ENTT_NOEXCEPT {
return (*this = static_cast<entity_type>(null));
}
/**
* @brief Constructs a const handle from a non-const one.
* @return A const handle referring to the same entity.
*/
[[nodiscard]] operator basic_handle<const entity_type>() const ENTT_NOEXCEPT {
return {*reg, entt};
}
/**
* @brief Converts a handle to its underlying entity.
* @return An entity identifier.
*/
[[nodiscard]] operator entity_type() const ENTT_NOEXCEPT {
return entity();
}
/**
* @brief Checks if a handle refers to a valid entity or not.
* @return True if the handle refers to a valid entity, false otherwise.
*/
[[nodiscard]] explicit operator bool() const {
return reg->valid(entt);
}
/**
* @brief Returns a reference to the underlying registry.
* @return A reference to the underlying registry.
*/
[[nodiscard]] registry_type & registry() const ENTT_NOEXCEPT {
return *reg;
}
/**
* @brief Returns the entity associated with a handle.
* @return The entity associated with the handle.
*/
[[nodiscard]] entity_type entity() const ENTT_NOEXCEPT {
return entt;
}
/**
* @brief Assigns the given component to a handle.
* @sa basic_registry::emplace
* @tparam Component Type of component to create.
* @tparam Args Types of arguments to use to construct the component.
* @param args Parameters to use to initialize the component.
* @return A reference to the newly created component.
*/
template<typename Component, typename... Args>
decltype(auto) emplace(Args &&... args) const {
return reg->template emplace<Component>(entt, std::forward<Args>(args)...);
}
/**
* @brief Assigns or replaces the given component for a handle.
* @sa basic_registry::emplace_or_replace
* @tparam Component Type of component to assign or replace.
* @tparam Args Types of arguments to use to construct the component.
* @param args Parameters to use to initialize the component.
* @return A reference to the newly created component.
*/
template<typename Component, typename... Args>
decltype(auto) emplace_or_replace(Args &&... args) const {
return reg->template emplace_or_replace<Component>(entt, std::forward<Args>(args)...);
}
/**
* @brief Patches the given component for a handle.
* @sa basic_registry::patch
* @tparam Component Type of component to patch.
* @tparam Func Types of the function objects to invoke.
* @param func Valid function objects.
* @return A reference to the patched component.
*/
template<typename Component, typename... Func>
decltype(auto) patch(Func &&... func) const {
return reg->template patch<Component>(entt, std::forward<Func>(func)...);
}
/**
* @brief Replaces the given component for a handle.
* @sa basic_registry::replace
* @tparam Component Type of component to replace.
* @tparam Args Types of arguments to use to construct the component.
* @param args Parameters to use to initialize the component.
* @return A reference to the component being replaced.
*/
template<typename Component, typename... Args>
decltype(auto) replace(Args &&... args) const {
return reg->template replace<Component>(entt, std::forward<Args>(args)...);
}
/**
* @brief Removes the given components from a handle.
* @sa basic_registry::remove
* @tparam Component Types of components to remove.
*/
template<typename... Components>
void remove() const {
reg->template remove<Components...>(entt);
}
/**
* @brief Removes the given components from a handle.
* @sa basic_registry::remove_if_exists
* @tparam Component Types of components to remove.
* @return The number of components actually removed.
*/
template<typename... Components>
decltype(auto) remove_if_exists() const {
return reg->template remove_if_exists<Components...>(entt);
}
/**
* @brief Removes all the components from a handle and makes it orphaned.
* @sa basic_registry::remove_all
*/
void remove_all() const {
reg->remove_all(entt);
}
/**
* @brief Checks if a handle has all the given components.
* @sa basic_registry::has
* @tparam Component Components for which to perform the check.
* @return True if the handle has all the components, false otherwise.
*/
template<typename... Components>
[[nodiscard]] decltype(auto) has() const {
return reg->template has<Components...>(entt);
}
/**
* @brief Checks if a handle has at least one of the given components.
* @sa basic_registry::any
* @tparam Component Components for which to perform the check.
* @return True if the handle has at least one of the given components,
* false otherwise.
*/
template<typename... Components>
[[nodiscard]] decltype(auto) any() const {
return reg->template any<Components...>(entt);
}
/**
* @brief Returns references to the given components for a handle.
* @sa basic_registry::get
* @tparam Component Types of components to get.
* @return References to the components owned by the handle.
*/
template<typename... Components>
[[nodiscard]] decltype(auto) get() const {
return reg->template get<Components...>(entt);
}
/**
* @brief Returns a reference to the given component for a handle.
* @sa basic_registry::get_or_emplace
* @tparam Component Type of component to get.
* @tparam Args Types of arguments to use to construct the component.
* @param args Parameters to use to initialize the component.
* @return Reference to the component owned by the handle.
*/
template<typename Component, typename... Args>
[[nodiscard]] decltype(auto) get_or_emplace(Args &&... args) const {
return reg->template get_or_emplace<Component>(entt, std::forward<Args>(args)...);
}
/**
* @brief Returns pointers to the given components for a handle.
* @sa basic_registry::try_get
* @tparam Component Types of components to get.
* @return Pointers to the components owned by the handle.
*/
template<typename... Components>
[[nodiscard]] decltype(auto) try_get() const {
return reg->template try_get<Components...>(entt);
}
/**
* @brief Checks if a handle has components assigned.
* @return True if the handle has no components assigned, false otherwise.
*/
[[nodiscard]] bool orphan() const {
return reg->orphan(entt);
}
/**
* @brief Visits a handle and returns the types for its components.
* @sa basic_registry::visit
* @tparam Func Type of the function object to invoke.
* @param func A valid function object.
*/
template<typename Func>
void visit(Func &&func) const {
reg->visit(entt, std::forward<Func>(func));
}
private:
registry_type *reg;
entity_type entt;
};
/**
* @brief Deduction guide.
* @tparam Entity A valid entity type (see entt_traits for more details).
*/
template<typename Entity>
basic_handle(basic_registry<Entity> &, Entity) -> basic_handle<Entity>;
/**
* @brief Deduction guide.
* @tparam Entity A valid entity type (see entt_traits for more details).
*/
template<typename Entity>
basic_handle(const basic_registry<Entity> &, Entity) -> basic_handle<const Entity>;
}
#endif
// #include "entity/helper.hpp"
#ifndef ENTT_ENTITY_HELPER_HPP
#define ENTT_ENTITY_HELPER_HPP
#include <type_traits>
// #include "../config/config.h"
// #include "../core/type_traits.hpp"
// #include "../signal/delegate.hpp"
// #include "registry.hpp"
// #include "fwd.hpp"
namespace entt {
/**
* @brief Converts a registry to a view.
* @tparam Const Constness of the accepted registry.
* @tparam Entity A valid entity type (see entt_traits for more details).
*/
template<bool Const, typename Entity>
struct as_view {
/*! @brief Type of registry to convert. */
using registry_type = std::conditional_t<Const, const basic_registry<Entity>, basic_registry<Entity>>;
/**
* @brief Constructs a converter for a given registry.
* @param source A valid reference to a registry.
*/
as_view(registry_type &source) ENTT_NOEXCEPT: reg{source} {}
/**
* @brief Conversion function from a registry to a view.
* @tparam Exclude Types of components used to filter the view.
* @tparam Component Type of components used to construct the view.
* @return A newly created view.
*/
template<typename Exclude, typename... Component>
operator basic_view<Entity, Exclude, Component...>() const {
return reg.template view<Component...>(Exclude{});
}
private:
registry_type &reg;
};
/**
* @brief Deduction guide.
*
* It allows to deduce the constness of a registry directly from the instance
* provided to the constructor.
*
* @tparam Entity A valid entity type (see entt_traits for more details).
*/
template<typename Entity>
as_view(basic_registry<Entity> &) ENTT_NOEXCEPT -> as_view<false, Entity>;
/*! @copydoc as_view */
template<typename Entity>
as_view(const basic_registry<Entity> &) ENTT_NOEXCEPT -> as_view<true, Entity>;
/**
* @brief Converts a registry to a group.
* @tparam Const Constness of the accepted registry.
* @tparam Entity A valid entity type (see entt_traits for more details).
*/
template<bool Const, typename Entity>
struct as_group {
/*! @brief Type of registry to convert. */
using registry_type = std::conditional_t<Const, const basic_registry<Entity>, basic_registry<Entity>>;
/**
* @brief Constructs a converter for a given registry.
* @param source A valid reference to a registry.
*/
as_group(registry_type &source) ENTT_NOEXCEPT: reg{source} {}
/**
* @brief Conversion function from a registry to a group.
* @tparam Exclude Types of components used to filter the group.
* @tparam Get Types of components observed by the group.
* @tparam Owned Types of components owned by the group.
* @return A newly created group.
*/
template<typename Exclude, typename Get, typename... Owned>
operator basic_group<Entity, Exclude, Get, Owned...>() const {
return reg.template group<Owned...>(Get{}, Exclude{});
}
private:
registry_type &reg;
};
/**
* @brief Deduction guide.
*
* It allows to deduce the constness of a registry directly from the instance
* provided to the constructor.
*
* @tparam Entity A valid entity type (see entt_traits for more details).
*/
template<typename Entity>
as_group(basic_registry<Entity> &) ENTT_NOEXCEPT -> as_group<false, Entity>;
/*! @copydoc as_group */
template<typename Entity>
as_group(const basic_registry<Entity> &) ENTT_NOEXCEPT -> as_group<true, Entity>;
/**
* @brief Helper to create a listener that directly invokes a member function.
* @tparam Member Member function to invoke on a component of the given type.
* @tparam Entity A valid entity type (see entt_traits for more details).
* @param reg A registry that contains the given entity and its components.
* @param entt Entity from which to get the component.
*/
template<auto Member, typename Entity = entity>
void invoke(basic_registry<Entity> &reg, const Entity entt) {
static_assert(std::is_member_function_pointer_v<decltype(Member)>, "Invalid pointer to non-static member function");
delegate<void(basic_registry<Entity> &, const Entity)> func;
func.template connect<Member>(reg.template get<member_class_t<decltype(Member)>>(entt));
func(reg, entt);
}
/**
* @brief Returns the entity associated with a given component.
* @tparam Entity A valid entity type (see entt_traits for more details).
* @tparam Component Type of component.
* @param reg A registry that contains the given entity and its components.
* @param component A valid component instance.
* @return The entity associated with the given component.
*/
template<typename Entity, typename Component>
Entity to_entity(const basic_registry<Entity> &reg, const Component &component) {
return *(reg.template data<Component>() + (&component - reg.template raw<Component>()));
}
}
#endif
// #include "entity/observer.hpp"
#ifndef ENTT_ENTITY_OBSERVER_HPP
#define ENTT_ENTITY_OBSERVER_HPP
#include <limits>
#include <cstddef>
#include <cstdint>
#include <utility>
#include <type_traits>
// #include "../config/config.h"
// #include "../core/type_traits.hpp"
// #include "registry.hpp"
// #include "storage.hpp"
// #include "utility.hpp"
// #include "entity.hpp"
// #include "fwd.hpp"
namespace entt {
/*! @brief Grouping matcher. */
template<typename...>
struct matcher {};
/**
* @brief Collector.
*
* Primary template isn't defined on purpose. All the specializations give a
* compile-time error, but for a few reasonable cases.
*/
template<typename...>
struct basic_collector;
/**
* @brief Collector.
*
* A collector contains a set of rules (literally, matchers) to use to track
* entities.<br/>
* Its main purpose is to generate a descriptor that allows an observer to know
* how to connect to a registry.
*/
template<>
struct basic_collector<> {
/**
* @brief Adds a grouping matcher to the collector.
* @tparam AllOf Types of components tracked by the matcher.
* @tparam NoneOf Types of components used to filter out entities.
* @return The updated collector.
*/
template<typename... AllOf, typename... NoneOf>
static constexpr auto group(exclude_t<NoneOf...> = {}) ENTT_NOEXCEPT {
return basic_collector<matcher<type_list<>, type_list<>, type_list<NoneOf...>, AllOf...>>{};
}
/**
* @brief Adds an observing matcher to the collector.
* @tparam AnyOf Type of component for which changes should be detected.
* @return The updated collector.
*/
template<typename AnyOf>
static constexpr auto update() ENTT_NOEXCEPT {
return basic_collector<matcher<type_list<>, type_list<>, AnyOf>>{};
}
};
/**
* @brief Collector.
* @copydetails basic_collector<>
* @tparam Reject Untracked types used to filter out entities.
* @tparam Require Untracked types required by the matcher.
* @tparam Rule Specific details of the current matcher.
* @tparam Other Other matchers.
*/
template<typename... Reject, typename... Require, typename... Rule, typename... Other>
struct basic_collector<matcher<type_list<Reject...>, type_list<Require...>, Rule...>, Other...> {
/*! @brief Current matcher. */
using current_type = matcher<type_list<Reject...>, type_list<Require...>, Rule...>;
/**
* @brief Adds a grouping matcher to the collector.
* @tparam AllOf Types of components tracked by the matcher.
* @tparam NoneOf Types of components used to filter out entities.
* @return The updated collector.
*/
template<typename... AllOf, typename... NoneOf>
static constexpr auto group(exclude_t<NoneOf...> = {}) ENTT_NOEXCEPT {
return basic_collector<matcher<type_list<>, type_list<>, type_list<NoneOf...>, AllOf...>, current_type, Other...>{};
}
/**
* @brief Adds an observing matcher to the collector.
* @tparam AnyOf Type of component for which changes should be detected.
* @return The updated collector.
*/
template<typename AnyOf>
static constexpr auto update() ENTT_NOEXCEPT {
return basic_collector<matcher<type_list<>, type_list<>, AnyOf>, current_type, Other...>{};
}
/**
* @brief Updates the filter of the last added matcher.
* @tparam AllOf Types of components required by the matcher.
* @tparam NoneOf Types of components used to filter out entities.
* @return The updated collector.
*/
template<typename... AllOf, typename... NoneOf>
static constexpr auto where(exclude_t<NoneOf...> = {}) ENTT_NOEXCEPT {
using extended_type = matcher<type_list<Reject..., NoneOf...>, type_list<Require..., AllOf...>, Rule...>;
return basic_collector<extended_type, Other...>{};
}
};
/*! @brief Variable template used to ease the definition of collectors. */
inline constexpr basic_collector<> collector{};
/**
* @brief Observer.
*
* An observer returns all the entities and only the entities that fit the
* requirements of at least one matcher. Moreover, it's guaranteed that the
* entity list is tightly packed in memory for fast iterations.<br/>
* In general, observers don't stay true to the order of any set of components.
*
* Observers work mainly with two types of matchers, provided through a
* collector:
*
* * Observing matcher: an observer will return at least all the living entities
* for which one or more of the given components have been updated and not yet
* destroyed.
* * Grouping matcher: an observer will return at least all the living entities
* that would have entered the given group if it existed and that would have
* not yet left it.
*
* If an entity respects the requirements of multiple matchers, it will be
* returned once and only once by the observer in any case.
*
* Matchers support also filtering by means of a _where_ clause that accepts
* both a list of types and an exclusion list.<br/>
* Whenever a matcher finds that an entity matches its requirements, the
* condition of the filter is verified before to register the entity itself.
* Moreover, a registered entity isn't returned by the observer if the condition
* set by the filter is broken in the meantime.
*
* @b Important
*
* Iterators aren't invalidated if:
*
* * New instances of the given components are created and assigned to entities.
* * The entity currently pointed is modified (as an example, if one of the
* given components is removed from the entity to which the iterator points).
* * The entity currently pointed is destroyed.
*
* In all the other cases, modifying the pools of the given components in any
* way invalidates all the iterators and using them results in undefined
* behavior.
*
* @warning
* Lifetime of an observer doesn't necessarily have to overcome that of the
* registry to which it is connected. However, the observer must be disconnected
* from the registry before being destroyed to avoid crashes due to dangling
* pointers.
*
* @tparam Entity A valid entity type (see entt_traits for more details).
*/
template<typename Entity>
class basic_observer {
using payload_type = std::uint32_t;
template<typename>
struct matcher_handler;
template<typename... Reject, typename... Require, typename AnyOf>
struct matcher_handler<matcher<type_list<Reject...>, type_list<Require...>, AnyOf>> {
template<std::size_t Index>
static void maybe_valid_if(basic_observer &obs, const basic_registry<Entity> &reg, const Entity entt) {
if(reg.template has<Require...>(entt) && !reg.template any<Reject...>(entt)) {
if(auto *comp = obs.view.try_get(entt); !comp) {
obs.view.emplace(entt);
}
obs.view.get(entt) |= (1 << Index);
}
}
template<std::size_t Index>
static void discard_if(basic_observer &obs, const basic_registry<Entity> &, const Entity entt) {
if(auto *value = obs.view.try_get(entt); value && !(*value &= (~(1 << Index)))) {
obs.view.erase(entt);
}
}
template<std::size_t Index>
static void connect(basic_observer &obs, basic_registry<Entity> &reg) {
(reg.template on_destroy<Require>().template connect<&discard_if<Index>>(obs), ...);
(reg.template on_construct<Reject>().template connect<&discard_if<Index>>(obs), ...);
reg.template on_update<AnyOf>().template connect<&maybe_valid_if<Index>>(obs);
reg.template on_destroy<AnyOf>().template connect<&discard_if<Index>>(obs);
}
static void disconnect(basic_observer &obs, basic_registry<Entity> &reg) {
(reg.template on_destroy<Require>().disconnect(obs), ...);
(reg.template on_construct<Reject>().disconnect(obs), ...);
reg.template on_update<AnyOf>().disconnect(obs);
reg.template on_destroy<AnyOf>().disconnect(obs);
}
};
template<typename... Reject, typename... Require, typename... NoneOf, typename... AllOf>
struct matcher_handler<matcher<type_list<Reject...>, type_list<Require...>, type_list<NoneOf...>, AllOf...>> {
template<std::size_t Index>
static void maybe_valid_if(basic_observer &obs, const basic_registry<Entity> &reg, const Entity entt) {
if(reg.template has<AllOf..., Require...>(entt) && !reg.template any<NoneOf..., Reject...>(entt)) {
if(auto *comp = obs.view.try_get(entt); !comp) {
obs.view.emplace(entt);
}
obs.view.get(entt) |= (1 << Index);
}
}
template<std::size_t Index>
static void discard_if(basic_observer &obs, const basic_registry<Entity> &, const Entity entt) {
if(auto *value = obs.view.try_get(entt); value && !(*value &= (~(1 << Index)))) {
obs.view.erase(entt);
}
}
template<std::size_t Index>
static void connect(basic_observer &obs, basic_registry<Entity> &reg) {
(reg.template on_destroy<Require>().template connect<&discard_if<Index>>(obs), ...);
(reg.template on_construct<Reject>().template connect<&discard_if<Index>>(obs), ...);
(reg.template on_construct<AllOf>().template connect<&maybe_valid_if<Index>>(obs), ...);
(reg.template on_destroy<NoneOf>().template connect<&maybe_valid_if<Index>>(obs), ...);
(reg.template on_destroy<AllOf>().template connect<&discard_if<Index>>(obs), ...);
(reg.template on_construct<NoneOf>().template connect<&discard_if<Index>>(obs), ...);
}
static void disconnect(basic_observer &obs, basic_registry<Entity> &reg) {
(reg.template on_destroy<Require>().disconnect(obs), ...);
(reg.template on_construct<Reject>().disconnect(obs), ...);
(reg.template on_construct<AllOf>().disconnect(obs), ...);
(reg.template on_destroy<NoneOf>().disconnect(obs), ...);
(reg.template on_destroy<AllOf>().disconnect(obs), ...);
(reg.template on_construct<NoneOf>().disconnect(obs), ...);
}
};
template<typename... Matcher>
static void disconnect(basic_observer &obs, basic_registry<Entity> &reg) {
(matcher_handler<Matcher>::disconnect(obs, reg), ...);
}
template<typename... Matcher, std::size_t... Index>
void connect(basic_registry<Entity> &reg, std::index_sequence<Index...>) {
static_assert(sizeof...(Matcher) < std::numeric_limits<payload_type>::digits, "Too many matchers");
(matcher_handler<Matcher>::template connect<Index>(*this, reg), ...);
release = &basic_observer::disconnect<Matcher...>;
}
public:
/*! @brief Underlying entity identifier. */
using entity_type = Entity;
/*! @brief Unsigned integer type. */
using size_type = std::size_t;
/*! @brief Random access iterator type. */
using iterator = typename sparse_set<Entity>::iterator;
/*! @brief Default constructor. */
basic_observer()
: target{}, release{}, view{}
{}
/*! @brief Default copy constructor, deleted on purpose. */
basic_observer(const basic_observer &) = delete;
/*! @brief Default move constructor, deleted on purpose. */
basic_observer(basic_observer &&) = delete;
/**
* @brief Creates an observer and connects it to a given registry.
* @tparam Matcher Types of matchers to use to initialize the observer.
* @param reg A valid reference to a registry.
*/
template<typename... Matcher>
basic_observer(basic_registry<entity_type> &reg, basic_collector<Matcher...>)
: target{&reg},
release{},
view{}
{
connect<Matcher...>(reg, std::index_sequence_for<Matcher...>{});
}
/*! @brief Default destructor. */
~basic_observer() = default;
/**
* @brief Default copy assignment operator, deleted on purpose.
* @return This observer.
*/
basic_observer & operator=(const basic_observer &) = delete;
/**
* @brief Default move assignment operator, deleted on purpose.
* @return This observer.
*/
basic_observer & operator=(basic_observer &&) = delete;
/**
* @brief Connects an observer to a given registry.
* @tparam Matcher Types of matchers to use to initialize the observer.
* @param reg A valid reference to a registry.
*/
template<typename... Matcher>
void connect(basic_registry<entity_type> &reg, basic_collector<Matcher...>) {
disconnect();
connect<Matcher...>(reg, std::index_sequence_for<Matcher...>{});
target = &reg;
view.clear();
}
/*! @brief Disconnects an observer from the registry it keeps track of. */
void disconnect() {
if(release) {
release(*this, *target);
release = nullptr;
}
}
/**
* @brief Returns the number of elements in an observer.
* @return Number of elements.
*/
[[nodiscard]] size_type size() const ENTT_NOEXCEPT {
return view.size();
}
/**
* @brief Checks whether an observer is empty.
* @return True if the observer is empty, false otherwise.
*/
[[nodiscard]] bool empty() const ENTT_NOEXCEPT {
return view.empty();
}
/**
* @brief Direct access to the list of entities of the observer.
*
* The returned pointer is such that range `[data(), data() + size()]` is
* always a valid range, even if the container is empty.
*
* @note
* Entities are in the reverse order as returned by the `begin`/`end`
* iterators.
*
* @return A pointer to the array of entities.
*/
[[nodiscard]] const entity_type * data() const ENTT_NOEXCEPT {
return view.data();
}
/**
* @brief Returns an iterator to the first entity of the observer.
*
* The returned iterator points to the first entity of the observer. If the
* container is empty, the returned iterator will be equal to `end()`.
*
* @return An iterator to the first entity of the observer.
*/
[[nodiscard]] iterator begin() const ENTT_NOEXCEPT {
return view.sparse_set<entity_type>::begin();
}
/**
* @brief Returns an iterator that is past the last entity of the observer.
*
* The returned iterator points to the entity following the last entity of
* the observer. Attempting to dereference the returned iterator results in
* undefined behavior.
*
* @return An iterator to the entity following the last entity of the
* observer.
*/
[[nodiscard]] iterator end() const ENTT_NOEXCEPT {
return view.sparse_set<entity_type>::end();
}
/*! @brief Clears the underlying container. */
void clear() ENTT_NOEXCEPT {
view.clear();
}
/**
* @brief Iterates entities and applies the given function object to them.
*
* The function object is invoked for each entity.<br/>
* The signature of the function must be equivalent to the following form:
*
* @code{.cpp}
* void(const entity_type);
* @endcode
*
* @tparam Func Type of the function object to invoke.
* @param func A valid function object.
*/
template<typename Func>
void each(Func func) const {
for(const auto entity: *this) {
func(entity);
}
}
/**
* @brief Iterates entities and applies the given function object to them,
* then clears the observer.
*
* @sa each
*
* @tparam Func Type of the function object to invoke.
* @param func A valid function object.
*/
template<typename Func>
void each(Func func) {
std::as_const(*this).each(std::move(func));
clear();
}
private:
basic_registry<entity_type> *target;
void(* release)(basic_observer &, basic_registry<entity_type> &);
storage<entity_type, payload_type> view;
};
}
#endif
// #include "entity/pool.hpp"
// #include "entity/registry.hpp"
// #include "entity/runtime_view.hpp"
// #include "entity/snapshot.hpp"
#ifndef ENTT_ENTITY_SNAPSHOT_HPP
#define ENTT_ENTITY_SNAPSHOT_HPP
#include <array>
#include <vector>
#include <cstddef>
#include <utility>
#include <iterator>
#include <type_traits>
#include <unordered_map>
// #include "../config/config.h"
// #include "entity.hpp"
// #include "fwd.hpp"
namespace entt {
/**
* @brief Utility class to create snapshots from a registry.
*
* A _snapshot_ can be either a dump of the entire registry or a narrower
* selection of components of interest.<br/>
* This type can be used in both cases if provided with a correctly configured
* output archive.
*
* @tparam Entity A valid entity type (see entt_traits for more details).
*/
template<typename Entity>
class basic_snapshot {
/*! @brief A registry is allowed to create snapshots. */
friend class basic_registry<Entity>;
using traits_type = entt_traits<Entity>;
template<typename Component, typename Archive, typename It>
void get(Archive &archive, std::size_t sz, It first, It last) const {
archive(typename traits_type::entity_type(sz));
while(first != last) {
const auto entt = *(first++);
if(reg->template has<Component>(entt)) {
if constexpr(std::is_empty_v<Component>) {
archive(entt);
} else {
archive(entt, reg->template get<Component>(entt));
}
}
}
}
template<typename... Component, typename Archive, typename It, std::size_t... Indexes>
void component(Archive &archive, It first, It last, std::index_sequence<Indexes...>) const {
std::array<std::size_t, sizeof...(Indexes)> size{};
auto begin = first;
while(begin != last) {
const auto entt = *(begin++);
((reg->template has<Component>(entt) ? ++size[Indexes] : size[Indexes]), ...);
}
(get<Component>(archive, size[Indexes], first, last), ...);
}
public:
/*! @brief Underlying entity identifier. */
using entity_type = Entity;
/**
* @brief Constructs an instance that is bound to a given registry.
* @param source A valid reference to a registry.
*/
basic_snapshot(const basic_registry<entity_type> &source) ENTT_NOEXCEPT
: reg{&source}
{}
/*! @brief Default move constructor. */
basic_snapshot(basic_snapshot &&) = default;
/*! @brief Default move assignment operator. @return This snapshot. */
basic_snapshot & operator=(basic_snapshot &&) = default;
/**
* @brief Puts aside all the entities from the underlying registry.
*
* Entities are serialized along with their versions. Destroyed entities are
* taken in consideration as well by this function.
*
* @tparam Archive Type of output archive.
* @param archive A valid reference to an output archive.
* @return An object of this type to continue creating the snapshot.
*/
template<typename Archive>
const basic_snapshot & entities(Archive &archive) const {
const auto sz = reg->size();
auto first = reg->data();
const auto last = first + sz;
archive(typename traits_type::entity_type(sz));
while(first != last) {
archive(*(first++));
}
return *this;
}
/**
* @brief Puts aside the given components.
*
* Each instance is serialized together with the entity to which it belongs.
* Entities are serialized along with their versions.
*
* @tparam Component Types of components to serialize.
* @tparam Archive Type of output archive.
* @param archive A valid reference to an output archive.
* @return An object of this type to continue creating the snapshot.
*/
template<typename... Component, typename Archive>
const basic_snapshot & component(Archive &archive) const {
(component<Component>(archive, reg->template data<Component>(), reg->template data<Component>() + reg->template size<Component>()), ...);
return *this;
}
/**
* @brief Puts aside the given components for the entities in a range.
*
* Each instance is serialized together with the entity to which it belongs.
* Entities are serialized along with their versions.
*
* @tparam Component Types of components to serialize.
* @tparam Archive Type of output archive.
* @tparam It Type of input iterator.
* @param archive A valid reference to an output archive.
* @param first An iterator to the first element of the range to serialize.
* @param last An iterator past the last element of the range to serialize.
* @return An object of this type to continue creating the snapshot.
*/
template<typename... Component, typename Archive, typename It>
const basic_snapshot & component(Archive &archive, It first, It last) const {
component<Component...>(archive, first, last, std::index_sequence_for<Component...>{});
return *this;
}
private:
const basic_registry<entity_type> *reg;
};
/**
* @brief Utility class to restore a snapshot as a whole.
*
* A snapshot loader requires that the destination registry be empty and loads
* all the data at once while keeping intact the identifiers that the entities
* originally had.<br/>
* An example of use is the implementation of a save/restore utility.
*
* @tparam Entity A valid entity type (see entt_traits for more details).
*/
template<typename Entity>
class basic_snapshot_loader {
/*! @brief A registry is allowed to create snapshot loaders. */
friend class basic_registry<Entity>;
using traits_type = entt_traits<Entity>;
template<typename Type, typename Archive>
void assign(Archive &archive) const {
typename traits_type::entity_type length{};
archive(length);
entity_type entt{};
if constexpr(std::is_empty_v<Type>) {
while(length--) {
archive(entt);
const auto entity = reg->valid(entt) ? entt : reg->create(entt);
ENTT_ASSERT(entity == entt);
reg->template emplace<Type>(entity);
}
} else {
Type instance{};
while(length--) {
archive(entt, instance);
const auto entity = reg->valid(entt) ? entt : reg->create(entt);
ENTT_ASSERT(entity == entt);
reg->template emplace<Type>(entity, std::move(instance));
}
}
}
public:
/*! @brief Underlying entity identifier. */
using entity_type = Entity;
/**
* @brief Constructs an instance that is bound to a given registry.
* @param source A valid reference to a registry.
*/
basic_snapshot_loader(basic_registry<entity_type> &source) ENTT_NOEXCEPT
: reg{&source}
{
// restoring a snapshot as a whole requires a clean registry
ENTT_ASSERT(reg->empty());
}
/*! @brief Default move constructor. */
basic_snapshot_loader(basic_snapshot_loader &&) = default;
/*! @brief Default move assignment operator. @return This loader. */
basic_snapshot_loader & operator=(basic_snapshot_loader &&) = default;
/**
* @brief Restores entities that were in use during serialization.
*
* This function restores the entities that were in use during serialization
* and gives them the versions they originally had.
*
* @tparam Archive Type of input archive.
* @param archive A valid reference to an input archive.
* @return A valid loader to continue restoring data.
*/
template<typename Archive>
const basic_snapshot_loader & entities(Archive &archive) const {
typename traits_type::entity_type length{};
archive(length);
std::vector<entity_type> all(length);
for(decltype(length) pos{}; pos < length; ++pos) {
archive(all[pos]);
}
reg->assign(all.cbegin(), all.cend());
return *this;
}
/**
* @brief Restores components and assigns them to the right entities.
*
* The template parameter list must be exactly the same used during
* serialization. In the event that the entity to which the component is
* assigned doesn't exist yet, the loader will take care to create it with
* the version it originally had.
*
* @tparam Component Types of components to restore.
* @tparam Archive Type of input archive.
* @param archive A valid reference to an input archive.
* @return A valid loader to continue restoring data.
*/
template<typename... Component, typename Archive>
const basic_snapshot_loader & component(Archive &archive) const {
(assign<Component>(archive), ...);
return *this;
}
/**
* @brief Destroys those entities that have no components.
*
* In case all the entities were serialized but only part of the components
* was saved, it could happen that some of the entities have no components
* once restored.<br/>
* This functions helps to identify and destroy those entities.
*
* @return A valid loader to continue restoring data.
*/
const basic_snapshot_loader & orphans() const {
reg->orphans([this](const auto entt) {
reg->destroy(entt);
});
return *this;
}
private:
basic_registry<entity_type> *reg;
};
/**
* @brief Utility class for _continuous loading_.
*
* A _continuous loader_ is designed to load data from a source registry to a
* (possibly) non-empty destination. The loader can accommodate in a registry
* more than one snapshot in a sort of _continuous loading_ that updates the
* destination one step at a time.<br/>
* Identifiers that entities originally had are not transferred to the target.
* Instead, the loader maps remote identifiers to local ones while restoring a
* snapshot.<br/>
* An example of use is the implementation of a client-server applications with
* the requirement of transferring somehow parts of the representation side to
* side.
*
* @tparam Entity A valid entity type (see entt_traits for more details).
*/
template<typename Entity>
class basic_continuous_loader {
using traits_type = entt_traits<Entity>;
void destroy(Entity entt) {
const auto it = remloc.find(entt);
if(it == remloc.cend()) {
const auto local = reg->create();
remloc.emplace(entt, std::make_pair(local, true));
reg->destroy(local);
}
}
void restore(Entity entt) {
const auto it = remloc.find(entt);
if(it == remloc.cend()) {
const auto local = reg->create();
remloc.emplace(entt, std::make_pair(local, true));
} else {
remloc[entt].first = reg->valid(remloc[entt].first) ? remloc[entt].first : reg->create();
// set the dirty flag
remloc[entt].second = true;
}
}
template<typename Container>
auto update(int, Container &container)
-> decltype(typename Container::mapped_type{}, void()) {
// map like container
Container other;
for(auto &&pair: container) {
using first_type = std::remove_const_t<typename std::decay_t<decltype(pair)>::first_type>;
using second_type = typename std::decay_t<decltype(pair)>::second_type;
if constexpr(std::is_same_v<first_type, entity_type> && std::is_same_v<second_type, entity_type>) {
other.emplace(map(pair.first), map(pair.second));
} else if constexpr(std::is_same_v<first_type, entity_type>) {
other.emplace(map(pair.first), std::move(pair.second));
} else {
static_assert(std::is_same_v<second_type, entity_type>, "Neither the key nor the value are of entity type");
other.emplace(std::move(pair.first), map(pair.second));
}
}
std::swap(container, other);
}
template<typename Container>
auto update(char, Container &container)
-> decltype(typename Container::value_type{}, void()) {
// vector like container
static_assert(std::is_same_v<typename Container::value_type, entity_type>, "Invalid value type");
for(auto &&entt: container) {
entt = map(entt);
}
}
template<typename Other, typename Type, typename Member>
void update([[maybe_unused]] Other &instance, [[maybe_unused]] Member Type:: *member) {
if constexpr(!std::is_same_v<Other, Type>) {
return;
} else if constexpr(std::is_same_v<Member, entity_type>) {
instance.*member = map(instance.*member);
} else {
// maybe a container? let's try...
update(0, instance.*member);
}
}
template<typename Component>
void remove_if_exists() {
for(auto &&ref: remloc) {
const auto local = ref.second.first;
if(reg->valid(local)) {
reg->template remove_if_exists<Component>(local);
}
}
}
template<typename Other, typename Archive, typename... Type, typename... Member>
void assign(Archive &archive, [[maybe_unused]] Member Type:: *... member) {
typename traits_type::entity_type length{};
archive(length);
entity_type entt{};
if constexpr(std::is_empty_v<Other>) {
while(length--) {
archive(entt);
restore(entt);
reg->template emplace_or_replace<Other>(map(entt));
}
} else {
Other instance{};
while(length--) {
archive(entt, instance);
(update(instance, member), ...);
restore(entt);
reg->template emplace_or_replace<Other>(map(entt), std::move(instance));
}
}
}
public:
/*! @brief Underlying entity identifier. */
using entity_type = Entity;
/**
* @brief Constructs an instance that is bound to a given registry.
* @param source A valid reference to a registry.
*/
basic_continuous_loader(basic_registry<entity_type> &source) ENTT_NOEXCEPT
: reg{&source}
{}
/*! @brief Default move constructor. */
basic_continuous_loader(basic_continuous_loader &&) = default;
/*! @brief Default move assignment operator. @return This loader. */
basic_continuous_loader & operator=(basic_continuous_loader &&) = default;
/**
* @brief Restores entities that were in use during serialization.
*
* This function restores the entities that were in use during serialization
* and creates local counterparts for them if required.
*
* @tparam Archive Type of input archive.
* @param archive A valid reference to an input archive.
* @return A non-const reference to this loader.
*/
template<typename Archive>
basic_continuous_loader & entities(Archive &archive) {
typename traits_type::entity_type length{};
entity_type entt{};
archive(length);
for(decltype(length) pos{}; pos < length; ++pos) {
archive(entt);
if(const auto entity = (to_integral(entt) & traits_type::entity_mask); entity == pos) {
restore(entt);
} else {
destroy(entt);
}
}
return *this;
}
/**
* @brief Restores components and assigns them to the right entities.
*
* The template parameter list must be exactly the same used during
* serialization. In the event that the entity to which the component is
* assigned doesn't exist yet, the loader will take care to create a local
* counterpart for it.<br/>
* Members can be either data members of type entity_type or containers of
* entities. In both cases, the loader will visit them and update the
* entities by replacing each one with its local counterpart.
*
* @tparam Component Type of component to restore.
* @tparam Archive Type of input archive.
* @tparam Type Types of components to update with local counterparts.
* @tparam Member Types of members to update with their local counterparts.
* @param archive A valid reference to an input archive.
* @param member Members to update with their local counterparts.
* @return A non-const reference to this loader.
*/
template<typename... Component, typename Archive, typename... Type, typename... Member>
basic_continuous_loader & component(Archive &archive, Member Type:: *... member) {
(remove_if_exists<Component>(), ...);
(assign<Component>(archive, member...), ...);
return *this;
}
/**
* @brief Helps to purge entities that no longer have a conterpart.
*
* Users should invoke this member function after restoring each snapshot,
* unless they know exactly what they are doing.
*
* @return A non-const reference to this loader.
*/
basic_continuous_loader & shrink() {
auto it = remloc.begin();
while(it != remloc.cend()) {
const auto local = it->second.first;
bool &dirty = it->second.second;
if(dirty) {
dirty = false;
++it;
} else {
if(reg->valid(local)) {
reg->destroy(local);
}
it = remloc.erase(it);
}
}
return *this;
}
/**
* @brief Destroys those entities that have no components.
*
* In case all the entities were serialized but only part of the components
* was saved, it could happen that some of the entities have no components
* once restored.<br/>
* This functions helps to identify and destroy those entities.
*
* @return A non-const reference to this loader.
*/
basic_continuous_loader & orphans() {
reg->orphans([this](const auto entt) {
reg->destroy(entt);
});
return *this;
}
/**
* @brief Tests if a loader knows about a given entity.
* @param entt An entity identifier.
* @return True if `entity` is managed by the loader, false otherwise.
*/
[[nodiscard]] bool contains(entity_type entt) const ENTT_NOEXCEPT {
return (remloc.find(entt) != remloc.cend());
}
/**
* @brief Returns the identifier to which an entity refers.
* @param entt An entity identifier.
* @return The local identifier if any, the null entity otherwise.
*/
[[nodiscard]] entity_type map(entity_type entt) const ENTT_NOEXCEPT {
const auto it = remloc.find(entt);
entity_type other = null;
if(it != remloc.cend()) {
other = it->second.first;
}
return other;
}
private:
std::unordered_map<entity_type, std::pair<entity_type, bool>> remloc;
basic_registry<entity_type> *reg;
};
}
#endif
// #include "entity/sparse_set.hpp"
// #include "entity/storage.hpp"
// #include "entity/utility.hpp"
// #include "entity/view.hpp"
// #include "locator/locator.hpp"
#ifndef ENTT_LOCATOR_LOCATOR_HPP
#define ENTT_LOCATOR_LOCATOR_HPP
#include <memory>
#include <utility>
// #include "../config/config.h"
#ifndef ENTT_CONFIG_CONFIG_H
#define ENTT_CONFIG_CONFIG_H
#ifndef ENTT_NOEXCEPT
# define ENTT_NOEXCEPT noexcept
#endif
#ifndef ENTT_HS_SUFFIX
# define ENTT_HS_SUFFIX _hs
#endif
#ifndef ENTT_HWS_SUFFIX
# define ENTT_HWS_SUFFIX _hws
#endif
#ifndef ENTT_USE_ATOMIC
# define ENTT_MAYBE_ATOMIC(Type) Type
#else
# include <atomic>
# define ENTT_MAYBE_ATOMIC(Type) std::atomic<Type>
#endif
#ifndef ENTT_ID_TYPE
# include <cstdint>
# define ENTT_ID_TYPE std::uint32_t
#endif
#ifndef ENTT_PAGE_SIZE
# define ENTT_PAGE_SIZE 32768
#endif
#ifndef ENTT_ASSERT
# include <cassert>
# define ENTT_ASSERT(condition) assert(condition)
#endif
#ifndef ENTT_NO_ETO
# include <type_traits>
# define ENTT_IS_EMPTY(Type) std::is_empty<Type>
#else
# include <type_traits>
# define ENTT_IS_EMPTY(Type) std::false_type
#endif
#ifndef ENTT_STANDARD_CPP
# if defined __clang__ || (defined __GNUC__ && __GNUC__ > 8)
# define ENTT_PRETTY_FUNCTION_CONSTEXPR
# define ENTT_PRETTY_FUNCTION __PRETTY_FUNCTION__
# define ENTT_PRETTY_FUNCTION_PREFIX '='
# define ENTT_PRETTY_FUNCTION_SUFFIX ']'
# elif defined __GNUC__
# define ENTT_PRETTY_FUNCTION __PRETTY_FUNCTION__
# define ENTT_PRETTY_FUNCTION_PREFIX '='
# define ENTT_PRETTY_FUNCTION_SUFFIX ']'
# elif defined _MSC_VER
# define ENTT_PRETTY_FUNCTION_CONSTEXPR
# define ENTT_PRETTY_FUNCTION __FUNCSIG__
# define ENTT_PRETTY_FUNCTION_PREFIX '<'
# define ENTT_PRETTY_FUNCTION_SUFFIX '>'
# endif
#endif
#ifndef ENTT_STANDALONE
# define ENTT_FAST_PATH(...) false
#else
# define ENTT_FAST_PATH(Cond) Cond
#endif
#endif
namespace entt {
/**
* @brief Service locator, nothing more.
*
* A service locator can be used to do what it promises: locate services.<br/>
* Usually service locators are tightly bound to the services they expose and
* thus it's hard to define a general purpose class to do that. This template
* based implementation tries to fill the gap and to get rid of the burden of
* defining a different specific locator for each application.
*
* @tparam Service Type of service managed by the locator.
*/
template<typename Service>
struct service_locator {
/*! @brief Type of service offered. */
using service_type = Service;
/*! @brief Default constructor, deleted on purpose. */
service_locator() = delete;
/*! @brief Default destructor, deleted on purpose. */
~service_locator() = delete;
/**
* @brief Tests if a valid service implementation is set.
* @return True if the service is set, false otherwise.
*/
[[nodiscard]] static bool empty() ENTT_NOEXCEPT {
return !static_cast<bool>(service);
}
/**
* @brief Returns a weak pointer to a service implementation, if any.
*
* Clients of a service shouldn't retain references to it. The recommended
* way is to retrieve the service implementation currently set each and
* every time the need of using it arises. Otherwise users can incur in
* unexpected behaviors.
*
* @return A reference to the service implementation currently set, if any.
*/
[[nodiscard]] static std::weak_ptr<Service> get() ENTT_NOEXCEPT {
return service;
}
/**
* @brief Returns a weak reference to a service implementation, if any.
*
* Clients of a service shouldn't retain references to it. The recommended
* way is to retrieve the service implementation currently set each and
* every time the need of using it arises. Otherwise users can incur in
* unexpected behaviors.
*
* @warning
* In case no service implementation has been set, a call to this function
* results in undefined behavior.
*
* @return A reference to the service implementation currently set, if any.
*/
[[nodiscard]] static Service & ref() ENTT_NOEXCEPT {
return *service;
}
/**
* @brief Sets or replaces a service.
* @tparam Impl Type of the new service to use.
* @tparam Args Types of arguments to use to construct the service.
* @param args Parameters to use to construct the service.
*/
template<typename Impl = Service, typename... Args>
static void set(Args &&... args) {
service = std::make_shared<Impl>(std::forward<Args>(args)...);
}
/**
* @brief Sets or replaces a service.
* @param ptr Service to use to replace the current one.
*/
static void set(std::shared_ptr<Service> ptr) {
ENTT_ASSERT(static_cast<bool>(ptr));
service = std::move(ptr);
}
/**
* @brief Resets a service.
*
* The service is no longer valid after a reset.
*/
static void reset() {
service.reset();
}
private:
inline static std::shared_ptr<Service> service = nullptr;
};
}
#endif
// #include "meta/container.hpp"
#ifndef ENTT_META_CONTAINER_HPP
#define ENTT_META_CONTAINER_HPP
#include <array>
#include <map>
#include <set>
#include <unordered_map>
#include <unordered_set>
#include <utility>
#include <vector>
// #include "../config/config.h"
#ifndef ENTT_CONFIG_CONFIG_H
#define ENTT_CONFIG_CONFIG_H
#ifndef ENTT_NOEXCEPT
# define ENTT_NOEXCEPT noexcept
#endif
#ifndef ENTT_HS_SUFFIX
# define ENTT_HS_SUFFIX _hs
#endif
#ifndef ENTT_HWS_SUFFIX
# define ENTT_HWS_SUFFIX _hws
#endif
#ifndef ENTT_USE_ATOMIC
# define ENTT_MAYBE_ATOMIC(Type) Type
#else
# include <atomic>
# define ENTT_MAYBE_ATOMIC(Type) std::atomic<Type>
#endif
#ifndef ENTT_ID_TYPE
# include <cstdint>
# define ENTT_ID_TYPE std::uint32_t
#endif
#ifndef ENTT_PAGE_SIZE
# define ENTT_PAGE_SIZE 32768
#endif
#ifndef ENTT_ASSERT
# include <cassert>
# define ENTT_ASSERT(condition) assert(condition)
#endif
#ifndef ENTT_NO_ETO
# include <type_traits>
# define ENTT_IS_EMPTY(Type) std::is_empty<Type>
#else
# include <type_traits>
# define ENTT_IS_EMPTY(Type) std::false_type
#endif
#ifndef ENTT_STANDARD_CPP
# if defined __clang__ || (defined __GNUC__ && __GNUC__ > 8)
# define ENTT_PRETTY_FUNCTION_CONSTEXPR
# define ENTT_PRETTY_FUNCTION __PRETTY_FUNCTION__
# define ENTT_PRETTY_FUNCTION_PREFIX '='
# define ENTT_PRETTY_FUNCTION_SUFFIX ']'
# elif defined __GNUC__
# define ENTT_PRETTY_FUNCTION __PRETTY_FUNCTION__
# define ENTT_PRETTY_FUNCTION_PREFIX '='
# define ENTT_PRETTY_FUNCTION_SUFFIX ']'
# elif defined _MSC_VER
# define ENTT_PRETTY_FUNCTION_CONSTEXPR
# define ENTT_PRETTY_FUNCTION __FUNCSIG__
# define ENTT_PRETTY_FUNCTION_PREFIX '<'
# define ENTT_PRETTY_FUNCTION_SUFFIX '>'
# endif
#endif
#ifndef ENTT_STANDALONE
# define ENTT_FAST_PATH(...) false
#else
# define ENTT_FAST_PATH(Cond) Cond
#endif
#endif
// #include "type_traits.hpp"
#ifndef ENTT_META_TYPE_TRAITS_HPP
#define ENTT_META_TYPE_TRAITS_HPP
#include <type_traits>
namespace entt {
/**
* @brief Traits class template to be specialized to enable support for meta
* sequence containers.
*/
template<typename>
struct meta_sequence_container_traits;
/**
* @brief Traits class template to be specialized to enable support for meta
* associative containers.
*/
template<typename>
struct meta_associative_container_traits;
/**
* @brief Provides the member constant `value` to true if support for meta
* sequence containers is enabled for the given type, false otherwise.
* @tparam Type Potentially sequence container type.
*/
template<typename Type, typename = void>
struct has_meta_sequence_container_traits: std::false_type {};
/*! @copydoc has_meta_sequence_container_traits */
template<typename Type>
struct has_meta_sequence_container_traits<Type, std::void_t<typename meta_sequence_container_traits<Type>::value_type>>
: std::true_type
{};
/**
* @brief Helper variable template.
* @tparam Type Potentially sequence container type.
*/
template<typename Type>
inline constexpr auto has_meta_sequence_container_traits_v = has_meta_sequence_container_traits<Type>::value;
/**
* @brief Provides the member constant `value` to true if support for meta
* associative containers is enabled for the given type, false otherwise.
* @tparam Type Potentially associative container type.
*/
template<typename, typename = void>
struct has_meta_associative_container_traits: std::false_type {};
/*! @copydoc has_meta_associative_container_traits */
template<typename Type>
struct has_meta_associative_container_traits<Type, std::void_t<typename meta_associative_container_traits<Type>::key_type>>
: std::true_type
{};
/**
* @brief Helper variable template.
* @tparam Type Potentially associative container type.
*/
template<typename Type>
inline constexpr auto has_meta_associative_container_traits_v = has_meta_associative_container_traits<Type>::value;
/**
* @brief Provides the member constant `value` to true if a meta associative
* container claims to wrap a key-only type, false otherwise.
* @tparam Type Potentially key-only meta associative container type.
*/
template<typename, typename = void>
struct is_key_only_meta_associative_container: std::true_type {};
/*! @copydoc is_key_only_meta_associative_container */
template<typename Type>
struct is_key_only_meta_associative_container<Type, std::void_t<typename meta_associative_container_traits<Type>::mapped_type>>
: std::false_type
{};
/**
* @brief Helper variable template.
* @tparam Type Potentially key-only meta associative container type.
*/
template<typename Type>
inline constexpr auto is_key_only_meta_associative_container_v = is_key_only_meta_associative_container<Type>::value;
/**
* @brief Provides the member constant `value` to true if a given type is a
* pointer-like type from the point of view of the meta system, false otherwise.
* @tparam Type Potentially pointer-like type.
*/
template<typename>
struct is_meta_pointer_like: std::false_type {};
/**
* @brief Helper variable template.
* @tparam Type Potentially pointer-like type.
*/
template<typename Type>
inline constexpr auto is_meta_pointer_like_v = is_meta_pointer_like<Type>::value;
}
#endif
namespace entt {
namespace internal {
template<typename Container, template<typename> class... Trait>
struct container_traits: public Trait<Container>... {};
/**
* @brief Basic STL-compatible container traits
* @tparam Container The type of the container.
*/
template<typename Container>
struct basic_container {
/*! @brief Iterator type of the container. */
using iterator = typename Container::iterator;
/*! @brief Unsigned integer type. */
using size_type = typename Container::size_type;
/*! @brief Value type of the container. */
using value_type = typename Container::value_type;
/**
* @brief Returns the size of the given container.
* @param cont The container for which to return the size.
* @return The size of the given container.
*/
[[nodiscard]] static size_type size(const Container &cont) ENTT_NOEXCEPT {
return cont.size();
}
/**
* @brief Returns an iterator to the first element of the given container.
* @param cont The container for which to return the iterator.
* @return An iterator to the first element of the given container.
*/
[[nodiscard]] static iterator begin(Container &cont) {
return cont.begin();
}
/**
* @brief Returns an iterator past the last element of the given container.
* @param cont The container for which to return the iterator.
* @return An iterator past the last element of the given container.
*/
[[nodiscard]] static iterator end(Container &cont) {
return cont.end();
}
};
/**
* @brief Basic STL-compatible associative container traits
* @tparam Container The type of the container.
*/
template<typename Container>
struct basic_associative_container {
/*! @brief Key type of the sequence container. */
using key_type = typename Container::key_type;
/**
* @brief Returns an iterator to the element with key equivalent to the given
* one, if any.
* @param cont The container in which to search for the element.
* @param key The key of the element to search.
* @return An iterator to the element with the given key, if any.
*/
[[nodiscard]] static typename Container::iterator find(Container &cont, const key_type &key) {
return cont.find(key);
}
};
/**
* @brief Basic STL-compatible dynamic container traits
* @tparam Container The type of the container.
*/
template<typename Container>
struct basic_dynamic_container {
/**
* @brief Clears the content of the given container.
* @param cont The container for which to clear the content.
* @return True in case of success, false otherwise.
*/
[[nodiscard]] static bool clear(Container &cont) {
return cont.clear(), true;
}
};
/**
* @brief Basic STL-compatible dynamic associative container traits
* @tparam Container The type of the container.
*/
template<typename Container>
struct basic_dynamic_associative_container {
/**
* @brief Removes the specified element from the given container.
* @param cont The container from which to remove the element.
* @param key The element to remove.
* @return A bool denoting whether the removal took place.
*/
[[nodiscard]] static bool erase(Container &cont, const typename Container::key_type &key) {
const auto sz = cont.size();
return cont.erase(key) != sz;
}
};
/**
* @brief Basic STL-compatible sequence container traits
* @tparam Container The type of the container.
*/
template<typename Container>
struct basic_sequence_container {
/**
* @brief Returns a reference to the element at the specified location of the
* given container (no bounds checking is performed).
* @param cont The container from which to get the element.
* @param pos The position of the element to return.
* @return A reference to the requested element.
*/
[[nodiscard]] static typename Container::value_type & get(Container &cont, typename Container::size_type pos) {
return cont[pos];
}
};
/**
* @brief STL-compatible dynamic associative key-only container traits
* @tparam Container The type of the container.
*/
template<typename Container>
struct dynamic_associative_key_only_container {
/**
* @brief Inserts an element into the given container.
* @param cont The container in which to insert the element.
* @param key The element to insert.
* @return A bool denoting whether the insertion took place.
*/
[[nodiscard]] static bool insert(Container &cont, const typename Container::key_type &key) {
return cont.insert(key).second;
}
};
/**
* @brief STL-compatible dynamic key-value associative container traits
* @tparam Container The type of the container.
*/
template<typename Container>
struct dynamic_associative_key_value_container {
/**
* @brief Inserts an element (a key/value pair) into the given container.
* @param cont The container in which to insert the element.
* @param key The key of the element to insert.
* @param value The value of the element to insert.
* @return A bool denoting whether the insertion took place.
*/
[[nodiscard]] static bool insert(Container &cont, const typename Container::key_type &key, const typename Container::mapped_type &value) {
return cont.insert(std::make_pair(key, value)).second;
}
};
/**
* @brief STL-compatible dynamic sequence container traits
* @tparam Container The type of the container.
*/
template<typename Container>
struct dynamic_sequence_container {
/**
* @brief Resizes the given container to contain the given number of elements.
* @param cont The container to resize.
* @param sz The new size of the container.
* @return True in case of success, false otherwise.
*/
[[nodiscard]] static bool resize(Container &cont, typename Container::size_type sz) {
return (cont.resize(sz), true);
}
/**
* @brief Inserts an element at the specified location of the given container.
* @param cont The container into which to insert the element.
* @param it Iterator before which the element will be inserted.
* @param value Element value to insert.
* @return A pair consisting of an iterator to the inserted element (in case
* of success) and a bool denoting whether the insertion took place.
*/
[[nodiscard]] static std::pair<typename Container::iterator, bool> insert(Container &cont, typename Container::iterator it, const typename Container::value_type &value) {
return { cont.insert(it, value), true };
}
/**
* @brief Removes the element at the specified location from the given container.
* @param cont The container from which to remove the element.
* @param it Iterator to the element to remove.
* @return A pair consisting of an iterator following the last removed
* element (in case of success) and a bool denoting whether the insertion
* took place.
*/
[[nodiscard]] static std::pair<typename Container::iterator, bool> erase(Container &cont, typename Container::iterator it) {
return { cont.erase(it), true };
}
};
/**
* @brief STL-compatible fixed sequence container traits
* @tparam Container The type of the container.
*/
template<typename Container>
struct fixed_sequence_container {
/**
* @brief Does nothing.
* @return False to indicate failure in all cases.
*/
[[nodiscard]] static bool resize(const Container &, typename Container::size_type) {
return false;
}
/**
* @brief Does nothing.
* @return False to indicate failure in all cases.
*/
[[nodiscard]] static bool clear(const Container &) {
return false;
}
/**
* @brief Does nothing.
* @return A pair consisting of an invalid iterator and a false value to
* indicate failure in all cases.
*/
[[nodiscard]] static std::pair<typename Container::iterator, bool> insert(const Container &, typename Container::iterator, const typename Container::value_type &) {
return { {}, false };
}
/**
* @brief Does nothing.
* @return A pair consisting of an invalid iterator and a false value to
* indicate failure in all cases.
*/
[[nodiscard]] static std::pair<typename Container::iterator, bool> erase(const Container &, typename Container::iterator) {
return { {}, false };
}
};
}
/**
* @brief Meta sequence container traits for `std::vector`s of any type.
* @tparam Type The type of elements.
* @tparam Args Other arguments.
*/
template<typename Type, typename... Args>
struct meta_sequence_container_traits<std::vector<Type, Args...>>
: internal::container_traits<
std::vector<Type, Args...>,
internal::basic_container,
internal::basic_dynamic_container,
internal::basic_sequence_container,
internal::dynamic_sequence_container
>
{};
/**
* @brief Meta sequence container traits for `std::array`s of any type.
* @tparam Type The type of elements.
* @tparam N The number of elements.
*/
template<typename Type, auto N>
struct meta_sequence_container_traits<std::array<Type, N>>
: internal::container_traits<
std::array<Type, N>,
internal::basic_container,
internal::basic_sequence_container,
internal::fixed_sequence_container
>
{};
/**
* @brief Meta associative container traits for `std::map`s of any type.
* @tparam Key The key type of elements.
* @tparam Value The value type of elements.
* @tparam Args Other arguments.
*/
template<typename Key, typename Value, typename... Args>
struct meta_associative_container_traits<std::map<Key, Value, Args...>>
: internal::container_traits<
std::map<Key, Value, Args...>,
internal::basic_container,
internal::basic_associative_container,
internal::basic_dynamic_container,
internal::basic_dynamic_associative_container,
internal::dynamic_associative_key_value_container
>
{
/*! @brief Mapped type of the sequence container. */
using mapped_type = typename std::map<Key, Value, Args...>::mapped_type;
};
/**
* @brief Meta associative container traits for `std::unordered_map`s of any
* type.
* @tparam Key The key type of elements.
* @tparam Value The value type of elements.
* @tparam Args Other arguments.
*/
template<typename Key, typename Value, typename... Args>
struct meta_associative_container_traits<std::unordered_map<Key, Value, Args...>>
: internal::container_traits<
std::unordered_map<Key, Value, Args...>,
internal::basic_container,
internal::basic_associative_container,
internal::basic_dynamic_container,
internal::basic_dynamic_associative_container,
internal::dynamic_associative_key_value_container
>
{
/*! @brief Mapped type of the sequence container. */
using mapped_type = typename std::unordered_map<Key, Value, Args...>::mapped_type;
};
/**
* @brief Meta associative container traits for `std::set`s of any type.
* @tparam Key The type of elements.
* @tparam Args Other arguments.
*/
template<typename Key, typename... Args>
struct meta_associative_container_traits<std::set<Key, Args...>>
: internal::container_traits<
std::set<Key, Args...>,
internal::basic_container,
internal::basic_associative_container,
internal::basic_dynamic_container,
internal::basic_dynamic_associative_container,
internal::dynamic_associative_key_only_container
>
{};
/**
* @brief Meta associative container traits for `std::unordered_set`s of any
* type.
* @tparam Key The type of elements.
* @tparam Args Other arguments.
*/
template<typename Key, typename... Args>
struct meta_associative_container_traits<std::unordered_set<Key, Args...>>
: internal::container_traits<
std::unordered_set<Key, Args...>,
internal::basic_container,
internal::basic_associative_container,
internal::basic_dynamic_container,
internal::basic_dynamic_associative_container,
internal::dynamic_associative_key_only_container
>
{};
}
#endif
// #include "meta/ctx.hpp"
#ifndef ENTT_META_CTX_HPP
#define ENTT_META_CTX_HPP
// #include "../core/attribute.h"
#ifndef ENTT_CORE_ATTRIBUTE_H
#define ENTT_CORE_ATTRIBUTE_H
#ifndef ENTT_EXPORT
# if defined _WIN32 || defined __CYGWIN__ || defined _MSC_VER
# define ENTT_EXPORT __declspec(dllexport)
# define ENTT_IMPORT __declspec(dllimport)
# define ENTT_HIDDEN
# elif defined __GNUC__ && __GNUC__ >= 4
# define ENTT_EXPORT __attribute__((visibility("default")))
# define ENTT_IMPORT __attribute__((visibility("default")))
# define ENTT_HIDDEN __attribute__((visibility("hidden")))
# else /* Unsupported compiler */
# define ENTT_EXPORT
# define ENTT_IMPORT
# define ENTT_HIDDEN
# endif
#endif
#ifndef ENTT_API
# if defined ENTT_API_EXPORT
# define ENTT_API ENTT_EXPORT
# elif defined ENTT_API_IMPORT
# define ENTT_API ENTT_IMPORT
# else /* No API */
# define ENTT_API
# endif
#endif
#endif
// #include "../config/config.h"
namespace entt {
/**
* @cond TURN_OFF_DOXYGEN
* Internal details not to be documented.
*/
namespace internal {
struct meta_type_node;
struct ENTT_API meta_context {
// we could use the lines below but VS2017 returns with an ICE if combined with ENTT_API despite the code being valid C++
// inline static meta_type_node *local = nullptr;
// inline static meta_type_node **global = &local;
[[nodiscard]] static meta_type_node * & local() ENTT_NOEXCEPT {
static meta_type_node *chain = nullptr;
return chain;
}
[[nodiscard]] static meta_type_node ** & global() ENTT_NOEXCEPT {
static meta_type_node **chain = &local();
return chain;
}
};
}
/**
* Internal details not to be documented.
* @endcond
*/
/*! @brief Opaque container for a meta context. */
struct meta_ctx {
/**
* @brief Binds the meta system to a given context.
* @param other A valid context to which to bind.
*/
static void bind(meta_ctx other) ENTT_NOEXCEPT {
internal::meta_context::global() = other.ctx;
}
private:
internal::meta_type_node **ctx{&internal::meta_context::local()};
};
}
#endif
// #include "meta/factory.hpp"
#ifndef ENTT_META_FACTORY_HPP
#define ENTT_META_FACTORY_HPP
#include <array>
#include <cstddef>
#include <functional>
#include <tuple>
#include <type_traits>
#include <utility>
// #include "../config/config.h"
// #include "../core/fwd.hpp"
#ifndef ENTT_CORE_FWD_HPP
#define ENTT_CORE_FWD_HPP
// #include "../config/config.h"
#ifndef ENTT_CONFIG_CONFIG_H
#define ENTT_CONFIG_CONFIG_H
#ifndef ENTT_NOEXCEPT
# define ENTT_NOEXCEPT noexcept
#endif
#ifndef ENTT_HS_SUFFIX
# define ENTT_HS_SUFFIX _hs
#endif
#ifndef ENTT_HWS_SUFFIX
# define ENTT_HWS_SUFFIX _hws
#endif
#ifndef ENTT_USE_ATOMIC
# define ENTT_MAYBE_ATOMIC(Type) Type
#else
# include <atomic>
# define ENTT_MAYBE_ATOMIC(Type) std::atomic<Type>
#endif
#ifndef ENTT_ID_TYPE
# include <cstdint>
# define ENTT_ID_TYPE std::uint32_t
#endif
#ifndef ENTT_PAGE_SIZE
# define ENTT_PAGE_SIZE 32768
#endif
#ifndef ENTT_ASSERT
# include <cassert>
# define ENTT_ASSERT(condition) assert(condition)
#endif
#ifndef ENTT_NO_ETO
# include <type_traits>
# define ENTT_IS_EMPTY(Type) std::is_empty<Type>
#else
# include <type_traits>
# define ENTT_IS_EMPTY(Type) std::false_type
#endif
#ifndef ENTT_STANDARD_CPP
# if defined __clang__ || (defined __GNUC__ && __GNUC__ > 8)
# define ENTT_PRETTY_FUNCTION_CONSTEXPR
# define ENTT_PRETTY_FUNCTION __PRETTY_FUNCTION__
# define ENTT_PRETTY_FUNCTION_PREFIX '='
# define ENTT_PRETTY_FUNCTION_SUFFIX ']'
# elif defined __GNUC__
# define ENTT_PRETTY_FUNCTION __PRETTY_FUNCTION__
# define ENTT_PRETTY_FUNCTION_PREFIX '='
# define ENTT_PRETTY_FUNCTION_SUFFIX ']'
# elif defined _MSC_VER
# define ENTT_PRETTY_FUNCTION_CONSTEXPR
# define ENTT_PRETTY_FUNCTION __FUNCSIG__
# define ENTT_PRETTY_FUNCTION_PREFIX '<'
# define ENTT_PRETTY_FUNCTION_SUFFIX '>'
# endif
#endif
#ifndef ENTT_STANDALONE
# define ENTT_FAST_PATH(...) false
#else
# define ENTT_FAST_PATH(Cond) Cond
#endif
#endif
namespace entt {
/*! @brief Alias declaration for type identifiers. */
using id_type = ENTT_ID_TYPE;
}
#endif
// #include "../core/type_info.hpp"
#ifndef ENTT_CORE_TYPE_INFO_HPP
#define ENTT_CORE_TYPE_INFO_HPP
#include <string_view>
// #include "../config/config.h"
// #include "../core/attribute.h"
#ifndef ENTT_CORE_ATTRIBUTE_H
#define ENTT_CORE_ATTRIBUTE_H
#ifndef ENTT_EXPORT
# if defined _WIN32 || defined __CYGWIN__ || defined _MSC_VER
# define ENTT_EXPORT __declspec(dllexport)
# define ENTT_IMPORT __declspec(dllimport)
# define ENTT_HIDDEN
# elif defined __GNUC__ && __GNUC__ >= 4
# define ENTT_EXPORT __attribute__((visibility("default")))
# define ENTT_IMPORT __attribute__((visibility("default")))
# define ENTT_HIDDEN __attribute__((visibility("hidden")))
# else /* Unsupported compiler */
# define ENTT_EXPORT
# define ENTT_IMPORT
# define ENTT_HIDDEN
# endif
#endif
#ifndef ENTT_API
# if defined ENTT_API_EXPORT
# define ENTT_API ENTT_EXPORT
# elif defined ENTT_API_IMPORT
# define ENTT_API ENTT_IMPORT
# else /* No API */
# define ENTT_API
# endif
#endif
#endif
// #include "hashed_string.hpp"
#ifndef ENTT_CORE_HASHED_STRING_HPP
#define ENTT_CORE_HASHED_STRING_HPP
#include <cstddef>
#include <cstdint>
// #include "../config/config.h"
// #include "fwd.hpp"
namespace entt {
/**
* @cond TURN_OFF_DOXYGEN
* Internal details not to be documented.
*/
namespace internal {
template<typename>
struct fnv1a_traits;
template<>
struct fnv1a_traits<std::uint32_t> {
using type = std::uint32_t;
static constexpr std::uint32_t offset = 2166136261;
static constexpr std::uint32_t prime = 16777619;
};
template<>
struct fnv1a_traits<std::uint64_t> {
using type = std::uint64_t;
static constexpr std::uint64_t offset = 14695981039346656037ull;
static constexpr std::uint64_t prime = 1099511628211ull;
};
}
/**
* Internal details not to be documented.
* @endcond
*/
/**
* @brief Zero overhead unique identifier.
*
* A hashed string is a compile-time tool that allows users to use
* human-readable identifers in the codebase while using their numeric
* counterparts at runtime.<br/>
* Because of that, a hashed string can also be used in constant expressions if
* required.
*
* @tparam Char Character type.
*/
template<typename Char>
class basic_hashed_string {
using traits_type = internal::fnv1a_traits<id_type>;
struct const_wrapper {
// non-explicit constructor on purpose
constexpr const_wrapper(const Char *curr) ENTT_NOEXCEPT: str{curr} {}
const Char *str;
};
// FowlerNollVo hash function v. 1a - the good
[[nodiscard]] static constexpr id_type helper(const Char *curr) ENTT_NOEXCEPT {
auto value = traits_type::offset;
while(*curr != 0) {
value = (value ^ static_cast<traits_type::type>(*(curr++))) * traits_type::prime;
}
return value;
}
public:
/*! @brief Character type. */
using value_type = Char;
/*! @brief Unsigned integer type. */
using hash_type = id_type;
/**
* @brief Returns directly the numeric representation of a string.
*
* Forcing template resolution avoids implicit conversions. An
* human-readable identifier can be anything but a plain, old bunch of
* characters.<br/>
* Example of use:
* @code{.cpp}
* const auto value = basic_hashed_string<char>::to_value("my.png");
* @endcode
*
* @tparam N Number of characters of the identifier.
* @param str Human-readable identifer.
* @return The numeric representation of the string.
*/
template<std::size_t N>
[[nodiscard]] static constexpr hash_type value(const value_type (&str)[N]) ENTT_NOEXCEPT {
return helper(str);
}
/**
* @brief Returns directly the numeric representation of a string.
* @param wrapper Helps achieving the purpose by relying on overloading.
* @return The numeric representation of the string.
*/
[[nodiscard]] static hash_type value(const_wrapper wrapper) ENTT_NOEXCEPT {
return helper(wrapper.str);
}
/**
* @brief Returns directly the numeric representation of a string view.
* @param str Human-readable identifer.
* @param size Length of the string to hash.
* @return The numeric representation of the string.
*/
[[nodiscard]] static hash_type value(const value_type *str, std::size_t size) ENTT_NOEXCEPT {
id_type partial{traits_type::offset};
while(size--) { partial = (partial^(str++)[0])*traits_type::prime; }
return partial;
}
/*! @brief Constructs an empty hashed string. */
constexpr basic_hashed_string() ENTT_NOEXCEPT
: str{nullptr}, hash{}
{}
/**
* @brief Constructs a hashed string from an array of const characters.
*
* Forcing template resolution avoids implicit conversions. An
* human-readable identifier can be anything but a plain, old bunch of
* characters.<br/>
* Example of use:
* @code{.cpp}
* basic_hashed_string<char> hs{"my.png"};
* @endcode
*
* @tparam N Number of characters of the identifier.
* @param curr Human-readable identifer.
*/
template<std::size_t N>
constexpr basic_hashed_string(const value_type (&curr)[N]) ENTT_NOEXCEPT
: str{curr}, hash{helper(curr)}
{}
/**
* @brief Explicit constructor on purpose to avoid constructing a hashed
* string directly from a `const value_type *`.
* @param wrapper Helps achieving the purpose by relying on overloading.
*/
explicit constexpr basic_hashed_string(const_wrapper wrapper) ENTT_NOEXCEPT
: str{wrapper.str}, hash{helper(wrapper.str)}
{}
/**
* @brief Returns the human-readable representation of a hashed string.
* @return The string used to initialize the instance.
*/
[[nodiscard]] constexpr const value_type * data() const ENTT_NOEXCEPT {
return str;
}
/**
* @brief Returns the numeric representation of a hashed string.
* @return The numeric representation of the instance.
*/
[[nodiscard]] constexpr hash_type value() const ENTT_NOEXCEPT {
return hash;
}
/*! @copydoc data */
[[nodiscard]] constexpr operator const value_type *() const ENTT_NOEXCEPT { return data(); }
/**
* @brief Returns the numeric representation of a hashed string.
* @return The numeric representation of the instance.
*/
[[nodiscard]] constexpr operator hash_type() const ENTT_NOEXCEPT { return value(); }
/**
* @brief Compares two hashed strings.
* @param other Hashed string with which to compare.
* @return True if the two hashed strings are identical, false otherwise.
*/
[[nodiscard]] constexpr bool operator==(const basic_hashed_string &other) const ENTT_NOEXCEPT {
return hash == other.hash;
}
private:
const value_type *str;
hash_type hash;
};
/**
* @brief Deduction guide.
*
* It allows to deduce the character type of the hashed string directly from a
* human-readable identifer provided to the constructor.
*
* @tparam Char Character type.
* @tparam N Number of characters of the identifier.
* @param str Human-readable identifer.
*/
template<typename Char, std::size_t N>
basic_hashed_string(const Char (&str)[N]) ENTT_NOEXCEPT
-> basic_hashed_string<Char>;
/**
* @brief Compares two hashed strings.
* @tparam Char Character type.
* @param lhs A valid hashed string.
* @param rhs A valid hashed string.
* @return True if the two hashed strings are identical, false otherwise.
*/
template<typename Char>
[[nodiscard]] constexpr bool operator!=(const basic_hashed_string<Char> &lhs, const basic_hashed_string<Char> &rhs) ENTT_NOEXCEPT {
return !(lhs == rhs);
}
/*! @brief Aliases for common character types. */
using hashed_string = basic_hashed_string<char>;
/*! @brief Aliases for common character types. */
using hashed_wstring = basic_hashed_string<wchar_t>;
}
/**
* @brief User defined literal for hashed strings.
* @param str The literal without its suffix.
* @return A properly initialized hashed string.
*/
[[nodiscard]] constexpr entt::hashed_string operator"" ENTT_HS_SUFFIX(const char *str, std::size_t) ENTT_NOEXCEPT {
return entt::hashed_string{str};
}
/**
* @brief User defined literal for hashed wstrings.
* @param str The literal without its suffix.
* @return A properly initialized hashed wstring.
*/
[[nodiscard]] constexpr entt::hashed_wstring operator"" ENTT_HWS_SUFFIX(const wchar_t *str, std::size_t) ENTT_NOEXCEPT {
return entt::hashed_wstring{str};
}
#endif
// #include "fwd.hpp"
namespace entt {
/**
* @cond TURN_OFF_DOXYGEN
* Internal details not to be documented.
*/
namespace internal {
struct ENTT_API type_index {
[[nodiscard]] static id_type next() ENTT_NOEXCEPT {
static ENTT_MAYBE_ATOMIC(id_type) value{};
return value++;
}
};
template<typename Type>
[[nodiscard]] constexpr auto type_name() ENTT_NOEXCEPT {
#if defined ENTT_PRETTY_FUNCTION
std::string_view pretty_function{ENTT_PRETTY_FUNCTION};
auto first = pretty_function.find_first_not_of(' ', pretty_function.find_first_of(ENTT_PRETTY_FUNCTION_PREFIX)+1);
auto value = pretty_function.substr(first, pretty_function.find_last_of(ENTT_PRETTY_FUNCTION_SUFFIX) - first);
return value;
#else
return std::string_view{};
#endif
}
}
/**
* Internal details not to be documented.
* @endcond
*/
/**
* @brief Type index.
* @tparam Type Type for which to generate a sequential identifier.
*/
template<typename Type, typename = void>
struct ENTT_API type_index {
/**
* @brief Returns the sequential identifier of a given type.
* @return The sequential identifier of a given type.
*/
[[nodiscard]] static id_type value() ENTT_NOEXCEPT {
static const id_type value = internal::type_index::next();
return value;
}
};
/**
* @brief Provides the member constant `value` to true if a given type is
* indexable, false otherwise.
* @tparam Type Potentially indexable type.
*/
template<typename, typename = void>
struct has_type_index: std::false_type {};
/*! @brief has_type_index */
template<typename Type>
struct has_type_index<Type, std::void_t<decltype(type_index<Type>::value())>>: std::true_type {};
/**
* @brief Helper variable template.
* @tparam Type Potentially indexable type.
*/
template<typename Type>
inline constexpr bool has_type_index_v = has_type_index<Type>::value;
/**
* @brief Type info.
* @tparam Type Type for which to generate information.
*/
template<typename Type, typename = void>
struct type_info {
/**
* @brief Returns the numeric representation of a given type.
* @return The numeric representation of the given type.
*/
#if defined ENTT_PRETTY_FUNCTION_CONSTEXPR
[[nodiscard]] static constexpr id_type id() ENTT_NOEXCEPT {
constexpr auto value = hashed_string::value(ENTT_PRETTY_FUNCTION);
return value;
}
#elif defined ENTT_PRETTY_FUNCTION
[[nodiscard]] static id_type id() ENTT_NOEXCEPT {
static const auto value = hashed_string::value(ENTT_PRETTY_FUNCTION);
return value;
}
#else
[[nodiscard]] static id_type id() ENTT_NOEXCEPT {
return type_index<Type>::value();
}
#endif
/**
* @brief Returns the name of a given type.
* @return The name of the given type.
*/
#if defined ENTT_PRETTY_FUNCTION_CONSTEXPR
[[nodiscard]] static constexpr std::string_view name() ENTT_NOEXCEPT {
constexpr auto value = internal::type_name<Type>();
return value;
}
#elif defined ENTT_PRETTY_FUNCTION
[[nodiscard]] static std::string_view name() ENTT_NOEXCEPT {
static const auto value = internal::type_name<Type>();
return value;
}
#else
[[nodiscard]] static constexpr std::string_view name() ENTT_NOEXCEPT {
return internal::type_name<Type>();
}
#endif
};
}
#endif
// #include "../core/type_traits.hpp"
#ifndef ENTT_CORE_TYPE_TRAITS_HPP
#define ENTT_CORE_TYPE_TRAITS_HPP
#include <cstddef>
#include <utility>
#include <type_traits>
// #include "../config/config.h"
// #include "fwd.hpp"
namespace entt {
/**
* @brief Using declaration to be used to _repeat_ the same type a number of
* times equal to the size of a given parameter pack.
* @tparam Type A type to repeat.
*/
template<typename Type, typename>
using unpack_as_t = Type;
/**
* @brief Helper variable template to be used to _repeat_ the same value a
* number of times equal to the size of a given parameter pack.
* @tparam Value A value to repeat.
*/
template<auto Value, typename>
inline constexpr auto unpack_as_v = Value;
/**
* @brief Wraps a static constant.
* @tparam Value A static constant.
*/
template<auto Value>
using integral_constant = std::integral_constant<decltype(Value), Value>;
/**
* @brief Alias template to ease the creation of named values.
* @tparam Value A constant value at least convertible to `id_type`.
*/
template<id_type Value>
using tag = integral_constant<Value>;
/**
* @brief Utility class to disambiguate overloaded functions.
* @tparam N Number of choices available.
*/
template<std::size_t N>
struct choice_t
// Unfortunately, doxygen cannot parse such a construct.
/*! @cond TURN_OFF_DOXYGEN */
: choice_t<N-1>
/*! @endcond */
{};
/*! @copybrief choice_t */
template<>
struct choice_t<0> {};
/**
* @brief Variable template for the choice trick.
* @tparam N Number of choices available.
*/
template<std::size_t N>
inline constexpr choice_t<N> choice{};
/*! @brief A class to use to push around lists of types, nothing more. */
template<typename...>
struct type_list {};
/*! @brief Primary template isn't defined on purpose. */
template<typename>
struct type_list_size;
/**
* @brief Compile-time number of elements in a type list.
* @tparam Type Types provided by the type list.
*/
template<typename... Type>
struct type_list_size<type_list<Type...>>
: std::integral_constant<std::size_t, sizeof...(Type)>
{};
/**
* @brief Helper variable template.
* @tparam List Type list.
*/
template<class List>
inline constexpr auto type_list_size_v = type_list_size<List>::value;
/*! @brief Primary template isn't defined on purpose. */
template<typename...>
struct type_list_cat;
/*! @brief Concatenates multiple type lists. */
template<>
struct type_list_cat<> {
/*! @brief A type list composed by the types of all the type lists. */
using type = type_list<>;
};
/**
* @brief Concatenates multiple type lists.
* @tparam Type Types provided by the first type list.
* @tparam Other Types provided by the second type list.
* @tparam List Other type lists, if any.
*/
template<typename... Type, typename... Other, typename... List>
struct type_list_cat<type_list<Type...>, type_list<Other...>, List...> {
/*! @brief A type list composed by the types of all the type lists. */
using type = typename type_list_cat<type_list<Type..., Other...>, List...>::type;
};
/**
* @brief Concatenates multiple type lists.
* @tparam Type Types provided by the type list.
*/
template<typename... Type>
struct type_list_cat<type_list<Type...>> {
/*! @brief A type list composed by the types of all the type lists. */
using type = type_list<Type...>;
};
/**
* @brief Helper type.
* @tparam List Type lists to concatenate.
*/
template<typename... List>
using type_list_cat_t = typename type_list_cat<List...>::type;
/*! @brief Primary template isn't defined on purpose. */
template<typename>
struct type_list_unique;
/**
* @brief Removes duplicates types from a type list.
* @tparam Type One of the types provided by the given type list.
* @tparam Other The other types provided by the given type list.
*/
template<typename Type, typename... Other>
struct type_list_unique<type_list<Type, Other...>> {
/*! @brief A type list without duplicate types. */
using type = std::conditional_t<
std::disjunction_v<std::is_same<Type, Other>...>,
typename type_list_unique<type_list<Other...>>::type,
type_list_cat_t<type_list<Type>, typename type_list_unique<type_list<Other...>>::type>
>;
};
/*! @brief Removes duplicates types from a type list. */
template<>
struct type_list_unique<type_list<>> {
/*! @brief A type list without duplicate types. */
using type = type_list<>;
};
/**
* @brief Helper type.
* @tparam Type A type list.
*/
template<typename Type>
using type_list_unique_t = typename type_list_unique<Type>::type;
/**
* @brief Provides the member constant `value` to true if a given type is
* equality comparable, false otherwise.
* @tparam Type Potentially equality comparable type.
*/
template<typename Type, typename = std::void_t<>>
struct is_equality_comparable: std::false_type {};
/*! @copydoc is_equality_comparable */
template<typename Type>
struct is_equality_comparable<Type, std::void_t<decltype(std::declval<Type>() == std::declval<Type>())>>
: std::true_type
{};
/**
* @brief Helper variable template.
* @tparam Type Potentially equality comparable type.
*/
template<class Type>
inline constexpr auto is_equality_comparable_v = is_equality_comparable<Type>::value;
/**
* @brief Provides the member constant `value` to true if a given type is empty
* and the empty type optimization is enabled, false otherwise.
* @tparam Type Potential empty type.
*/
template<typename Type, typename = void>
struct is_eto_eligible
: ENTT_IS_EMPTY(Type)
{};
/**
* @brief Helper variable template.
* @tparam Type Potential empty type.
*/
template<typename Type>
inline constexpr auto is_eto_eligible_v = is_eto_eligible<Type>::value;
/**
* @brief Extracts the class of a non-static member object or function.
* @tparam Member A pointer to a non-static member object or function.
*/
template<typename Member>
class member_class {
static_assert(std::is_member_pointer_v<Member>, "Invalid pointer type to non-static member object or function");
template<typename Class, typename Ret, typename... Args>
static Class * clazz(Ret(Class:: *)(Args...));
template<typename Class, typename Ret, typename... Args>
static Class * clazz(Ret(Class:: *)(Args...) const);
template<typename Class, typename Type>
static Class * clazz(Type Class:: *);
public:
/*! @brief The class of the given non-static member object or function. */
using type = std::remove_pointer_t<decltype(clazz(std::declval<Member>()))>;
};
/**
* @brief Helper type.
* @tparam Member A pointer to a non-static member object or function.
*/
template<typename Member>
using member_class_t = typename member_class<Member>::type;
}
#endif
// #include "internal.hpp"
#ifndef ENTT_META_INTERNAL_HPP
#define ENTT_META_INTERNAL_HPP
#include <cstddef>
#include <functional>
#include <iterator>
#include <type_traits>
#include <utility>
// #include "../core/attribute.h"
// #include "../config/config.h"
// #include "../core/fwd.hpp"
// #include "../core/type_info.hpp"
// #include "../core/type_traits.hpp"
// #include "type_traits.hpp"
namespace entt {
class meta_any;
struct meta_handle;
/**
* @cond TURN_OFF_DOXYGEN
* Internal details not to be documented.
*/
namespace internal {
class meta_storage {
using storage_type = std::aligned_storage_t<sizeof(void *), alignof(void *)>;
using copy_fn_type = void(meta_storage &, const meta_storage &);
using steal_fn_type = void(meta_storage &, meta_storage &);
using destroy_fn_type = void(meta_storage &);
template<typename Type, typename = std::void_t<>>
struct type_traits {
template<typename... Args>
static void instance(meta_storage &buffer, Args &&... args) {
buffer.instance = new Type{std::forward<Args>(args)...};
new (&buffer.storage) Type *{static_cast<Type *>(buffer.instance)};
}
static void destroy(meta_storage &buffer) {
delete static_cast<Type *>(buffer.instance);
}
static void copy(meta_storage &to, const meta_storage &from) {
to.instance = new Type{*static_cast<const Type *>(from.instance)};
new (&to.storage) Type *{static_cast<Type *>(to.instance)};
}
static void steal(meta_storage &to, meta_storage &from) {
new (&to.storage) Type *{static_cast<Type *>(from.instance)};
to.instance = from.instance;
}
};
template<typename Type>
struct type_traits<Type, std::enable_if_t<sizeof(Type) <= sizeof(void *) && std::is_nothrow_move_constructible_v<Type>>> {
template<typename... Args>
static void instance(meta_storage &buffer, Args &&... args) {
buffer.instance = new (&buffer.storage) Type{std::forward<Args>(args)...};
}
static void destroy(meta_storage &buffer) {
static_cast<Type *>(buffer.instance)->~Type();
}
static void copy(meta_storage &to, const meta_storage &from) {
to.instance = new (&to.storage) Type{*static_cast<const Type *>(from.instance)};
}
static void steal(meta_storage &to, meta_storage &from) {
to.instance = new (&to.storage) Type{std::move(*static_cast<Type *>(from.instance))};
destroy(from);
}
};
public:
/*! @brief Default constructor. */
meta_storage() ENTT_NOEXCEPT
: storage{},
instance{},
destroy_fn{},
copy_fn{},
steal_fn{}
{}
template<typename Type, typename... Args>
explicit meta_storage(std::in_place_type_t<Type>, [[maybe_unused]] Args &&... args)
: meta_storage{}
{
if constexpr(!std::is_void_v<Type>) {
type_traits<Type>::instance(*this, std::forward<Args>(args)...);
destroy_fn = &type_traits<Type>::destroy;
copy_fn = &type_traits<Type>::copy;
steal_fn = &type_traits<Type>::steal;
}
}
template<typename Type>
meta_storage(std::reference_wrapper<Type> value)
: meta_storage{}
{
instance = &value.get();
}
template<typename Type, typename = std::enable_if_t<!std::is_same_v<std::remove_cv_t<std::remove_reference_t<Type>>, meta_storage>>>
meta_storage(Type &&value)
: meta_storage{std::in_place_type<std::remove_cv_t<std::remove_reference_t<Type>>>, std::forward<Type>(value)}
{}
meta_storage(const meta_storage &other)
: meta_storage{}
{
(other.copy_fn ? other.copy_fn : [](auto &to, const auto &from) { to.instance = from.instance; })(*this, other);
destroy_fn = other.destroy_fn;
copy_fn = other.copy_fn;
steal_fn = other.steal_fn;
}
meta_storage(meta_storage &&other)
: meta_storage{}
{
swap(*this, other);
}
~meta_storage() {
if(destroy_fn) {
destroy_fn(*this);
}
}
meta_storage & operator=(meta_storage other) {
swap(other, *this);
return *this;
}
[[nodiscard]] const void * data() const ENTT_NOEXCEPT {
return instance;
}
[[nodiscard]] void * data() ENTT_NOEXCEPT {
return const_cast<void *>(std::as_const(*this).data());
}
template<typename Type, typename... Args>
void emplace(Args &&... args) {
*this = meta_storage{std::in_place_type<Type>, std::forward<Args>(args)...};
}
[[nodiscard]] meta_storage ref() const ENTT_NOEXCEPT {
meta_storage other{};
other.instance = instance;
return other;
}
[[nodiscard]] explicit operator bool() const ENTT_NOEXCEPT {
return !(instance == nullptr);
}
friend void swap(meta_storage &lhs, meta_storage &rhs) {
using std::swap;
if(lhs.steal_fn && rhs.steal_fn) {
meta_storage buffer{};
lhs.steal_fn(buffer, lhs);
rhs.steal_fn(lhs, rhs);
lhs.steal_fn(rhs, buffer);
} else if(lhs.steal_fn) {
lhs.steal_fn(rhs, lhs);
} else if(rhs.steal_fn) {
rhs.steal_fn(lhs, rhs);
} else {
swap(lhs.instance, rhs.instance);
}
swap(lhs.destroy_fn, rhs.destroy_fn);
swap(lhs.copy_fn, rhs.copy_fn);
swap(lhs.steal_fn, rhs.steal_fn);
}
private:
storage_type storage;
void *instance;
destroy_fn_type *destroy_fn;
copy_fn_type *copy_fn;
steal_fn_type *steal_fn;
};
struct meta_type_node;
struct meta_prop_node {
meta_prop_node * next;
meta_any(* const key)();
meta_any(* const value)();
};
struct meta_base_node {
meta_type_node * const parent;
meta_base_node * next;
meta_type_node *(* const type)() ENTT_NOEXCEPT;
const void *(* const cast)(const void *) ENTT_NOEXCEPT;
};
struct meta_conv_node {
meta_type_node * const parent;
meta_conv_node * next;
meta_type_node *(* const type)() ENTT_NOEXCEPT;
meta_any(* const conv)(const void *);
};
struct meta_ctor_node {
using size_type = std::size_t;
meta_type_node * const parent;
meta_ctor_node * next;
meta_prop_node * prop;
const size_type size;
meta_type_node *(* const arg)(size_type) ENTT_NOEXCEPT;
meta_any(* const invoke)(meta_any * const);
};
struct meta_data_node {
id_type id;
meta_type_node * const parent;
meta_data_node * next;
meta_prop_node * prop;
const bool is_static;
meta_type_node *(* const type)() ENTT_NOEXCEPT;
bool(* const set)(meta_handle, meta_any);
meta_any(* const get)(meta_handle);
};
struct meta_func_node {
using size_type = std::size_t;
id_type id;
meta_type_node * const parent;
meta_func_node * next;
meta_prop_node * prop;
const size_type size;
const bool is_const;
const bool is_static;
meta_type_node *(* const ret)() ENTT_NOEXCEPT;
meta_type_node *(* const arg)(size_type) ENTT_NOEXCEPT;
meta_any(* const invoke)(meta_handle, meta_any *);
};
struct meta_type_node {
using size_type = std::size_t;
const id_type type_id;
id_type id;
meta_type_node * next;
meta_prop_node * prop;
const bool is_void;
const bool is_integral;
const bool is_floating_point;
const bool is_array;
const bool is_enum;
const bool is_union;
const bool is_class;
const bool is_pointer;
const bool is_function_pointer;
const bool is_member_object_pointer;
const bool is_member_function_pointer;
const bool is_pointer_like;
const bool is_sequence_container;
const bool is_associative_container;
const size_type rank;
size_type(* const extent)(size_type);
bool(* const compare)(const void *, const void *);
meta_type_node *(* const remove_pointer)() ENTT_NOEXCEPT;
meta_type_node *(* const remove_extent)() ENTT_NOEXCEPT;
meta_base_node *base{nullptr};
meta_conv_node *conv{nullptr};
meta_ctor_node *ctor{nullptr};
meta_data_node *data{nullptr};
meta_func_node *func{nullptr};
void(* dtor)(void *){nullptr};
};
template<typename Node>
class meta_range {
struct range_iterator {
using difference_type = std::ptrdiff_t;
using value_type = Node;
using pointer = value_type *;
using reference = value_type &;
using iterator_category = std::forward_iterator_tag;
range_iterator() ENTT_NOEXCEPT = default;
range_iterator(Node *head) ENTT_NOEXCEPT
: node{head}
{}
range_iterator & operator++() ENTT_NOEXCEPT {
return node = node->next, *this;
}
range_iterator operator++(int) ENTT_NOEXCEPT {
range_iterator orig = *this;
return ++(*this), orig;
}
[[nodiscard]] bool operator==(const range_iterator &other) const ENTT_NOEXCEPT {
return other.node == node;
}
[[nodiscard]] bool operator!=(const range_iterator &other) const ENTT_NOEXCEPT {
return !(*this == other);
}
[[nodiscard]] pointer operator->() const ENTT_NOEXCEPT {
return node;
}
[[nodiscard]] reference operator*() const ENTT_NOEXCEPT {
return *operator->();
}
private:
Node *node{nullptr};
};
public:
using iterator = range_iterator;
meta_range() ENTT_NOEXCEPT = default;
meta_range(Node *head)
: node{head}
{}
[[nodiscard]] iterator begin() const ENTT_NOEXCEPT {
return iterator{node};
}
[[nodiscard]] iterator end() const ENTT_NOEXCEPT {
return iterator{};
}
private:
Node *node{nullptr};
};
template<auto Member, typename Op>
auto find_if(const Op &op, const meta_type_node *node)
-> std::decay_t<decltype(node->*Member)> {
std::decay_t<decltype(node->*Member)> ret = nullptr;
for(auto &&curr: meta_range{node->*Member}) {
if(op(&curr)) {
ret = &curr;
break;
}
}
if(!ret) {
for(auto &&curr: meta_range{node->base}) {
if(ret = find_if<Member>(op, curr.type()); ret) {
break;
}
}
}
return ret;
}
template<typename Type>
class ENTT_API meta_node {
static_assert(std::is_same_v<Type, std::remove_cv_t<std::remove_reference_t<Type>>>, "Invalid type");
[[nodiscard]] static bool compare(const void *lhs, const void *rhs) {
if constexpr(!std::is_function_v<Type> && is_equality_comparable_v<Type>) {
return *static_cast<const Type *>(lhs) == *static_cast<const Type *>(rhs);
} else {
return lhs == rhs;
}
}
template<std::size_t... Index>
[[nodiscard]] static auto extent(meta_type_node::size_type dim, std::index_sequence<Index...>) {
meta_type_node::size_type ext{};
((ext = (dim == Index ? std::extent_v<Type, Index> : ext)), ...);
return ext;
}
public:
[[nodiscard]] static meta_type_node * resolve() ENTT_NOEXCEPT {
static meta_type_node node{
type_info<Type>::id(),
{},
nullptr,
nullptr,
std::is_void_v<Type>,
std::is_integral_v<Type>,
std::is_floating_point_v<Type>,
std::is_array_v<Type>,
std::is_enum_v<Type>,
std::is_union_v<Type>,
std::is_class_v<Type>,
std::is_pointer_v<Type>,
std::is_pointer_v<Type> && std::is_function_v<std::remove_pointer_t<Type>>,
std::is_member_object_pointer_v<Type>,
std::is_member_function_pointer_v<Type>,
is_meta_pointer_like_v<Type>,
has_meta_sequence_container_traits_v<Type>,
has_meta_associative_container_traits_v<Type>,
std::rank_v<Type>,
[](meta_type_node::size_type dim) {
return extent(dim, std::make_index_sequence<std::rank_v<Type>>{});
},
&compare, // workaround for an issue with VS2017
&meta_node<std::remove_const_t<std::remove_pointer_t<Type>>>::resolve,
&meta_node<std::remove_const_t<std::remove_extent_t<Type>>>::resolve
};
return &node;
}
};
template<typename... Type>
struct meta_info: meta_node<std::remove_cv_t<std::remove_reference_t<Type>>...> {};
}
/**
* Internal details not to be documented.
* @endcond
*/
}
#endif
// #include "meta.hpp"
#ifndef ENTT_META_META_HPP
#define ENTT_META_META_HPP
#include <algorithm>
#include <array>
#include <cstddef>
#include <iterator>
#include <functional>
#include <type_traits>
#include <utility>
// #include "../config/config.h"
// #include "../core/fwd.hpp"
// #include "../core/utility.hpp"
#ifndef ENTT_CORE_UTILITY_HPP
#define ENTT_CORE_UTILITY_HPP
#include <utility>
// #include "../config/config.h"
namespace entt {
/*! @brief Identity function object (waiting for C++20). */
struct identity {
/**
* @brief Returns its argument unchanged.
* @tparam Type Type of the argument.
* @param value The actual argument.
* @return The submitted value as-is.
*/
template<class Type>
[[nodiscard]] constexpr Type && operator()(Type &&value) const ENTT_NOEXCEPT {
return std::forward<Type>(value);
}
};
/**
* @brief Constant utility to disambiguate overloaded members of a class.
* @tparam Type Type of the desired overload.
* @tparam Class Type of class to which the member belongs.
* @param member A valid pointer to a member.
* @return Pointer to the member.
*/
template<typename Type, typename Class>
[[nodiscard]] constexpr auto overload(Type Class:: *member) ENTT_NOEXCEPT { return member; }
/**
* @brief Constant utility to disambiguate overloaded functions.
* @tparam Func Function type of the desired overload.
* @param func A valid pointer to a function.
* @return Pointer to the function.
*/
template<typename Func>
[[nodiscard]] constexpr auto overload(Func *func) ENTT_NOEXCEPT { return func; }
/**
* @brief Helper type for visitors.
* @tparam Func Types of function objects.
*/
template<class... Func>
struct overloaded: Func... {
using Func::operator()...;
};
/**
* @brief Deduction guide.
* @tparam Func Types of function objects.
*/
template<class... Func>
overloaded(Func...) -> overloaded<Func...>;
/**
* @brief Basic implementation of a y-combinator.
* @tparam Func Type of a potentially recursive function.
*/
template<class Func>
struct y_combinator {
/**
* @brief Constructs a y-combinator from a given function.
* @param recursive A potentially recursive function.
*/
y_combinator(Func recursive):
func{std::move(recursive)}
{}
/**
* @brief Invokes a y-combinator and therefore its underlying function.
* @tparam Args Types of arguments to use to invoke the underlying function.
* @param args Parameters to use to invoke the underlying function.
* @return Return value of the underlying function, if any.
*/
template <class... Args>
decltype(auto) operator()(Args &&... args) const {
return func(*this, std::forward<Args>(args)...);
}
/*! @copydoc operator()() */
template <class... Args>
decltype(auto) operator()(Args &&... args) {
return func(*this, std::forward<Args>(args)...);
}
private:
Func func;
};
}
#endif
// #include "ctx.hpp"
// #include "internal.hpp"
// #include "range.hpp"
#ifndef ENTT_META_RANGE_HPP
#define ENTT_META_RANGE_HPP
// #include "internal.hpp"
namespace entt {
/**
* @brief Iterable range to use to iterate all types of meta objects.
* @tparam Type Type of meta objects iterated.
*/
template<typename Type>
class meta_range {
struct range_iterator {
using difference_type = std::ptrdiff_t;
using value_type = Type;
using pointer = void;
using reference = value_type;
using iterator_category = std::input_iterator_tag;
using node_type = typename Type::node_type;
range_iterator() ENTT_NOEXCEPT = default;
range_iterator(node_type *head) ENTT_NOEXCEPT
: it{head}
{}
range_iterator & operator++() ENTT_NOEXCEPT {
return ++it, *this;
}
range_iterator operator++(int) ENTT_NOEXCEPT {
range_iterator orig = *this;
return ++(*this), orig;
}
[[nodiscard]] reference operator*() const ENTT_NOEXCEPT {
return it.operator->();
}
[[nodiscard]] bool operator==(const range_iterator &other) const ENTT_NOEXCEPT {
return other.it == it;
}
[[nodiscard]] bool operator!=(const range_iterator &other) const ENTT_NOEXCEPT {
return !(*this == other);
}
private:
typename internal::meta_range<node_type>::iterator it{};
};
public:
/*! @brief Node type. */
using node_type = typename Type::node_type;
/*! @brief Input iterator type. */
using iterator = range_iterator;
/*! @brief Default constructor. */
meta_range() ENTT_NOEXCEPT = default;
/**
* @brief Constructs a meta range from a given node.
* @param head The underlying node with which to construct the range.
*/
meta_range(node_type *head)
: node{head}
{}
/**
* @brief Returns an iterator to the beginning.
* @return An iterator to the first meta object of the range.
*/
[[nodiscard]] iterator begin() const ENTT_NOEXCEPT {
return iterator{node};
}
/**
* @brief Returns an iterator to the end.
* @return An iterator to the element following the last meta object of the
* range.
*/
[[nodiscard]] iterator end() const ENTT_NOEXCEPT {
return iterator{};
}
private:
node_type *node{nullptr};
};
}
#endif
// #include "type_traits.hpp"
namespace entt {
class meta_type;
class meta_any;
/*! @brief Proxy object for sequence containers. */
class meta_sequence_container {
template<typename>
struct meta_sequence_container_proxy;
class meta_iterator;
public:
/*! @brief Unsigned integer type. */
using size_type = std::size_t;
/*! @brief Meta iterator type. */
using iterator = meta_iterator;
/*! @brief Default constructor. */
meta_sequence_container() ENTT_NOEXCEPT
: instance{nullptr}
{}
/**
* @brief Construct a proxy object for sequence containers.
* @tparam Type Type of container to wrap.
* @param container The container to wrap.
*/
template<typename Type>
meta_sequence_container(Type *container) ENTT_NOEXCEPT
: value_type_fn{&meta_sequence_container_proxy<Type>::value_type},
size_fn{&meta_sequence_container_proxy<Type>::size},
resize_fn{&meta_sequence_container_proxy<Type>::resize},
clear_fn{&meta_sequence_container_proxy<Type>::clear},
begin_fn{&meta_sequence_container_proxy<Type>::begin},
end_fn{&meta_sequence_container_proxy<Type>::end},
insert_fn{&meta_sequence_container_proxy<Type>::insert},
erase_fn{&meta_sequence_container_proxy<Type>::erase},
get_fn{&meta_sequence_container_proxy<Type>::get},
instance{container}
{}
[[nodiscard]] inline meta_type value_type() const ENTT_NOEXCEPT;
[[nodiscard]] inline size_type size() const ENTT_NOEXCEPT;
inline bool resize(size_type) const;
inline bool clear();
[[nodiscard]] inline iterator begin();
[[nodiscard]] inline iterator end();
inline std::pair<iterator, bool> insert(iterator, meta_any);
inline std::pair<iterator, bool> erase(iterator);
[[nodiscard]] inline meta_any operator[](size_type);
[[nodiscard]] inline explicit operator bool() const ENTT_NOEXCEPT;
private:
meta_type(* value_type_fn)() ENTT_NOEXCEPT;
size_type(* size_fn)(const void *) ENTT_NOEXCEPT;
bool(* resize_fn)(void *, size_type);
bool(* clear_fn)(void *);
iterator(* begin_fn)(void *);
iterator(* end_fn)(void *);
std::pair<iterator, bool>(* insert_fn)(void *, iterator, meta_any);
std::pair<iterator, bool>(* erase_fn)(void *, iterator);
meta_any(* get_fn)(void *, size_type);
void *instance;
};
/*! @brief Proxy object for associative containers. */
class meta_associative_container {
template<typename>
struct meta_associative_container_proxy;
class meta_iterator;
public:
/*! @brief Unsigned integer type. */
using size_type = std::size_t;
/*! @brief Meta iterator type. */
using iterator = meta_iterator;
/*! @brief Default constructor. */
meta_associative_container() ENTT_NOEXCEPT
: instance{nullptr}
{}
/**
* @brief Construct a proxy object for associative containers.
* @tparam Type Type of container to wrap.
* @param container The container to wrap.
*/
template<typename Type>
meta_associative_container(Type *container) ENTT_NOEXCEPT
: key_only_container{is_key_only_meta_associative_container_v<Type>},
key_type_fn{&meta_associative_container_proxy<Type>::key_type},
mapped_type_fn{&meta_associative_container_proxy<Type>::mapped_type},
value_type_fn{&meta_associative_container_proxy<Type>::value_type},
size_fn{&meta_associative_container_proxy<Type>::size},
clear_fn{&meta_associative_container_proxy<Type>::clear},
begin_fn{&meta_associative_container_proxy<Type>::begin},
end_fn{&meta_associative_container_proxy<Type>::end},
insert_fn{&meta_associative_container_proxy<Type>::insert},
erase_fn{&meta_associative_container_proxy<Type>::erase},
find_fn{&meta_associative_container_proxy<Type>::find},
instance{container}
{}
[[nodiscard]] inline bool key_only() const ENTT_NOEXCEPT;
[[nodiscard]] inline meta_type key_type() const ENTT_NOEXCEPT;
[[nodiscard]] inline meta_type mapped_type() const ENTT_NOEXCEPT;
[[nodiscard]] inline meta_type value_type() const ENTT_NOEXCEPT;
[[nodiscard]] inline size_type size() const ENTT_NOEXCEPT;
inline bool clear();
[[nodiscard]] inline iterator begin();
[[nodiscard]] inline iterator end();
inline bool insert(meta_any, meta_any);
inline bool erase(meta_any);
[[nodiscard]] inline iterator find(meta_any);
[[nodiscard]] inline explicit operator bool() const ENTT_NOEXCEPT;
private:
bool key_only_container;
meta_type(* key_type_fn)() ENTT_NOEXCEPT;
meta_type(* mapped_type_fn)() ENTT_NOEXCEPT;
meta_type(* value_type_fn)() ENTT_NOEXCEPT;
size_type(* size_fn)(const void *) ENTT_NOEXCEPT;
bool(* clear_fn)(void *);
iterator(* begin_fn)(void *);
iterator(* end_fn)(void *);
bool(* insert_fn)(void *, meta_any, meta_any);
bool(* erase_fn)(void *, meta_any);
iterator(* find_fn)(void *, meta_any);
void *instance;
};
/**
* @brief Opaque wrapper for values of any type.
*
* This class uses a technique called small buffer optimization (SBO) to get rid
* of memory allocations if possible. This should improve overall performance.
*/
class meta_any {
using dereference_operator_type = meta_any(meta_any &);
template<typename Type>
[[nodiscard]] static meta_any dereference_operator(meta_any &any) {
if constexpr(is_meta_pointer_like_v<Type>) {
if constexpr(std::is_const_v<std::remove_reference_t<decltype(*std::declval<Type>())>>) {
return *any.cast<Type>();
} else {
return std::ref(*any.cast<Type>());
}
} else {
return {};
}
}
template<typename Type>
[[nodiscard]] static meta_sequence_container meta_sequence_container_factory([[maybe_unused]] void *container) ENTT_NOEXCEPT {
if constexpr(has_meta_sequence_container_traits_v<Type>) {
return static_cast<Type *>(container);
} else {
return {};
}
}
template<typename Type>
[[nodiscard]] static meta_associative_container meta_associative_container_factory([[maybe_unused]] void *container) ENTT_NOEXCEPT {
if constexpr(has_meta_associative_container_traits_v<Type>) {
return static_cast<Type *>(container);
} else {
return {};
}
}
public:
/*! @brief Default constructor. */
meta_any() ENTT_NOEXCEPT
: storage{},
node{},
deref{nullptr},
seq_factory{nullptr},
assoc_factory{nullptr}
{}
/**
* @brief Constructs a meta any by directly initializing the new object.
* @tparam Type Type of object to use to initialize the wrapper.
* @tparam Args Types of arguments to use to construct the new instance.
* @param args Parameters to use to construct the instance.
*/
template<typename Type, typename... Args>
explicit meta_any(std::in_place_type_t<Type>, [[maybe_unused]] Args &&... args)
: storage(std::in_place_type<Type>, std::forward<Args>(args)...),
node{internal::meta_info<Type>::resolve()},
deref{&dereference_operator<Type>},
seq_factory{&meta_sequence_container_factory<Type>},
assoc_factory{&meta_associative_container_factory<Type>}
{}
/**
* @brief Constructs a meta any that holds an unmanaged object.
* @tparam Type Type of object to use to initialize the wrapper.
* @param value An instance of an object to use to initialize the wrapper.
*/
template<typename Type>
meta_any(std::reference_wrapper<Type> value)
: storage{value},
node{internal::meta_info<Type>::resolve()},
deref{&dereference_operator<Type>},
seq_factory{&meta_sequence_container_factory<Type>},
assoc_factory{&meta_associative_container_factory<Type>}
{}
/**
* @brief Constructs a meta any from a given value.
* @tparam Type Type of object to use to initialize the wrapper.
* @param value An instance of an object to use to initialize the wrapper.
*/
template<typename Type, typename = std::enable_if_t<!std::is_same_v<std::remove_cv_t<std::remove_reference_t<Type>>, meta_any>>>
meta_any(Type &&value)
: meta_any{std::in_place_type<std::remove_cv_t<std::remove_reference_t<Type>>>, std::forward<Type>(value)}
{}
/**
* @brief Copy constructor.
* @param other The instance to copy from.
*/
meta_any(const meta_any &other) = default;
/**
* @brief Move constructor.
* @param other The instance to move from.
*/
meta_any(meta_any &&other)
: meta_any{}
{
swap(*this, other);
}
/*! @brief Frees the internal storage, whatever it means. */
~meta_any() {
if(node && node->dtor) {
node->dtor(storage.data());
}
}
/**
* @brief Assignment operator.
* @param other The instance to assign from.
* @return This meta any object.
*/
meta_any & operator=(meta_any other) {
swap(other, *this);
return *this;
}
/**
* @brief Returns the meta type of the underlying object.
* @return The meta type of the underlying object, if any.
*/
[[nodiscard]] inline meta_type type() const ENTT_NOEXCEPT;
/**
* @brief Returns an opaque pointer to the contained instance.
* @return An opaque pointer the contained instance, if any.
*/
[[nodiscard]] const void * data() const ENTT_NOEXCEPT {
return storage.data();
}
/*! @copydoc data */
[[nodiscard]] void * data() ENTT_NOEXCEPT {
return storage.data();
}
/**
* @brief Tries to cast an instance to a given type.
* @tparam Type Type to which to cast the instance.
* @return A (possibly null) pointer to the contained instance.
*/
template<typename Type>
[[nodiscard]] const Type * try_cast() const {
if(node) {
if(const auto type_id = internal::meta_info<Type>::resolve()->type_id; node->type_id == type_id) {
return static_cast<const Type *>(storage.data());
} else if(const auto *base = internal::find_if<&internal::meta_type_node::base>([type_id](const auto *curr) { return curr->type()->type_id == type_id; }, node); base) {
return static_cast<const Type *>(base->cast(storage.data()));
}
}
return nullptr;
}
/*! @copydoc try_cast */
template<typename Type>
[[nodiscard]] Type * try_cast() {
return const_cast<Type *>(std::as_const(*this).try_cast<Type>());
}
/**
* @brief Tries to cast an instance to a given type.
*
* The type of the instance must be such that the cast is possible.
*
* @warning
* Attempting to perform a cast that isn't viable results in undefined
* behavior.<br/>
* An assertion will abort the execution at runtime in debug mode in case
* the cast is not feasible.
*
* @tparam Type Type to which to cast the instance.
* @return A reference to the contained instance.
*/
template<typename Type>
[[nodiscard]] const Type & cast() const {
auto * const actual = try_cast<Type>();
ENTT_ASSERT(actual);
return *actual;
}
/*! @copydoc cast */
template<typename Type>
[[nodiscard]] Type & cast() {
return const_cast<Type &>(std::as_const(*this).cast<Type>());
}
/**
* @brief Tries to convert an instance to a given type and returns it.
* @tparam Type Type to which to convert the instance.
* @return A valid meta any object if the conversion is possible, an invalid
* one otherwise.
*/
template<typename Type>
[[nodiscard]] meta_any convert() const {
if(node) {
if(const auto type_id = internal::meta_info<Type>::resolve()->type_id; node->type_id == type_id) {
return *this;
} else if(const auto * const conv = internal::find_if<&internal::meta_type_node::conv>([type_id](const auto *curr) { return curr->type()->type_id == type_id; }, node); conv) {
return conv->conv(storage.data());
}
}
return {};
}
/**
* @brief Tries to convert an instance to a given type.
* @tparam Type Type to which to convert the instance.
* @return True if the conversion is possible, false otherwise.
*/
template<typename Type>
bool convert() {
bool valid = (node && node->type_id == internal::meta_info<Type>::resolve()->type_id);
if(!valid) {
if(auto any = std::as_const(*this).convert<Type>(); any) {
swap(any, *this);
valid = true;
}
}
return valid;
}
/**
* @brief Replaces the contained object by creating a new instance directly.
* @tparam Type Type of object to use to initialize the wrapper.
* @tparam Args Types of arguments to use to construct the new instance.
* @param args Parameters to use to construct the instance.
*/
template<typename Type, typename... Args>
void emplace(Args &&... args) {
*this = meta_any{std::in_place_type<Type>, std::forward<Args>(args)...};
}
/**
* @brief Aliasing constructor.
* @return A meta any that shares a reference to an unmanaged object.
*/
[[nodiscard]] meta_any ref() const ENTT_NOEXCEPT {
meta_any other{};
other.node = node;
other.storage = storage.ref();
other.deref = deref;
other.seq_factory = seq_factory;
other.assoc_factory = assoc_factory;
return other;
}
/**
* @brief Returns a sequence container proxy.
* @return A sequence container proxy for the underlying object.
*/
[[nodiscard]] meta_sequence_container as_sequence_container() ENTT_NOEXCEPT {
return seq_factory(storage.data());
}
/**
* @brief Returns an associative container proxy.
* @return An associative container proxy for the underlying object.
*/
[[nodiscard]] meta_associative_container as_associative_container() ENTT_NOEXCEPT {
return assoc_factory(storage.data());
}
/**
* @brief Indirection operator for dereferencing opaque objects.
* @return A meta any that shares a reference to an unmanaged object if the
* wrapped element is dereferenceable, an invalid meta any otherwise.
*/
[[nodiscard]] meta_any operator*() ENTT_NOEXCEPT {
return deref(*this);
}
/**
* @brief Returns false if a wrapper is empty, true otherwise.
* @return False if the wrapper is empty, true otherwise.
*/
[[nodiscard]] explicit operator bool() const ENTT_NOEXCEPT {
return !(node == nullptr);
}
/**
* @brief Checks if two wrappers differ in their content.
* @param other Wrapper with which to compare.
* @return False if the two objects differ in their content, true otherwise.
*/
[[nodiscard]] bool operator==(const meta_any &other) const {
return (!node && !other.node) || (node && other.node && node->type_id == other.node->type_id && node->compare(storage.data(), other.storage.data()));
}
/**
* @brief Swaps two meta any objects.
* @param lhs A valid meta any object.
* @param rhs A valid meta any object.
*/
friend void swap(meta_any &lhs, meta_any &rhs) {
using std::swap;
swap(lhs.storage, rhs.storage);
swap(lhs.node, rhs.node);
swap(lhs.deref, rhs.deref);
swap(lhs.seq_factory, rhs.seq_factory);
swap(lhs.assoc_factory, rhs.assoc_factory);
}
private:
internal::meta_storage storage;
internal::meta_type_node *node;
dereference_operator_type *deref;
meta_sequence_container(* seq_factory)(void *);
meta_associative_container(* assoc_factory)(void *);
};
/**
* @brief Checks if two wrappers differ in their content.
* @param lhs A meta any object, either empty or not.
* @param rhs A meta any object, either empty or not.
* @return True if the two wrappers differ in their content, false otherwise.
*/
[[nodiscard]] inline bool operator!=(const meta_any &lhs, const meta_any &rhs) ENTT_NOEXCEPT {
return !(lhs == rhs);
}
/**
* @brief Opaque pointers to instances of any type.
*
* A handle doesn't perform copies and isn't responsible for the contained
* object. It doesn't prolong the lifetime of the pointed instance.<br/>
* Handles are used to generate meta references to actual objects when needed.
*/
struct meta_handle {
/*! @brief Default constructor. */
meta_handle() = default;
/**
* @brief Creates a handle that points to an unmanaged object.
* @tparam Type Type of object to use to initialize the handle.
* @param value An instance of an object to use to initialize the handle.
*/
template<typename Type, typename = std::enable_if_t<!std::is_same_v<std::remove_cv_t<std::remove_reference_t<Type>>, meta_handle>>>
meta_handle(Type &&value) ENTT_NOEXCEPT
: meta_handle{}
{
if constexpr(std::is_same_v<std::remove_cv_t<std::remove_reference_t<Type>>, meta_any>) {
any = value.ref();
} else {
static_assert(std::is_lvalue_reference_v<Type>, "Lvalue reference required");
any = std::ref(value);
}
}
/**
* @brief Dereference operator for accessing the contained opaque object.
* @return A meta any that shares a reference to an unmanaged object.
*/
[[nodiscard]] meta_any operator*() const {
return any;
}
/**
* @brief Access operator for accessing the contained opaque object.
* @return A meta any that shares a reference to an unmanaged object.
*/
[[nodiscard]] meta_any * operator->() {
return &any;
}
private:
meta_any any;
};
/*! @brief Opaque wrapper for meta properties of any type. */
struct meta_prop {
/*! @brief Node type. */
using node_type = internal::meta_prop_node;
/**
* @brief Constructs an instance from a given node.
* @param curr The underlying node with which to construct the instance.
*/
meta_prop(const node_type *curr = nullptr) ENTT_NOEXCEPT
: node{curr}
{}
/**
* @brief Returns the stored key.
* @return A meta any containing the key stored with the property.
*/
[[nodiscard]] meta_any key() const {
return node->key();
}
/**
* @brief Returns the stored value.
* @return A meta any containing the value stored with the property.
*/
[[nodiscard]] meta_any value() const {
return node->value();
}
/**
* @brief Returns true if a meta object is valid, false otherwise.
* @return True if the meta object is valid, false otherwise.
*/
[[nodiscard]] explicit operator bool() const ENTT_NOEXCEPT {
return !(node == nullptr);
}
private:
const node_type *node;
};
/*! @brief Opaque wrapper for meta base classes. */
struct meta_base {
/*! @brief Node type. */
using node_type = internal::meta_base_node;
/*! @copydoc meta_prop::meta_prop */
meta_base(const node_type *curr = nullptr) ENTT_NOEXCEPT
: node{curr}
{}
/**
* @brief Returns the meta type to which a meta object belongs.
* @return The meta type to which the meta object belongs.
*/
[[nodiscard]] inline meta_type parent() const ENTT_NOEXCEPT;
/*! @copydoc meta_any::type */
[[nodiscard]] inline meta_type type() const ENTT_NOEXCEPT;
/**
* @brief Casts an instance from a parent type to a base type.
* @param instance The instance to cast.
* @return An opaque pointer to the base type.
*/
[[nodiscard]] const void * cast(const void *instance) const ENTT_NOEXCEPT {
return node->cast(instance);
}
/**
* @brief Returns true if a meta object is valid, false otherwise.
* @return True if the meta object is valid, false otherwise.
*/
[[nodiscard]] explicit operator bool() const ENTT_NOEXCEPT {
return !(node == nullptr);
}
private:
const node_type *node;
};
/*! @brief Opaque wrapper for meta conversion functions. */
struct meta_conv {
/*! @brief Node type. */
using node_type = internal::meta_conv_node;
/*! @copydoc meta_prop::meta_prop */
meta_conv(const node_type *curr = nullptr) ENTT_NOEXCEPT
: node{curr}
{}
/*! @copydoc meta_base::parent */
[[nodiscard]] inline meta_type parent() const ENTT_NOEXCEPT;
/*! @copydoc meta_any::type */
[[nodiscard]] inline meta_type type() const ENTT_NOEXCEPT;
/**
* @brief Converts an instance to the underlying type.
* @param instance The instance to convert.
* @return An opaque pointer to the instance to convert.
*/
[[nodiscard]] meta_any convert(const void *instance) const {
return node->conv(instance);
}
/**
* @brief Returns true if a meta object is valid, false otherwise.
* @return True if the meta object is valid, false otherwise.
*/
[[nodiscard]] explicit operator bool() const ENTT_NOEXCEPT {
return !(node == nullptr);
}
private:
const node_type *node;
};
/*! @brief Opaque wrapper for meta constructors. */
struct meta_ctor {
/*! @brief Node type. */
using node_type = internal::meta_ctor_node;
/*! @brief Unsigned integer type. */
using size_type = typename node_type::size_type;
/*! @copydoc meta_prop::meta_prop */
meta_ctor(const node_type *curr = nullptr) ENTT_NOEXCEPT
: node{curr}
{}
/*! @copydoc meta_base::parent */
[[nodiscard]] inline meta_type parent() const ENTT_NOEXCEPT;
/**
* @brief Returns the number of arguments accepted by a meta constructor.
* @return The number of arguments accepted by the meta constructor.
*/
[[nodiscard]] size_type size() const ENTT_NOEXCEPT {
return node->size;
}
/**
* @brief Returns the meta type of the i-th argument of a meta constructor.
* @param index The index of the argument of which to return the meta type.
* @return The meta type of the i-th argument of a meta constructor, if any.
*/
[[nodiscard]] meta_type arg(size_type index) const ENTT_NOEXCEPT;
/**
* @brief Creates an instance of the underlying type, if possible.
*
* To create a valid instance, the parameters must be such that a cast or
* conversion to the required types is possible. Otherwise, an empty and
* thus invalid wrapper is returned.
*
* @param args Parameters to use to construct the instance.
* @param sz Number of parameters to use to construct the instance.
* @return A meta any containing the new instance, if any.
*/
[[nodiscard]] meta_any invoke(meta_any * const args, const std::size_t sz) const {
return sz == size() ? node->invoke(args) : meta_any{};
}
/**
* @copybrief invoke
*
* @sa invoke
*
* @tparam Args Types of arguments to use to construct the instance.
* @param args Parameters to use to construct the instance.
* @return A meta any containing the new instance, if any.
*/
template<typename... Args>
[[nodiscard]] meta_any invoke([[maybe_unused]] Args &&... args) const {
std::array<meta_any, sizeof...(Args)> arguments{std::forward<Args>(args)...};
return invoke(arguments.data(), sizeof...(Args));
}
/**
* @brief Returns a range to use to visit all meta properties.
* @return An iterable range to use to visit all meta properties.
*/
[[nodiscard]] meta_range<meta_prop> prop() const ENTT_NOEXCEPT {
return node->prop;
}
/**
* @brief Returns the property associated with a given key.
* @param key The key to use to search for a property.
* @return The property associated with the given key, if any.
*/
[[nodiscard]] meta_prop prop(meta_any key) const {
internal::meta_range range{node->prop};
return std::find_if(range.begin(), range.end(), [&key](const auto &curr) { return curr.key() == key; }).operator->();
}
/**
* @brief Returns true if a meta object is valid, false otherwise.
* @return True if the meta object is valid, false otherwise.
*/
[[nodiscard]] explicit operator bool() const ENTT_NOEXCEPT {
return !(node == nullptr);
}
private:
const node_type *node;
};
/*! @brief Opaque wrapper for meta data. */
struct meta_data {
/*! @brief Node type. */
using node_type = internal::meta_data_node;
/*! @copydoc meta_prop::meta_prop */
meta_data(const node_type *curr = nullptr) ENTT_NOEXCEPT
: node{curr}
{}
/*! @copydoc meta_type::id */
[[nodiscard]] id_type id() const ENTT_NOEXCEPT {
return node->id;
}
/*! @copydoc meta_base::parent */
[[nodiscard]] inline meta_type parent() const ENTT_NOEXCEPT;
/**
* @brief Indicates whether a meta data is constant or not.
* @return True if the meta data is constant, false otherwise.
*/
[[nodiscard]] bool is_const() const ENTT_NOEXCEPT {
return (node->set == nullptr);
}
/**
* @brief Indicates whether a meta data is static or not.
* @return True if the meta data is static, false otherwise.
*/
[[nodiscard]] bool is_static() const ENTT_NOEXCEPT {
return node->is_static;
}
/*! @copydoc meta_any::type */
[[nodiscard]] inline meta_type type() const ENTT_NOEXCEPT;
/**
* @brief Sets the value of a given variable.
*
* It must be possible to cast the instance to the parent type of the meta
* data. Otherwise, invoking the setter results in an undefined
* behavior.<br/>
* The type of the value must be such that a cast or conversion to the type
* of the variable is possible. Otherwise, invoking the setter does nothing.
*
* @tparam Type Type of value to assign.
* @param instance An opaque instance of the underlying type.
* @param value Parameter to use to set the underlying variable.
* @return True in case of success, false otherwise.
*/
template<typename Type>
bool set(meta_handle instance, Type &&value) const {
return node->set && node->set(std::move(instance), std::forward<Type>(value));
}
/**
* @brief Gets the value of a given variable.
*
* It must be possible to cast the instance to the parent type of the meta
* data. Otherwise, invoking the getter results in an undefined behavior.
*
* @param instance An opaque instance of the underlying type.
* @return A meta any containing the value of the underlying variable.
*/
[[nodiscard]] meta_any get(meta_handle instance) const {
return node->get(std::move(instance));
}
/*! @copydoc meta_ctor::prop */
[[nodiscard]] meta_range<meta_prop> prop() const ENTT_NOEXCEPT {
return node->prop;
}
/**
* @brief Returns the property associated with a given key.
* @param key The key to use to search for a property.
* @return The property associated with the given key, if any.
*/
[[nodiscard]] meta_prop prop(meta_any key) const {
internal::meta_range range{node->prop};
return std::find_if(range.begin(), range.end(), [&key](const auto &curr) { return curr.key() == key; }).operator->();
}
/**
* @brief Returns true if a meta object is valid, false otherwise.
* @return True if the meta object is valid, false otherwise.
*/
[[nodiscard]] explicit operator bool() const ENTT_NOEXCEPT {
return !(node == nullptr);
}
private:
const node_type *node;
};
/*! @brief Opaque wrapper for meta functions. */
struct meta_func {
/*! @brief Node type. */
using node_type = internal::meta_func_node;
/*! @brief Unsigned integer type. */
using size_type = typename node_type::size_type;
/*! @copydoc meta_prop::meta_prop */
meta_func(const node_type *curr = nullptr) ENTT_NOEXCEPT
: node{curr}
{}
/*! @copydoc meta_type::id */
[[nodiscard]] id_type id() const ENTT_NOEXCEPT {
return node->id;
}
/*! @copydoc meta_base::parent */
[[nodiscard]] inline meta_type parent() const ENTT_NOEXCEPT;
/**
* @brief Returns the number of arguments accepted by a meta function.
* @return The number of arguments accepted by the meta function.
*/
[[nodiscard]] size_type size() const ENTT_NOEXCEPT {
return node->size;
}
/**
* @brief Indicates whether a meta function is constant or not.
* @return True if the meta function is constant, false otherwise.
*/
[[nodiscard]] bool is_const() const ENTT_NOEXCEPT {
return node->is_const;
}
/**
* @brief Indicates whether a meta function is static or not.
* @return True if the meta function is static, false otherwise.
*/
[[nodiscard]] bool is_static() const ENTT_NOEXCEPT {
return node->is_static;
}
/**
* @brief Returns the meta type of the return type of a meta function.
* @return The meta type of the return type of the meta function.
*/
[[nodiscard]] inline meta_type ret() const ENTT_NOEXCEPT;
/**
* @brief Returns the meta type of the i-th argument of a meta function.
* @param index The index of the argument of which to return the meta type.
* @return The meta type of the i-th argument of a meta function, if any.
*/
[[nodiscard]] inline meta_type arg(size_type index) const ENTT_NOEXCEPT;
/**
* @brief Invokes the underlying function, if possible.
*
* To invoke a meta function, the parameters must be such that a cast or
* conversion to the required types is possible. Otherwise, an empty and
* thus invalid wrapper is returned.<br/>
* It must be possible to cast the instance to the parent type of the meta
* function. Otherwise, invoking the underlying function results in an
* undefined behavior.
*
* @param instance An opaque instance of the underlying type.
* @param args Parameters to use to invoke the function.
* @param sz Number of parameters to use to invoke the function.
* @return A meta any containing the returned value, if any.
*/
[[nodiscard]] meta_any invoke(meta_handle instance, meta_any * const args, const std::size_t sz) const {
return sz == size() ? node->invoke(instance, args) : meta_any{};
}
/**
* @copybrief invoke
*
* @sa invoke
*
* @tparam Args Types of arguments to use to invoke the function.
* @param instance An opaque instance of the underlying type.
* @param args Parameters to use to invoke the function.
* @return A meta any containing the new instance, if any.
*/
template<typename... Args>
meta_any invoke(meta_handle instance, Args &&... args) const {
std::array<meta_any, sizeof...(Args)> arguments{std::forward<Args>(args)...};
return invoke(instance, arguments.data(), sizeof...(Args));
}
/*! @copydoc meta_ctor::prop */
[[nodiscard]] meta_range<meta_prop> prop() const ENTT_NOEXCEPT {
return node->prop;
}
/**
* @brief Returns the property associated with a given key.
* @param key The key to use to search for a property.
* @return The property associated with the given key, if any.
*/
[[nodiscard]] meta_prop prop(meta_any key) const {
internal::meta_range range{node->prop};
return std::find_if(range.begin(), range.end(), [&key](const auto &curr) { return curr.key() == key; }).operator->();
}
/**
* @brief Returns true if a meta object is valid, false otherwise.
* @return True if the meta object is valid, false otherwise.
*/
[[nodiscard]] explicit operator bool() const ENTT_NOEXCEPT {
return !(node == nullptr);
}
private:
const node_type *node;
};
/*! @brief Opaque wrapper for meta types. */
class meta_type {
template<typename... Args, std::size_t... Indexes>
[[nodiscard]] auto ctor(std::index_sequence<Indexes...>) const {
internal::meta_range range{node->ctor};
return std::find_if(range.begin(), range.end(), [](const auto &candidate) {
return candidate.size == sizeof...(Args) && ([](auto *from, auto *to) {
return (from->type_id == to->type_id)
|| internal::find_if<&node_type::base>([to](const auto *curr) { return curr->type()->type_id == to->type_id; }, from)
|| internal::find_if<&node_type::conv>([to](const auto *curr) { return curr->type()->type_id == to->type_id; }, from);
}(internal::meta_info<Args>::resolve(), candidate.arg(Indexes)) && ...);
}).operator->();
}
public:
/*! @brief Node type. */
using node_type = internal::meta_type_node;
/*! @brief Unsigned integer type. */
using size_type = typename node_type::size_type;
/*! @copydoc meta_prop::meta_prop */
meta_type(node_type *curr = nullptr) ENTT_NOEXCEPT
: node{curr}
{}
/**
* @brief Returns the type id of the underlying type.
* @return The type id of the underlying type.
*/
[[nodiscard]] id_type type_id() const ENTT_NOEXCEPT {
return node->type_id;
}
/**
* @brief Returns the identifier assigned to a meta object.
* @return The identifier assigned to the meta object.
*/
[[nodiscard]] id_type id() const ENTT_NOEXCEPT {
return node->id;
}
/**
* @brief Checks whether a type refers to void or not.
* @return True if the underlying type is void, false otherwise.
*/
[[nodiscard]] bool is_void() const ENTT_NOEXCEPT {
return node->is_void;
}
/**
* @brief Checks whether a type refers to an integral type or not.
* @return True if the underlying type is an integral type, false otherwise.
*/
[[nodiscard]] bool is_integral() const ENTT_NOEXCEPT {
return node->is_integral;
}
/**
* @brief Checks whether a type refers to a floating-point type or not.
* @return True if the underlying type is a floating-point type, false
* otherwise.
*/
[[nodiscard]] bool is_floating_point() const ENTT_NOEXCEPT {
return node->is_floating_point;
}
/**
* @brief Checks whether a type refers to an array type or not.
* @return True if the underlying type is an array type, false otherwise.
*/
[[nodiscard]] bool is_array() const ENTT_NOEXCEPT {
return node->is_array;
}
/**
* @brief Checks whether a type refers to an enum or not.
* @return True if the underlying type is an enum, false otherwise.
*/
[[nodiscard]] bool is_enum() const ENTT_NOEXCEPT {
return node->is_enum;
}
/**
* @brief Checks whether a type refers to an union or not.
* @return True if the underlying type is an union, false otherwise.
*/
[[nodiscard]] bool is_union() const ENTT_NOEXCEPT {
return node->is_union;
}
/**
* @brief Checks whether a type refers to a class or not.
* @return True if the underlying type is a class, false otherwise.
*/
[[nodiscard]] bool is_class() const ENTT_NOEXCEPT {
return node->is_class;
}
/**
* @brief Checks whether a type refers to a pointer or not.
* @return True if the underlying type is a pointer, false otherwise.
*/
[[nodiscard]] bool is_pointer() const ENTT_NOEXCEPT {
return node->is_pointer;
}
/**
* @brief Checks whether a type refers to a function pointer or not.
* @return True if the underlying type is a function pointer, false
* otherwise.
*/
[[nodiscard]] bool is_function_pointer() const ENTT_NOEXCEPT {
return node->is_function_pointer;
}
/**
* @brief Checks whether a type refers to a pointer to data member or not.
* @return True if the underlying type is a pointer to data member, false
* otherwise.
*/
[[nodiscard]] bool is_member_object_pointer() const ENTT_NOEXCEPT {
return node->is_member_object_pointer;
}
/**
* @brief Checks whether a type refers to a pointer to member function or
* not.
* @return True if the underlying type is a pointer to member function,
* false otherwise.
*/
[[nodiscard]] bool is_member_function_pointer() const ENTT_NOEXCEPT {
return node->is_member_function_pointer;
}
/**
* @brief Checks whether a type is a pointer-like type or not.
* @return True if the underlying type is a pointer-like one, false
* otherwise.
*/
[[nodiscard]] bool is_pointer_like() const ENTT_NOEXCEPT {
return node->is_pointer_like;
}
/**
* @brief Checks whether a type refers to a sequence container or not.
* @return True if the underlying type is a sequence container, false
* otherwise.
*/
[[nodiscard]] bool is_sequence_container() const ENTT_NOEXCEPT {
return node->is_sequence_container;
}
/**
* @brief Checks whether a type refers to an associative container or not.
* @return True if the underlying type is an associative container, false
* otherwise.
*/
[[nodiscard]] bool is_associative_container() const ENTT_NOEXCEPT {
return node->is_associative_container;
}
/**
* @brief If a type refers to an array type, provides the number of
* dimensions of the array.
* @return The number of dimensions of the array if the underlying type is
* an array type, 0 otherwise.
*/
[[nodiscard]] size_type rank() const ENTT_NOEXCEPT {
return node->rank;
}
/**
* @brief If a type refers to an array type, provides the number of elements
* along the given dimension of the array.
* @param dim The dimension of which to return the number of elements.
* @return The number of elements along the given dimension of the array if
* the underlying type is an array type, 0 otherwise.
*/
[[nodiscard]] size_type extent(size_type dim = {}) const ENTT_NOEXCEPT {
return node->extent(dim);
}
/**
* @brief Provides the meta type for which the pointer is defined.
* @return The meta type for which the pointer is defined or this meta type
* if it doesn't refer to a pointer type.
*/
[[nodiscard]] meta_type remove_pointer() const ENTT_NOEXCEPT {
return node->remove_pointer();
}
/**
* @brief Provides the meta type for which the array is defined.
* @return The meta type for which the array is defined or this meta type
* if it doesn't refer to an array type.
*/
[[nodiscard]] meta_type remove_extent() const ENTT_NOEXCEPT {
return node->remove_extent();
}
/**
* @brief Returns a range to use to visit top-level meta bases.
* @return An iterable range to use to visit top-level meta bases.
*/
[[nodiscard]] meta_range<meta_base> base() const ENTT_NOEXCEPT {
return node->base;
}
/**
* @brief Returns the meta base associated with a given identifier.
* @param id Unique identifier.
* @return The meta base associated with the given identifier, if any.
*/
[[nodiscard]] meta_base base(const id_type id) const {
return internal::find_if<&node_type::base>([id](const auto *curr) {
return curr->type()->id == id;
}, node);
}
/**
* @brief Returns a range to use to visit top-level meta conversion
* functions.
* @return An iterable range to use to visit top-level meta conversion
* functions.
*/
[[nodiscard]] meta_range<meta_conv> conv() const ENTT_NOEXCEPT {
return node->conv;
}
/**
* @brief Returns the meta conversion function associated with a given type.
* @tparam Type The type to use to search for a meta conversion function.
* @return The meta conversion function associated with the given type, if
* any.
*/
template<typename Type>
[[nodiscard]] meta_conv conv() const {
return internal::find_if<&node_type::conv>([type_id = internal::meta_info<Type>::resolve()->type_id](const auto *curr) {
return curr->type()->type_id == type_id;
}, node);
}
/**
* @brief Returns a range to use to visit top-level meta constructors.
* @return An iterable range to use to visit top-level meta constructors.
*/
[[nodiscard]] meta_range<meta_ctor> ctor() const ENTT_NOEXCEPT {
return node->ctor;
}
/**
* @brief Returns the meta constructor that accepts a given list of types of
* arguments.
* @return The requested meta constructor, if any.
*/
template<typename... Args>
[[nodiscard]] meta_ctor ctor() const {
return ctor<Args...>(std::index_sequence_for<Args...>{});
}
/**
* @brief Returns a range to use to visit top-level meta data.
* @return An iterable range to use to visit top-level meta data.
*/
[[nodiscard]] meta_range<meta_data> data() const ENTT_NOEXCEPT {
return node->data;
}
/**
* @brief Returns the meta data associated with a given identifier.
*
* The meta data of the base classes will also be visited, if any.
*
* @param id Unique identifier.
* @return The meta data associated with the given identifier, if any.
*/
[[nodiscard]] meta_data data(const id_type id) const {
return internal::find_if<&node_type::data>([id](const auto *curr) {
return curr->id == id;
}, node);
}
/**
* @brief Returns a range to use to visit top-level meta functions.
* @return An iterable range to use to visit top-level meta functions.
*/
[[nodiscard]] meta_range<meta_func> func() const ENTT_NOEXCEPT {
return node->func;
}
/**
* @brief Returns the meta function associated with a given identifier.
*
* The meta functions of the base classes will also be visited, if any.
*
* @param id Unique identifier.
* @return The meta function associated with the given identifier, if any.
*/
[[nodiscard]] meta_func func(const id_type id) const {
return internal::find_if<&node_type::func>([id](const auto *curr) {
return curr->id == id;
}, node);
}
/**
* @brief Creates an instance of the underlying type, if possible.
*
* To create a valid instance, the parameters must be such that a cast or
* conversion to the required types is possible. Otherwise, an empty and
* thus invalid wrapper is returned.
*
* @param args Parameters to use to construct the instance.
* @param sz Number of parameters to use to construct the instance.
* @return A meta any containing the new instance, if any.
*/
[[nodiscard]] meta_any construct(meta_any * const args, const std::size_t sz) const {
meta_any any{};
internal::find_if<&node_type::ctor>([args, sz, &any](const auto *curr) {
return (curr->size == sz) && (any = curr->invoke(args));
}, node);
return any;
}
/**
* @copybrief construct
*
* @sa construct
*
* @tparam Args Types of arguments to use to construct the instance.
* @param args Parameters to use to construct the instance.
* @return A meta any containing the new instance, if any.
*/
template<typename... Args>
[[nodiscard]] meta_any construct(Args &&... args) const {
std::array<meta_any, sizeof...(Args)> arguments{std::forward<Args>(args)...};
return construct(arguments.data(), sizeof...(Args));
}
/**
* @brief Returns a range to use to visit top-level meta properties.
* @return An iterable range to use to visit top-level meta properties.
*/
[[nodiscard]] meta_range<meta_prop> prop() const ENTT_NOEXCEPT {
return node->prop;
}
/**
* @brief Returns the property associated with a given key.
*
* Properties of the base classes will also be visited, if any.
*
* @param key The key to use to search for a property.
* @return The property associated with the given key, if any.
*/
[[nodiscard]] meta_prop prop(meta_any key) const {
return internal::find_if<&node_type::prop>([key = std::move(key)](const auto *curr) {
return curr->key() == key;
}, node);
}
/**
* @brief Returns true if a meta object is valid, false otherwise.
* @return True if the meta object is valid, false otherwise.
*/
[[nodiscard]] explicit operator bool() const ENTT_NOEXCEPT {
return !(node == nullptr);
}
/**
* @brief Checks if two meta objects refer to the same type.
* @param other The meta object with which to compare.
* @return True if the two meta objects refer to the same type, false
* otherwise.
*/
[[nodiscard]] bool operator==(const meta_type &other) const ENTT_NOEXCEPT {
return (!node && !other.node) || (node && other.node && node->type_id == other.node->type_id);
}
/**
* @brief Resets a meta type and all its parts.
*
* This function resets a meta type and all its data members, member
* functions and properties, as well as its constructors, destructors and
* conversion functions if any.<br/>
* Base classes aren't reset but the link between the two types is removed.
*
* The meta type is also removed from the list of searchable types.
*/
void reset() ENTT_NOEXCEPT {
auto** it = internal::meta_context::global();
while (*it && *it != node) {
it = &(*it)->next;
}
if(*it) {
*it = (*it)->next;
}
const auto unregister_all = y_combinator{
[](auto &&self, auto **curr, auto... member) {
while(*curr) {
auto *prev = *curr;
(self(&(prev->*member)), ...);
*curr = prev->next;
prev->next = nullptr;
}
}
};
unregister_all(&node->prop);
unregister_all(&node->base);
unregister_all(&node->conv);
unregister_all(&node->ctor, &internal::meta_ctor_node::prop);
unregister_all(&node->data, &internal::meta_data_node::prop);
unregister_all(&node->func, &internal::meta_func_node::prop);
node->id = {};
node->dtor = nullptr;
}
private:
node_type *node;
};
/**
* @brief Checks if two meta objects refer to the same type.
* @param lhs A meta object, either valid or not.
* @param rhs A meta object, either valid or not.
* @return False if the two meta objects refer to the same node, true otherwise.
*/
[[nodiscard]] inline bool operator!=(const meta_type &lhs, const meta_type &rhs) ENTT_NOEXCEPT {
return !(lhs == rhs);
}
[[nodiscard]] inline meta_type meta_any::type() const ENTT_NOEXCEPT {
return node;
}
[[nodiscard]] inline meta_type meta_base::parent() const ENTT_NOEXCEPT {
return node->parent;
}
[[nodiscard]] inline meta_type meta_base::type() const ENTT_NOEXCEPT {
return node->type();
}
[[nodiscard]] inline meta_type meta_conv::parent() const ENTT_NOEXCEPT {
return node->parent;
}
[[nodiscard]] inline meta_type meta_conv::type() const ENTT_NOEXCEPT {
return node->type();
}
[[nodiscard]] inline meta_type meta_ctor::parent() const ENTT_NOEXCEPT {
return node->parent;
}
[[nodiscard]] inline meta_type meta_ctor::arg(size_type index) const ENTT_NOEXCEPT {
return index < size() ? node->arg(index) : nullptr;
}
[[nodiscard]] inline meta_type meta_data::parent() const ENTT_NOEXCEPT {
return node->parent;
}
[[nodiscard]] inline meta_type meta_data::type() const ENTT_NOEXCEPT {
return node->type();
}
[[nodiscard]] inline meta_type meta_func::parent() const ENTT_NOEXCEPT {
return node->parent;
}
[[nodiscard]] inline meta_type meta_func::ret() const ENTT_NOEXCEPT {
return node->ret();
}
[[nodiscard]] inline meta_type meta_func::arg(size_type index) const ENTT_NOEXCEPT {
return index < size() ? node->arg(index) : nullptr;
}
/*! @brief Opaque iterator for meta sequence containers. */
class meta_sequence_container::meta_iterator {
/*! @brief A meta sequence container can access the underlying iterator. */
friend class meta_sequence_container;
template<typename It>
static void incr(meta_any any) {
++any.cast<It>();
}
template<typename It>
[[nodiscard]] static meta_any deref(meta_any any) {
if constexpr(std::is_const_v<std::remove_reference_t<decltype(*std::declval<It>())>>) {
return *any.cast<It>();
} else {
return std::ref(*any.cast<It>());
}
}
public:
/*! @brief Signed integer type. */
using difference_type = std::ptrdiff_t;
/*! @brief Type of elements returned by the iterator. */
using value_type = meta_any;
/*! @brief Pointer type, `void` on purpose. */
using pointer = void;
/*! @brief Reference type, it is **not** an actual reference. */
using reference = value_type;
/*! @brief Iterator category. */
using iterator_category = std::input_iterator_tag;
/*! @brief Default constructor. */
meta_iterator() ENTT_NOEXCEPT = default;
/**
* @brief Constructs a meta iterator from a given iterator.
* @tparam It Type of actual iterator with which to build the meta iterator.
* @param iter The actual iterator with which to build the meta iterator.
*/
template<typename It>
meta_iterator(It iter)
: next_fn{&incr<It>},
get_fn{&deref<It>},
handle{std::move(iter)}
{}
/*! @brief Pre-increment operator. @return This iterator. */
meta_iterator & operator++() ENTT_NOEXCEPT {
return next_fn(handle.ref()), *this;
}
/*! @brief Post-increment operator. @return This iterator. */
meta_iterator operator++(int) ENTT_NOEXCEPT {
meta_iterator orig = *this;
return ++(*this), orig;
}
/**
* @brief Checks if two meta iterators refer to the same element.
* @param other The meta iterator with which to compare.
* @return True if the two meta iterators refer to the same element, false
* otherwise.
*/
[[nodiscard]] bool operator==(const meta_iterator &other) const ENTT_NOEXCEPT {
return handle == other.handle;
}
/**
* @brief Checks if two meta iterators refer to the same element.
* @param other The meta iterator with which to compare.
* @return False if the two meta iterators refer to the same element, true
* otherwise.
*/
[[nodiscard]] bool operator!=(const meta_iterator &other) const ENTT_NOEXCEPT {
return !(*this == other);
}
/**
* @brief Indirection operator.
* @return The element to which the meta pointer points.
*/
[[nodiscard]] reference operator*() const {
return get_fn(handle.ref());
}
/**
* @brief Returns false if an iterator is invalid, true otherwise.
* @return False if the iterator is invalid, true otherwise.
*/
[[nodiscard]] explicit operator bool() const ENTT_NOEXCEPT {
return static_cast<bool>(handle);
}
private:
void(* next_fn)(meta_any);
meta_any(* get_fn)(meta_any);
meta_any handle;
};
template<typename Type>
struct meta_sequence_container::meta_sequence_container_proxy {
using traits_type = meta_sequence_container_traits<Type>;
[[nodiscard]] static meta_type value_type() ENTT_NOEXCEPT {
return internal::meta_info<typename traits_type::value_type>::resolve();
}
[[nodiscard]] static size_type size(const void *container) ENTT_NOEXCEPT {
return traits_type::size(*static_cast<const Type *>(container));
}
[[nodiscard]] static bool resize(void *container, size_type sz) {
return traits_type::resize(*static_cast<Type *>(container), sz);
}
[[nodiscard]] static bool clear(void *container) {
return traits_type::clear(*static_cast<Type *>(container));
}
[[nodiscard]] static iterator begin(void *container) {
return iterator{traits_type::begin(*static_cast<Type *>(container))};
}
[[nodiscard]] static iterator end(void *container) {
return iterator{traits_type::end(*static_cast<Type *>(container))};
}
[[nodiscard]] static std::pair<iterator, bool> insert(void *container, iterator it, meta_any value) {
if(const auto *v_ptr = value.try_cast<typename traits_type::value_type>(); v_ptr || value.convert<typename traits_type::value_type>()) {
auto ret = traits_type::insert(*static_cast<Type *>(container), it.handle.cast<typename traits_type::iterator>(), v_ptr ? *v_ptr : value.cast<typename traits_type::value_type>());
return {iterator{std::move(ret.first)}, ret.second};
}
return {};
}
[[nodiscard]] static std::pair<iterator, bool> erase(void *container, iterator it) {
auto ret = traits_type::erase(*static_cast<Type *>(container), it.handle.cast<typename traits_type::iterator>());
return {iterator{std::move(ret.first)}, ret.second};
}
[[nodiscard]] static meta_any get(void *container, size_type pos) {
return std::ref(traits_type::get(*static_cast<Type *>(container), pos));
}
};
/**
* @brief Returns the value meta type of the wrapped container type.
* @return The value meta type of the wrapped container type.
*/
[[nodiscard]] inline meta_type meta_sequence_container::value_type() const ENTT_NOEXCEPT {
return value_type_fn();
}
/**
* @brief Returns the size of the wrapped container.
* @return The size of the wrapped container.
*/
[[nodiscard]] inline meta_sequence_container::size_type meta_sequence_container::size() const ENTT_NOEXCEPT {
return size_fn(instance);
}
/**
* @brief Resizes the wrapped container to contain a given number of elements.
* @param sz The new size of the container.
* @return True in case of success, false otherwise.
*/
inline bool meta_sequence_container::resize(size_type sz) const {
return resize_fn(instance, sz);
}
/**
* @brief Clears the content of the wrapped container.
* @return True in case of success, false otherwise.
*/
inline bool meta_sequence_container::clear() {
return clear_fn(instance);
}
/**
* @brief Returns a meta iterator to the first element of the wrapped container.
* @return A meta iterator to the first element of the wrapped container.
*/
[[nodiscard]] inline meta_sequence_container::iterator meta_sequence_container::begin() {
return begin_fn(instance);
}
/**
* @brief Returns a meta iterator that is past the last element of the wrapped
* container.
* @return A meta iterator that is past the last element of the wrapped
* container.
*/
[[nodiscard]] inline meta_sequence_container::iterator meta_sequence_container::end() {
return end_fn(instance);
}
/**
* @brief Inserts an element at a specified location of the wrapped container.
* @param it Meta iterator before which the element will be inserted.
* @param value Element value to insert.
* @return A pair consisting of a meta iterator to the inserted element (in
* case of success) and a bool denoting whether the insertion took place.
*/
inline std::pair<meta_sequence_container::iterator, bool> meta_sequence_container::insert(iterator it, meta_any value) {
return insert_fn(instance, it, value.ref());
}
/**
* @brief Removes the specified element from the wrapped container.
* @param it Meta iterator to the element to remove.
* @return A pair consisting of a meta iterator following the last removed
* element (in case of success) and a bool denoting whether the insertion
* took place.
*/
inline std::pair<meta_sequence_container::iterator, bool> meta_sequence_container::erase(iterator it) {
return erase_fn(instance, it);
}
/**
* @brief Returns a reference to the element at a specified location of the
* wrapped container (no bounds checking is performed).
* @param pos The position of the element to return.
* @return A reference to the requested element properly wrapped.
*/
[[nodiscard]] inline meta_any meta_sequence_container::operator[](size_type pos) {
return get_fn(instance, pos);
}
/**
* @brief Returns false if a proxy is invalid, true otherwise.
* @return False if the proxy is invalid, true otherwise.
*/
[[nodiscard]] inline meta_sequence_container::operator bool() const ENTT_NOEXCEPT {
return (instance != nullptr);
}
/*! @brief Opaque iterator for meta associative containers. */
class meta_associative_container::meta_iterator {
template<typename It>
static void incr(meta_any any) {
++any.cast<It>();
}
template<bool KeyOnly, typename It>
[[nodiscard]] static meta_any key(meta_any any) {
if constexpr(KeyOnly) {
return *any.cast<It>();
} else {
return any.cast<It>()->first;
}
}
template<bool KeyOnly, typename It>
[[nodiscard]] static meta_any value([[maybe_unused]] meta_any any) {
if constexpr(KeyOnly) {
return meta_any{};
} else {
return std::ref(any.cast<It>()->second);
}
}
public:
/*! @brief Signed integer type. */
using difference_type = std::ptrdiff_t;
/*! @brief Type of elements returned by the iterator. */
using value_type = std::pair<meta_any, meta_any>;
/*! @brief Pointer type, `void` on purpose. */
using pointer = void;
/*! @brief Reference type, it is **not** an actual reference. */
using reference = value_type;
/*! @brief Iterator category. */
using iterator_category = std::input_iterator_tag;
/*! @brief Default constructor. */
meta_iterator() ENTT_NOEXCEPT = default;
/**
* @brief Constructs a meta iterator from a given iterator.
* @tparam KeyOnly True if the associative container is also key-only, false
* otherwise.
* @tparam It Type of actual iterator with which to build the meta iterator.
* @param iter The actual iterator with which to build the meta iterator.
*/
template<bool KeyOnly, typename It>
meta_iterator(std::integral_constant<bool, KeyOnly>, It iter)
: next_fn{&incr<It>},
key_fn{&key<KeyOnly, It>},
value_fn{&value<KeyOnly, It>},
handle{std::move(iter)}
{}
/*! @brief Pre-increment operator. @return This iterator. */
meta_iterator & operator++() ENTT_NOEXCEPT {
return next_fn(handle.ref()), *this;
}
/*! @brief Post-increment operator. @return This iterator. */
meta_iterator operator++(int) ENTT_NOEXCEPT {
meta_iterator orig = *this;
return ++(*this), orig;
}
/**
* @brief Checks if two meta iterators refer to the same element.
* @param other The meta iterator with which to compare.
* @return True if the two meta iterators refer to the same element, false
* otherwise.
*/
[[nodiscard]] bool operator==(const meta_iterator &other) const ENTT_NOEXCEPT {
return handle == other.handle;
}
/**
* @brief Checks if two meta iterators refer to the same element.
* @param other The meta iterator with which to compare.
* @return False if the two meta iterators refer to the same element, true
* otherwise.
*/
[[nodiscard]] bool operator!=(const meta_iterator &other) const ENTT_NOEXCEPT {
return !(*this == other);
}
/**
* @brief Indirection operator.
* @return The element to which the meta pointer points.
*/
[[nodiscard]] reference operator*() const {
return { key_fn(handle.ref()), value_fn(handle.ref()) };
}
/**
* @brief Returns false if an iterator is invalid, true otherwise.
* @return False if the iterator is invalid, true otherwise.
*/
[[nodiscard]] explicit operator bool() const ENTT_NOEXCEPT {
return static_cast<bool>(handle);
}
private:
void(* next_fn)(meta_any);
meta_any(* key_fn)(meta_any);
meta_any(* value_fn)(meta_any);
meta_any handle;
};
template<typename Type>
struct meta_associative_container::meta_associative_container_proxy {
using traits_type = meta_associative_container_traits<Type>;
[[nodiscard]] static meta_type key_type() ENTT_NOEXCEPT {
return internal::meta_info<typename traits_type::key_type>::resolve();
}
[[nodiscard]] static meta_type mapped_type() ENTT_NOEXCEPT {
if constexpr(is_key_only_meta_associative_container_v<Type>) {
return meta_type{};
} else {
return internal::meta_info<typename traits_type::mapped_type>::resolve();
}
}
[[nodiscard]] static meta_type value_type() ENTT_NOEXCEPT {
return internal::meta_info<typename traits_type::value_type>::resolve();
}
[[nodiscard]] static size_type size(const void *container) ENTT_NOEXCEPT {
return traits_type::size(*static_cast<const Type *>(container));
}
[[nodiscard]] static bool clear(void *container) {
return traits_type::clear(*static_cast<Type *>(container));
}
[[nodiscard]] static iterator begin(void *container) {
return iterator{is_key_only_meta_associative_container<Type>{}, traits_type::begin(*static_cast<Type *>(container))};
}
[[nodiscard]] static iterator end(void *container) {
return iterator{is_key_only_meta_associative_container<Type>{}, traits_type::end(*static_cast<Type *>(container))};
}
[[nodiscard]] static bool insert(void *container, meta_any key, meta_any value) {
if(const auto *k_ptr = key.try_cast<typename traits_type::key_type>(); k_ptr || key.convert<typename traits_type::key_type>()) {
if constexpr(is_key_only_meta_associative_container_v<Type>) {
return traits_type::insert(*static_cast<Type *>(container), k_ptr ? *k_ptr : key.cast<typename traits_type::key_type>());
} else {
if(auto *m_ptr = value.try_cast<typename traits_type::mapped_type>(); m_ptr || value.convert<typename traits_type::mapped_type>()) {
return traits_type::insert(*static_cast<Type *>(container), k_ptr ? *k_ptr : key.cast<typename traits_type::key_type>(), m_ptr ? *m_ptr : value.cast<typename traits_type::mapped_type>());
}
}
}
return false;
}
[[nodiscard]] static bool erase(void *container, meta_any key) {
if(const auto *k_ptr = key.try_cast<typename traits_type::key_type>(); k_ptr || key.convert<typename traits_type::key_type>()) {
return traits_type::erase(*static_cast<Type *>(container), k_ptr ? *k_ptr : key.cast<typename traits_type::key_type>());
}
return false;
}
[[nodiscard]] static iterator find(void *container, meta_any key) {
if(const auto *k_ptr = key.try_cast<typename traits_type::key_type>(); k_ptr || key.convert<typename traits_type::key_type>()) {
return iterator{is_key_only_meta_associative_container<Type>{}, traits_type::find(*static_cast<Type *>(container), k_ptr ? *k_ptr : key.cast<typename traits_type::key_type>())};
}
return {};
}
};
/**
* @brief Returns true if the associative container is also key-only, false
* otherwise.
* @return True if the associative container is also key-only, false otherwise.
*/
[[nodiscard]] inline bool meta_associative_container::key_only() const ENTT_NOEXCEPT {
return key_only_container;
}
/**
* @brief Returns the key meta type of the wrapped container type.
* @return The key meta type of the wrapped container type.
*/
[[nodiscard]] inline meta_type meta_associative_container::key_type() const ENTT_NOEXCEPT {
return key_type_fn();
}
/**
* @brief Returns the mapped meta type of the wrapped container type.
* @return The mapped meta type of the wrapped container type.
*/
[[nodiscard]] inline meta_type meta_associative_container::mapped_type() const ENTT_NOEXCEPT {
return mapped_type_fn();
}
/*! @copydoc meta_sequence_container::value_type */
[[nodiscard]] inline meta_type meta_associative_container::value_type() const ENTT_NOEXCEPT {
return value_type_fn();
}
/*! @copydoc meta_sequence_container::size */
[[nodiscard]] inline meta_associative_container::size_type meta_associative_container::size() const ENTT_NOEXCEPT {
return size_fn(instance);
}
/*! @copydoc meta_sequence_container::clear */
inline bool meta_associative_container::clear() {
return clear_fn(instance);
}
/*! @copydoc meta_sequence_container::begin */
[[nodiscard]] inline meta_associative_container::iterator meta_associative_container::begin() {
return begin_fn(instance);
}
/*! @copydoc meta_sequence_container::end */
[[nodiscard]] inline meta_associative_container::iterator meta_associative_container::end() {
return end_fn(instance);
}
/**
* @brief Inserts an element (a key/value pair) into the wrapped container.
* @param key The key of the element to insert.
* @param value The value of the element to insert.
* @return A bool denoting whether the insertion took place.
*/
inline bool meta_associative_container::insert(meta_any key, meta_any value = {}) {
return insert_fn(instance, key.ref(), value.ref());
}
/**
* @brief Removes the specified element from the wrapped container.
* @param key The key of the element to remove.
* @return A bool denoting whether the removal took place.
*/
inline bool meta_associative_container::erase(meta_any key) {
return erase_fn(instance, key.ref());
}
/**
* @brief Returns an iterator to the element with key equivalent to a given
* one, if any.
* @param key The key of the element to search.
* @return An iterator to the element with the given key, if any.
*/
[[nodiscard]] inline meta_associative_container::iterator meta_associative_container::find(meta_any key) {
return find_fn(instance, key.ref());
}
/**
* @brief Returns false if a proxy is invalid, true otherwise.
* @return False if the proxy is invalid, true otherwise.
*/
[[nodiscard]] inline meta_associative_container::operator bool() const ENTT_NOEXCEPT {
return (instance != nullptr);
}
}
#endif
// #include "policy.hpp"
#ifndef ENTT_META_POLICY_HPP
#define ENTT_META_POLICY_HPP
namespace entt {
/*! @brief Empty class type used to request the _as ref_ policy. */
struct as_ref_t {};
/*! @brief Disambiguation tag. */
inline constexpr as_ref_t as_ref;
/*! @brief Empty class type used to request the _as-is_ policy. */
struct as_is_t {};
/*! @brief Empty class type used to request the _as void_ policy. */
struct as_void_t {};
}
#endif
namespace entt {
/**
* @cond TURN_OFF_DOXYGEN
* Internal details not to be documented.
*/
namespace internal {
template<typename, bool = false>
struct meta_function_helper;
template<typename Ret, typename... Args, bool Const>
struct meta_function_helper<Ret(Args...), Const> {
using return_type = std::remove_cv_t<std::remove_reference_t<Ret>>;
using args_type = std::tuple<std::remove_cv_t<std::remove_reference_t<Args>>...>;
static constexpr auto is_const = Const;
[[nodiscard]] static auto arg(typename internal::meta_func_node::size_type index) ENTT_NOEXCEPT {
return std::array<meta_type_node *, sizeof...(Args)>{{meta_info<Args>::resolve()...}}[index];
}
};
template<typename Ret, typename... Args, typename Class>
constexpr meta_function_helper<Ret(Args...), true>
to_meta_function_helper(Ret(Class:: *)(Args...) const);
template<typename Ret, typename... Args, typename Class>
constexpr meta_function_helper<Ret(Args...)>
to_meta_function_helper(Ret(Class:: *)(Args...));
template<typename Ret, typename... Args>
constexpr meta_function_helper<Ret(Args...)>
to_meta_function_helper(Ret(*)(Args...));
constexpr void to_meta_function_helper(...);
template<typename Candidate>
using meta_function_helper_t = decltype(to_meta_function_helper(std::declval<Candidate>()));
template<typename Type, typename... Args, std::size_t... Indexes>
[[nodiscard]] meta_any construct(meta_any * const args, std::index_sequence<Indexes...>) {
[[maybe_unused]] auto direct = std::make_tuple((args+Indexes)->try_cast<Args>()...);
return ((std::get<Indexes>(direct) || (args+Indexes)->convert<Args>()) && ...)
? Type{(std::get<Indexes>(direct) ? *std::get<Indexes>(direct) : (args+Indexes)->cast<Args>())...}
: meta_any{};
}
template<typename Type, auto Data>
[[nodiscard]] bool setter([[maybe_unused]] meta_handle instance, [[maybe_unused]] meta_any value) {
bool accepted = false;
if constexpr(std::is_function_v<std::remove_reference_t<std::remove_pointer_t<decltype(Data)>>> || std::is_member_function_pointer_v<decltype(Data)>) {
using helper_type = meta_function_helper_t<decltype(Data)>;
using data_type = std::tuple_element_t<!std::is_member_function_pointer_v<decltype(Data)>, typename helper_type::args_type>;
if(auto * const clazz = instance->try_cast<Type>(); clazz) {
if(auto * const direct = value.try_cast<data_type>(); direct || value.convert<data_type>()) {
std::invoke(Data, *clazz, direct ? *direct : value.cast<data_type>());
accepted = true;
}
}
} else if constexpr(std::is_member_object_pointer_v<decltype(Data)>) {
using data_type = std::remove_cv_t<std::remove_reference_t<decltype(std::declval<Type>().*Data)>>;
if constexpr(!std::is_array_v<data_type>) {
if(auto * const clazz = instance->try_cast<Type>(); clazz) {
if(auto * const direct = value.try_cast<data_type>(); direct || value.convert<data_type>()) {
std::invoke(Data, clazz) = (direct ? *direct : value.cast<data_type>());
accepted = true;
}
}
}
} else {
using data_type = std::remove_cv_t<std::remove_reference_t<decltype(*Data)>>;
if constexpr(!std::is_array_v<data_type>) {
if(auto * const direct = value.try_cast<data_type>(); direct || value.convert<data_type>()) {
*Data = (direct ? *direct : value.cast<data_type>());
accepted = true;
}
}
}
return accepted;
}
template<typename Type, auto Data, typename Policy>
[[nodiscard]] meta_any getter([[maybe_unused]] meta_handle instance) {
[[maybe_unused]] auto dispatch = [](auto &&value) {
if constexpr(std::is_same_v<Policy, as_void_t>) {
return meta_any{std::in_place_type<void>, std::forward<decltype(value)>(value)};
} else if constexpr(std::is_same_v<Policy, as_ref_t>) {
return meta_any{std::ref(std::forward<decltype(value)>(value))};
} else {
static_assert(std::is_same_v<Policy, as_is_t>, "Policy not supported");
return meta_any{std::forward<decltype(value)>(value)};
}
};
if constexpr(std::is_function_v<std::remove_reference_t<std::remove_pointer_t<decltype(Data)>>> || std::is_member_function_pointer_v<decltype(Data)>) {
auto * const clazz = instance->try_cast<Type>();
return clazz ? dispatch(std::invoke(Data, *clazz)) : meta_any{};
} else if constexpr(std::is_member_object_pointer_v<decltype(Data)>) {
if constexpr(std::is_array_v<std::remove_cv_t<std::remove_reference_t<decltype(std::declval<Type>().*Data)>>>) {
return meta_any{};
} else {
auto * const clazz = instance->try_cast<Type>();
return clazz ? dispatch(std::invoke(Data, clazz)) : meta_any{};
}
} else if constexpr(std::is_pointer_v<std::decay_t<decltype(Data)>>) {
if constexpr(std::is_array_v<std::remove_pointer_t<decltype(Data)>>) {
return meta_any{};
} else {
return dispatch(*Data);
}
} else {
return dispatch(Data);
}
}
template<typename Type, auto Candidate, typename Policy, std::size_t... Indexes>
[[nodiscard]] meta_any invoke([[maybe_unused]] meta_handle instance, meta_any *args, std::index_sequence<Indexes...>) {
using helper_type = meta_function_helper_t<decltype(Candidate)>;
auto dispatch = [](auto *... params) {
if constexpr(std::is_void_v<typename helper_type::return_type> || std::is_same_v<Policy, as_void_t>) {
std::invoke(Candidate, *params...);
return meta_any{std::in_place_type<void>};
} else if constexpr(std::is_same_v<Policy, as_ref_t>) {
return meta_any{std::ref(std::invoke(Candidate, *params...))};
} else {
static_assert(std::is_same_v<Policy, as_is_t>, "Policy not supported");
return meta_any{std::invoke(Candidate, *params...)};
}
};
[[maybe_unused]] const auto direct = std::make_tuple([](meta_any *any, auto *value) {
using arg_type = std::remove_reference_t<decltype(*value)>;
if(!value && any->convert<arg_type>()) {
value = any->try_cast<arg_type>();
}
return value;
}(args+Indexes, (args+Indexes)->try_cast<std::tuple_element_t<Indexes, typename helper_type::args_type>>())...);
if constexpr(std::is_function_v<std::remove_reference_t<std::remove_pointer_t<decltype(Candidate)>>>) {
return (std::get<Indexes>(direct) && ...) ? dispatch(std::get<Indexes>(direct)...) : meta_any{};
} else {
auto * const clazz = instance->try_cast<Type>();
return (clazz && (std::get<Indexes>(direct) && ...)) ? dispatch(clazz, std::get<Indexes>(direct)...) : meta_any{};
}
}
}
/**
* Internal details not to be documented.
* @endcond
*/
/**
* @brief Meta factory to be used for reflection purposes.
*
* The meta factory is an utility class used to reflect types, data members and
* functions of all sorts. This class ensures that the underlying web of types
* is built correctly and performs some checks in debug mode to ensure that
* there are no subtle errors at runtime.
*/
template<typename...>
class meta_factory;
/**
* @brief Extended meta factory to be used for reflection purposes.
* @tparam Type Reflected type for which the factory was created.
* @tparam Spec Property specialization pack used to disambiguate overloads.
*/
template<typename Type, typename... Spec>
class meta_factory<Type, Spec...>: public meta_factory<Type> {
[[nodiscard]] bool exists(const meta_any &key, const internal::meta_prop_node *node) ENTT_NOEXCEPT {
return node && (node->key() == key || exists(key, node->next));
}
template<std::size_t Step = 0, std::size_t... Index, typename... Property, typename... Other>
void unpack(std::index_sequence<Index...>, std::tuple<Property...> property, Other &&... other) {
unroll<Step>(choice<3>, std::move(std::get<Index>(property))..., std::forward<Other>(other)...);
}
template<std::size_t Step = 0, typename... Property, typename... Other>
void unroll(choice_t<3>, std::tuple<Property...> property, Other &&... other) {
unpack<Step>(std::index_sequence_for<Property...>{}, std::move(property), std::forward<Other>(other)...);
}
template<std::size_t Step = 0, typename... Property, typename... Other>
void unroll(choice_t<2>, std::pair<Property...> property, Other &&... other) {
assign<Step>(std::move(property.first), std::move(property.second));
unroll<Step+1>(choice<3>, std::forward<Other>(other)...);
}
template<std::size_t Step = 0, typename Property, typename... Other>
std::enable_if_t<!std::is_invocable_v<Property>>
unroll(choice_t<1>, Property &&property, Other &&... other) {
assign<Step>(std::forward<Property>(property));
unroll<Step+1>(choice<3>, std::forward<Other>(other)...);
}
template<std::size_t Step = 0, typename Func, typename... Other>
void unroll(choice_t<0>, Func &&invocable, Other &&... other) {
unroll<Step>(choice<3>, std::forward<Func>(invocable)(), std::forward<Other>(other)...);
}
template<std::size_t>
void unroll(choice_t<0>) {}
template<std::size_t = 0, typename Key, typename... Value>
void assign(Key &&key, Value &&... value) {
static const auto property{std::make_tuple(std::forward<Key>(key), std::forward<Value>(value)...)};
static internal::meta_prop_node node{
nullptr,
[]() -> meta_any {
return std::get<0>(property);
},
[]() -> meta_any {
if constexpr(sizeof...(Value) == 0) {
return {};
} else {
return std::get<1>(property);
}
}
};
ENTT_ASSERT(!exists(node.key(), *curr));
node.next = *curr;
*curr = &node;
}
public:
/**
* @brief Constructs an extended factory from a given node.
* @param target The underlying node to which to assign the properties.
*/
meta_factory(internal::meta_prop_node **target) ENTT_NOEXCEPT
: curr{target}
{}
/**
* @brief Assigns a property to the last meta object created.
*
* Both the key and the value (if any) must be at least copy constructible.
*
* @tparam PropertyOrKey Type of the property or property key.
* @tparam Value Optional type of the property value.
* @param property_or_key Property or property key.
* @param value Optional property value.
* @return A meta factory for the parent type.
*/
template<typename PropertyOrKey, typename... Value>
auto prop(PropertyOrKey &&property_or_key, Value &&... value) && {
if constexpr(sizeof...(Value) == 0) {
unroll(choice<3>, std::forward<PropertyOrKey>(property_or_key));
} else {
assign(std::forward<PropertyOrKey>(property_or_key), std::forward<Value>(value)...);
}
return meta_factory<Type, Spec..., PropertyOrKey, Value...>{curr};
}
/**
* @brief Assigns properties to the last meta object created.
*
* Both the keys and the values (if any) must be at least copy
* constructible.
*
* @tparam Property Types of the properties.
* @param property Properties to assign to the last meta object created.
* @return A meta factory for the parent type.
*/
template <typename... Property>
auto props(Property... property) && {
unroll(choice<3>, std::forward<Property>(property)...);
return meta_factory<Type, Spec..., Property...>{curr};
}
private:
internal::meta_prop_node **curr;
};
/**
* @brief Basic meta factory to be used for reflection purposes.
* @tparam Type Reflected type for which the factory was created.
*/
template<typename Type>
class meta_factory<Type> {
template<typename Node>
bool exists(const Node *candidate, const Node *node) ENTT_NOEXCEPT {
return node && (node == candidate || exists(candidate, node->next));
}
template<typename Node>
bool exists(const id_type id, const Node *node) ENTT_NOEXCEPT {
return node && (node->id == id || exists(id, node->next));
}
public:
/**
* @brief Makes a meta type _searchable_.
* @param id Optional unique identifier.
* @return An extended meta factory for the given type.
*/
auto type(const id_type id = type_info<Type>::id()) {
auto * const node = internal::meta_info<Type>::resolve();
ENTT_ASSERT(!exists(id, *internal::meta_context::global()));
ENTT_ASSERT(!exists(node, *internal::meta_context::global()));
node->id = id;
node->next = *internal::meta_context::global();
*internal::meta_context::global() = node;
return meta_factory<Type, Type>{&node->prop};
}
/**
* @brief Assigns a meta base to a meta type.
*
* A reflected base class must be a real base class of the reflected type.
*
* @tparam Base Type of the base class to assign to the meta type.
* @return A meta factory for the parent type.
*/
template<typename Base>
auto base() ENTT_NOEXCEPT {
static_assert(std::is_base_of_v<Base, Type>, "Invalid base type");
auto * const type = internal::meta_info<Type>::resolve();
static internal::meta_base_node node{
type,
nullptr,
&internal::meta_info<Base>::resolve,
[](const void *instance) ENTT_NOEXCEPT -> const void * {
return static_cast<const Base *>(static_cast<const Type *>(instance));
}
};
ENTT_ASSERT(!exists(&node, type->base));
node.next = type->base;
type->base = &node;
return meta_factory<Type>{};
}
/**
* @brief Assigns a meta conversion function to a meta type.
*
* The given type must be such that an instance of the reflected type can be
* converted to it.
*
* @tparam To Type of the conversion function to assign to the meta type.
* @return A meta factory for the parent type.
*/
template<typename To>
auto conv() ENTT_NOEXCEPT {
static_assert(std::is_convertible_v<Type, To>, "Could not convert to the required type");
auto * const type = internal::meta_info<Type>::resolve();
static internal::meta_conv_node node{
type,
nullptr,
&internal::meta_info<To>::resolve,
[](const void *instance) -> meta_any {
return static_cast<To>(*static_cast<const Type *>(instance));
}
};
ENTT_ASSERT(!exists(&node, type->conv));
node.next = type->conv;
type->conv = &node;
return meta_factory<Type>{};
}
/**
* @brief Assigns a meta conversion function to a meta type.
*
* Conversion functions can be either free functions or member
* functions.<br/>
* In case of free functions, they must accept a const reference to an
* instance of the parent type as an argument. In case of member functions,
* they should have no arguments at all.
*
* @tparam Candidate The actual function to use for the conversion.
* @return A meta factory for the parent type.
*/
template<auto Candidate>
auto conv() ENTT_NOEXCEPT {
using conv_type = std::invoke_result_t<decltype(Candidate), Type &>;
auto * const type = internal::meta_info<Type>::resolve();
static internal::meta_conv_node node{
type,
nullptr,
&internal::meta_info<conv_type>::resolve,
[](const void *instance) -> meta_any {
return std::invoke(Candidate, *static_cast<const Type *>(instance));
}
};
ENTT_ASSERT(!exists(&node, type->conv));
node.next = type->conv;
type->conv = &node;
return meta_factory<Type>{};
}
/**
* @brief Assigns a meta constructor to a meta type.
*
* Free functions can be assigned to meta types in the role of constructors.
* All that is required is that they return an instance of the underlying
* type.<br/>
* From a client's point of view, nothing changes if a constructor of a meta
* type is a built-in one or a free function.
*
* @tparam Func The actual function to use as a constructor.
* @tparam Policy Optional policy (no policy set by default).
* @return An extended meta factory for the parent type.
*/
template<auto Func, typename Policy = as_is_t>
auto ctor() ENTT_NOEXCEPT {
using helper_type = internal::meta_function_helper_t<decltype(Func)>;
static_assert(std::is_same_v<typename helper_type::return_type, Type>, "The function doesn't return an object of the required type");
auto * const type = internal::meta_info<Type>::resolve();
static internal::meta_ctor_node node{
type,
nullptr,
nullptr,
std::tuple_size_v<typename helper_type::args_type>,
&helper_type::arg,
[](meta_any * const any) {
return internal::invoke<Type, Func, Policy>({}, any, std::make_index_sequence<std::tuple_size_v<typename helper_type::args_type>>{});
}
};
ENTT_ASSERT(!exists(&node, type->ctor));
node.next = type->ctor;
type->ctor = &node;
return meta_factory<Type, std::integral_constant<decltype(Func), Func>>{&node.prop};
}
/**
* @brief Assigns a meta constructor to a meta type.
*
* A meta constructor is uniquely identified by the types of its arguments
* and is such that there exists an actual constructor of the underlying
* type that can be invoked with parameters whose types are those given.
*
* @tparam Args Types of arguments to use to construct an instance.
* @return An extended meta factory for the parent type.
*/
template<typename... Args>
auto ctor() ENTT_NOEXCEPT {
using helper_type = internal::meta_function_helper_t<Type(*)(Args...)>;
auto * const type = internal::meta_info<Type>::resolve();
static internal::meta_ctor_node node{
type,
nullptr,
nullptr,
std::tuple_size_v<typename helper_type::args_type>,
&helper_type::arg,
[](meta_any * const any) {
return internal::construct<Type, std::remove_cv_t<std::remove_reference_t<Args>>...>(any, std::make_index_sequence<std::tuple_size_v<typename helper_type::args_type>>{});
}
};
ENTT_ASSERT(!exists(&node, type->ctor));
node.next = type->ctor;
type->ctor = &node;
return meta_factory<Type, Type(Args...)>{&node.prop};
}
/**
* @brief Assigns a meta destructor to a meta type.
*
* Free functions can be assigned to meta types in the role of destructors.
* The signature of the function should identical to the following:
*
* @code{.cpp}
* void(Type &);
* @endcode
*
* The purpose is to give users the ability to free up resources that
* require special treatment before an object is actually destroyed.
*
* @tparam Func The actual function to use as a destructor.
* @return A meta factory for the parent type.
*/
template<auto Func>
auto dtor() ENTT_NOEXCEPT {
static_assert(std::is_invocable_v<decltype(Func), Type &>, "The function doesn't accept an object of the type provided");
auto * const type = internal::meta_info<Type>::resolve();
ENTT_ASSERT(!type->dtor);
type->dtor = [](void *instance) {
if(instance) {
std::invoke(Func, *static_cast<Type *>(instance));
}
};
return meta_factory<Type>{};
}
/**
* @brief Assigns a meta data to a meta type.
*
* Both data members and static and global variables, as well as constants
* of any kind, can be assigned to a meta type.<br/>
* From a client's point of view, all the variables associated with the
* reflected object will appear as if they were part of the type itself.
*
* @tparam Data The actual variable to attach to the meta type.
* @tparam Policy Optional policy (no policy set by default).
* @param id Unique identifier.
* @return An extended meta factory for the parent type.
*/
template<auto Data, typename Policy = as_is_t>
auto data(const id_type id) ENTT_NOEXCEPT {
if constexpr(std::is_member_object_pointer_v<decltype(Data)>) {
return data<Data, Data, Policy>(id);
} else {
using data_type = std::remove_pointer_t<std::decay_t<decltype(Data)>>;
auto * const type = internal::meta_info<Type>::resolve();
static internal::meta_data_node node{
{},
type,
nullptr,
nullptr,
true,
&internal::meta_info<data_type>::resolve,
[]() -> std::remove_const_t<decltype(internal::meta_data_node::set)> {
if constexpr(std::is_same_v<Type, data_type> || std::is_const_v<data_type>) {
return nullptr;
} else {
return &internal::setter<Type, Data>;
}
}(),
&internal::getter<Type, Data, Policy>
};
ENTT_ASSERT(!exists(id, type->data));
ENTT_ASSERT(!exists(&node, type->data));
node.id = id;
node.next = type->data;
type->data = &node;
return meta_factory<Type, std::integral_constant<decltype(Data), Data>>{&node.prop};
}
}
/**
* @brief Assigns a meta data to a meta type by means of its setter and
* getter.
*
* Setters and getters can be either free functions, member functions or a
* mix of them.<br/>
* In case of free functions, setters and getters must accept a reference to
* an instance of the parent type as their first argument. A setter has then
* an extra argument of a type convertible to that of the parameter to
* set.<br/>
* In case of member functions, getters have no arguments at all, while
* setters has an argument of a type convertible to that of the parameter to
* set.
*
* @tparam Setter The actual function to use as a setter.
* @tparam Getter The actual function to use as a getter.
* @tparam Policy Optional policy (no policy set by default).
* @param id Unique identifier.
* @return An extended meta factory for the parent type.
*/
template<auto Setter, auto Getter, typename Policy = as_is_t>
auto data(const id_type id) ENTT_NOEXCEPT {
using underlying_type = std::remove_reference_t<std::invoke_result_t<decltype(Getter), Type &>>;
auto * const type = internal::meta_info<Type>::resolve();
static internal::meta_data_node node{
{},
type,
nullptr,
nullptr,
false,
&internal::meta_info<underlying_type>::resolve,
[]() -> std::remove_const_t<decltype(internal::meta_data_node::set)> {
if constexpr(std::is_same_v<decltype(Setter), std::nullptr_t> || (std::is_member_object_pointer_v<decltype(Setter)> && std::is_const_v<underlying_type>)) {
return nullptr;
} else {
return &internal::setter<Type, Setter>;
}
}(),
&internal::getter<Type, Getter, Policy>
};
ENTT_ASSERT(!exists(id, type->data));
ENTT_ASSERT(!exists(&node, type->data));
node.id = id;
node.next = type->data;
type->data = &node;
return meta_factory<Type, std::integral_constant<decltype(Setter), Setter>, std::integral_constant<decltype(Getter), Getter>>{&node.prop};
}
/**
* @brief Assigns a meta funcion to a meta type.
*
* Both member functions and free functions can be assigned to a meta
* type.<br/>
* From a client's point of view, all the functions associated with the
* reflected object will appear as if they were part of the type itself.
*
* @tparam Candidate The actual function to attach to the meta type.
* @tparam Policy Optional policy (no policy set by default).
* @param id Unique identifier.
* @return An extended meta factory for the parent type.
*/
template<auto Candidate, typename Policy = as_is_t>
auto func(const id_type id) ENTT_NOEXCEPT {
using helper_type = internal::meta_function_helper_t<decltype(Candidate)>;
auto * const type = internal::meta_info<Type>::resolve();
static internal::meta_func_node node{
{},
type,
nullptr,
nullptr,
std::tuple_size_v<typename helper_type::args_type>,
helper_type::is_const,
!std::is_member_function_pointer_v<decltype(Candidate)>,
&internal::meta_info<std::conditional_t<std::is_same_v<Policy, as_void_t>, void, typename helper_type::return_type>>::resolve,
&helper_type::arg,
[](meta_handle instance, meta_any *args) {
return internal::invoke<Type, Candidate, Policy>(*instance, args, std::make_index_sequence<std::tuple_size_v<typename helper_type::args_type>>{});
}
};
ENTT_ASSERT(!exists(id, type->func));
ENTT_ASSERT(!exists(&node, type->func));
node.id = id;
node.next = type->func;
type->func = &node;
return meta_factory<Type, std::integral_constant<decltype(Candidate), Candidate>>{&node.prop};
}
};
/**
* @brief Utility function to use for reflection.
*
* This is the point from which everything starts.<br/>
* By invoking this function with a type that is not yet reflected, a meta type
* is created to which it will be possible to attach meta objects through a
* dedicated factory.
*
* @tparam Type Type to reflect.
* @return A meta factory for the given type.
*/
template<typename Type>
[[nodiscard]] auto meta() ENTT_NOEXCEPT {
auto * const node = internal::meta_info<Type>::resolve();
// extended meta factory to allow assigning properties to opaque meta types
return meta_factory<Type, Type>{&node->prop};
}
}
#endif
// #include "meta/internal.hpp"
// #include "meta/meta.hpp"
// #include "meta/pointer.hpp"
#ifndef ENTT_META_POINTER_HPP
#define ENTT_META_POINTER_HPP
#include <memory>
#include <type_traits>
// #include "type_traits.hpp"
namespace entt {
/**
* @brief Makes plain pointers pointer-like types for the meta system.
* @tparam Type Element type.
*/
template<typename Type>
struct is_meta_pointer_like<Type *>
: std::true_type
{};
/**
* @brief Makes `std::shared_ptr`s of any type pointer-like types for the meta
* system.
* @tparam Type Element type.
*/
template<typename Type>
struct is_meta_pointer_like<std::shared_ptr<Type>>
: std::true_type
{};
/**
* @brief Makes `std::unique_ptr`s of any type pointer-like types for the meta
* system.
* @tparam Type Element type.
* @tparam Args Other arguments.
*/
template<typename Type, typename... Args>
struct is_meta_pointer_like<std::unique_ptr<Type, Args...>>
: std::true_type
{};
}
#endif
// #include "meta/policy.hpp"
// #include "meta/range.hpp"
// #include "meta/resolve.hpp"
#ifndef ENTT_META_RESOLVE_HPP
#define ENTT_META_RESOLVE_HPP
#include <algorithm>
// #include "ctx.hpp"
// #include "meta.hpp"
// #include "range.hpp"
namespace entt {
/**
* @brief Returns the meta type associated with a given type.
* @tparam Type Type to use to search for a meta type.
* @return The meta type associated with the given type, if any.
*/
template<typename Type>
[[nodiscard]] meta_type resolve() ENTT_NOEXCEPT {
return internal::meta_info<Type>::resolve();
}
/**
* @brief Returns a range to use to visit all meta types.
* @return An iterable range to use to visit all meta types.
*/
[[nodiscard]] inline meta_range<meta_type> resolve() {
return *internal::meta_context::global();
}
/**
* @brief Returns the meta type associated with a given identifier, if any.
* @param id Unique identifier.
* @return The meta type associated with the given identifier, if any.
*/
[[nodiscard]] inline meta_type resolve_id(const id_type id) ENTT_NOEXCEPT {
internal::meta_range range{*internal::meta_context::global()};
return std::find_if(range.begin(), range.end(), [id](const auto &curr) { return curr.id == id; }).operator->();
}
/**
* @brief Returns the meta type associated with a given type id, if any.
* @param id Unique identifier.
* @return The meta type associated with the given type id, if any.
*/
[[nodiscard]] inline meta_type resolve_type(const id_type id) ENTT_NOEXCEPT {
internal::meta_range range{*internal::meta_context::global()};
return std::find_if(range.begin(), range.end(), [id](const auto &curr) { return curr.type_id == id; }).operator->();
}
}
#endif
// #include "meta/type_traits.hpp"
// #include "platform/android-ndk-r17.hpp"
#ifndef ENTT_PLATFORM_ANDROID_NDK_R17_HPP
#define ENTT_PLATFORM_ANDROID_NDK_R17_HPP
/**
* @cond TURN_OFF_DOXYGEN
* Internal details not to be documented.
*/
#ifdef __ANDROID__
#include <android/ndk-version.h>
#if __NDK_MAJOR__ == 17
#include <functional>
#include <type_traits>
#include <utility>
namespace std {
namespace internal {
template<typename Func, typename... Args>
constexpr auto is_invocable(int) -> decltype(std::invoke(std::declval<Func>(), std::declval<Args>()...), std::true_type{});
template<typename, typename...>
constexpr std::false_type is_invocable(...);
template<typename Ret, typename Func, typename... Args>
constexpr auto is_invocable_r(int)
-> std::enable_if_t<decltype(std::is_convertible_v<decltype(std::invoke(std::declval<Func>(), std::declval<Args>()...)), Ret>, std::true_type>;
template<typename, typename, typename...>
constexpr std::false_type is_invocable_r(...);
}
template<typename Func, typename... Args>
struct is_invocable: decltype(internal::is_invocable<Func, Args...>(0)) {};
template<typename Func, typename... Argsv>
inline constexpr bool is_invocable_v = std::is_invocable<Func, Args...>::value;
template<typename Ret, typename Func, typename... Args>
struct is_invocable_r: decltype(internal::is_invocable_r<Ret, Func, Args...>(0)) {};
template<typename Ret, typename Func, typename... Args>
inline constexpr bool is_invocable_r_v = std::is_invocable_r<Ret, Func, Args...>::value;
template<typename Func, typename...Args>
struct invoke_result {
using type = decltype(std::invoke(std::declval<Func>(), std::declval<Args>()...));
};
template<typename Func, typename... Args>
using invoke_result_t = typename std::invoke_result<Func, Args...>::type;
}
#endif
#endif
/**
* Internal details not to be documented.
* @endcond
*/
#endif
// #include "process/process.hpp"
#ifndef ENTT_PROCESS_PROCESS_HPP
#define ENTT_PROCESS_PROCESS_HPP
#include <utility>
#include <type_traits>
// #include "../config/config.h"
#ifndef ENTT_CONFIG_CONFIG_H
#define ENTT_CONFIG_CONFIG_H
#ifndef ENTT_NOEXCEPT
# define ENTT_NOEXCEPT noexcept
#endif
#ifndef ENTT_HS_SUFFIX
# define ENTT_HS_SUFFIX _hs
#endif
#ifndef ENTT_HWS_SUFFIX
# define ENTT_HWS_SUFFIX _hws
#endif
#ifndef ENTT_USE_ATOMIC
# define ENTT_MAYBE_ATOMIC(Type) Type
#else
# include <atomic>
# define ENTT_MAYBE_ATOMIC(Type) std::atomic<Type>
#endif
#ifndef ENTT_ID_TYPE
# include <cstdint>
# define ENTT_ID_TYPE std::uint32_t
#endif
#ifndef ENTT_PAGE_SIZE
# define ENTT_PAGE_SIZE 32768
#endif
#ifndef ENTT_ASSERT
# include <cassert>
# define ENTT_ASSERT(condition) assert(condition)
#endif
#ifndef ENTT_NO_ETO
# include <type_traits>
# define ENTT_IS_EMPTY(Type) std::is_empty<Type>
#else
# include <type_traits>
# define ENTT_IS_EMPTY(Type) std::false_type
#endif
#ifndef ENTT_STANDARD_CPP
# if defined __clang__ || (defined __GNUC__ && __GNUC__ > 8)
# define ENTT_PRETTY_FUNCTION_CONSTEXPR
# define ENTT_PRETTY_FUNCTION __PRETTY_FUNCTION__
# define ENTT_PRETTY_FUNCTION_PREFIX '='
# define ENTT_PRETTY_FUNCTION_SUFFIX ']'
# elif defined __GNUC__
# define ENTT_PRETTY_FUNCTION __PRETTY_FUNCTION__
# define ENTT_PRETTY_FUNCTION_PREFIX '='
# define ENTT_PRETTY_FUNCTION_SUFFIX ']'
# elif defined _MSC_VER
# define ENTT_PRETTY_FUNCTION_CONSTEXPR
# define ENTT_PRETTY_FUNCTION __FUNCSIG__
# define ENTT_PRETTY_FUNCTION_PREFIX '<'
# define ENTT_PRETTY_FUNCTION_SUFFIX '>'
# endif
#endif
#ifndef ENTT_STANDALONE
# define ENTT_FAST_PATH(...) false
#else
# define ENTT_FAST_PATH(Cond) Cond
#endif
#endif
// #include "../core/type_traits.hpp"
#ifndef ENTT_CORE_TYPE_TRAITS_HPP
#define ENTT_CORE_TYPE_TRAITS_HPP
#include <cstddef>
#include <utility>
#include <type_traits>
// #include "../config/config.h"
#ifndef ENTT_CONFIG_CONFIG_H
#define ENTT_CONFIG_CONFIG_H
#ifndef ENTT_NOEXCEPT
# define ENTT_NOEXCEPT noexcept
#endif
#ifndef ENTT_HS_SUFFIX
# define ENTT_HS_SUFFIX _hs
#endif
#ifndef ENTT_HWS_SUFFIX
# define ENTT_HWS_SUFFIX _hws
#endif
#ifndef ENTT_USE_ATOMIC
# define ENTT_MAYBE_ATOMIC(Type) Type
#else
# include <atomic>
# define ENTT_MAYBE_ATOMIC(Type) std::atomic<Type>
#endif
#ifndef ENTT_ID_TYPE
# include <cstdint>
# define ENTT_ID_TYPE std::uint32_t
#endif
#ifndef ENTT_PAGE_SIZE
# define ENTT_PAGE_SIZE 32768
#endif
#ifndef ENTT_ASSERT
# include <cassert>
# define ENTT_ASSERT(condition) assert(condition)
#endif
#ifndef ENTT_NO_ETO
# include <type_traits>
# define ENTT_IS_EMPTY(Type) std::is_empty<Type>
#else
# include <type_traits>
# define ENTT_IS_EMPTY(Type) std::false_type
#endif
#ifndef ENTT_STANDARD_CPP
# if defined __clang__ || (defined __GNUC__ && __GNUC__ > 8)
# define ENTT_PRETTY_FUNCTION_CONSTEXPR
# define ENTT_PRETTY_FUNCTION __PRETTY_FUNCTION__
# define ENTT_PRETTY_FUNCTION_PREFIX '='
# define ENTT_PRETTY_FUNCTION_SUFFIX ']'
# elif defined __GNUC__
# define ENTT_PRETTY_FUNCTION __PRETTY_FUNCTION__
# define ENTT_PRETTY_FUNCTION_PREFIX '='
# define ENTT_PRETTY_FUNCTION_SUFFIX ']'
# elif defined _MSC_VER
# define ENTT_PRETTY_FUNCTION_CONSTEXPR
# define ENTT_PRETTY_FUNCTION __FUNCSIG__
# define ENTT_PRETTY_FUNCTION_PREFIX '<'
# define ENTT_PRETTY_FUNCTION_SUFFIX '>'
# endif
#endif
#ifndef ENTT_STANDALONE
# define ENTT_FAST_PATH(...) false
#else
# define ENTT_FAST_PATH(Cond) Cond
#endif
#endif
// #include "fwd.hpp"
#ifndef ENTT_CORE_FWD_HPP
#define ENTT_CORE_FWD_HPP
// #include "../config/config.h"
namespace entt {
/*! @brief Alias declaration for type identifiers. */
using id_type = ENTT_ID_TYPE;
}
#endif
namespace entt {
/**
* @brief Using declaration to be used to _repeat_ the same type a number of
* times equal to the size of a given parameter pack.
* @tparam Type A type to repeat.
*/
template<typename Type, typename>
using unpack_as_t = Type;
/**
* @brief Helper variable template to be used to _repeat_ the same value a
* number of times equal to the size of a given parameter pack.
* @tparam Value A value to repeat.
*/
template<auto Value, typename>
inline constexpr auto unpack_as_v = Value;
/**
* @brief Wraps a static constant.
* @tparam Value A static constant.
*/
template<auto Value>
using integral_constant = std::integral_constant<decltype(Value), Value>;
/**
* @brief Alias template to ease the creation of named values.
* @tparam Value A constant value at least convertible to `id_type`.
*/
template<id_type Value>
using tag = integral_constant<Value>;
/**
* @brief Utility class to disambiguate overloaded functions.
* @tparam N Number of choices available.
*/
template<std::size_t N>
struct choice_t
// Unfortunately, doxygen cannot parse such a construct.
/*! @cond TURN_OFF_DOXYGEN */
: choice_t<N-1>
/*! @endcond */
{};
/*! @copybrief choice_t */
template<>
struct choice_t<0> {};
/**
* @brief Variable template for the choice trick.
* @tparam N Number of choices available.
*/
template<std::size_t N>
inline constexpr choice_t<N> choice{};
/*! @brief A class to use to push around lists of types, nothing more. */
template<typename...>
struct type_list {};
/*! @brief Primary template isn't defined on purpose. */
template<typename>
struct type_list_size;
/**
* @brief Compile-time number of elements in a type list.
* @tparam Type Types provided by the type list.
*/
template<typename... Type>
struct type_list_size<type_list<Type...>>
: std::integral_constant<std::size_t, sizeof...(Type)>
{};
/**
* @brief Helper variable template.
* @tparam List Type list.
*/
template<class List>
inline constexpr auto type_list_size_v = type_list_size<List>::value;
/*! @brief Primary template isn't defined on purpose. */
template<typename...>
struct type_list_cat;
/*! @brief Concatenates multiple type lists. */
template<>
struct type_list_cat<> {
/*! @brief A type list composed by the types of all the type lists. */
using type = type_list<>;
};
/**
* @brief Concatenates multiple type lists.
* @tparam Type Types provided by the first type list.
* @tparam Other Types provided by the second type list.
* @tparam List Other type lists, if any.
*/
template<typename... Type, typename... Other, typename... List>
struct type_list_cat<type_list<Type...>, type_list<Other...>, List...> {
/*! @brief A type list composed by the types of all the type lists. */
using type = typename type_list_cat<type_list<Type..., Other...>, List...>::type;
};
/**
* @brief Concatenates multiple type lists.
* @tparam Type Types provided by the type list.
*/
template<typename... Type>
struct type_list_cat<type_list<Type...>> {
/*! @brief A type list composed by the types of all the type lists. */
using type = type_list<Type...>;
};
/**
* @brief Helper type.
* @tparam List Type lists to concatenate.
*/
template<typename... List>
using type_list_cat_t = typename type_list_cat<List...>::type;
/*! @brief Primary template isn't defined on purpose. */
template<typename>
struct type_list_unique;
/**
* @brief Removes duplicates types from a type list.
* @tparam Type One of the types provided by the given type list.
* @tparam Other The other types provided by the given type list.
*/
template<typename Type, typename... Other>
struct type_list_unique<type_list<Type, Other...>> {
/*! @brief A type list without duplicate types. */
using type = std::conditional_t<
std::disjunction_v<std::is_same<Type, Other>...>,
typename type_list_unique<type_list<Other...>>::type,
type_list_cat_t<type_list<Type>, typename type_list_unique<type_list<Other...>>::type>
>;
};
/*! @brief Removes duplicates types from a type list. */
template<>
struct type_list_unique<type_list<>> {
/*! @brief A type list without duplicate types. */
using type = type_list<>;
};
/**
* @brief Helper type.
* @tparam Type A type list.
*/
template<typename Type>
using type_list_unique_t = typename type_list_unique<Type>::type;
/**
* @brief Provides the member constant `value` to true if a given type is
* equality comparable, false otherwise.
* @tparam Type Potentially equality comparable type.
*/
template<typename Type, typename = std::void_t<>>
struct is_equality_comparable: std::false_type {};
/*! @copydoc is_equality_comparable */
template<typename Type>
struct is_equality_comparable<Type, std::void_t<decltype(std::declval<Type>() == std::declval<Type>())>>
: std::true_type
{};
/**
* @brief Helper variable template.
* @tparam Type Potentially equality comparable type.
*/
template<class Type>
inline constexpr auto is_equality_comparable_v = is_equality_comparable<Type>::value;
/**
* @brief Provides the member constant `value` to true if a given type is empty
* and the empty type optimization is enabled, false otherwise.
* @tparam Type Potential empty type.
*/
template<typename Type, typename = void>
struct is_eto_eligible
: ENTT_IS_EMPTY(Type)
{};
/**
* @brief Helper variable template.
* @tparam Type Potential empty type.
*/
template<typename Type>
inline constexpr auto is_eto_eligible_v = is_eto_eligible<Type>::value;
/**
* @brief Extracts the class of a non-static member object or function.
* @tparam Member A pointer to a non-static member object or function.
*/
template<typename Member>
class member_class {
static_assert(std::is_member_pointer_v<Member>, "Invalid pointer type to non-static member object or function");
template<typename Class, typename Ret, typename... Args>
static Class * clazz(Ret(Class:: *)(Args...));
template<typename Class, typename Ret, typename... Args>
static Class * clazz(Ret(Class:: *)(Args...) const);
template<typename Class, typename Type>
static Class * clazz(Type Class:: *);
public:
/*! @brief The class of the given non-static member object or function. */
using type = std::remove_pointer_t<decltype(clazz(std::declval<Member>()))>;
};
/**
* @brief Helper type.
* @tparam Member A pointer to a non-static member object or function.
*/
template<typename Member>
using member_class_t = typename member_class<Member>::type;
}
#endif
namespace entt {
/**
* @brief Base class for processes.
*
* This class stays true to the CRTP idiom. Derived classes must specify what's
* the intended type for elapsed times.<br/>
* A process should expose publicly the following member functions whether
* required:
*
* * @code{.cpp}
* void update(Delta, void *);
* @endcode
*
* It's invoked once per tick until a process is explicitly aborted or it
* terminates either with or without errors. Even though it's not mandatory to
* declare this member function, as a rule of thumb each process should at
* least define it to work properly. The `void *` parameter is an opaque
* pointer to user data (if any) forwarded directly to the process during an
* update.
*
* * @code{.cpp}
* void init();
* @endcode
*
* It's invoked when the process joins the running queue of a scheduler. This
* happens as soon as it's attached to the scheduler if the process is a top
* level one, otherwise when it replaces its parent if the process is a
* continuation.
*
* * @code{.cpp}
* void succeeded();
* @endcode
*
* It's invoked in case of success, immediately after an update and during the
* same tick.
*
* * @code{.cpp}
* void failed();
* @endcode
*
* It's invoked in case of errors, immediately after an update and during the
* same tick.
*
* * @code{.cpp}
* void aborted();
* @endcode
*
* It's invoked only if a process is explicitly aborted. There is no guarantee
* that it executes in the same tick, this depends solely on whether the
* process is aborted immediately or not.
*
* Derived classes can change the internal state of a process by invoking the
* `succeed` and `fail` protected member functions and even pause or unpause the
* process itself.
*
* @sa scheduler
*
* @tparam Derived Actual type of process that extends the class template.
* @tparam Delta Type to use to provide elapsed time.
*/
template<typename Derived, typename Delta>
class process {
enum class state: unsigned int {
UNINITIALIZED = 0,
RUNNING,
PAUSED,
SUCCEEDED,
FAILED,
ABORTED,
FINISHED
};
template<typename Target = Derived>
auto next(integral_constant<state::UNINITIALIZED>)
-> decltype(std::declval<Target>().init(), void()) {
static_cast<Target *>(this)->init();
}
template<typename Target = Derived>
auto next(integral_constant<state::RUNNING>, Delta delta, void *data)
-> decltype(std::declval<Target>().update(delta, data), void()) {
static_cast<Target *>(this)->update(delta, data);
}
template<typename Target = Derived>
auto next(integral_constant<state::SUCCEEDED>)
-> decltype(std::declval<Target>().succeeded(), void()) {
static_cast<Target *>(this)->succeeded();
}
template<typename Target = Derived>
auto next(integral_constant<state::FAILED>)
-> decltype(std::declval<Target>().failed(), void()) {
static_cast<Target *>(this)->failed();
}
template<typename Target = Derived>
auto next(integral_constant<state::ABORTED>)
-> decltype(std::declval<Target>().aborted(), void()) {
static_cast<Target *>(this)->aborted();
}
void next(...) const ENTT_NOEXCEPT {}
protected:
/**
* @brief Terminates a process with success if it's still alive.
*
* The function is idempotent and it does nothing if the process isn't
* alive.
*/
void succeed() ENTT_NOEXCEPT {
if(alive()) {
current = state::SUCCEEDED;
}
}
/**
* @brief Terminates a process with errors if it's still alive.
*
* The function is idempotent and it does nothing if the process isn't
* alive.
*/
void fail() ENTT_NOEXCEPT {
if(alive()) {
current = state::FAILED;
}
}
/**
* @brief Stops a process if it's in a running state.
*
* The function is idempotent and it does nothing if the process isn't
* running.
*/
void pause() ENTT_NOEXCEPT {
if(current == state::RUNNING) {
current = state::PAUSED;
}
}
/**
* @brief Restarts a process if it's paused.
*
* The function is idempotent and it does nothing if the process isn't
* paused.
*/
void unpause() ENTT_NOEXCEPT {
if(current == state::PAUSED) {
current = state::RUNNING;
}
}
public:
/*! @brief Type used to provide elapsed time. */
using delta_type = Delta;
/*! @brief Default destructor. */
virtual ~process() {
static_assert(std::is_base_of_v<process, Derived>, "Incorrect use of the class template");
}
/**
* @brief Aborts a process if it's still alive.
*
* The function is idempotent and it does nothing if the process isn't
* alive.
*
* @param immediately Requests an immediate operation.
*/
void abort(const bool immediately = false) {
if(alive()) {
current = state::ABORTED;
if(immediately) {
tick({});
}
}
}
/**
* @brief Returns true if a process is either running or paused.
* @return True if the process is still alive, false otherwise.
*/
[[nodiscard]] bool alive() const ENTT_NOEXCEPT {
return current == state::RUNNING || current == state::PAUSED;
}
/**
* @brief Returns true if a process is already terminated.
* @return True if the process is terminated, false otherwise.
*/
[[nodiscard]] bool dead() const ENTT_NOEXCEPT {
return current == state::FINISHED;
}
/**
* @brief Returns true if a process is currently paused.
* @return True if the process is paused, false otherwise.
*/
[[nodiscard]] bool paused() const ENTT_NOEXCEPT {
return current == state::PAUSED;
}
/**
* @brief Returns true if a process terminated with errors.
* @return True if the process terminated with errors, false otherwise.
*/
[[nodiscard]] bool rejected() const ENTT_NOEXCEPT {
return stopped;
}
/**
* @brief Updates a process and its internal state if required.
* @param delta Elapsed time.
* @param data Optional data.
*/
void tick(const Delta delta, void *data = nullptr) {
switch (current) {
case state::UNINITIALIZED:
next(integral_constant<state::UNINITIALIZED>{});
current = state::RUNNING;
break;
case state::RUNNING:
next(integral_constant<state::RUNNING>{}, delta, data);
break;
default:
// suppress warnings
break;
}
// if it's dead, it must be notified and removed immediately
switch(current) {
case state::SUCCEEDED:
next(integral_constant<state::SUCCEEDED>{});
current = state::FINISHED;
break;
case state::FAILED:
next(integral_constant<state::FAILED>{});
current = state::FINISHED;
stopped = true;
break;
case state::ABORTED:
next(integral_constant<state::ABORTED>{});
current = state::FINISHED;
stopped = true;
break;
default:
// suppress warnings
break;
}
}
private:
state current{state::UNINITIALIZED};
bool stopped{false};
};
/**
* @brief Adaptor for lambdas and functors to turn them into processes.
*
* Lambdas and functors can't be used directly with a scheduler for they are not
* properly defined processes with managed life cycles.<br/>
* This class helps in filling the gap and turning lambdas and functors into
* full featured processes usable by a scheduler.
*
* The signature of the function call operator should be equivalent to the
* following:
*
* @code{.cpp}
* void(Delta delta, void *data, auto succeed, auto fail);
* @endcode
*
* Where:
*
* * `delta` is the elapsed time.
* * `data` is an opaque pointer to user data if any, `nullptr` otherwise.
* * `succeed` is a function to call when a process terminates with success.
* * `fail` is a function to call when a process terminates with errors.
*
* The signature of the function call operator of both `succeed` and `fail`
* is equivalent to the following:
*
* @code{.cpp}
* void();
* @endcode
*
* Usually users shouldn't worry about creating adaptors. A scheduler will
* create them internally each and avery time a lambda or a functor is used as
* a process.
*
* @sa process
* @sa scheduler
*
* @tparam Func Actual type of process.
* @tparam Delta Type to use to provide elapsed time.
*/
template<typename Func, typename Delta>
struct process_adaptor: process<process_adaptor<Func, Delta>, Delta>, private Func {
/**
* @brief Constructs a process adaptor from a lambda or a functor.
* @tparam Args Types of arguments to use to initialize the actual process.
* @param args Parameters to use to initialize the actual process.
*/
template<typename... Args>
process_adaptor(Args &&... args)
: Func{std::forward<Args>(args)...}
{}
/**
* @brief Updates a process and its internal state if required.
* @param delta Elapsed time.
* @param data Optional data.
*/
void update(const Delta delta, void *data) {
Func::operator()(delta, data, [this]() { this->succeed(); }, [this]() { this->fail(); });
}
};
}
#endif
// #include "process/scheduler.hpp"
#ifndef ENTT_PROCESS_SCHEDULER_HPP
#define ENTT_PROCESS_SCHEDULER_HPP
#include <vector>
#include <memory>
#include <utility>
#include <algorithm>
#include <type_traits>
// #include "../config/config.h"
// #include "process.hpp"
namespace entt {
/**
* @brief Cooperative scheduler for processes.
*
* A cooperative scheduler runs processes and helps managing their life cycles.
*
* Each process is invoked once per tick. If a process terminates, it's
* removed automatically from the scheduler and it's never invoked again.<br/>
* A process can also have a child. In this case, the process is replaced with
* its child when it terminates if it returns with success. In case of errors,
* both the process and its child are discarded.
*
* Example of use (pseudocode):
*
* @code{.cpp}
* scheduler.attach([](auto delta, void *, auto succeed, auto fail) {
* // code
* }).then<my_process>(arguments...);
* @endcode
*
* In order to invoke all scheduled processes, call the `update` member function
* passing it the elapsed time to forward to the tasks.
*
* @sa process
*
* @tparam Delta Type to use to provide elapsed time.
*/
template<typename Delta>
class scheduler {
struct process_handler {
using instance_type = std::unique_ptr<void, void(*)(void *)>;
using update_fn_type = bool(process_handler &, Delta, void *);
using abort_fn_type = void(process_handler &, bool);
using next_type = std::unique_ptr<process_handler>;
instance_type instance;
update_fn_type *update;
abort_fn_type *abort;
next_type next;
};
struct continuation {
continuation(process_handler *ref)
: handler{ref}
{
ENTT_ASSERT(handler);
}
template<typename Proc, typename... Args>
continuation then(Args &&... args) {
static_assert(std::is_base_of_v<process<Proc, Delta>, Proc>, "Invalid process type");
auto proc = typename process_handler::instance_type{new Proc{std::forward<Args>(args)...}, &scheduler::deleter<Proc>};
handler->next.reset(new process_handler{std::move(proc), &scheduler::update<Proc>, &scheduler::abort<Proc>, nullptr});
handler = handler->next.get();
return *this;
}
template<typename Func>
continuation then(Func &&func) {
return then<process_adaptor<std::decay_t<Func>, Delta>>(std::forward<Func>(func));
}
private:
process_handler *handler;
};
template<typename Proc>
[[nodiscard]] static bool update(process_handler &handler, const Delta delta, void *data) {
auto *process = static_cast<Proc *>(handler.instance.get());
process->tick(delta, data);
auto dead = process->dead();
if(dead) {
if(handler.next && !process->rejected()) {
handler = std::move(*handler.next);
// forces the process to exit the uninitialized state
dead = handler.update(handler, {}, nullptr);
} else {
handler.instance.reset();
}
}
return dead;
}
template<typename Proc>
static void abort(process_handler &handler, const bool immediately) {
static_cast<Proc *>(handler.instance.get())->abort(immediately);
}
template<typename Proc>
static void deleter(void *proc) {
delete static_cast<Proc *>(proc);
}
public:
/*! @brief Unsigned integer type. */
using size_type = std::size_t;
/*! @brief Default constructor. */
scheduler() = default;
/*! @brief Default move constructor. */
scheduler(scheduler &&) = default;
/*! @brief Default move assignment operator. @return This scheduler. */
scheduler & operator=(scheduler &&) = default;
/**
* @brief Number of processes currently scheduled.
* @return Number of processes currently scheduled.
*/
[[nodiscard]] size_type size() const ENTT_NOEXCEPT {
return handlers.size();
}
/**
* @brief Returns true if at least a process is currently scheduled.
* @return True if there are scheduled processes, false otherwise.
*/
[[nodiscard]] bool empty() const ENTT_NOEXCEPT {
return handlers.empty();
}
/**
* @brief Discards all scheduled processes.
*
* Processes aren't aborted. They are discarded along with their children
* and never executed again.
*/
void clear() {
handlers.clear();
}
/**
* @brief Schedules a process for the next tick.
*
* Returned value is an opaque object that can be used to attach a child to
* the given process. The child is automatically scheduled when the process
* terminates and only if the process returns with success.
*
* Example of use (pseudocode):
*
* @code{.cpp}
* // schedules a task in the form of a process class
* scheduler.attach<my_process>(arguments...)
* // appends a child in the form of a lambda function
* .then([](auto delta, void *, auto succeed, auto fail) {
* // code
* })
* // appends a child in the form of another process class
* .then<my_other_process>();
* @endcode
*
* @tparam Proc Type of process to schedule.
* @tparam Args Types of arguments to use to initialize the process.
* @param args Parameters to use to initialize the process.
* @return An opaque object to use to concatenate processes.
*/
template<typename Proc, typename... Args>
auto attach(Args &&... args) {
static_assert(std::is_base_of_v<process<Proc, Delta>, Proc>, "Invalid process type");
auto proc = typename process_handler::instance_type{new Proc{std::forward<Args>(args)...}, &scheduler::deleter<Proc>};
process_handler handler{std::move(proc), &scheduler::update<Proc>, &scheduler::abort<Proc>, nullptr};
// forces the process to exit the uninitialized state
handler.update(handler, {}, nullptr);
return continuation{&handlers.emplace_back(std::move(handler))};
}
/**
* @brief Schedules a process for the next tick.
*
* A process can be either a lambda or a functor. The scheduler wraps both
* of them in a process adaptor internally.<br/>
* The signature of the function call operator should be equivalent to the
* following:
*
* @code{.cpp}
* void(Delta delta, void *data, auto succeed, auto fail);
* @endcode
*
* Where:
*
* * `delta` is the elapsed time.
* * `data` is an opaque pointer to user data if any, `nullptr` otherwise.
* * `succeed` is a function to call when a process terminates with success.
* * `fail` is a function to call when a process terminates with errors.
*
* The signature of the function call operator of both `succeed` and `fail`
* is equivalent to the following:
*
* @code{.cpp}
* void();
* @endcode
*
* Returned value is an opaque object that can be used to attach a child to
* the given process. The child is automatically scheduled when the process
* terminates and only if the process returns with success.
*
* Example of use (pseudocode):
*
* @code{.cpp}
* // schedules a task in the form of a lambda function
* scheduler.attach([](auto delta, void *, auto succeed, auto fail) {
* // code
* })
* // appends a child in the form of another lambda function
* .then([](auto delta, void *, auto succeed, auto fail) {
* // code
* })
* // appends a child in the form of a process class
* .then<my_process>(arguments...);
* @endcode
*
* @sa process_adaptor
*
* @tparam Func Type of process to schedule.
* @param func Either a lambda or a functor to use as a process.
* @return An opaque object to use to concatenate processes.
*/
template<typename Func>
auto attach(Func &&func) {
using Proc = process_adaptor<std::decay_t<Func>, Delta>;
return attach<Proc>(std::forward<Func>(func));
}
/**
* @brief Updates all scheduled processes.
*
* All scheduled processes are executed in no specific order.<br/>
* If a process terminates with success, it's replaced with its child, if
* any. Otherwise, if a process terminates with an error, it's removed along
* with its child.
*
* @param delta Elapsed time.
* @param data Optional data.
*/
void update(const Delta delta, void *data = nullptr) {
bool clean = false;
for(auto pos = handlers.size(); pos; --pos) {
auto &handler = handlers[pos-1];
const bool dead = handler.update(handler, delta, data);
clean = clean || dead;
}
if(clean) {
handlers.erase(std::remove_if(handlers.begin(), handlers.end(), [](auto &handler) {
return !handler.instance;
}), handlers.end());
}
}
/**
* @brief Aborts all scheduled processes.
*
* Unless an immediate operation is requested, the abort is scheduled for
* the next tick. Processes won't be executed anymore in any case.<br/>
* Once a process is fully aborted and thus finished, it's discarded along
* with its child, if any.
*
* @param immediately Requests an immediate operation.
*/
void abort(const bool immediately = false) {
decltype(handlers) exec;
exec.swap(handlers);
for(auto &&handler: exec) {
handler.abort(handler, immediately);
}
std::move(handlers.begin(), handlers.end(), std::back_inserter(exec));
handlers.swap(exec);
}
private:
std::vector<process_handler> handlers{};
};
}
#endif
// #include "resource/cache.hpp"
#ifndef ENTT_RESOURCE_CACHE_HPP
#define ENTT_RESOURCE_CACHE_HPP
#include <memory>
#include <type_traits>
#include <unordered_map>
#include <utility>
// #include "../config/config.h"
#ifndef ENTT_CONFIG_CONFIG_H
#define ENTT_CONFIG_CONFIG_H
#ifndef ENTT_NOEXCEPT
# define ENTT_NOEXCEPT noexcept
#endif
#ifndef ENTT_HS_SUFFIX
# define ENTT_HS_SUFFIX _hs
#endif
#ifndef ENTT_HWS_SUFFIX
# define ENTT_HWS_SUFFIX _hws
#endif
#ifndef ENTT_USE_ATOMIC
# define ENTT_MAYBE_ATOMIC(Type) Type
#else
# include <atomic>
# define ENTT_MAYBE_ATOMIC(Type) std::atomic<Type>
#endif
#ifndef ENTT_ID_TYPE
# include <cstdint>
# define ENTT_ID_TYPE std::uint32_t
#endif
#ifndef ENTT_PAGE_SIZE
# define ENTT_PAGE_SIZE 32768
#endif
#ifndef ENTT_ASSERT
# include <cassert>
# define ENTT_ASSERT(condition) assert(condition)
#endif
#ifndef ENTT_NO_ETO
# include <type_traits>
# define ENTT_IS_EMPTY(Type) std::is_empty<Type>
#else
# include <type_traits>
# define ENTT_IS_EMPTY(Type) std::false_type
#endif
#ifndef ENTT_STANDARD_CPP
# if defined __clang__ || (defined __GNUC__ && __GNUC__ > 8)
# define ENTT_PRETTY_FUNCTION_CONSTEXPR
# define ENTT_PRETTY_FUNCTION __PRETTY_FUNCTION__
# define ENTT_PRETTY_FUNCTION_PREFIX '='
# define ENTT_PRETTY_FUNCTION_SUFFIX ']'
# elif defined __GNUC__
# define ENTT_PRETTY_FUNCTION __PRETTY_FUNCTION__
# define ENTT_PRETTY_FUNCTION_PREFIX '='
# define ENTT_PRETTY_FUNCTION_SUFFIX ']'
# elif defined _MSC_VER
# define ENTT_PRETTY_FUNCTION_CONSTEXPR
# define ENTT_PRETTY_FUNCTION __FUNCSIG__
# define ENTT_PRETTY_FUNCTION_PREFIX '<'
# define ENTT_PRETTY_FUNCTION_SUFFIX '>'
# endif
#endif
#ifndef ENTT_STANDALONE
# define ENTT_FAST_PATH(...) false
#else
# define ENTT_FAST_PATH(Cond) Cond
#endif
#endif
// #include "../core/fwd.hpp"
#ifndef ENTT_CORE_FWD_HPP
#define ENTT_CORE_FWD_HPP
// #include "../config/config.h"
#ifndef ENTT_CONFIG_CONFIG_H
#define ENTT_CONFIG_CONFIG_H
#ifndef ENTT_NOEXCEPT
# define ENTT_NOEXCEPT noexcept
#endif
#ifndef ENTT_HS_SUFFIX
# define ENTT_HS_SUFFIX _hs
#endif
#ifndef ENTT_HWS_SUFFIX
# define ENTT_HWS_SUFFIX _hws
#endif
#ifndef ENTT_USE_ATOMIC
# define ENTT_MAYBE_ATOMIC(Type) Type
#else
# include <atomic>
# define ENTT_MAYBE_ATOMIC(Type) std::atomic<Type>
#endif
#ifndef ENTT_ID_TYPE
# include <cstdint>
# define ENTT_ID_TYPE std::uint32_t
#endif
#ifndef ENTT_PAGE_SIZE
# define ENTT_PAGE_SIZE 32768
#endif
#ifndef ENTT_ASSERT
# include <cassert>
# define ENTT_ASSERT(condition) assert(condition)
#endif
#ifndef ENTT_NO_ETO
# include <type_traits>
# define ENTT_IS_EMPTY(Type) std::is_empty<Type>
#else
# include <type_traits>
# define ENTT_IS_EMPTY(Type) std::false_type
#endif
#ifndef ENTT_STANDARD_CPP
# if defined __clang__ || (defined __GNUC__ && __GNUC__ > 8)
# define ENTT_PRETTY_FUNCTION_CONSTEXPR
# define ENTT_PRETTY_FUNCTION __PRETTY_FUNCTION__
# define ENTT_PRETTY_FUNCTION_PREFIX '='
# define ENTT_PRETTY_FUNCTION_SUFFIX ']'
# elif defined __GNUC__
# define ENTT_PRETTY_FUNCTION __PRETTY_FUNCTION__
# define ENTT_PRETTY_FUNCTION_PREFIX '='
# define ENTT_PRETTY_FUNCTION_SUFFIX ']'
# elif defined _MSC_VER
# define ENTT_PRETTY_FUNCTION_CONSTEXPR
# define ENTT_PRETTY_FUNCTION __FUNCSIG__
# define ENTT_PRETTY_FUNCTION_PREFIX '<'
# define ENTT_PRETTY_FUNCTION_SUFFIX '>'
# endif
#endif
#ifndef ENTT_STANDALONE
# define ENTT_FAST_PATH(...) false
#else
# define ENTT_FAST_PATH(Cond) Cond
#endif
#endif
namespace entt {
/*! @brief Alias declaration for type identifiers. */
using id_type = ENTT_ID_TYPE;
}
#endif
// #include "handle.hpp"
#ifndef ENTT_RESOURCE_HANDLE_HPP
#define ENTT_RESOURCE_HANDLE_HPP
#include <memory>
#include <utility>
// #include "../config/config.h"
// #include "fwd.hpp"
#ifndef ENTT_RESOURCE_FWD_HPP
#define ENTT_RESOURCE_FWD_HPP
namespace entt {
template<typename>
struct resource_cache;
template<typename>
class resource_handle;
template<typename, typename>
class resource_loader;
}
#endif
namespace entt {
/**
* @brief Shared resource handle.
*
* A shared resource handle is a small class that wraps a resource and keeps it
* alive even if it's deleted from the cache. It can be either copied or
* moved. A handle shares a reference to the same resource with all the other
* handles constructed for the same identifier.<br/>
* As a rule of thumb, resources should never be copied nor moved. Handles are
* the way to go to keep references to them.
*
* @tparam Resource Type of resource managed by a handle.
*/
template<typename Resource>
class resource_handle {
/*! @brief Resource handles are friends of their caches. */
friend struct resource_cache<Resource>;
resource_handle(std::shared_ptr<Resource> res) ENTT_NOEXCEPT
: resource{std::move(res)}
{}
public:
/*! @brief Default constructor. */
resource_handle() ENTT_NOEXCEPT = default;
/**
* @brief Gets a reference to the managed resource.
*
* @warning
* The behavior is undefined if the handle doesn't contain a resource.<br/>
* An assertion will abort the execution at runtime in debug mode if the
* handle is empty.
*
* @return A reference to the managed resource.
*/
[[nodiscard]] const Resource & get() const ENTT_NOEXCEPT {
ENTT_ASSERT(static_cast<bool>(resource));
return *resource;
}
/*! @copydoc get */
[[nodiscard]] Resource & get() ENTT_NOEXCEPT {
return const_cast<Resource &>(std::as_const(*this).get());
}
/*! @copydoc get */
[[nodiscard]] operator const Resource & () const ENTT_NOEXCEPT {
return get();
}
/*! @copydoc get */
[[nodiscard]] operator Resource & () ENTT_NOEXCEPT {
return get();
}
/*! @copydoc get */
[[nodiscard]] const Resource & operator *() const ENTT_NOEXCEPT {
return get();
}
/*! @copydoc get */
[[nodiscard]] Resource & operator *() ENTT_NOEXCEPT {
return get();
}
/**
* @brief Gets a pointer to the managed resource.
*
* @warning
* The behavior is undefined if the handle doesn't contain a resource.<br/>
* An assertion will abort the execution at runtime in debug mode if the
* handle is empty.
*
* @return A pointer to the managed resource or `nullptr` if the handle
* contains no resource at all.
*/
[[nodiscard]] const Resource * operator->() const ENTT_NOEXCEPT {
ENTT_ASSERT(static_cast<bool>(resource));
return resource.get();
}
/*! @copydoc operator-> */
[[nodiscard]] Resource * operator->() ENTT_NOEXCEPT {
return const_cast<Resource *>(std::as_const(*this).operator->());
}
/**
* @brief Returns true if a handle contains a resource, false otherwise.
* @return True if the handle contains a resource, false otherwise.
*/
[[nodiscard]] explicit operator bool() const ENTT_NOEXCEPT {
return static_cast<bool>(resource);
}
private:
std::shared_ptr<Resource> resource;
};
}
#endif
// #include "loader.hpp"
#ifndef ENTT_RESOURCE_LOADER_HPP
#define ENTT_RESOURCE_LOADER_HPP
#include <memory>
// #include "fwd.hpp"
namespace entt {
/**
* @brief Base class for resource loaders.
*
* Resource loaders must inherit from this class and stay true to the CRTP
* idiom. Moreover, a resource loader must expose a public, const member
* function named `load` that accepts a variable number of arguments and returns
* a shared pointer to the resource just created.<br/>
* As an example:
*
* @code{.cpp}
* struct my_resource {};
*
* struct my_loader: entt::resource_loader<my_loader, my_resource> {
* std::shared_ptr<my_resource> load(int) const {
* // use the integer value somehow
* return std::make_shared<my_resource>();
* }
* };
* @endcode
*
* In general, resource loaders should not have a state or retain data of any
* type. They should let the cache manage their resources instead.
*
* @note
* Base class and CRTP idiom aren't strictly required with the current
* implementation. One could argue that a cache can easily work with loaders of
* any type. However, future changes won't be breaking ones by forcing the use
* of a base class today and that's why the model is already in its place.
*
* @tparam Loader Type of the derived class.
* @tparam Resource Type of resource for which to use the loader.
*/
template<typename Loader, typename Resource>
class resource_loader {
/*! @brief Resource loaders are friends of their caches. */
friend struct resource_cache<Resource>;
/**
* @brief Loads the resource and returns it.
* @tparam Args Types of arguments for the loader.
* @param args Arguments for the loader.
* @return The resource just loaded or an empty pointer in case of errors.
*/
template<typename... Args>
[[nodiscard]] std::shared_ptr<Resource> get(Args &&... args) const {
return static_cast<const Loader *>(this)->load(std::forward<Args>(args)...);
}
};
}
#endif
// #include "fwd.hpp"
namespace entt {
/**
* @brief Simple cache for resources of a given type.
*
* Minimal implementation of a cache for resources of a given type. It doesn't
* offer much functionalities but it's suitable for small or medium sized
* applications and can be freely inherited to add targeted functionalities for
* large sized applications.
*
* @tparam Resource Type of resources managed by a cache.
*/
template<typename Resource>
struct resource_cache {
/*! @brief Unsigned integer type. */
using size_type = std::size_t;
/*! @brief Type of resources managed by a cache. */
using resource_type = Resource;
/*! @brief Default constructor. */
resource_cache() = default;
/*! @brief Default move constructor. */
resource_cache(resource_cache &&) = default;
/*! @brief Default move assignment operator. @return This cache. */
resource_cache & operator=(resource_cache &&) = default;
/**
* @brief Number of resources managed by a cache.
* @return Number of resources currently stored.
*/
[[nodiscard]] size_type size() const ENTT_NOEXCEPT {
return resources.size();
}
/**
* @brief Returns true if a cache contains no resources, false otherwise.
* @return True if the cache contains no resources, false otherwise.
*/
[[nodiscard]] bool empty() const ENTT_NOEXCEPT {
return resources.empty();
}
/**
* @brief Clears a cache and discards all its resources.
*
* Handles are not invalidated and the memory used by a resource isn't
* freed as long as at least a handle keeps the resource itself alive.
*/
void clear() ENTT_NOEXCEPT {
resources.clear();
}
/**
* @brief Loads the resource that corresponds to a given identifier.
*
* In case an identifier isn't already present in the cache, it loads its
* resource and stores it aside for future uses. Arguments are forwarded
* directly to the loader in order to construct properly the requested
* resource.
*
* @note
* If the identifier is already present in the cache, this function does
* nothing and the arguments are simply discarded.
*
* @warning
* If the resource cannot be loaded correctly, the returned handle will be
* invalid and any use of it will result in undefined behavior.
*
* @tparam Loader Type of loader to use to load the resource if required.
* @tparam Args Types of arguments to use to load the resource if required.
* @param id Unique resource identifier.
* @param args Arguments to use to load the resource if required.
* @return A handle for the given resource.
*/
template<typename Loader, typename... Args>
resource_handle<Resource> load(const id_type id, Args &&... args) {
static_assert(std::is_base_of_v<resource_loader<Loader, Resource>, Loader>, "Invalid loader type");
resource_handle<Resource> resource{};
if(auto it = resources.find(id); it == resources.cend()) {
if(auto instance = Loader{}.get(std::forward<Args>(args)...); instance) {
resources[id] = instance;
resource = std::move(instance);
}
} else {
resource = it->second;
}
return resource;
}
/**
* @brief Reloads a resource or loads it for the first time if not present.
*
* Equivalent to the following snippet (pseudocode):
*
* @code{.cpp}
* cache.discard(id);
* cache.load(id, args...);
* @endcode
*
* Arguments are forwarded directly to the loader in order to construct
* properly the requested resource.
*
* @warning
* If the resource cannot be loaded correctly, the returned handle will be
* invalid and any use of it will result in undefined behavior.
*
* @tparam Loader Type of loader to use to load the resource.
* @tparam Args Types of arguments to use to load the resource.
* @param id Unique resource identifier.
* @param args Arguments to use to load the resource.
* @return A handle for the given resource.
*/
template<typename Loader, typename... Args>
resource_handle<Resource> reload(const id_type id, Args &&... args) {
return (discard(id), load<Loader>(id, std::forward<Args>(args)...));
}
/**
* @brief Creates a temporary handle for a resource.
*
* Arguments are forwarded directly to the loader in order to construct
* properly the requested resource. The handle isn't stored aside and the
* cache isn't in charge of the lifetime of the resource itself.
*
* @tparam Loader Type of loader to use to load the resource.
* @tparam Args Types of arguments to use to load the resource.
* @param args Arguments to use to load the resource.
* @return A handle for the given resource.
*/
template<typename Loader, typename... Args>
[[nodiscard]] resource_handle<Resource> temp(Args &&... args) const {
return { Loader{}.get(std::forward<Args>(args)...) };
}
/**
* @brief Creates a handle for a given resource identifier.
*
* A resource handle can be in a either valid or invalid state. In other
* terms, a resource handle is properly initialized with a resource if the
* cache contains the resource itself. Otherwise the returned handle is
* uninitialized and accessing it results in undefined behavior.
*
* @sa resource_handle
*
* @param id Unique resource identifier.
* @return A handle for the given resource.
*/
[[nodiscard]] resource_handle<Resource> handle(const id_type id) const {
auto it = resources.find(id);
return { it == resources.end() ? nullptr : it->second };
}
/**
* @brief Checks if a cache contains a given identifier.
* @param id Unique resource identifier.
* @return True if the cache contains the resource, false otherwise.
*/
[[nodiscard]] bool contains(const id_type id) const {
return (resources.find(id) != resources.cend());
}
/**
* @brief Discards the resource that corresponds to a given identifier.
*
* Handles are not invalidated and the memory used by the resource isn't
* freed as long as at least a handle keeps the resource itself alive.
*
* @param id Unique resource identifier.
*/
void discard(const id_type id) {
if(auto it = resources.find(id); it != resources.end()) {
resources.erase(it);
}
}
/**
* @brief Iterates all resources.
*
* The function object is invoked for each element. It is provided with
* either the resource identifier, the resource handle or both of them.<br/>
* The signature of the function must be equivalent to one of the following
* forms:
*
* @code{.cpp}
* void(const entt::id_type);
* void(entt::resource_handle<Resource>);
* void(const entt::id_type, entt::resource_handle<Resource>);
* @endcode
*
* @tparam Func Type of the function object to invoke.
* @param func A valid function object.
*/
template <typename Func>
void each(Func func) const {
auto begin = resources.begin();
auto end = resources.end();
while(begin != end) {
auto curr = begin++;
if constexpr(std::is_invocable_v<Func, id_type>) {
func(curr->first);
} else if constexpr(std::is_invocable_v<Func, resource_handle<Resource>>) {
func(resource_handle{ curr->second });
} else {
func(curr->first, resource_handle{ curr->second });
}
}
}
private:
std::unordered_map<id_type, std::shared_ptr<Resource>> resources;
};
}
#endif
// #include "resource/handle.hpp"
// #include "resource/loader.hpp"
// #include "signal/delegate.hpp"
#ifndef ENTT_SIGNAL_DELEGATE_HPP
#define ENTT_SIGNAL_DELEGATE_HPP
#include <tuple>
#include <cstddef>
#include <utility>
#include <functional>
#include <type_traits>
// #include "../config/config.h"
#ifndef ENTT_CONFIG_CONFIG_H
#define ENTT_CONFIG_CONFIG_H
#ifndef ENTT_NOEXCEPT
# define ENTT_NOEXCEPT noexcept
#endif
#ifndef ENTT_HS_SUFFIX
# define ENTT_HS_SUFFIX _hs
#endif
#ifndef ENTT_HWS_SUFFIX
# define ENTT_HWS_SUFFIX _hws
#endif
#ifndef ENTT_USE_ATOMIC
# define ENTT_MAYBE_ATOMIC(Type) Type
#else
# include <atomic>
# define ENTT_MAYBE_ATOMIC(Type) std::atomic<Type>
#endif
#ifndef ENTT_ID_TYPE
# include <cstdint>
# define ENTT_ID_TYPE std::uint32_t
#endif
#ifndef ENTT_PAGE_SIZE
# define ENTT_PAGE_SIZE 32768
#endif
#ifndef ENTT_ASSERT
# include <cassert>
# define ENTT_ASSERT(condition) assert(condition)
#endif
#ifndef ENTT_NO_ETO
# include <type_traits>
# define ENTT_IS_EMPTY(Type) std::is_empty<Type>
#else
# include <type_traits>
# define ENTT_IS_EMPTY(Type) std::false_type
#endif
#ifndef ENTT_STANDARD_CPP
# if defined __clang__ || (defined __GNUC__ && __GNUC__ > 8)
# define ENTT_PRETTY_FUNCTION_CONSTEXPR
# define ENTT_PRETTY_FUNCTION __PRETTY_FUNCTION__
# define ENTT_PRETTY_FUNCTION_PREFIX '='
# define ENTT_PRETTY_FUNCTION_SUFFIX ']'
# elif defined __GNUC__
# define ENTT_PRETTY_FUNCTION __PRETTY_FUNCTION__
# define ENTT_PRETTY_FUNCTION_PREFIX '='
# define ENTT_PRETTY_FUNCTION_SUFFIX ']'
# elif defined _MSC_VER
# define ENTT_PRETTY_FUNCTION_CONSTEXPR
# define ENTT_PRETTY_FUNCTION __FUNCSIG__
# define ENTT_PRETTY_FUNCTION_PREFIX '<'
# define ENTT_PRETTY_FUNCTION_SUFFIX '>'
# endif
#endif
#ifndef ENTT_STANDALONE
# define ENTT_FAST_PATH(...) false
#else
# define ENTT_FAST_PATH(Cond) Cond
#endif
#endif
namespace entt {
/**
* @cond TURN_OFF_DOXYGEN
* Internal details not to be documented.
*/
namespace internal {
template<typename Ret, typename... Args>
auto function_pointer(Ret(*)(Args...)) -> Ret(*)(Args...);
template<typename Ret, typename Type, typename... Args, typename Other>
auto function_pointer(Ret(*)(Type, Args...), Other &&) -> Ret(*)(Args...);
template<typename Class, typename Ret, typename... Args, typename... Other>
auto function_pointer(Ret(Class:: *)(Args...), Other &&...) -> Ret(*)(Args...);
template<typename Class, typename Ret, typename... Args, typename... Other>
auto function_pointer(Ret(Class:: *)(Args...) const, Other &&...) -> Ret(*)(Args...);
template<typename Class, typename Type, typename... Other>
auto function_pointer(Type Class:: *, Other &&...) -> Type(*)();
template<typename... Type>
using function_pointer_t = decltype(internal::function_pointer(std::declval<Type>()...));
template<typename... Class, typename Ret, typename... Args>
[[nodiscard]] constexpr auto index_sequence_for(Ret(*)(Args...)) {
return std::index_sequence_for<Class..., Args...>{};
}
}
/**
* Internal details not to be documented.
* @endcond
*/
/*! @brief Used to wrap a function or a member of a specified type. */
template<auto>
struct connect_arg_t {};
/*! @brief Constant of type connect_arg_t used to disambiguate calls. */
template<auto Func>
inline constexpr connect_arg_t<Func> connect_arg{};
/**
* @brief Basic delegate implementation.
*
* Primary template isn't defined on purpose. All the specializations give a
* compile-time error unless the template parameter is a function type.
*/
template<typename>
class delegate;
/**
* @brief Utility class to use to send around functions and members.
*
* Unmanaged delegate for function pointers and members. Users of this class are
* in charge of disconnecting instances before deleting them.
*
* A delegate can be used as a general purpose invoker without memory overhead
* for free functions possibly with payloads and bound or unbound members.
*
* @tparam Ret Return type of a function type.
* @tparam Args Types of arguments of a function type.
*/
template<typename Ret, typename... Args>
class delegate<Ret(Args...)> {
template<auto Candidate, std::size_t... Index>
[[nodiscard]] auto wrap(std::index_sequence<Index...>) ENTT_NOEXCEPT {
return [](const void *, Args... args) -> Ret {
[[maybe_unused]] const auto arguments = std::forward_as_tuple(std::forward<Args>(args)...);
return Ret(std::invoke(Candidate, std::forward<std::tuple_element_t<Index, std::tuple<Args...>>>(std::get<Index>(arguments))...));
};
}
template<auto Candidate, typename Type, std::size_t... Index>
[[nodiscard]] auto wrap(Type &, std::index_sequence<Index...>) ENTT_NOEXCEPT {
return [](const void *payload, Args... args) -> Ret {
[[maybe_unused]] const auto arguments = std::forward_as_tuple(std::forward<Args>(args)...);
Type *curr = static_cast<Type *>(const_cast<std::conditional_t<std::is_const_v<Type>, const void *, void *>>(payload));
return Ret(std::invoke(Candidate, *curr, std::forward<std::tuple_element_t<Index, std::tuple<Args...>>>(std::get<Index>(arguments))...));
};
}
template<auto Candidate, typename Type, std::size_t... Index>
[[nodiscard]] auto wrap(Type *, std::index_sequence<Index...>) ENTT_NOEXCEPT {
return [](const void *payload, Args... args) -> Ret {
[[maybe_unused]] const auto arguments = std::forward_as_tuple(std::forward<Args>(args)...);
Type *curr = static_cast<Type *>(const_cast<std::conditional_t<std::is_const_v<Type>, const void *, void *>>(payload));
return Ret(std::invoke(Candidate, curr, std::forward<std::tuple_element_t<Index, std::tuple<Args...>>>(std::get<Index>(arguments))...));
};
}
public:
/*! @brief Function type of the contained target. */
using function_type = Ret(const void *, Args...);
/*! @brief Function type of the delegate. */
using type = Ret(Args...);
/*! @brief Return type of the delegate. */
using result_type = Ret;
/*! @brief Default constructor. */
delegate() ENTT_NOEXCEPT
: fn{nullptr}, data{nullptr}
{}
/**
* @brief Constructs a delegate and connects a free function or an unbound
* member.
* @tparam Candidate Function or member to connect to the delegate.
*/
template<auto Candidate>
delegate(connect_arg_t<Candidate>) ENTT_NOEXCEPT {
connect<Candidate>();
}
/**
* @brief Constructs a delegate and connects a free function with payload or
* a bound member.
* @tparam Candidate Function or member to connect to the delegate.
* @tparam Type Type of class or type of payload.
* @param value_or_instance A valid object that fits the purpose.
*/
template<auto Candidate, typename Type>
delegate(connect_arg_t<Candidate>, Type &&value_or_instance) ENTT_NOEXCEPT {
connect<Candidate>(std::forward<Type>(value_or_instance));
}
/**
* @brief Constructs a delegate and connects an user defined function with
* optional payload.
* @param function Function to connect to the delegate.
* @param payload User defined arbitrary data.
*/
delegate(function_type *function, const void *payload = nullptr) ENTT_NOEXCEPT {
connect(function, payload);
}
/**
* @brief Connects a free function or an unbound member to a delegate.
* @tparam Candidate Function or member to connect to the delegate.
*/
template<auto Candidate>
void connect() ENTT_NOEXCEPT {
data = nullptr;
if constexpr(std::is_invocable_r_v<Ret, decltype(Candidate), Args...>) {
fn = [](const void *, Args... args) -> Ret {
return Ret(std::invoke(Candidate, std::forward<Args>(args)...));
};
} else if constexpr(std::is_member_pointer_v<decltype(Candidate)>) {
fn = wrap<Candidate>(internal::index_sequence_for<std::tuple_element_t<0, std::tuple<Args...>>>(internal::function_pointer_t<decltype(Candidate)>{}));
} else {
fn = wrap<Candidate>(internal::index_sequence_for(internal::function_pointer_t<decltype(Candidate)>{}));
}
}
/**
* @brief Connects a free function with payload or a bound member to a
* delegate.
*
* The delegate isn't responsible for the connected object or the payload.
* Users must always guarantee that the lifetime of the instance overcomes
* the one of the delegate.<br/>
* When used to connect a free function with payload, its signature must be
* such that the instance is the first argument before the ones used to
* define the delegate itself.
*
* @tparam Candidate Function or member to connect to the delegate.
* @tparam Type Type of class or type of payload.
* @param value_or_instance A valid reference that fits the purpose.
*/
template<auto Candidate, typename Type>
void connect(Type &value_or_instance) ENTT_NOEXCEPT {
data = &value_or_instance;
if constexpr(std::is_invocable_r_v<Ret, decltype(Candidate), Type &, Args...>) {
fn = [](const void *payload, Args... args) -> Ret {
Type *curr = static_cast<Type *>(const_cast<std::conditional_t<std::is_const_v<Type>, const void *, void *>>(payload));
return Ret(std::invoke(Candidate, *curr, std::forward<Args>(args)...));
};
} else {
fn = wrap<Candidate>(value_or_instance, internal::index_sequence_for(internal::function_pointer_t<decltype(Candidate), Type>{}));
}
}
/**
* @brief Connects a free function with payload or a bound member to a
* delegate.
*
* @sa connect(Type &)
*
* @tparam Candidate Function or member to connect to the delegate.
* @tparam Type Type of class or type of payload.
* @param value_or_instance A valid pointer that fits the purpose.
*/
template<auto Candidate, typename Type>
void connect(Type *value_or_instance) ENTT_NOEXCEPT {
data = value_or_instance;
if constexpr(std::is_invocable_r_v<Ret, decltype(Candidate), Type *, Args...>) {
fn = [](const void *payload, Args... args) -> Ret {
Type *curr = static_cast<Type *>(const_cast<std::conditional_t<std::is_const_v<Type>, const void *, void *>>(payload));
return Ret(std::invoke(Candidate, curr, std::forward<Args>(args)...));
};
} else {
fn = wrap<Candidate>(value_or_instance, internal::index_sequence_for(internal::function_pointer_t<decltype(Candidate), Type>{}));
}
}
/**
* @brief Connects an user defined function with optional payload to a
* delegate.
*
* The delegate isn't responsible for the connected object or the payload.
* Users must always guarantee that the lifetime of an instance overcomes
* the one of the delegate.<br/>
* The payload is returned as the first argument to the target function in
* all cases.
*
* @param function Function to connect to the delegate.
* @param payload User defined arbitrary data.
*/
void connect(function_type *function, const void *payload = nullptr) ENTT_NOEXCEPT {
fn = function;
data = payload;
}
/**
* @brief Resets a delegate.
*
* After a reset, a delegate cannot be invoked anymore.
*/
void reset() ENTT_NOEXCEPT {
fn = nullptr;
data = nullptr;
}
/**
* @brief Returns the instance or the payload linked to a delegate, if any.
* @return An opaque pointer to the underlying data.
*/
[[nodiscard]] const void * instance() const ENTT_NOEXCEPT {
return data;
}
/**
* @brief Triggers a delegate.
*
* The delegate invokes the underlying function and returns the result.
*
* @warning
* Attempting to trigger an invalid delegate results in undefined
* behavior.<br/>
* An assertion will abort the execution at runtime in debug mode if the
* delegate has not yet been set.
*
* @param args Arguments to use to invoke the underlying function.
* @return The value returned by the underlying function.
*/
Ret operator()(Args... args) const {
ENTT_ASSERT(fn);
return fn(data, std::forward<Args>(args)...);
}
/**
* @brief Checks whether a delegate actually stores a listener.
* @return False if the delegate is empty, true otherwise.
*/
[[nodiscard]] explicit operator bool() const ENTT_NOEXCEPT {
// no need to test also data
return !(fn == nullptr);
}
/**
* @brief Compares the contents of two delegates.
* @param other Delegate with which to compare.
* @return False if the two contents differ, true otherwise.
*/
[[nodiscard]] bool operator==(const delegate<Ret(Args...)> &other) const ENTT_NOEXCEPT {
return fn == other.fn && data == other.data;
}
private:
function_type *fn;
const void *data;
};
/**
* @brief Compares the contents of two delegates.
* @tparam Ret Return type of a function type.
* @tparam Args Types of arguments of a function type.
* @param lhs A valid delegate object.
* @param rhs A valid delegate object.
* @return True if the two contents differ, false otherwise.
*/
template<typename Ret, typename... Args>
[[nodiscard]] bool operator!=(const delegate<Ret(Args...)> &lhs, const delegate<Ret(Args...)> &rhs) ENTT_NOEXCEPT {
return !(lhs == rhs);
}
/**
* @brief Deduction guide.
* @tparam Candidate Function or member to connect to the delegate.
*/
template<auto Candidate>
delegate(connect_arg_t<Candidate>) ENTT_NOEXCEPT
-> delegate<std::remove_pointer_t<internal::function_pointer_t<decltype(Candidate)>>>;
/**
* @brief Deduction guide.
* @tparam Candidate Function or member to connect to the delegate.
* @tparam Type Type of class or type of payload.
*/
template<auto Candidate, typename Type>
delegate(connect_arg_t<Candidate>, Type &&) ENTT_NOEXCEPT
-> delegate<std::remove_pointer_t<internal::function_pointer_t<decltype(Candidate), Type>>>;
/*! @brief Deduction guide. */
template<typename Ret, typename... Args>
delegate(Ret(*)(const void *, Args...), const void * = nullptr) ENTT_NOEXCEPT
-> delegate<Ret(Args...)>;
}
#endif
// #include "signal/dispatcher.hpp"
#ifndef ENTT_SIGNAL_DISPATCHER_HPP
#define ENTT_SIGNAL_DISPATCHER_HPP
#include <cstddef>
#include <memory>
#include <type_traits>
#include <utility>
#include <vector>
// #include "../config/config.h"
// #include "../core/fwd.hpp"
#ifndef ENTT_CORE_FWD_HPP
#define ENTT_CORE_FWD_HPP
// #include "../config/config.h"
#ifndef ENTT_CONFIG_CONFIG_H
#define ENTT_CONFIG_CONFIG_H
#ifndef ENTT_NOEXCEPT
# define ENTT_NOEXCEPT noexcept
#endif
#ifndef ENTT_HS_SUFFIX
# define ENTT_HS_SUFFIX _hs
#endif
#ifndef ENTT_HWS_SUFFIX
# define ENTT_HWS_SUFFIX _hws
#endif
#ifndef ENTT_USE_ATOMIC
# define ENTT_MAYBE_ATOMIC(Type) Type
#else
# include <atomic>
# define ENTT_MAYBE_ATOMIC(Type) std::atomic<Type>
#endif
#ifndef ENTT_ID_TYPE
# include <cstdint>
# define ENTT_ID_TYPE std::uint32_t
#endif
#ifndef ENTT_PAGE_SIZE
# define ENTT_PAGE_SIZE 32768
#endif
#ifndef ENTT_ASSERT
# include <cassert>
# define ENTT_ASSERT(condition) assert(condition)
#endif
#ifndef ENTT_NO_ETO
# include <type_traits>
# define ENTT_IS_EMPTY(Type) std::is_empty<Type>
#else
# include <type_traits>
# define ENTT_IS_EMPTY(Type) std::false_type
#endif
#ifndef ENTT_STANDARD_CPP
# if defined __clang__ || (defined __GNUC__ && __GNUC__ > 8)
# define ENTT_PRETTY_FUNCTION_CONSTEXPR
# define ENTT_PRETTY_FUNCTION __PRETTY_FUNCTION__
# define ENTT_PRETTY_FUNCTION_PREFIX '='
# define ENTT_PRETTY_FUNCTION_SUFFIX ']'
# elif defined __GNUC__
# define ENTT_PRETTY_FUNCTION __PRETTY_FUNCTION__
# define ENTT_PRETTY_FUNCTION_PREFIX '='
# define ENTT_PRETTY_FUNCTION_SUFFIX ']'
# elif defined _MSC_VER
# define ENTT_PRETTY_FUNCTION_CONSTEXPR
# define ENTT_PRETTY_FUNCTION __FUNCSIG__
# define ENTT_PRETTY_FUNCTION_PREFIX '<'
# define ENTT_PRETTY_FUNCTION_SUFFIX '>'
# endif
#endif
#ifndef ENTT_STANDALONE
# define ENTT_FAST_PATH(...) false
#else
# define ENTT_FAST_PATH(Cond) Cond
#endif
#endif
namespace entt {
/*! @brief Alias declaration for type identifiers. */
using id_type = ENTT_ID_TYPE;
}
#endif
// #include "../core/type_info.hpp"
#ifndef ENTT_CORE_TYPE_INFO_HPP
#define ENTT_CORE_TYPE_INFO_HPP
#include <string_view>
// #include "../config/config.h"
// #include "../core/attribute.h"
#ifndef ENTT_CORE_ATTRIBUTE_H
#define ENTT_CORE_ATTRIBUTE_H
#ifndef ENTT_EXPORT
# if defined _WIN32 || defined __CYGWIN__ || defined _MSC_VER
# define ENTT_EXPORT __declspec(dllexport)
# define ENTT_IMPORT __declspec(dllimport)
# define ENTT_HIDDEN
# elif defined __GNUC__ && __GNUC__ >= 4
# define ENTT_EXPORT __attribute__((visibility("default")))
# define ENTT_IMPORT __attribute__((visibility("default")))
# define ENTT_HIDDEN __attribute__((visibility("hidden")))
# else /* Unsupported compiler */
# define ENTT_EXPORT
# define ENTT_IMPORT
# define ENTT_HIDDEN
# endif
#endif
#ifndef ENTT_API
# if defined ENTT_API_EXPORT
# define ENTT_API ENTT_EXPORT
# elif defined ENTT_API_IMPORT
# define ENTT_API ENTT_IMPORT
# else /* No API */
# define ENTT_API
# endif
#endif
#endif
// #include "hashed_string.hpp"
#ifndef ENTT_CORE_HASHED_STRING_HPP
#define ENTT_CORE_HASHED_STRING_HPP
#include <cstddef>
#include <cstdint>
// #include "../config/config.h"
// #include "fwd.hpp"
namespace entt {
/**
* @cond TURN_OFF_DOXYGEN
* Internal details not to be documented.
*/
namespace internal {
template<typename>
struct fnv1a_traits;
template<>
struct fnv1a_traits<std::uint32_t> {
using type = std::uint32_t;
static constexpr std::uint32_t offset = 2166136261;
static constexpr std::uint32_t prime = 16777619;
};
template<>
struct fnv1a_traits<std::uint64_t> {
using type = std::uint64_t;
static constexpr std::uint64_t offset = 14695981039346656037ull;
static constexpr std::uint64_t prime = 1099511628211ull;
};
}
/**
* Internal details not to be documented.
* @endcond
*/
/**
* @brief Zero overhead unique identifier.
*
* A hashed string is a compile-time tool that allows users to use
* human-readable identifers in the codebase while using their numeric
* counterparts at runtime.<br/>
* Because of that, a hashed string can also be used in constant expressions if
* required.
*
* @tparam Char Character type.
*/
template<typename Char>
class basic_hashed_string {
using traits_type = internal::fnv1a_traits<id_type>;
struct const_wrapper {
// non-explicit constructor on purpose
constexpr const_wrapper(const Char *curr) ENTT_NOEXCEPT: str{curr} {}
const Char *str;
};
// FowlerNollVo hash function v. 1a - the good
[[nodiscard]] static constexpr id_type helper(const Char *curr) ENTT_NOEXCEPT {
auto value = traits_type::offset;
while(*curr != 0) {
value = (value ^ static_cast<traits_type::type>(*(curr++))) * traits_type::prime;
}
return value;
}
public:
/*! @brief Character type. */
using value_type = Char;
/*! @brief Unsigned integer type. */
using hash_type = id_type;
/**
* @brief Returns directly the numeric representation of a string.
*
* Forcing template resolution avoids implicit conversions. An
* human-readable identifier can be anything but a plain, old bunch of
* characters.<br/>
* Example of use:
* @code{.cpp}
* const auto value = basic_hashed_string<char>::to_value("my.png");
* @endcode
*
* @tparam N Number of characters of the identifier.
* @param str Human-readable identifer.
* @return The numeric representation of the string.
*/
template<std::size_t N>
[[nodiscard]] static constexpr hash_type value(const value_type (&str)[N]) ENTT_NOEXCEPT {
return helper(str);
}
/**
* @brief Returns directly the numeric representation of a string.
* @param wrapper Helps achieving the purpose by relying on overloading.
* @return The numeric representation of the string.
*/
[[nodiscard]] static hash_type value(const_wrapper wrapper) ENTT_NOEXCEPT {
return helper(wrapper.str);
}
/**
* @brief Returns directly the numeric representation of a string view.
* @param str Human-readable identifer.
* @param size Length of the string to hash.
* @return The numeric representation of the string.
*/
[[nodiscard]] static hash_type value(const value_type *str, std::size_t size) ENTT_NOEXCEPT {
id_type partial{traits_type::offset};
while(size--) { partial = (partial^(str++)[0])*traits_type::prime; }
return partial;
}
/*! @brief Constructs an empty hashed string. */
constexpr basic_hashed_string() ENTT_NOEXCEPT
: str{nullptr}, hash{}
{}
/**
* @brief Constructs a hashed string from an array of const characters.
*
* Forcing template resolution avoids implicit conversions. An
* human-readable identifier can be anything but a plain, old bunch of
* characters.<br/>
* Example of use:
* @code{.cpp}
* basic_hashed_string<char> hs{"my.png"};
* @endcode
*
* @tparam N Number of characters of the identifier.
* @param curr Human-readable identifer.
*/
template<std::size_t N>
constexpr basic_hashed_string(const value_type (&curr)[N]) ENTT_NOEXCEPT
: str{curr}, hash{helper(curr)}
{}
/**
* @brief Explicit constructor on purpose to avoid constructing a hashed
* string directly from a `const value_type *`.
* @param wrapper Helps achieving the purpose by relying on overloading.
*/
explicit constexpr basic_hashed_string(const_wrapper wrapper) ENTT_NOEXCEPT
: str{wrapper.str}, hash{helper(wrapper.str)}
{}
/**
* @brief Returns the human-readable representation of a hashed string.
* @return The string used to initialize the instance.
*/
[[nodiscard]] constexpr const value_type * data() const ENTT_NOEXCEPT {
return str;
}
/**
* @brief Returns the numeric representation of a hashed string.
* @return The numeric representation of the instance.
*/
[[nodiscard]] constexpr hash_type value() const ENTT_NOEXCEPT {
return hash;
}
/*! @copydoc data */
[[nodiscard]] constexpr operator const value_type *() const ENTT_NOEXCEPT { return data(); }
/**
* @brief Returns the numeric representation of a hashed string.
* @return The numeric representation of the instance.
*/
[[nodiscard]] constexpr operator hash_type() const ENTT_NOEXCEPT { return value(); }
/**
* @brief Compares two hashed strings.
* @param other Hashed string with which to compare.
* @return True if the two hashed strings are identical, false otherwise.
*/
[[nodiscard]] constexpr bool operator==(const basic_hashed_string &other) const ENTT_NOEXCEPT {
return hash == other.hash;
}
private:
const value_type *str;
hash_type hash;
};
/**
* @brief Deduction guide.
*
* It allows to deduce the character type of the hashed string directly from a
* human-readable identifer provided to the constructor.
*
* @tparam Char Character type.
* @tparam N Number of characters of the identifier.
* @param str Human-readable identifer.
*/
template<typename Char, std::size_t N>
basic_hashed_string(const Char (&str)[N]) ENTT_NOEXCEPT
-> basic_hashed_string<Char>;
/**
* @brief Compares two hashed strings.
* @tparam Char Character type.
* @param lhs A valid hashed string.
* @param rhs A valid hashed string.
* @return True if the two hashed strings are identical, false otherwise.
*/
template<typename Char>
[[nodiscard]] constexpr bool operator!=(const basic_hashed_string<Char> &lhs, const basic_hashed_string<Char> &rhs) ENTT_NOEXCEPT {
return !(lhs == rhs);
}
/*! @brief Aliases for common character types. */
using hashed_string = basic_hashed_string<char>;
/*! @brief Aliases for common character types. */
using hashed_wstring = basic_hashed_string<wchar_t>;
}
/**
* @brief User defined literal for hashed strings.
* @param str The literal without its suffix.
* @return A properly initialized hashed string.
*/
[[nodiscard]] constexpr entt::hashed_string operator"" ENTT_HS_SUFFIX(const char *str, std::size_t) ENTT_NOEXCEPT {
return entt::hashed_string{str};
}
/**
* @brief User defined literal for hashed wstrings.
* @param str The literal without its suffix.
* @return A properly initialized hashed wstring.
*/
[[nodiscard]] constexpr entt::hashed_wstring operator"" ENTT_HWS_SUFFIX(const wchar_t *str, std::size_t) ENTT_NOEXCEPT {
return entt::hashed_wstring{str};
}
#endif
// #include "fwd.hpp"
namespace entt {
/**
* @cond TURN_OFF_DOXYGEN
* Internal details not to be documented.
*/
namespace internal {
struct ENTT_API type_index {
[[nodiscard]] static id_type next() ENTT_NOEXCEPT {
static ENTT_MAYBE_ATOMIC(id_type) value{};
return value++;
}
};
template<typename Type>
[[nodiscard]] constexpr auto type_name() ENTT_NOEXCEPT {
#if defined ENTT_PRETTY_FUNCTION
std::string_view pretty_function{ENTT_PRETTY_FUNCTION};
auto first = pretty_function.find_first_not_of(' ', pretty_function.find_first_of(ENTT_PRETTY_FUNCTION_PREFIX)+1);
auto value = pretty_function.substr(first, pretty_function.find_last_of(ENTT_PRETTY_FUNCTION_SUFFIX) - first);
return value;
#else
return std::string_view{};
#endif
}
}
/**
* Internal details not to be documented.
* @endcond
*/
/**
* @brief Type index.
* @tparam Type Type for which to generate a sequential identifier.
*/
template<typename Type, typename = void>
struct ENTT_API type_index {
/**
* @brief Returns the sequential identifier of a given type.
* @return The sequential identifier of a given type.
*/
[[nodiscard]] static id_type value() ENTT_NOEXCEPT {
static const id_type value = internal::type_index::next();
return value;
}
};
/**
* @brief Provides the member constant `value` to true if a given type is
* indexable, false otherwise.
* @tparam Type Potentially indexable type.
*/
template<typename, typename = void>
struct has_type_index: std::false_type {};
/*! @brief has_type_index */
template<typename Type>
struct has_type_index<Type, std::void_t<decltype(type_index<Type>::value())>>: std::true_type {};
/**
* @brief Helper variable template.
* @tparam Type Potentially indexable type.
*/
template<typename Type>
inline constexpr bool has_type_index_v = has_type_index<Type>::value;
/**
* @brief Type info.
* @tparam Type Type for which to generate information.
*/
template<typename Type, typename = void>
struct type_info {
/**
* @brief Returns the numeric representation of a given type.
* @return The numeric representation of the given type.
*/
#if defined ENTT_PRETTY_FUNCTION_CONSTEXPR
[[nodiscard]] static constexpr id_type id() ENTT_NOEXCEPT {
constexpr auto value = hashed_string::value(ENTT_PRETTY_FUNCTION);
return value;
}
#elif defined ENTT_PRETTY_FUNCTION
[[nodiscard]] static id_type id() ENTT_NOEXCEPT {
static const auto value = hashed_string::value(ENTT_PRETTY_FUNCTION);
return value;
}
#else
[[nodiscard]] static id_type id() ENTT_NOEXCEPT {
return type_index<Type>::value();
}
#endif
/**
* @brief Returns the name of a given type.
* @return The name of the given type.
*/
#if defined ENTT_PRETTY_FUNCTION_CONSTEXPR
[[nodiscard]] static constexpr std::string_view name() ENTT_NOEXCEPT {
constexpr auto value = internal::type_name<Type>();
return value;
}
#elif defined ENTT_PRETTY_FUNCTION
[[nodiscard]] static std::string_view name() ENTT_NOEXCEPT {
static const auto value = internal::type_name<Type>();
return value;
}
#else
[[nodiscard]] static constexpr std::string_view name() ENTT_NOEXCEPT {
return internal::type_name<Type>();
}
#endif
};
}
#endif
// #include "sigh.hpp"
#ifndef ENTT_SIGNAL_SIGH_HPP
#define ENTT_SIGNAL_SIGH_HPP
#include <vector>
#include <utility>
#include <iterator>
#include <algorithm>
#include <functional>
#include <type_traits>
// #include "../config/config.h"
// #include "delegate.hpp"
// #include "fwd.hpp"
#ifndef ENTT_SIGNAL_FWD_HPP
#define ENTT_SIGNAL_FWD_HPP
namespace entt {
template<typename>
class delegate;
class dispatcher;
template<typename>
class emitter;
class connection;
struct scoped_connection;
template<typename>
class sink;
template<typename>
class sigh;
}
#endif
namespace entt {
/**
* @brief Sink class.
*
* Primary template isn't defined on purpose. All the specializations give a
* compile-time error unless the template parameter is a function type.
*
* @tparam Function A valid function type.
*/
template<typename Function>
class sink;
/**
* @brief Unmanaged signal handler.
*
* Primary template isn't defined on purpose. All the specializations give a
* compile-time error unless the template parameter is a function type.
*
* @tparam Function A valid function type.
*/
template<typename Function>
class sigh;
/**
* @brief Unmanaged signal handler.
*
* It works directly with references to classes and pointers to member functions
* as well as pointers to free functions. Users of this class are in charge of
* disconnecting instances before deleting them.
*
* This class serves mainly two purposes:
*
* * Creating signals to use later to notify a bunch of listeners.
* * Collecting results from a set of functions like in a voting system.
*
* @tparam Ret Return type of a function type.
* @tparam Args Types of arguments of a function type.
*/
template<typename Ret, typename... Args>
class sigh<Ret(Args...)> {
/*! @brief A sink is allowed to modify a signal. */
friend class sink<Ret(Args...)>;
public:
/*! @brief Unsigned integer type. */
using size_type = std::size_t;
/*! @brief Sink type. */
using sink_type = sink<Ret(Args...)>;
/**
* @brief Instance type when it comes to connecting member functions.
* @tparam Class Type of class to which the member function belongs.
*/
template<typename Class>
using instance_type = Class *;
/**
* @brief Number of listeners connected to the signal.
* @return Number of listeners currently connected.
*/
[[nodiscard]] size_type size() const ENTT_NOEXCEPT {
return calls.size();
}
/**
* @brief Returns false if at least a listener is connected to the signal.
* @return True if the signal has no listeners connected, false otherwise.
*/
[[nodiscard]] bool empty() const ENTT_NOEXCEPT {
return calls.empty();
}
/**
* @brief Triggers a signal.
*
* All the listeners are notified. Order isn't guaranteed.
*
* @param args Arguments to use to invoke listeners.
*/
void publish(Args... args) const {
for(auto &&call: std::as_const(calls)) {
call(args...);
}
}
/**
* @brief Collects return values from the listeners.
*
* The collector must expose a call operator with the following properties:
*
* * The return type is either `void` or such that it's convertible to
* `bool`. In the second case, a true value will stop the iteration.
* * The list of parameters is empty if `Ret` is `void`, otherwise it
* contains a single element such that `Ret` is convertible to it.
*
* @tparam Func Type of collector to use, if any.
* @param func A valid function object.
* @param args Arguments to use to invoke listeners.
*/
template<typename Func>
void collect(Func func, Args... args) const {
for(auto &&call: calls) {
if constexpr(std::is_void_v<Ret>) {
if constexpr(std::is_invocable_r_v<bool, Func>) {
call(args...);
if(func()) { break; }
} else {
call(args...);
func();
}
} else {
if constexpr(std::is_invocable_r_v<bool, Func, Ret>) {
if(func(call(args...))) { break; }
} else {
func(call(args...));
}
}
}
}
private:
std::vector<delegate<Ret(Args...)>> calls;
};
/**
* @brief Connection class.
*
* Opaque object the aim of which is to allow users to release an already
* estabilished connection without having to keep a reference to the signal or
* the sink that generated it.
*/
class connection {
/*! @brief A sink is allowed to create connection objects. */
template<typename>
friend class sink;
connection(delegate<void(void *)> fn, void *ref)
: disconnect{fn}, signal{ref}
{}
public:
/*! @brief Default constructor. */
connection() = default;
/**
* @brief Checks whether a connection is properly initialized.
* @return True if the connection is properly initialized, false otherwise.
*/
[[nodiscard]] explicit operator bool() const ENTT_NOEXCEPT {
return static_cast<bool>(disconnect);
}
/*! @brief Breaks the connection. */
void release() {
if(disconnect) {
disconnect(signal);
disconnect.reset();
}
}
private:
delegate<void(void *)> disconnect;
void *signal{};
};
/**
* @brief Scoped connection class.
*
* Opaque object the aim of which is to allow users to release an already
* estabilished connection without having to keep a reference to the signal or
* the sink that generated it.<br/>
* A scoped connection automatically breaks the link between the two objects
* when it goes out of scope.
*/
struct scoped_connection {
/*! @brief Default constructor. */
scoped_connection() = default;
/**
* @brief Constructs a scoped connection from a basic connection.
* @param other A valid connection object.
*/
scoped_connection(const connection &other)
: conn{other}
{}
/*! @brief Default copy constructor, deleted on purpose. */
scoped_connection(const scoped_connection &) = delete;
/*! @brief Automatically breaks the link on destruction. */
~scoped_connection() {
conn.release();
}
/**
* @brief Default copy assignment operator, deleted on purpose.
* @return This scoped connection.
*/
scoped_connection & operator=(const scoped_connection &) = delete;
/**
* @brief Acquires a connection.
* @param other The connection object to acquire.
* @return This scoped connection.
*/
scoped_connection & operator=(connection other) {
conn = std::move(other);
return *this;
}
/**
* @brief Checks whether a scoped connection is properly initialized.
* @return True if the connection is properly initialized, false otherwise.
*/
[[nodiscard]] explicit operator bool() const ENTT_NOEXCEPT {
return static_cast<bool>(conn);
}
/*! @brief Breaks the connection. */
void release() {
conn.release();
}
private:
connection conn;
};
/**
* @brief Sink class.
*
* A sink is used to connect listeners to signals and to disconnect them.<br/>
* The function type for a listener is the one of the signal to which it
* belongs.
*
* The clear separation between a signal and a sink permits to store the former
* as private data member without exposing the publish functionality to the
* users of the class.
*
* @warning
* Lifetime of a sink must not overcome that of the signal to which it refers.
* In any other case, attempting to use a sink results in undefined behavior.
*
* @tparam Ret Return type of a function type.
* @tparam Args Types of arguments of a function type.
*/
template<typename Ret, typename... Args>
class sink<Ret(Args...)> {
using signal_type = sigh<Ret(Args...)>;
using difference_type = typename std::iterator_traits<typename decltype(signal_type::calls)::iterator>::difference_type;
template<auto Candidate, typename Type>
static void release(Type value_or_instance, void *signal) {
sink{*static_cast<signal_type *>(signal)}.disconnect<Candidate>(value_or_instance);
}
template<auto Candidate>
static void release(void *signal) {
sink{*static_cast<signal_type *>(signal)}.disconnect<Candidate>();
}
public:
/**
* @brief Constructs a sink that is allowed to modify a given signal.
* @param ref A valid reference to a signal object.
*/
sink(sigh<Ret(Args...)> &ref) ENTT_NOEXCEPT
: offset{},
signal{&ref}
{}
/**
* @brief Returns false if at least a listener is connected to the sink.
* @return True if the sink has no listeners connected, false otherwise.
*/
[[nodiscard]] bool empty() const ENTT_NOEXCEPT {
return signal->calls.empty();
}
/**
* @brief Returns a sink that connects before a given free function or an
* unbound member.
* @tparam Function A valid free function pointer.
* @return A properly initialized sink object.
*/
template<auto Function>
[[nodiscard]] sink before() {
delegate<Ret(Args...)> call{};
call.template connect<Function>();
const auto &calls = signal->calls;
const auto it = std::find(calls.cbegin(), calls.cend(), std::move(call));
sink other{*this};
other.offset = std::distance(it, calls.cend());
return other;
}
/**
* @brief Returns a sink that connects before a free function with payload
* or a bound member.
* @tparam Candidate Member or free function to look for.
* @tparam Type Type of class or type of payload.
* @param value_or_instance A valid object that fits the purpose.
* @return A properly initialized sink object.
*/
template<auto Candidate, typename Type>
[[nodiscard]] sink before(Type &&value_or_instance) {
delegate<Ret(Args...)> call{};
call.template connect<Candidate>(value_or_instance);
const auto &calls = signal->calls;
const auto it = std::find(calls.cbegin(), calls.cend(), std::move(call));
sink other{*this};
other.offset = std::distance(it, calls.cend());
return other;
}
/**
* @brief Returns a sink that connects before a given instance or specific
* payload.
* @tparam Type Type of class or type of payload.
* @param value_or_instance A valid object that fits the purpose.
* @return A properly initialized sink object.
*/
template<typename Type>
[[nodiscard]] sink before(Type &value_or_instance) {
return before(&value_or_instance);
}
/**
* @brief Returns a sink that connects before a given instance or specific
* payload.
* @tparam Type Type of class or type of payload.
* @param value_or_instance A valid pointer that fits the purpose.
* @return A properly initialized sink object.
*/
template<typename Type>
[[nodiscard]] sink before(Type *value_or_instance) {
sink other{*this};
if(value_or_instance) {
const auto &calls = signal->calls;
const auto it = std::find_if(calls.cbegin(), calls.cend(), [value_or_instance](const auto &delegate) {
return delegate.instance() == value_or_instance;
});
other.offset = std::distance(it, calls.cend());
}
return other;
}
/**
* @brief Returns a sink that connects before anything else.
* @return A properly initialized sink object.
*/
[[nodiscard]] sink before() {
sink other{*this};
other.offset = signal->calls.size();
return other;
}
/**
* @brief Connects a free function or an unbound member to a signal.
*
* The signal handler performs checks to avoid multiple connections for the
* same function.
*
* @tparam Candidate Function or member to connect to the signal.
* @return A properly initialized connection object.
*/
template<auto Candidate>
connection connect() {
disconnect<Candidate>();
delegate<Ret(Args...)> call{};
call.template connect<Candidate>();
signal->calls.insert(signal->calls.end() - offset, std::move(call));
delegate<void(void *)> conn{};
conn.template connect<&release<Candidate>>();
return { std::move(conn), signal };
}
/**
* @brief Connects a free function with payload or a bound member to a
* signal.
*
* The signal isn't responsible for the connected object or the payload.
* Users must always guarantee that the lifetime of the instance overcomes
* the one of the signal. On the other side, the signal handler performs
* checks to avoid multiple connections for the same function.<br/>
* When used to connect a free function with payload, its signature must be
* such that the instance is the first argument before the ones used to
* define the signal itself.
*
* @tparam Candidate Function or member to connect to the signal.
* @tparam Type Type of class or type of payload.
* @param value_or_instance A valid object that fits the purpose.
* @return A properly initialized connection object.
*/
template<auto Candidate, typename Type>
connection connect(Type &&value_or_instance) {
disconnect<Candidate>(value_or_instance);
delegate<Ret(Args...)> call{};
call.template connect<Candidate>(value_or_instance);
signal->calls.insert(signal->calls.end() - offset, std::move(call));
delegate<void(void *)> conn{};
conn.template connect<&release<Candidate, Type>>(value_or_instance);
return { std::move(conn), signal };
}
/**
* @brief Disconnects a free function or an unbound member from a signal.
* @tparam Candidate Function or member to disconnect from the signal.
*/
template<auto Candidate>
void disconnect() {
auto &calls = signal->calls;
delegate<Ret(Args...)> call{};
call.template connect<Candidate>();
calls.erase(std::remove(calls.begin(), calls.end(), std::move(call)), calls.end());
}
/**
* @brief Disconnects a free function with payload or a bound member from a
* signal.
* @tparam Candidate Function or member to disconnect from the signal.
* @tparam Type Type of class or type of payload.
* @param value_or_instance A valid object that fits the purpose.
*/
template<auto Candidate, typename Type>
void disconnect(Type &&value_or_instance) {
auto &calls = signal->calls;
delegate<Ret(Args...)> call{};
call.template connect<Candidate>(value_or_instance);
calls.erase(std::remove(calls.begin(), calls.end(), std::move(call)), calls.end());
}
/**
* @brief Disconnects free functions with payload or bound members from a
* signal.
* @tparam Type Type of class or type of payload.
* @param value_or_instance A valid object that fits the purpose.
*/
template<typename Type>
void disconnect(Type &value_or_instance) {
disconnect(&value_or_instance);
}
/**
* @brief Disconnects free functions with payload or bound members from a
* signal.
* @tparam Type Type of class or type of payload.
* @param value_or_instance A valid object that fits the purpose.
*/
template<typename Type>
void disconnect(Type *value_or_instance) {
if(value_or_instance) {
auto &calls = signal->calls;
calls.erase(std::remove_if(calls.begin(), calls.end(), [value_or_instance](const auto &delegate) {
return delegate.instance() == value_or_instance;
}), calls.end());
}
}
/*! @brief Disconnects all the listeners from a signal. */
void disconnect() {
signal->calls.clear();
}
private:
difference_type offset;
signal_type *signal;
};
/**
* @brief Deduction guide.
*
* It allows to deduce the function type of a sink directly from the signal it
* refers to.
*
* @tparam Ret Return type of a function type.
* @tparam Args Types of arguments of a function type.
*/
template<typename Ret, typename... Args>
sink(sigh<Ret(Args...)> &) ENTT_NOEXCEPT -> sink<Ret(Args...)>;
}
#endif
namespace entt {
/**
* @brief Basic dispatcher implementation.
*
* A dispatcher can be used either to trigger an immediate event or to enqueue
* events to be published all together once per tick.<br/>
* Listeners are provided in the form of member functions. For each event of
* type `Event`, listeners are such that they can be invoked with an argument of
* type `Event &`, no matter what the return type is.
*
* The dispatcher creates instances of the `sigh` class internally. Refer to the
* documentation of the latter for more details.
*/
class dispatcher {
struct basic_pool {
virtual ~basic_pool() = default;
virtual void publish() = 0;
virtual void disconnect(void *) = 0;
virtual void clear() ENTT_NOEXCEPT = 0;
[[nodiscard]] virtual id_type type_id() const ENTT_NOEXCEPT = 0;
};
template<typename Event>
struct pool_handler final: basic_pool {
using signal_type = sigh<void(Event &)>;
using sink_type = typename signal_type::sink_type;
void publish() override {
const auto length = events.size();
for(std::size_t pos{}; pos < length; ++pos) {
signal.publish(events[pos]);
}
events.erase(events.cbegin(), events.cbegin()+length);
}
void disconnect(void *instance) override {
sink().disconnect(instance);
}
void clear() ENTT_NOEXCEPT override {
events.clear();
}
[[nodiscard]] sink_type sink() ENTT_NOEXCEPT {
return entt::sink{signal};
}
template<typename... Args>
void trigger(Args &&... args) {
Event instance{std::forward<Args>(args)...};
signal.publish(instance);
}
template<typename... Args>
void enqueue(Args &&... args) {
if constexpr(std::is_aggregate_v<Event>) {
events.push_back(Event{std::forward<Args>(args)...});
} else {
events.emplace_back(std::forward<Args>(args)...);
}
}
[[nodiscard]] id_type type_id() const ENTT_NOEXCEPT override {
return type_info<Event>::id();
}
private:
signal_type signal{};
std::vector<Event> events;
};
template<typename Event>
[[nodiscard]] pool_handler<Event> & assure() {
static_assert(std::is_same_v<Event, std::decay_t<Event>>, "Invalid event type");
if constexpr(ENTT_FAST_PATH(has_type_index_v<Event>)) {
const auto index = type_index<Event>::value();
if(!(index < pools.size())) {
pools.resize(index+1u);
}
if(!pools[index]) {
pools[index].reset(new pool_handler<Event>{});
}
return static_cast<pool_handler<Event> &>(*pools[index]);
} else {
auto it = std::find_if(pools.begin(), pools.end(), [id = type_info<Event>::id()](const auto &cpool) { return id == cpool->type_id(); });
return static_cast<pool_handler<Event> &>(it == pools.cend() ? *pools.emplace_back(new pool_handler<Event>{}) : **it);
}
}
public:
/**
* @brief Returns a sink object for the given event.
*
* A sink is an opaque object used to connect listeners to events.
*
* The function type for a listener is _compatible_ with:
* @code{.cpp}
* void(Event &);
* @endcode
*
* The order of invocation of the listeners isn't guaranteed.
*
* @sa sink
*
* @tparam Event Type of event of which to get the sink.
* @return A temporary sink object.
*/
template<typename Event>
[[nodiscard]] auto sink() {
return assure<Event>().sink();
}
/**
* @brief Triggers an immediate event of the given type.
*
* All the listeners registered for the given type are immediately notified.
* The event is discarded after the execution.
*
* @tparam Event Type of event to trigger.
* @tparam Args Types of arguments to use to construct the event.
* @param args Arguments to use to construct the event.
*/
template<typename Event, typename... Args>
void trigger(Args &&... args) {
assure<Event>().trigger(std::forward<Args>(args)...);
}
/**
* @brief Triggers an immediate event of the given type.
*
* All the listeners registered for the given type are immediately notified.
* The event is discarded after the execution.
*
* @tparam Event Type of event to trigger.
* @param event An instance of the given type of event.
*/
template<typename Event>
void trigger(Event &&event) {
assure<std::decay_t<Event>>().trigger(std::forward<Event>(event));
}
/**
* @brief Enqueues an event of the given type.
*
* An event of the given type is queued. No listener is invoked. Use the
* `update` member function to notify listeners when ready.
*
* @tparam Event Type of event to enqueue.
* @tparam Args Types of arguments to use to construct the event.
* @param args Arguments to use to construct the event.
*/
template<typename Event, typename... Args>
void enqueue(Args &&... args) {
assure<Event>().enqueue(std::forward<Args>(args)...);
}
/**
* @brief Enqueues an event of the given type.
*
* An event of the given type is queued. No listener is invoked. Use the
* `update` member function to notify listeners when ready.
*
* @tparam Event Type of event to enqueue.
* @param event An instance of the given type of event.
*/
template<typename Event>
void enqueue(Event &&event) {
assure<std::decay_t<Event>>().enqueue(std::forward<Event>(event));
}
/**
* @brief Utility function to disconnect everything related to a given value
* or instance from a dispatcher.
* @tparam Type Type of class or type of payload.
* @param value_or_instance A valid object that fits the purpose.
*/
template<typename Type>
void disconnect(Type &value_or_instance) {
disconnect(&value_or_instance);
}
/**
* @brief Utility function to disconnect everything related to a given value
* or instance from a dispatcher.
* @tparam Type Type of class or type of payload.
* @param value_or_instance A valid object that fits the purpose.
*/
template<typename Type>
void disconnect(Type *value_or_instance) {
for(auto &&cpool: pools) {
if(cpool) {
cpool->disconnect(value_or_instance);
}
}
}
/**
* @brief Discards all the events queued so far.
*
* If no types are provided, the dispatcher will clear all the existing
* pools.
*
* @tparam Event Type of events to discard.
*/
template<typename... Event>
void clear() {
if constexpr(sizeof...(Event) == 0) {
for(auto &&cpool: pools) {
if(cpool) {
cpool->clear();
}
}
} else {
(assure<Event>().clear(), ...);
}
}
/**
* @brief Delivers all the pending events of the given type.
*
* This method is blocking and it doesn't return until all the events are
* delivered to the registered listeners. It's responsibility of the users
* to reduce at a minimum the time spent in the bodies of the listeners.
*
* @tparam Event Type of events to send.
*/
template<typename Event>
void update() {
assure<Event>().publish();
}
/**
* @brief Delivers all the pending events.
*
* This method is blocking and it doesn't return until all the events are
* delivered to the registered listeners. It's responsibility of the users
* to reduce at a minimum the time spent in the bodies of the listeners.
*/
void update() const {
for(auto pos = pools.size(); pos; --pos) {
if(auto &&cpool = pools[pos-1]; cpool) {
cpool->publish();
}
}
}
private:
std::vector<std::unique_ptr<basic_pool>> pools;
};
}
#endif
// #include "signal/emitter.hpp"
#ifndef ENTT_SIGNAL_EMITTER_HPP
#define ENTT_SIGNAL_EMITTER_HPP
#include <algorithm>
#include <functional>
#include <iterator>
#include <list>
#include <memory>
#include <type_traits>
#include <utility>
#include <vector>
// #include "../config/config.h"
// #include "../core/fwd.hpp"
// #include "../core/type_info.hpp"
namespace entt {
/**
* @brief General purpose event emitter.
*
* The emitter class template follows the CRTP idiom. To create a custom emitter
* type, derived classes must inherit directly from the base class as:
*
* @code{.cpp}
* struct my_emitter: emitter<my_emitter> {
* // ...
* }
* @endcode
*
* Pools for the type of events are created internally on the fly. It's not
* required to specify in advance the full list of accepted types.<br/>
* Moreover, whenever an event is published, an emitter provides the listeners
* with a reference to itself along with a reference to the event. Therefore
* listeners have an handy way to work with it without incurring in the need of
* capturing a reference to the emitter.
*
* @tparam Derived Actual type of emitter that extends the class template.
*/
template<typename Derived>
class emitter {
struct basic_pool {
virtual ~basic_pool() = default;
virtual bool empty() const ENTT_NOEXCEPT = 0;
virtual void clear() ENTT_NOEXCEPT = 0;
virtual id_type type_id() const ENTT_NOEXCEPT = 0;
};
template<typename Event>
struct pool_handler final: basic_pool {
using listener_type = std::function<void(Event &, Derived &)>;
using element_type = std::pair<bool, listener_type>;
using container_type = std::list<element_type>;
using connection_type = typename container_type::iterator;
[[nodiscard]] bool empty() const ENTT_NOEXCEPT override {
auto pred = [](auto &&element) { return element.first; };
return std::all_of(once_list.cbegin(), once_list.cend(), pred) &&
std::all_of(on_list.cbegin(), on_list.cend(), pred);
}
void clear() ENTT_NOEXCEPT override {
if(publishing) {
for(auto &&element: once_list) {
element.first = true;
}
for(auto &&element: on_list) {
element.first = true;
}
} else {
once_list.clear();
on_list.clear();
}
}
connection_type once(listener_type listener) {
return once_list.emplace(once_list.cend(), false, std::move(listener));
}
connection_type on(listener_type listener) {
return on_list.emplace(on_list.cend(), false, std::move(listener));
}
void erase(connection_type conn) {
conn->first = true;
if(!publishing) {
auto pred = [](auto &&element) { return element.first; };
once_list.remove_if(pred);
on_list.remove_if(pred);
}
}
void publish(Event &event, Derived &ref) {
container_type swap_list;
once_list.swap(swap_list);
publishing = true;
for(auto &&element: on_list) {
element.first ? void() : element.second(event, ref);
}
for(auto &&element: swap_list) {
element.first ? void() : element.second(event, ref);
}
publishing = false;
on_list.remove_if([](auto &&element) { return element.first; });
}
[[nodiscard]] id_type type_id() const ENTT_NOEXCEPT override {
return type_info<Event>::id();
}
private:
bool publishing{false};
container_type once_list{};
container_type on_list{};
};
template<typename Event>
[[nodiscard]] const pool_handler<Event> & assure() const {
static_assert(std::is_same_v<Event, std::decay_t<Event>>, "Invalid event type");
if constexpr(ENTT_FAST_PATH(has_type_index_v<Event>)) {
const auto index = type_index<Event>::value();
if(!(index < pools.size())) {
pools.resize(index+1u);
}
if(!pools[index]) {
pools[index].reset(new pool_handler<Event>{});
}
return static_cast<pool_handler<Event> &>(*pools[index]);
} else {
auto it = std::find_if(pools.begin(), pools.end(), [id = type_info<Event>::id()](const auto &cpool) { return id == cpool->type_id(); });
return static_cast<pool_handler<Event> &>(it == pools.cend() ? *pools.emplace_back(new pool_handler<Event>{}) : **it);
}
}
template<typename Event>
[[nodiscard]] pool_handler<Event> & assure() {
return const_cast<pool_handler<Event> &>(std::as_const(*this).template assure<Event>());
}
public:
/** @brief Type of listeners accepted for the given event. */
template<typename Event>
using listener = typename pool_handler<Event>::listener_type;
/**
* @brief Generic connection type for events.
*
* Type of the connection object returned by the event emitter whenever a
* listener for the given type is registered.<br/>
* It can be used to break connections still in use.
*
* @tparam Event Type of event for which the connection is created.
*/
template<typename Event>
struct connection: private pool_handler<Event>::connection_type {
/** @brief Event emitters are friend classes of connections. */
friend class emitter;
/*! @brief Default constructor. */
connection() = default;
/**
* @brief Creates a connection that wraps its underlying instance.
* @param conn A connection object to wrap.
*/
connection(typename pool_handler<Event>::connection_type conn)
: pool_handler<Event>::connection_type{std::move(conn)}
{}
};
/*! @brief Default constructor. */
emitter() = default;
/*! @brief Default destructor. */
virtual ~emitter() {
static_assert(std::is_base_of_v<emitter<Derived>, Derived>, "Incorrect use of the class template");
}
/*! @brief Default move constructor. */
emitter(emitter &&) = default;
/*! @brief Default move assignment operator. @return This emitter. */
emitter & operator=(emitter &&) = default;
/**
* @brief Emits the given event.
*
* All the listeners registered for the specific event type are invoked with
* the given event. The event type must either have a proper constructor for
* the arguments provided or be an aggregate type.
*
* @tparam Event Type of event to publish.
* @tparam Args Types of arguments to use to construct the event.
* @param args Parameters to use to initialize the event.
*/
template<typename Event, typename... Args>
void publish(Args &&... args) {
Event instance{std::forward<Args>(args)...};
assure<Event>().publish(instance, *static_cast<Derived *>(this));
}
/**
* @brief Registers a long-lived listener with the event emitter.
*
* This method can be used to register a listener designed to be invoked
* more than once for the given event type.<br/>
* The connection returned by the method can be freely discarded. It's meant
* to be used later to disconnect the listener if required.
*
* The listener is as a callable object that can be moved and the type of
* which is _compatible_ with `void(Event &, Derived &)`.
*
* @note
* Whenever an event is emitted, the emitter provides the listener with a
* reference to the derived class. Listeners don't have to capture those
* instances for later uses.
*
* @tparam Event Type of event to which to connect the listener.
* @param instance The listener to register.
* @return Connection object that can be used to disconnect the listener.
*/
template<typename Event>
connection<Event> on(listener<Event> instance) {
return assure<Event>().on(std::move(instance));
}
/**
* @brief Registers a short-lived listener with the event emitter.
*
* This method can be used to register a listener designed to be invoked
* only once for the given event type.<br/>
* The connection returned by the method can be freely discarded. It's meant
* to be used later to disconnect the listener if required.
*
* The listener is as a callable object that can be moved and the type of
* which is _compatible_ with `void(Event &, Derived &)`.
*
* @note
* Whenever an event is emitted, the emitter provides the listener with a
* reference to the derived class. Listeners don't have to capture those
* instances for later uses.
*
* @tparam Event Type of event to which to connect the listener.
* @param instance The listener to register.
* @return Connection object that can be used to disconnect the listener.
*/
template<typename Event>
connection<Event> once(listener<Event> instance) {
return assure<Event>().once(std::move(instance));
}
/**
* @brief Disconnects a listener from the event emitter.
*
* Do not use twice the same connection to disconnect a listener, it results
* in undefined behavior. Once used, discard the connection object.
*
* @tparam Event Type of event of the connection.
* @param conn A valid connection.
*/
template<typename Event>
void erase(connection<Event> conn) {
assure<Event>().erase(std::move(conn));
}
/**
* @brief Disconnects all the listeners for the given event type.
*
* All the connections previously returned for the given event are
* invalidated. Using them results in undefined behavior.
*
* @tparam Event Type of event to reset.
*/
template<typename Event>
void clear() {
assure<Event>().clear();
}
/**
* @brief Disconnects all the listeners.
*
* All the connections previously returned are invalidated. Using them
* results in undefined behavior.
*/
void clear() ENTT_NOEXCEPT {
for(auto &&cpool: pools) {
if(cpool) {
cpool->clear();
}
}
}
/**
* @brief Checks if there are listeners registered for the specific event.
* @tparam Event Type of event to test.
* @return True if there are no listeners registered, false otherwise.
*/
template<typename Event>
[[nodiscard]] bool empty() const {
return assure<Event>().empty();
}
/**
* @brief Checks if there are listeners registered with the event emitter.
* @return True if there are no listeners registered, false otherwise.
*/
[[nodiscard]] bool empty() const ENTT_NOEXCEPT {
return std::all_of(pools.cbegin(), pools.cend(), [](auto &&cpool) {
return !cpool || cpool->empty();
});
}
private:
mutable std::vector<std::unique_ptr<basic_pool>> pools{};
};
}
#endif
// #include "signal/sigh.hpp"
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