#ifndef ENTT_CONTAINER_DENSE_MAP_HPP
#define ENTT_CONTAINER_DENSE_MAP_HPP
#include <cmath>
#include <cstddef>
#include <functional>
#include <iterator>
#include <limits>
#include <memory>
#include <tuple>
#include <type_traits>
#include <utility>
#include <vector>
#include "../config/config.h"
#include "../core/compressed_pair.hpp"
#include "../core/iterator.hpp"
#include "../core/memory.hpp"
#include "../core/type_traits.hpp"
#include "fwd.hpp"
namespace entt {
/**
* @cond TURN_OFF_DOXYGEN
* Internal details not to be documented.
*/
namespace internal {
template<typename Key, typename Type>
struct dense_map_node final {
using value_type = std::pair<Key, Type>;
template<typename... Args>
dense_map_node(const std::size_t pos, Args &&...args)
: next{pos},
element{std::forward<Args>(args)...} {}
template<typename Allocator, typename... Args>
dense_map_node(std::allocator_arg_t, const Allocator &allocator, const std::size_t pos, Args &&...args)
: next{pos},
element{entt::make_obj_using_allocator<value_type>(allocator, std::forward<Args>(args)...)} {}
template<typename Allocator>
dense_map_node(std::allocator_arg_t, const Allocator &allocator, const dense_map_node &other)
: next{other.next},
element{entt::make_obj_using_allocator<value_type>(allocator, other.element)} {}
template<typename Allocator>
dense_map_node(std::allocator_arg_t, const Allocator &allocator, dense_map_node &&other)
: next{other.next},
element{entt::make_obj_using_allocator<value_type>(allocator, std::move(other.element))} {}
std::size_t next;
value_type element;
};
template<typename It>
class dense_map_iterator final {
template<typename>
friend class dense_map_iterator;
using first_type = decltype(std::as_const(std::declval<It>()->element.first));
using second_type = decltype((std::declval<It>()->element.second));
public:
using value_type = std::pair<first_type, second_type>;
using pointer = input_iterator_pointer<value_type>;
using reference = value_type;
using difference_type = std::ptrdiff_t;
using iterator_category = std::input_iterator_tag;
constexpr dense_map_iterator() noexcept
: it{} {}
constexpr dense_map_iterator(const It iter) noexcept
: it{iter} {}
template<typename Other, typename = std::enable_if_t<!std::is_same_v<It, Other> && std::is_constructible_v<It, Other>>>
constexpr dense_map_iterator(const dense_map_iterator<Other> &other) noexcept
: it{other.it} {}
constexpr dense_map_iterator &operator++() noexcept {
return ++it, *this;
}
constexpr dense_map_iterator operator++(int) noexcept {
dense_map_iterator orig = *this;
return ++(*this), orig;
}
constexpr dense_map_iterator &operator--() noexcept {
return --it, *this;
}
constexpr dense_map_iterator operator--(int) noexcept {
dense_map_iterator orig = *this;
return operator--(), orig;
}
constexpr dense_map_iterator &operator+=(const difference_type value) noexcept {
it += value;
return *this;
}
constexpr dense_map_iterator operator+(const difference_type value) const noexcept {
dense_map_iterator copy = *this;
return (copy += value);
}
constexpr dense_map_iterator &operator-=(const difference_type value) noexcept {
return (*this += -value);
}
constexpr dense_map_iterator operator-(const difference_type value) const noexcept {
return (*this + -value);
}
[[nodiscard]] constexpr reference operator[](const difference_type value) const noexcept {
return {it[value].element.first, it[value].element.second};
}
[[nodiscard]] constexpr pointer operator->() const noexcept {
return operator*();
}
[[nodiscard]] constexpr reference operator*() const noexcept {
return {it->element.first, it->element.second};
}
template<typename ILhs, typename IRhs>
friend constexpr std::ptrdiff_t operator-(const dense_map_iterator<ILhs> &, const dense_map_iterator<IRhs> &) noexcept;
template<typename ILhs, typename IRhs>
friend constexpr bool operator==(const dense_map_iterator<ILhs> &, const dense_map_iterator<IRhs> &) noexcept;
template<typename ILhs, typename IRhs>
friend constexpr bool operator<(const dense_map_iterator<ILhs> &, const dense_map_iterator<IRhs> &) noexcept;
private:
It it;
};
template<typename ILhs, typename IRhs>
[[nodiscard]] constexpr std::ptrdiff_t operator-(const dense_map_iterator<ILhs> &lhs, const dense_map_iterator<IRhs> &rhs) noexcept {
return lhs.it - rhs.it;
}
template<typename ILhs, typename IRhs>
[[nodiscard]] constexpr bool operator==(const dense_map_iterator<ILhs> &lhs, const dense_map_iterator<IRhs> &rhs) noexcept {
return lhs.it == rhs.it;
}
template<typename ILhs, typename IRhs>
[[nodiscard]] constexpr bool operator!=(const dense_map_iterator<ILhs> &lhs, const dense_map_iterator<IRhs> &rhs) noexcept {
return !(lhs == rhs);
}
template<typename ILhs, typename IRhs>
[[nodiscard]] constexpr bool operator<(const dense_map_iterator<ILhs> &lhs, const dense_map_iterator<IRhs> &rhs) noexcept {
return lhs.it < rhs.it;
}
template<typename ILhs, typename IRhs>
[[nodiscard]] constexpr bool operator>(const dense_map_iterator<ILhs> &lhs, const dense_map_iterator<IRhs> &rhs) noexcept {
return rhs < lhs;
}
template<typename ILhs, typename IRhs>
[[nodiscard]] constexpr bool operator<=(const dense_map_iterator<ILhs> &lhs, const dense_map_iterator<IRhs> &rhs) noexcept {
return !(lhs > rhs);
}
template<typename ILhs, typename IRhs>
[[nodiscard]] constexpr bool operator>=(const dense_map_iterator<ILhs> &lhs, const dense_map_iterator<IRhs> &rhs) noexcept {
return !(lhs < rhs);
}
template<typename It>
class dense_map_local_iterator final {
template<typename>
friend class dense_map_local_iterator;
using first_type = decltype(std::as_const(std::declval<It>()->element.first));
using second_type = decltype((std::declval<It>()->element.second));
public:
using value_type = std::pair<first_type, second_type>;
using pointer = input_iterator_pointer<value_type>;
using reference = value_type;
using difference_type = std::ptrdiff_t;
using iterator_category = std::input_iterator_tag;
constexpr dense_map_local_iterator() noexcept
: it{},
offset{} {}
constexpr dense_map_local_iterator(It iter, const std::size_t pos) noexcept
: it{iter},
offset{pos} {}
template<typename Other, typename = std::enable_if_t<!std::is_same_v<It, Other> && std::is_constructible_v<It, Other>>>
constexpr dense_map_local_iterator(const dense_map_local_iterator<Other> &other) noexcept
: it{other.it},
offset{other.offset} {}
constexpr dense_map_local_iterator &operator++() noexcept {
return offset = it[offset].next, *this;
}
constexpr dense_map_local_iterator operator++(int) noexcept {
dense_map_local_iterator orig = *this;
return ++(*this), orig;
}
[[nodiscard]] constexpr pointer operator->() const noexcept {
return operator*();
}
[[nodiscard]] constexpr reference operator*() const noexcept {
return {it[offset].element.first, it[offset].element.second};
}
[[nodiscard]] constexpr std::size_t index() const noexcept {
return offset;
}
private:
It it;
std::size_t offset;
};
template<typename ILhs, typename IRhs>
[[nodiscard]] constexpr bool operator==(const dense_map_local_iterator<ILhs> &lhs, const dense_map_local_iterator<IRhs> &rhs) noexcept {
return lhs.index() == rhs.index();
}
template<typename ILhs, typename IRhs>
[[nodiscard]] constexpr bool operator!=(const dense_map_local_iterator<ILhs> &lhs, const dense_map_local_iterator<IRhs> &rhs) noexcept {
return !(lhs == rhs);
}
} // namespace internal
/**
* Internal details not to be documented.
* @endcond
*/
/**
* @brief Associative container for key-value pairs with unique keys.
*
* Internally, elements are organized into buckets. Which bucket an element is
* placed into depends entirely on the hash of its key. Keys with the same hash
* code appear in the same bucket.
*
* @tparam Key Key type of the associative container.
* @tparam Type Mapped type of the associative container.
* @tparam Hash Type of function to use to hash the keys.
* @tparam KeyEqual Type of function to use to compare the keys for equality.
* @tparam Allocator Type of allocator used to manage memory and elements.
*/
template<typename Key, typename Type, typename Hash, typename KeyEqual, typename Allocator>
class dense_map {
static constexpr float default_threshold = 0.875f;
static constexpr std::size_t minimum_capacity = 8u;
using node_type = internal::dense_map_node<Key, Type>;
using alloc_traits = typename std::allocator_traits<Allocator>;
static_assert(std::is_same_v<typename alloc_traits::value_type, std::pair<const Key, Type>>, "Invalid value type");
using sparse_container_type = std::vector<std::size_t, typename alloc_traits::template rebind_alloc<std::size_t>>;
using packed_container_type = std::vector<node_type, typename alloc_traits::template rebind_alloc<node_type>>;
template<typename Other>
[[nodiscard]] std::size_t key_to_bucket(const Other &key) const noexcept {
return fast_mod(sparse.second()(key), bucket_count());
}
template<typename Other>
[[nodiscard]] auto constrained_find(const Other &key, std::size_t bucket) {
for(auto it = begin(bucket), last = end(bucket); it != last; ++it) {
if(packed.second()(it->first, key)) {
return begin() + static_cast<typename iterator::difference_type>(it.index());
}
}
return end();
}
template<typename Other>
[[nodiscard]] auto constrained_find(const Other &key, std::size_t bucket) const {
for(auto it = cbegin(bucket), last = cend(bucket); it != last; ++it) {
if(packed.second()(it->first, key)) {
return cbegin() + static_cast<typename iterator::difference_type>(it.index());
}
}
return cend();
}
template<typename Other, typename... Args>
[[nodiscard]] auto insert_or_do_nothing(Other &&key, Args &&...args) {
const auto index = key_to_bucket(key);
if(auto it = constrained_find(key, index); it != end()) {
return std::make_pair(it, false);
}
packed.first().emplace_back(sparse.first()[index], std::piecewise_construct, std::forward_as_tuple(std::forward<Other>(key)), std::forward_as_tuple(std::forward<Args>(args)...));
sparse.first()[index] = packed.first().size() - 1u;
rehash_if_required();
return std::make_pair(--end(), true);
}
template<typename Other, typename Arg>
[[nodiscard]] auto insert_or_overwrite(Other &&key, Arg &&value) {
const auto index = key_to_bucket(key);
if(auto it = constrained_find(key, index); it != end()) {
it->second = std::forward<Arg>(value);
return std::make_pair(it, false);
}
packed.first().emplace_back(sparse.first()[index], std::forward<Other>(key), std::forward<Arg>(value));
sparse.first()[index] = packed.first().size() - 1u;
rehash_if_required();
return std::make_pair(--end(), true);
}
void move_and_pop(const std::size_t pos) {
if(const auto last = size() - 1u; pos != last) {
size_type *curr = sparse.first().data() + key_to_bucket(packed.first().back().element.first);
packed.first()[pos] = std::move(packed.first().back());
for(; *curr != last; curr = &packed.first()[*curr].next) {}
*curr = pos;
}
packed.first().pop_back();
}
void rehash_if_required() {
if(size() > (bucket_count() * max_load_factor())) {
rehash(bucket_count() * 2u);
}
}
public:
/*! @brief Key type of the container. */
using key_type = Key;
/*! @brief Mapped type of the container. */
using mapped_type = Type;
/*! @brief Key-value type of the container. */
using value_type = std::pair<const Key, Type>;
/*! @brief Unsigned integer type. */
using size_type = std::size_t;
/*! @brief Type of function to use to hash the keys. */
using hasher = Hash;
/*! @brief Type of function to use to compare the keys for equality. */
using key_equal = KeyEqual;
/*! @brief Allocator type. */
using allocator_type = Allocator;
/*! @brief Input iterator type. */
using iterator = internal::dense_map_iterator<typename packed_container_type::iterator>;
/*! @brief Constant input iterator type. */
using const_iterator = internal::dense_map_iterator<typename packed_container_type::const_iterator>;
/*! @brief Input iterator type. */
using local_iterator = internal::dense_map_local_iterator<typename packed_container_type::iterator>;
/*! @brief Constant input iterator type. */
using const_local_iterator = internal::dense_map_local_iterator<typename packed_container_type::const_iterator>;
/*! @brief Default constructor. */
dense_map()
: dense_map{minimum_capacity} {}
/**
* @brief Constructs an empty container with a given allocator.
* @param allocator The allocator to use.
*/
explicit dense_map(const allocator_type &allocator)
: dense_map{minimum_capacity, hasher{}, key_equal{}, allocator} {}
/**
* @brief Constructs an empty container with a given allocator and user
* supplied minimal number of buckets.
* @param cnt Minimal number of buckets.
* @param allocator The allocator to use.
*/
dense_map(const size_type cnt, const allocator_type &allocator)
: dense_map{cnt, hasher{}, key_equal{}, allocator} {}
/**
* @brief Constructs an empty container with a given allocator, hash
* function and user supplied minimal number of buckets.
* @param cnt Minimal number of buckets.
* @param hash Hash function to use.
* @param allocator The allocator to use.
*/
dense_map(const size_type cnt, const hasher &hash, const allocator_type &allocator)
: dense_map{cnt, hash, key_equal{}, allocator} {}
/**
* @brief Constructs an empty container with a given allocator, hash
* function, compare function and user supplied minimal number of buckets.
* @param cnt Minimal number of buckets.
* @param hash Hash function to use.
* @param equal Compare function to use.
* @param allocator The allocator to use.
*/
explicit dense_map(const size_type cnt, const hasher &hash = hasher{}, const key_equal &equal = key_equal{}, const allocator_type &allocator = allocator_type{})
: sparse{allocator, hash},
packed{allocator, equal},
threshold{default_threshold} {
rehash(cnt);
}
/*! @brief Default copy constructor. */
dense_map(const dense_map &) = default;
/**
* @brief Allocator-extended copy constructor.
* @param other The instance to copy from.
* @param allocator The allocator to use.
*/
dense_map(const dense_map &other, const allocator_type &allocator)
: sparse{std::piecewise_construct, std::forward_as_tuple(other.sparse.first(), allocator), std::forward_as_tuple(other.sparse.second())},
packed{std::piecewise_construct, std::forward_as_tuple(other.packed.first(), allocator), std::forward_as_tuple(other.packed.second())},
threshold{other.threshold} {}
/*! @brief Default move constructor. */
dense_map(dense_map &&) noexcept(std::is_nothrow_move_constructible_v<compressed_pair<sparse_container_type, hasher>> &&std::is_nothrow_move_constructible_v<compressed_pair<packed_container_type, key_equal>>) = default;
/**
* @brief Allocator-extended move constructor.
* @param other The instance to move from.
* @param allocator The allocator to use.
*/
dense_map(dense_map &&other, const allocator_type &allocator)
: sparse{std::piecewise_construct, std::forward_as_tuple(std::move(other.sparse.first()), allocator), std::forward_as_tuple(std::move(other.sparse.second()))},
packed{std::piecewise_construct, std::forward_as_tuple(std::move(other.packed.first()), allocator), std::forward_as_tuple(std::move(other.packed.second()))},
threshold{other.threshold} {}
/**
* @brief Default copy assignment operator.
* @return This container.
*/
dense_map &operator=(const dense_map &) = default;
/**
* @brief Default move assignment operator.
* @return This container.
*/
dense_map &operator=(dense_map &&) noexcept(std::is_nothrow_move_assignable_v<compressed_pair<sparse_container_type, hasher>> &&std::is_nothrow_move_assignable_v<compressed_pair<packed_container_type, key_equal>>) = default;
/**
* @brief Returns the associated allocator.
* @return The associated allocator.
*/
[[nodiscard]] constexpr allocator_type get_allocator() const noexcept {
return sparse.first().get_allocator();
}
/**
* @brief Returns an iterator to the beginning.
*
* The returned iterator points to the first instance of the internal array.
* If the array 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 noexcept {
return packed.first().begin();
}
/*! @copydoc cbegin */
[[nodiscard]] const_iterator begin() const noexcept {
return cbegin();
}
/*! @copydoc begin */
[[nodiscard]] iterator begin() noexcept {
return packed.first().begin();
}
/**
* @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 noexcept {
return packed.first().end();
}
/*! @copydoc cend */
[[nodiscard]] const_iterator end() const noexcept {
return cend();
}
/*! @copydoc end */
[[nodiscard]] iterator end() noexcept {
return packed.first().end();
}
/**
* @brief Checks whether a container is empty.
* @return True if the container is empty, false otherwise.
*/
[[nodiscard]] bool empty() const noexcept {
return packed.first().empty();
}
/**
* @brief Returns the number of elements in a container.
* @return Number of elements in a container.
*/
[[nodiscard]] size_type size() const noexcept {
return packed.first().size();
}
/**
* @brief Returns the maximum possible number of elements.
* @return Maximum possible number of elements.
*/
[[nodiscard]] size_type max_size() const noexcept {
return packed.first().max_size();
}
/*! @brief Clears the container. */
void clear() noexcept {
sparse.first().clear();
packed.first().clear();
rehash(0u);
}
/**
* @brief Inserts an element into the container, if the key does not exist.
* @param value A key-value pair eventually convertible to the value type.
* @return A pair consisting of an iterator to the inserted element (or to
* the element that prevented the insertion) and a bool denoting whether the
* insertion took place.
*/
std::pair<iterator, bool> insert(const value_type &value) {
return insert_or_do_nothing(value.first, value.second);
}
/*! @copydoc insert */
std::pair<iterator, bool> insert(value_type &&value) {
return insert_or_do_nothing(std::move(value.first), std::move(value.second));
}
/**
* @copydoc insert
* @tparam Arg Type of the key-value pair to insert into the container.
*/
template<typename Arg>
std::enable_if_t<std::is_constructible_v<value_type, Arg &&>, std::pair<iterator, bool>>
insert(Arg &&value) {
return insert_or_do_nothing(std::forward<Arg>(value).first, std::forward<Arg>(value).second);
}
/**
* @brief Inserts elements into the container, if their keys do not exist.
* @tparam It Type of input iterator.
* @param first An iterator to the first element of the range of elements.
* @param last An iterator past the last element of the range of elements.
*/
template<typename It>
void insert(It first, It last) {
for(; first != last; ++first) {
insert(*first);
}
}
/**
* @brief Inserts an element into the container or assigns to the current
* element if the key already exists.
* @tparam Arg Type of the value to insert or assign.
* @param key A key used both to look up and to insert if not found.
* @param value A value to insert or assign.
* @return A pair consisting of an iterator to the element and a bool
* denoting whether the insertion took place.
*/
template<typename Arg>
std::pair<iterator, bool> insert_or_assign(const key_type &key, Arg &&value) {
return insert_or_overwrite(key, std::forward<Arg>(value));
}
/*! @copydoc insert_or_assign */
template<typename Arg>
std::pair<iterator, bool> insert_or_assign(key_type &&key, Arg &&value) {
return insert_or_overwrite(std::move(key), std::forward<Arg>(value));
}
/**
* @brief Constructs an element in-place, if the key does not exist.
*
* The element is also constructed when the container already has the key,
* in which case the newly constructed object is destroyed immediately.
*
* @tparam Args Types of arguments to forward to the constructor of the
* element.
* @param args Arguments to forward to the constructor of the element.
* @return A pair consisting of an iterator to the inserted element (or to
* the element that prevented the insertion) and a bool denoting whether the
* insertion took place.
*/
template<typename... Args>
std::pair<iterator, bool> emplace([[maybe_unused]] Args &&...args) {
if constexpr(sizeof...(Args) == 0u) {
return insert_or_do_nothing(key_type{});
} else if constexpr(sizeof...(Args) == 1u) {
return insert_or_do_nothing(std::forward<Args>(args).first..., std::forward<Args>(args).second...);
} else if constexpr(sizeof...(Args) == 2u) {
return insert_or_do_nothing(std::forward<Args>(args)...);
} else {
auto &node = packed.first().emplace_back(packed.first().size(), std::forward<Args>(args)...);
const auto index = key_to_bucket(node.element.first);
if(auto it = constrained_find(node.element.first, index); it != end()) {
packed.first().pop_back();
return std::make_pair(it, false);
}
std::swap(node.next, sparse.first()[index]);
rehash_if_required();
return std::make_pair(--end(), true);
}
}
/**
* @brief Inserts in-place if the key does not exist, does nothing if the
* key exists.
* @tparam Args Types of arguments to forward to the constructor of the
* element.
* @param key A key used both to look up and to insert if not found.
* @param args Arguments to forward to the constructor of the element.
* @return A pair consisting of an iterator to the inserted element (or to
* the element that prevented the insertion) and a bool denoting whether the
* insertion took place.
*/
template<typename... Args>
std::pair<iterator, bool> try_emplace(const key_type &key, Args &&...args) {
return insert_or_do_nothing(key, std::forward<Args>(args)...);
}
/*! @copydoc try_emplace */
template<typename... Args>
std::pair<iterator, bool> try_emplace(key_type &&key, Args &&...args) {
return insert_or_do_nothing(std::move(key), std::forward<Args>(args)...);
}
/**
* @brief Removes an element from a given position.
* @param pos An iterator to the element to remove.
* @return An iterator following the removed element.
*/
iterator erase(const_iterator pos) {
const auto diff = pos - cbegin();
erase(pos->first);
return begin() + diff;
}
/**
* @brief Removes the given elements from a container.
* @param first An iterator to the first element of the range of elements.
* @param last An iterator past the last element of the range of elements.
* @return An iterator following the last removed element.
*/
iterator erase(const_iterator first, const_iterator last) {
const auto dist = first - cbegin();
for(auto from = last - cbegin(); from != dist; --from) {
erase(packed.first()[from - 1u].element.first);
}
return (begin() + dist);
}
/**
* @brief Removes the element associated with a given key.
* @param key A key value of an element to remove.
* @return Number of elements removed (either 0 or 1).
*/
size_type erase(const key_type &key) {
for(size_type *curr = sparse.first().data() + key_to_bucket(key); *curr != (std::numeric_limits<size_type>::max)(); curr = &packed.first()[*curr].next) {
if(packed.second()(packed.first()[*curr].element.first, key)) {
const auto index = *curr;
*curr = packed.first()[*curr].next;
move_and_pop(index);
return 1u;
}
}
return 0u;
}
/**
* @brief Exchanges the contents with those of a given container.
* @param other Container to exchange the content with.
*/
void swap(dense_map &other) {
using std::swap;
swap(sparse, other.sparse);
swap(packed, other.packed);
swap(threshold, other.threshold);
}
/**
* @brief Accesses a given element with bounds checking.
* @param key A key of an element to find.
* @return A reference to the mapped value of the requested element.
*/
[[nodiscard]] mapped_type &at(const key_type &key) {
auto it = find(key);
ENTT_ASSERT(it != end(), "Invalid key");
return it->second;
}
/*! @copydoc at */
[[nodiscard]] const mapped_type &at(const key_type &key) const {
auto it = find(key);
ENTT_ASSERT(it != cend(), "Invalid key");
return it->second;
}
/**
* @brief Accesses or inserts a given element.
* @param key A key of an element to find or insert.
* @return A reference to the mapped value of the requested element.
*/
[[nodiscard]] mapped_type &operator[](const key_type &key) {
return insert_or_do_nothing(key).first->second;
}
/**
* @brief Accesses or inserts a given element.
* @param key A key of an element to find or insert.
* @return A reference to the mapped value of the requested element.
*/
[[nodiscard]] mapped_type &operator[](key_type &&key) {
return insert_or_do_nothing(std::move(key)).first->second;
}
/**
* @brief Returns the number of elements matching a key (either 1 or 0).
* @param key Key value of an element to search for.
* @return Number of elements matching the key (either 1 or 0).
*/
[[nodiscard]] size_type count(const key_type &key) const {
return find(key) != end();
}
/**
* @brief Returns the number of elements matching a key (either 1 or 0).
* @tparam Other Type of the key value of an element to search for.
* @param key Key value of an element to search for.
* @return Number of elements matching the key (either 1 or 0).
*/
template<typename Other>
[[nodiscard]] std::enable_if_t<is_transparent_v<hasher> && is_transparent_v<key_equal>, std::conditional_t<false, Other, size_type>>
count(const Other &key) const {
return find(key) != end();
}
/**
* @brief Finds an element with a given key.
* @param key Key value of an element to search for.
* @return An iterator to an element with the given key. If no such element
* is found, a past-the-end iterator is returned.
*/
[[nodiscard]] iterator find(const key_type &key) {
return constrained_find(key, key_to_bucket(key));
}
/*! @copydoc find */
[[nodiscard]] const_iterator find(const key_type &key) const {
return constrained_find(key, key_to_bucket(key));
}
/**
* @brief Finds an element with a key that compares _equivalent_ to a given
* key.
* @tparam Other Type of the key value of an element to search for.
* @param key Key value of an element to search for.
* @return An iterator to an element with the given key. If no such element
* is found, a past-the-end iterator is returned.
*/
template<typename Other>
[[nodiscard]] std::enable_if_t<is_transparent_v<hasher> && is_transparent_v<key_equal>, std::conditional_t<false, Other, iterator>>
find(const Other &key) {
return constrained_find(key, key_to_bucket(key));
}
/*! @copydoc find */
template<typename Other>
[[nodiscard]] std::enable_if_t<is_transparent_v<hasher> && is_transparent_v<key_equal>, std::conditional_t<false, Other, const_iterator>>
find(const Other &key) const {
return constrained_find(key, key_to_bucket(key));
}
/**
* @brief Returns a range containing all elements with a given key.
* @param key Key value of an element to search for.
* @return A pair of iterators pointing to the first element and past the
* last element of the range.
*/
[[nodiscard]] std::pair<iterator, iterator> equal_range(const key_type &key) {
const auto it = find(key);
return {it, it + !(it == end())};
}
/*! @copydoc equal_range */
[[nodiscard]] std::pair<const_iterator, const_iterator> equal_range(const key_type &key) const {
const auto it = find(key);
return {it, it + !(it == cend())};
}
/**
* @brief Returns a range containing all elements that compare _equivalent_
* to a given key.
* @tparam Other Type of an element to search for.
* @param key Key value of an element to search for.
* @return A pair of iterators pointing to the first element and past the
* last element of the range.
*/
template<typename Other>
[[nodiscard]] std::enable_if_t<is_transparent_v<hasher> && is_transparent_v<key_equal>, std::conditional_t<false, Other, std::pair<iterator, iterator>>>
equal_range(const Other &key) {
const auto it = find(key);
return {it, it + !(it == end())};
}
/*! @copydoc equal_range */
template<class Other>
[[nodiscard]] std::enable_if_t<is_transparent_v<hasher> && is_transparent_v<key_equal>, std::conditional_t<false, Other, std::pair<const_iterator, const_iterator>>>
equal_range(const Other &key) const {
const auto it = find(key);
return {it, it + !(it == cend())};
}
/**
* @brief Checks if the container contains an element with a given key.
* @param key Key value of an element to search for.
* @return True if there is such an element, false otherwise.
*/
[[nodiscard]] bool contains(const key_type &key) const {
return (find(key) != cend());
}
/**
* @brief Checks if the container contains an element with a key that
* compares _equivalent_ to a given value.
* @tparam Other Type of the key value of an element to search for.
* @param key Key value of an element to search for.
* @return True if there is such an element, false otherwise.
*/
template<typename Other>
[[nodiscard]] std::enable_if_t<is_transparent_v<hasher> && is_transparent_v<key_equal>, std::conditional_t<false, Other, bool>>
contains(const Other &key) const {
return (find(key) != cend());
}
/**
* @brief Returns an iterator to the beginning of a given bucket.
* @param index An index of a bucket to access.
* @return An iterator to the beginning of the given bucket.
*/
[[nodiscard]] const_local_iterator cbegin(const size_type index) const {
return {packed.first().begin(), sparse.first()[index]};
}
/**
* @brief Returns an iterator to the beginning of a given bucket.
* @param index An index of a bucket to access.
* @return An iterator to the beginning of the given bucket.
*/
[[nodiscard]] const_local_iterator begin(const size_type index) const {
return cbegin(index);
}
/**
* @brief Returns an iterator to the beginning of a given bucket.
* @param index An index of a bucket to access.
* @return An iterator to the beginning of the given bucket.
*/
[[nodiscard]] local_iterator begin(const size_type index) {
return {packed.first().begin(), sparse.first()[index]};
}
/**
* @brief Returns an iterator to the end of a given bucket.
* @param index An index of a bucket to access.
* @return An iterator to the end of the given bucket.
*/
[[nodiscard]] const_local_iterator cend([[maybe_unused]] const size_type index) const {
return {packed.first().begin(), (std::numeric_limits<size_type>::max)()};
}
/**
* @brief Returns an iterator to the end of a given bucket.
* @param index An index of a bucket to access.
* @return An iterator to the end of the given bucket.
*/
[[nodiscard]] const_local_iterator end(const size_type index) const {
return cend(index);
}
/**
* @brief Returns an iterator to the end of a given bucket.
* @param index An index of a bucket to access.
* @return An iterator to the end of the given bucket.
*/
[[nodiscard]] local_iterator end([[maybe_unused]] const size_type index) {
return {packed.first().begin(), (std::numeric_limits<size_type>::max)()};
}
/**
* @brief Returns the number of buckets.
* @return The number of buckets.
*/
[[nodiscard]] size_type bucket_count() const {
return sparse.first().size();
}
/**
* @brief Returns the maximum number of buckets.
* @return The maximum number of buckets.
*/
[[nodiscard]] size_type max_bucket_count() const {
return sparse.first().max_size();
}
/**
* @brief Returns the number of elements in a given bucket.
* @param index The index of the bucket to examine.
* @return The number of elements in the given bucket.
*/
[[nodiscard]] size_type bucket_size(const size_type index) const {
return static_cast<size_type>(std::distance(begin(index), end(index)));
}
/**
* @brief Returns the bucket for a given key.
* @param key The value of the key to examine.
* @return The bucket for the given key.
*/
[[nodiscard]] size_type bucket(const key_type &key) const {
return key_to_bucket(key);
}
/**
* @brief Returns the average number of elements per bucket.
* @return The average number of elements per bucket.
*/
[[nodiscard]] float load_factor() const {
return size() / static_cast<float>(bucket_count());
}
/**
* @brief Returns the maximum average number of elements per bucket.
* @return The maximum average number of elements per bucket.
*/
[[nodiscard]] float max_load_factor() const {
return threshold;
}
/**
* @brief Sets the desired maximum average number of elements per bucket.
* @param value A desired maximum average number of elements per bucket.
*/
void max_load_factor(const float value) {
ENTT_ASSERT(value > 0.f, "Invalid load factor");
threshold = value;
rehash(0u);
}
/**
* @brief Reserves at least the specified number of buckets and regenerates
* the hash table.
* @param cnt New number of buckets.
*/
void rehash(const size_type cnt) {
auto value = cnt > minimum_capacity ? cnt : minimum_capacity;
const auto cap = static_cast<size_type>(size() / max_load_factor());
value = value > cap ? value : cap;
if(const auto sz = next_power_of_two(value); sz != bucket_count()) {
sparse.first().resize(sz);
for(auto &&elem: sparse.first()) {
elem = std::numeric_limits<size_type>::max();
}
for(size_type pos{}, last = size(); pos < last; ++pos) {
const auto index = key_to_bucket(packed.first()[pos].element.first);
packed.first()[pos].next = std::exchange(sparse.first()[index], pos);
}
}
}
/**
* @brief Reserves space for at least the specified number of elements and
* regenerates the hash table.
* @param cnt New number of elements.
*/
void reserve(const size_type cnt) {
packed.first().reserve(cnt);
rehash(static_cast<size_type>(std::ceil(cnt / max_load_factor())));
}
/**
* @brief Returns the function used to hash the keys.
* @return The function used to hash the keys.
*/
[[nodiscard]] hasher hash_function() const {
return sparse.second();
}
/**
* @brief Returns the function used to compare keys for equality.
* @return The function used to compare keys for equality.
*/
[[nodiscard]] key_equal key_eq() const {
return packed.second();
}
private:
compressed_pair<sparse_container_type, hasher> sparse;
compressed_pair<packed_container_type, key_equal> packed;
float threshold;
};
} // namespace entt
/**
* @cond TURN_OFF_DOXYGEN
* Internal details not to be documented.
*/
namespace std {
template<typename Key, typename Value, typename Allocator>
struct uses_allocator<entt::internal::dense_map_node<Key, Value>, Allocator>
: std::true_type {};
} // namespace std
/**
* Internal details not to be documented.
* @endcond
*/
#endif