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flat_hash_map.hpp
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flat_hash_map.hpp
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// Copyright Malte Skarupke 2017.
// Distributed under the Boost Software License, Version 1.0.
// (See http://www.boost.org/LICENSE_1_0.txt)
#pragma once
#include <cstdint>
#include <cstddef>
#include <functional>
#include <cmath>
#include <algorithm>
#include <iterator>
#include <utility>
#include <type_traits>
#ifdef _MSC_VER
#define SKA_NOINLINE(...) __declspec(noinline) __VA_ARGS__
#else
#define SKA_NOINLINE(...) __VA_ARGS__ __attribute__((noinline))
#endif
namespace ska
{
struct prime_number_hash_policy;
struct power_of_two_hash_policy;
struct fibonacci_hash_policy;
namespace detailv3
{
template<typename Result, typename Functor>
struct functor_storage : Functor
{
functor_storage() = default;
functor_storage(const Functor & functor)
: Functor(functor)
{
}
template<typename... Args>
Result operator()(Args &&... args)
{
return static_cast<Functor &>(*this)(std::forward<Args>(args)...);
}
template<typename... Args>
Result operator()(Args &&... args) const
{
return static_cast<const Functor &>(*this)(std::forward<Args>(args)...);
}
};
template<typename Result, typename... Args>
struct functor_storage<Result, Result (*)(Args...)>
{
typedef Result (*function_ptr)(Args...);
function_ptr function;
functor_storage(function_ptr function)
: function(function)
{
}
Result operator()(Args... args) const
{
return function(std::forward<Args>(args)...);
}
operator function_ptr &()
{
return function;
}
operator const function_ptr &()
{
return function;
}
};
template<typename key_type, typename value_type, typename hasher>
struct KeyOrValueHasher : functor_storage<size_t, hasher>
{
typedef functor_storage<size_t, hasher> hasher_storage;
KeyOrValueHasher() = default;
KeyOrValueHasher(const hasher & hash)
: hasher_storage(hash)
{
}
size_t operator()(const key_type & key)
{
return static_cast<hasher_storage &>(*this)(key);
}
size_t operator()(const key_type & key) const
{
return static_cast<const hasher_storage &>(*this)(key);
}
size_t operator()(const value_type & value)
{
return static_cast<hasher_storage &>(*this)(value.first);
}
size_t operator()(const value_type & value) const
{
return static_cast<const hasher_storage &>(*this)(value.first);
}
template<typename F, typename S>
size_t operator()(const std::pair<F, S> & value)
{
return static_cast<hasher_storage &>(*this)(value.first);
}
template<typename F, typename S>
size_t operator()(const std::pair<F, S> & value) const
{
return static_cast<const hasher_storage &>(*this)(value.first);
}
};
template<typename key_type, typename value_type, typename key_equal>
struct KeyOrValueEquality : functor_storage<bool, key_equal>
{
typedef functor_storage<bool, key_equal> equality_storage;
KeyOrValueEquality() = default;
KeyOrValueEquality(const key_equal & equality)
: equality_storage(equality)
{
}
bool operator()(const key_type & lhs, const key_type & rhs)
{
return static_cast<equality_storage &>(*this)(lhs, rhs);
}
bool operator()(const key_type & lhs, const value_type & rhs)
{
return static_cast<equality_storage &>(*this)(lhs, rhs.first);
}
bool operator()(const value_type & lhs, const key_type & rhs)
{
return static_cast<equality_storage &>(*this)(lhs.first, rhs);
}
bool operator()(const value_type & lhs, const value_type & rhs)
{
return static_cast<equality_storage &>(*this)(lhs.first, rhs.first);
}
template<typename F, typename S>
bool operator()(const key_type & lhs, const std::pair<F, S> & rhs)
{
return static_cast<equality_storage &>(*this)(lhs, rhs.first);
}
template<typename F, typename S>
bool operator()(const std::pair<F, S> & lhs, const key_type & rhs)
{
return static_cast<equality_storage &>(*this)(lhs.first, rhs);
}
template<typename F, typename S>
bool operator()(const value_type & lhs, const std::pair<F, S> & rhs)
{
return static_cast<equality_storage &>(*this)(lhs.first, rhs.first);
}
template<typename F, typename S>
bool operator()(const std::pair<F, S> & lhs, const value_type & rhs)
{
return static_cast<equality_storage &>(*this)(lhs.first, rhs.first);
}
template<typename FL, typename SL, typename FR, typename SR>
bool operator()(const std::pair<FL, SL> & lhs, const std::pair<FR, SR> & rhs)
{
return static_cast<equality_storage &>(*this)(lhs.first, rhs.first);
}
};
static constexpr int8_t min_lookups = 4;
template<typename T>
struct sherwood_v3_entry
{
sherwood_v3_entry()
{
}
sherwood_v3_entry(int8_t distance_from_desired)
: distance_from_desired(distance_from_desired)
{
}
~sherwood_v3_entry()
{
}
static sherwood_v3_entry * empty_default_table()
{
static sherwood_v3_entry result[min_lookups] = { {}, {}, {}, {special_end_value} };
return result;
}
bool has_value() const
{
return distance_from_desired >= 0;
}
bool is_empty() const
{
return distance_from_desired < 0;
}
bool is_at_desired_position() const
{
return distance_from_desired <= 0;
}
template<typename... Args>
void emplace(int8_t distance, Args &&... args)
{
new (std::addressof(value)) T(std::forward<Args>(args)...);
distance_from_desired = distance;
}
void destroy_value()
{
value.~T();
distance_from_desired = -1;
}
int8_t distance_from_desired = -1;
static constexpr int8_t special_end_value = 0;
union { T value; };
};
inline int8_t log2(size_t value)
{
static constexpr int8_t table[64] =
{
63, 0, 58, 1, 59, 47, 53, 2,
60, 39, 48, 27, 54, 33, 42, 3,
61, 51, 37, 40, 49, 18, 28, 20,
55, 30, 34, 11, 43, 14, 22, 4,
62, 57, 46, 52, 38, 26, 32, 41,
50, 36, 17, 19, 29, 10, 13, 21,
56, 45, 25, 31, 35, 16, 9, 12,
44, 24, 15, 8, 23, 7, 6, 5
};
value |= value >> 1;
value |= value >> 2;
value |= value >> 4;
value |= value >> 8;
value |= value >> 16;
value |= value >> 32;
return table[((value - (value >> 1)) * 0x07EDD5E59A4E28C2) >> 58];
}
template<typename T, bool>
struct AssignIfTrue
{
void operator()(T & lhs, const T & rhs)
{
lhs = rhs;
}
void operator()(T & lhs, T && rhs)
{
lhs = std::move(rhs);
}
};
template<typename T>
struct AssignIfTrue<T, false>
{
void operator()(T &, const T &)
{
}
void operator()(T &, T &&)
{
}
};
inline size_t next_power_of_two(size_t i)
{
--i;
i |= i >> 1;
i |= i >> 2;
i |= i >> 4;
i |= i >> 8;
i |= i >> 16;
i |= i >> 32;
++i;
return i;
}
template<typename...> using void_t = void;
template<typename T, typename = void>
struct HashPolicySelector
{
typedef fibonacci_hash_policy type;
};
template<typename T>
struct HashPolicySelector<T, void_t<typename T::hash_policy>>
{
typedef typename T::hash_policy type;
};
template<typename T, typename FindKey, typename ArgumentHash, typename Hasher, typename ArgumentEqual, typename Equal, typename ArgumentAlloc, typename EntryAlloc>
class sherwood_v3_table : private EntryAlloc, private Hasher, private Equal
{
using Entry = detailv3::sherwood_v3_entry<T>;
using AllocatorTraits = std::allocator_traits<EntryAlloc>;
using EntryPointer = typename AllocatorTraits::pointer;
struct convertible_to_iterator;
public:
using value_type = T;
using size_type = size_t;
using difference_type = std::ptrdiff_t;
using hasher = ArgumentHash;
using key_equal = ArgumentEqual;
using allocator_type = EntryAlloc;
using reference = value_type &;
using const_reference = const value_type &;
using pointer = value_type *;
using const_pointer = const value_type *;
sherwood_v3_table()
{
}
explicit sherwood_v3_table(size_type bucket_count, const ArgumentHash & hash = ArgumentHash(), const ArgumentEqual & equal = ArgumentEqual(), const ArgumentAlloc & alloc = ArgumentAlloc())
: EntryAlloc(alloc), Hasher(hash), Equal(equal)
{
rehash(bucket_count);
}
sherwood_v3_table(size_type bucket_count, const ArgumentAlloc & alloc)
: sherwood_v3_table(bucket_count, ArgumentHash(), ArgumentEqual(), alloc)
{
}
sherwood_v3_table(size_type bucket_count, const ArgumentHash & hash, const ArgumentAlloc & alloc)
: sherwood_v3_table(bucket_count, hash, ArgumentEqual(), alloc)
{
}
explicit sherwood_v3_table(const ArgumentAlloc & alloc)
: EntryAlloc(alloc)
{
}
template<typename It>
sherwood_v3_table(It first, It last, size_type bucket_count = 0, const ArgumentHash & hash = ArgumentHash(), const ArgumentEqual & equal = ArgumentEqual(), const ArgumentAlloc & alloc = ArgumentAlloc())
: sherwood_v3_table(bucket_count, hash, equal, alloc)
{
insert(first, last);
}
template<typename It>
sherwood_v3_table(It first, It last, size_type bucket_count, const ArgumentAlloc & alloc)
: sherwood_v3_table(first, last, bucket_count, ArgumentHash(), ArgumentEqual(), alloc)
{
}
template<typename It>
sherwood_v3_table(It first, It last, size_type bucket_count, const ArgumentHash & hash, const ArgumentAlloc & alloc)
: sherwood_v3_table(first, last, bucket_count, hash, ArgumentEqual(), alloc)
{
}
sherwood_v3_table(std::initializer_list<T> il, size_type bucket_count = 0, const ArgumentHash & hash = ArgumentHash(), const ArgumentEqual & equal = ArgumentEqual(), const ArgumentAlloc & alloc = ArgumentAlloc())
: sherwood_v3_table(bucket_count, hash, equal, alloc)
{
if (bucket_count == 0)
rehash(il.size());
insert(il.begin(), il.end());
}
sherwood_v3_table(std::initializer_list<T> il, size_type bucket_count, const ArgumentAlloc & alloc)
: sherwood_v3_table(il, bucket_count, ArgumentHash(), ArgumentEqual(), alloc)
{
}
sherwood_v3_table(std::initializer_list<T> il, size_type bucket_count, const ArgumentHash & hash, const ArgumentAlloc & alloc)
: sherwood_v3_table(il, bucket_count, hash, ArgumentEqual(), alloc)
{
}
sherwood_v3_table(const sherwood_v3_table & other)
: sherwood_v3_table(other, AllocatorTraits::select_on_container_copy_construction(other.get_allocator()))
{
}
sherwood_v3_table(const sherwood_v3_table & other, const ArgumentAlloc & alloc)
: EntryAlloc(alloc), Hasher(other), Equal(other), _max_load_factor(other._max_load_factor)
{
rehash_for_other_container(other);
try
{
insert(other.begin(), other.end());
}
catch(...)
{
clear();
deallocate_data(entries, num_slots_minus_one, max_lookups);
throw;
}
}
sherwood_v3_table(sherwood_v3_table && other) noexcept
: EntryAlloc(std::move(other)), Hasher(std::move(other)), Equal(std::move(other))
{
swap_pointers(other);
}
sherwood_v3_table(sherwood_v3_table && other, const ArgumentAlloc & alloc) noexcept
: EntryAlloc(alloc), Hasher(std::move(other)), Equal(std::move(other))
{
swap_pointers(other);
}
sherwood_v3_table & operator=(const sherwood_v3_table & other)
{
if (this == std::addressof(other))
return *this;
clear();
if (AllocatorTraits::propagate_on_container_copy_assignment::value)
{
if (static_cast<EntryAlloc &>(*this) != static_cast<const EntryAlloc &>(other))
{
reset_to_empty_state();
}
AssignIfTrue<EntryAlloc, AllocatorTraits::propagate_on_container_copy_assignment::value>()(*this, other);
}
_max_load_factor = other._max_load_factor;
static_cast<Hasher &>(*this) = other;
static_cast<Equal &>(*this) = other;
rehash_for_other_container(other);
insert(other.begin(), other.end());
return *this;
}
sherwood_v3_table & operator=(sherwood_v3_table && other) noexcept
{
if (this == std::addressof(other))
return *this;
else if (AllocatorTraits::propagate_on_container_move_assignment::value)
{
clear();
reset_to_empty_state();
AssignIfTrue<EntryAlloc, AllocatorTraits::propagate_on_container_move_assignment::value>()(*this, std::move(other));
swap_pointers(other);
}
else if (static_cast<EntryAlloc &>(*this) == static_cast<EntryAlloc &>(other))
{
swap_pointers(other);
}
else
{
clear();
_max_load_factor = other._max_load_factor;
rehash_for_other_container(other);
for (T & elem : other)
emplace(std::move(elem));
other.clear();
}
static_cast<Hasher &>(*this) = std::move(other);
static_cast<Equal &>(*this) = std::move(other);
return *this;
}
~sherwood_v3_table()
{
clear();
deallocate_data(entries, num_slots_minus_one, max_lookups);
}
const allocator_type & get_allocator() const
{
return static_cast<const allocator_type &>(*this);
}
const ArgumentEqual & key_eq() const
{
return static_cast<const ArgumentEqual &>(*this);
}
const ArgumentHash & hash_function() const
{
return static_cast<const ArgumentHash &>(*this);
}
template<typename ValueType>
struct templated_iterator
{
templated_iterator() = default;
templated_iterator(EntryPointer current)
: current(current)
{
}
EntryPointer current = EntryPointer();
using iterator_category = std::forward_iterator_tag;
using value_type = ValueType;
using difference_type = ptrdiff_t;
using pointer = ValueType *;
using reference = ValueType &;
friend bool operator==(const templated_iterator & lhs, const templated_iterator & rhs)
{
return lhs.current == rhs.current;
}
friend bool operator!=(const templated_iterator & lhs, const templated_iterator & rhs)
{
return !(lhs == rhs);
}
templated_iterator & operator++()
{
do
{
++current;
}
while(current->is_empty());
return *this;
}
templated_iterator operator++(int)
{
templated_iterator copy(*this);
++*this;
return copy;
}
ValueType & operator*() const
{
return current->value;
}
ValueType * operator->() const
{
return std::addressof(current->value);
}
operator templated_iterator<const value_type>() const
{
return { current };
}
};
using iterator = templated_iterator<value_type>;
using const_iterator = templated_iterator<const value_type>;
iterator begin()
{
for (EntryPointer it = entries;; ++it)
{
if (it->has_value())
return { it };
}
}
const_iterator begin() const
{
for (EntryPointer it = entries;; ++it)
{
if (it->has_value())
return { it };
}
}
const_iterator cbegin() const
{
return begin();
}
iterator end()
{
return { entries + static_cast<ptrdiff_t>(num_slots_minus_one + max_lookups) };
}
const_iterator end() const
{
return { entries + static_cast<ptrdiff_t>(num_slots_minus_one + max_lookups) };
}
const_iterator cend() const
{
return end();
}
iterator find(const FindKey & key)
{
size_t index = hash_policy.index_for_hash(hash_object(key), num_slots_minus_one);
EntryPointer it = entries + ptrdiff_t(index);
for (int8_t distance = 0; it->distance_from_desired >= distance; ++distance, ++it)
{
if (compares_equal(key, it->value))
return { it };
}
return end();
}
const_iterator find(const FindKey & key) const
{
return const_cast<sherwood_v3_table *>(this)->find(key);
}
size_t count(const FindKey & key) const
{
return find(key) == end() ? 0 : 1;
}
std::pair<iterator, iterator> equal_range(const FindKey & key)
{
iterator found = find(key);
if (found == end())
return { found, found };
else
return { found, std::next(found) };
}
std::pair<const_iterator, const_iterator> equal_range(const FindKey & key) const
{
const_iterator found = find(key);
if (found == end())
return { found, found };
else
return { found, std::next(found) };
}
template<typename Key, typename... Args>
std::pair<iterator, bool> emplace(Key && key, Args &&... args)
{
size_t index = hash_policy.index_for_hash(hash_object(key), num_slots_minus_one);
EntryPointer current_entry = entries + ptrdiff_t(index);
int8_t distance_from_desired = 0;
for (; current_entry->distance_from_desired >= distance_from_desired; ++current_entry, ++distance_from_desired)
{
if (compares_equal(key, current_entry->value))
return { { current_entry }, false };
}
return emplace_new_key(distance_from_desired, current_entry, std::forward<Key>(key), std::forward<Args>(args)...);
}
std::pair<iterator, bool> insert(const value_type & value)
{
return emplace(value);
}
std::pair<iterator, bool> insert(value_type && value)
{
return emplace(std::move(value));
}
template<typename... Args>
iterator emplace_hint(const_iterator, Args &&... args)
{
return emplace(std::forward<Args>(args)...).first;
}
iterator insert(const_iterator, const value_type & value)
{
return emplace(value).first;
}
iterator insert(const_iterator, value_type && value)
{
return emplace(std::move(value)).first;
}
template<typename It>
void insert(It begin, It end)
{
for (; begin != end; ++begin)
{
emplace(*begin);
}
}
void insert(std::initializer_list<value_type> il)
{
insert(il.begin(), il.end());
}
void rehash(size_t num_buckets)
{
num_buckets = std::max(num_buckets, static_cast<size_t>(std::ceil(num_elements / static_cast<double>(_max_load_factor))));
if (num_buckets == 0)
{
reset_to_empty_state();
return;
}
auto new_prime_index = hash_policy.next_size_over(num_buckets);
if (num_buckets == bucket_count())
return;
int8_t new_max_lookups = compute_max_lookups(num_buckets);
EntryPointer new_buckets(AllocatorTraits::allocate(*this, num_buckets + new_max_lookups));
EntryPointer special_end_item = new_buckets + static_cast<ptrdiff_t>(num_buckets + new_max_lookups - 1);
for (EntryPointer it = new_buckets; it != special_end_item; ++it)
it->distance_from_desired = -1;
special_end_item->distance_from_desired = Entry::special_end_value;
std::swap(entries, new_buckets);
std::swap(num_slots_minus_one, num_buckets);
--num_slots_minus_one;
hash_policy.commit(new_prime_index);
int8_t old_max_lookups = max_lookups;
max_lookups = new_max_lookups;
num_elements = 0;
for (EntryPointer it = new_buckets, end = it + static_cast<ptrdiff_t>(num_buckets + old_max_lookups); it != end; ++it)
{
if (it->has_value())
{
emplace(std::move(it->value));
it->destroy_value();
}
}
deallocate_data(new_buckets, num_buckets, old_max_lookups);
}
void reserve(size_t num_elements)
{
size_t required_buckets = num_buckets_for_reserve(num_elements);
if (required_buckets > bucket_count())
rehash(required_buckets);
}
// the return value is a type that can be converted to an iterator
// the reason for doing this is that it's not free to find the
// iterator pointing at the next element. if you care about the
// next iterator, turn the return value into an iterator
convertible_to_iterator erase(const_iterator to_erase)
{
EntryPointer current = to_erase.current;
current->destroy_value();
--num_elements;
for (EntryPointer next = current + ptrdiff_t(1); !next->is_at_desired_position(); ++current, ++next)
{
current->emplace(next->distance_from_desired - 1, std::move(next->value));
next->destroy_value();
}
return { to_erase.current };
}
iterator erase(const_iterator begin_it, const_iterator end_it)
{
if (begin_it == end_it)
return { begin_it.current };
for (EntryPointer it = begin_it.current, end = end_it.current; it != end; ++it)
{
if (it->has_value())
{
it->destroy_value();
--num_elements;
}
}
if (end_it == this->end())
return this->end();
ptrdiff_t num_to_move = std::min(static_cast<ptrdiff_t>(end_it.current->distance_from_desired), end_it.current - begin_it.current);
EntryPointer to_return = end_it.current - num_to_move;
for (EntryPointer it = end_it.current; !it->is_at_desired_position();)
{
EntryPointer target = it - num_to_move;
target->emplace(it->distance_from_desired - num_to_move, std::move(it->value));
it->destroy_value();
++it;
num_to_move = std::min(static_cast<ptrdiff_t>(it->distance_from_desired), num_to_move);
}
return { to_return };
}
size_t erase(const FindKey & key)
{
auto found = find(key);
if (found == end())
return 0;
else
{
erase(found);
return 1;
}
}
void clear()
{
for (EntryPointer it = entries, end = it + static_cast<ptrdiff_t>(num_slots_minus_one + max_lookups); it != end; ++it)
{
if (it->has_value())
it->destroy_value();
}
num_elements = 0;
}
void shrink_to_fit()
{
rehash_for_other_container(*this);
}
void swap(sherwood_v3_table & other)
{
using std::swap;
swap_pointers(other);
swap(static_cast<ArgumentHash &>(*this), static_cast<ArgumentHash &>(other));
swap(static_cast<ArgumentEqual &>(*this), static_cast<ArgumentEqual &>(other));
if (AllocatorTraits::propagate_on_container_swap::value)
swap(static_cast<EntryAlloc &>(*this), static_cast<EntryAlloc &>(other));
}
size_t size() const
{
return num_elements;
}
size_t max_size() const
{
return (AllocatorTraits::max_size(*this)) / sizeof(Entry);
}
size_t bucket_count() const
{
return num_slots_minus_one ? num_slots_minus_one + 1 : 0;
}
size_type max_bucket_count() const
{
return (AllocatorTraits::max_size(*this) - min_lookups) / sizeof(Entry);
}
size_t bucket(const FindKey & key) const
{
return hash_policy.index_for_hash(hash_object(key), num_slots_minus_one);
}
float load_factor() const
{
size_t buckets = bucket_count();
if (buckets)
return static_cast<float>(num_elements) / bucket_count();
else
return 0;
}
void max_load_factor(float value)
{
_max_load_factor = value;
}
float max_load_factor() const
{
return _max_load_factor;
}
bool empty() const
{
return num_elements == 0;
}
private:
EntryPointer entries = Entry::empty_default_table();
size_t num_slots_minus_one = 0;
typename HashPolicySelector<ArgumentHash>::type hash_policy;
int8_t max_lookups = detailv3::min_lookups - 1;
float _max_load_factor = 0.5f;
size_t num_elements = 0;
static int8_t compute_max_lookups(size_t num_buckets)
{
int8_t desired = detailv3::log2(num_buckets);
return std::max(detailv3::min_lookups, desired);
}
size_t num_buckets_for_reserve(size_t num_elements) const
{
return static_cast<size_t>(std::ceil(num_elements / std::min(0.5, static_cast<double>(_max_load_factor))));
}
void rehash_for_other_container(const sherwood_v3_table & other)
{
rehash(std::min(num_buckets_for_reserve(other.size()), other.bucket_count()));
}
void swap_pointers(sherwood_v3_table & other)
{
using std::swap;
swap(hash_policy, other.hash_policy);
swap(entries, other.entries);
swap(num_slots_minus_one, other.num_slots_minus_one);
swap(num_elements, other.num_elements);
swap(max_lookups, other.max_lookups);
swap(_max_load_factor, other._max_load_factor);
}
template<typename Key, typename... Args>
SKA_NOINLINE(std::pair<iterator, bool>) emplace_new_key(int8_t distance_from_desired, EntryPointer current_entry, Key && key, Args &&... args)
{
using std::swap;
if (num_slots_minus_one == 0 || distance_from_desired == max_lookups || num_elements + 1 > (num_slots_minus_one + 1) * static_cast<double>(_max_load_factor))
{
grow();
return emplace(std::forward<Key>(key), std::forward<Args>(args)...);
}
else if (current_entry->is_empty())
{
current_entry->emplace(distance_from_desired, std::forward<Key>(key), std::forward<Args>(args)...);
++num_elements;
return { { current_entry }, true };
}
value_type to_insert(std::forward<Key>(key), std::forward<Args>(args)...);
swap(distance_from_desired, current_entry->distance_from_desired);
swap(to_insert, current_entry->value);
iterator result = { current_entry };
for (++distance_from_desired, ++current_entry;; ++current_entry)
{
if (current_entry->is_empty())
{
current_entry->emplace(distance_from_desired, std::move(to_insert));
++num_elements;
return { result, true };
}
else if (current_entry->distance_from_desired < distance_from_desired)
{
swap(distance_from_desired, current_entry->distance_from_desired);
swap(to_insert, current_entry->value);
++distance_from_desired;
}
else
{
++distance_from_desired;
if (distance_from_desired == max_lookups)
{
swap(to_insert, result.current->value);
grow();
return emplace(std::move(to_insert));
}
}
}
}
void grow()
{
rehash(std::max(size_t(4), 2 * bucket_count()));
}
void deallocate_data(EntryPointer begin, size_t num_slots_minus_one, int8_t max_lookups)
{
if (begin != Entry::empty_default_table())
{
AllocatorTraits::deallocate(*this, begin, num_slots_minus_one + max_lookups + 1);
}
}
void reset_to_empty_state()
{
deallocate_data(entries, num_slots_minus_one, max_lookups);
entries = Entry::empty_default_table();
num_slots_minus_one = 0;
hash_policy.reset();
max_lookups = detailv3::min_lookups - 1;
}
template<typename U>
size_t hash_object(const U & key)
{
return static_cast<Hasher &>(*this)(key);
}
template<typename U>
size_t hash_object(const U & key) const
{
return static_cast<const Hasher &>(*this)(key);
}
template<typename L, typename R>
bool compares_equal(const L & lhs, const R & rhs)
{
return static_cast<Equal &>(*this)(lhs, rhs);
}
struct convertible_to_iterator
{
EntryPointer it;
operator iterator()
{
if (it->has_value())
return { it };
else
return ++iterator{it};
}
operator const_iterator()
{
if (it->has_value())
return { it };
else
return ++const_iterator{it};
}
};
};
}
struct prime_number_hash_policy
{
static size_t mod0(size_t) { return 0llu; }
static size_t mod2(size_t hash) { return hash % 2llu; }
static size_t mod3(size_t hash) { return hash % 3llu; }
static size_t mod5(size_t hash) { return hash % 5llu; }
static size_t mod7(size_t hash) { return hash % 7llu; }
static size_t mod11(size_t hash) { return hash % 11llu; }
static size_t mod13(size_t hash) { return hash % 13llu; }
static size_t mod17(size_t hash) { return hash % 17llu; }
static size_t mod23(size_t hash) { return hash % 23llu; }
static size_t mod29(size_t hash) { return hash % 29llu; }
static size_t mod37(size_t hash) { return hash % 37llu; }
static size_t mod47(size_t hash) { return hash % 47llu; }
static size_t mod59(size_t hash) { return hash % 59llu; }
static size_t mod73(size_t hash) { return hash % 73llu; }
static size_t mod97(size_t hash) { return hash % 97llu; }
static size_t mod127(size_t hash) { return hash % 127llu; }
static size_t mod151(size_t hash) { return hash % 151llu; }
static size_t mod197(size_t hash) { return hash % 197llu; }
static size_t mod251(size_t hash) { return hash % 251llu; }
static size_t mod313(size_t hash) { return hash % 313llu; }
static size_t mod397(size_t hash) { return hash % 397llu; }
static size_t mod499(size_t hash) { return hash % 499llu; }
static size_t mod631(size_t hash) { return hash % 631llu; }
static size_t mod797(size_t hash) { return hash % 797llu; }
static size_t mod1009(size_t hash) { return hash % 1009llu; }
static size_t mod1259(size_t hash) { return hash % 1259llu; }
static size_t mod1597(size_t hash) { return hash % 1597llu; }
static size_t mod2011(size_t hash) { return hash % 2011llu; }
static size_t mod2539(size_t hash) { return hash % 2539llu; }
static size_t mod3203(size_t hash) { return hash % 3203llu; }
static size_t mod4027(size_t hash) { return hash % 4027llu; }
static size_t mod5087(size_t hash) { return hash % 5087llu; }
static size_t mod6421(size_t hash) { return hash % 6421llu; }
static size_t mod8089(size_t hash) { return hash % 8089llu; }
static size_t mod10193(size_t hash) { return hash % 10193llu; }
static size_t mod12853(size_t hash) { return hash % 12853llu; }
static size_t mod16193(size_t hash) { return hash % 16193llu; }
static size_t mod20399(size_t hash) { return hash % 20399llu; }
static size_t mod25717(size_t hash) { return hash % 25717llu; }
static size_t mod32401(size_t hash) { return hash % 32401llu; }
static size_t mod40823(size_t hash) { return hash % 40823llu; }
static size_t mod51437(size_t hash) { return hash % 51437llu; }
static size_t mod64811(size_t hash) { return hash % 64811llu; }
static size_t mod81649(size_t hash) { return hash % 81649llu; }
static size_t mod102877(size_t hash) { return hash % 102877llu; }
static size_t mod129607(size_t hash) { return hash % 129607llu; }
static size_t mod163307(size_t hash) { return hash % 163307llu; }
static size_t mod205759(size_t hash) { return hash % 205759llu; }
static size_t mod259229(size_t hash) { return hash % 259229llu; }
static size_t mod326617(size_t hash) { return hash % 326617llu; }
static size_t mod411527(size_t hash) { return hash % 411527llu; }
static size_t mod518509(size_t hash) { return hash % 518509llu; }
static size_t mod653267(size_t hash) { return hash % 653267llu; }
static size_t mod823117(size_t hash) { return hash % 823117llu; }
static size_t mod1037059(size_t hash) { return hash % 1037059llu; }
static size_t mod1306601(size_t hash) { return hash % 1306601llu; }
static size_t mod1646237(size_t hash) { return hash % 1646237llu; }
static size_t mod2074129(size_t hash) { return hash % 2074129llu; }
static size_t mod2613229(size_t hash) { return hash % 2613229llu; }
static size_t mod3292489(size_t hash) { return hash % 3292489llu; }
static size_t mod4148279(size_t hash) { return hash % 4148279llu; }
static size_t mod5226491(size_t hash) { return hash % 5226491llu; }
static size_t mod6584983(size_t hash) { return hash % 6584983llu; }
static size_t mod8296553(size_t hash) { return hash % 8296553llu; }
static size_t mod10453007(size_t hash) { return hash % 10453007llu; }
static size_t mod13169977(size_t hash) { return hash % 13169977llu; }
static size_t mod16593127(size_t hash) { return hash % 16593127llu; }
static size_t mod20906033(size_t hash) { return hash % 20906033llu; }
static size_t mod26339969(size_t hash) { return hash % 26339969llu; }