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f8d7b4daea
Example failure: IDAllocator.h only pulls in AK/Hashtable.h, so any compilation unit that includes AK/IDAllocator.h without including AK/Traits.h before it used to be doomed to fail with the cryptic error message "In instantiation of 'AK::HashTable<T, TraitsForT, IsOrdered>::Iterator AK::HashTable<T, TraitsForT, IsOrdered>::find(const T&) [with T = int; TraitsForT = AK::Traits: incomplete type 'AK::Traits<int>' used in nested name specifier".
500 lines
14 KiB
C++
500 lines
14 KiB
C++
/*
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* Copyright (c) 2018-2020, Andreas Kling <kling@serenityos.org>
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*
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* SPDX-License-Identifier: BSD-2-Clause
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*/
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#pragma once
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#include <AK/Forward.h>
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#include <AK/HashFunctions.h>
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#include <AK/StdLibExtras.h>
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#include <AK/Traits.h>
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#include <AK/Types.h>
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#include <AK/kmalloc.h>
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namespace AK {
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enum class HashSetResult {
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Failed = 0,
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InsertedNewEntry,
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ReplacedExistingEntry,
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KeptExistingEntry
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};
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enum class HashSetExistingEntryBehavior {
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Keep,
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Replace
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};
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template<typename HashTableType, typename T, typename BucketType>
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class HashTableIterator {
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friend HashTableType;
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public:
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bool operator==(const HashTableIterator& other) const { return m_bucket == other.m_bucket; }
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bool operator!=(const HashTableIterator& other) const { return m_bucket != other.m_bucket; }
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T& operator*() { return *m_bucket->slot(); }
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T* operator->() { return m_bucket->slot(); }
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void operator++() { skip_to_next(); }
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private:
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void skip_to_next()
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{
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if (!m_bucket)
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return;
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do {
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++m_bucket;
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if (m_bucket->used)
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return;
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} while (!m_bucket->end);
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if (m_bucket->end)
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m_bucket = nullptr;
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}
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explicit HashTableIterator(BucketType* bucket)
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: m_bucket(bucket)
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{
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}
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BucketType* m_bucket { nullptr };
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};
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template<typename OrderedHashTableType, typename T, typename BucketType>
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class OrderedHashTableIterator {
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friend OrderedHashTableType;
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public:
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bool operator==(const OrderedHashTableIterator& other) const { return m_bucket == other.m_bucket; }
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bool operator!=(const OrderedHashTableIterator& other) const { return m_bucket != other.m_bucket; }
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T& operator*() { return *m_bucket->slot(); }
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T* operator->() { return m_bucket->slot(); }
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void operator++() { m_bucket = m_bucket->next; }
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void operator--() { m_bucket = m_bucket->previous; }
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private:
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explicit OrderedHashTableIterator(BucketType* bucket)
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: m_bucket(bucket)
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{
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}
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BucketType* m_bucket { nullptr };
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};
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template<typename T, typename TraitsForT, bool IsOrdered>
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class HashTable {
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static constexpr size_t load_factor_in_percent = 60;
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struct Bucket {
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bool used;
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bool deleted;
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bool end;
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alignas(T) u8 storage[sizeof(T)];
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T* slot() { return reinterpret_cast<T*>(storage); }
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const T* slot() const { return reinterpret_cast<const T*>(storage); }
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};
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struct OrderedBucket {
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OrderedBucket* previous;
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OrderedBucket* next;
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bool used;
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bool deleted;
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alignas(T) u8 storage[sizeof(T)];
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T* slot() { return reinterpret_cast<T*>(storage); }
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const T* slot() const { return reinterpret_cast<const T*>(storage); }
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};
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using BucketType = Conditional<IsOrdered, OrderedBucket, Bucket>;
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struct CollectionData {
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};
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struct OrderedCollectionData {
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BucketType* head { nullptr };
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BucketType* tail { nullptr };
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};
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using CollectionDataType = Conditional<IsOrdered, OrderedCollectionData, CollectionData>;
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public:
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HashTable() = default;
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explicit HashTable(size_t capacity) { rehash(capacity); }
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~HashTable()
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{
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if (!m_buckets)
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return;
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for (size_t i = 0; i < m_capacity; ++i) {
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if (m_buckets[i].used)
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m_buckets[i].slot()->~T();
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}
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kfree_sized(m_buckets, size_in_bytes(m_capacity));
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}
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HashTable(const HashTable& other)
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{
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rehash(other.capacity());
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for (auto& it : other)
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set(it);
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}
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HashTable& operator=(const HashTable& other)
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{
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HashTable temporary(other);
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swap(*this, temporary);
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return *this;
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}
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HashTable(HashTable&& other) noexcept
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: m_buckets(other.m_buckets)
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, m_collection_data(other.m_collection_data)
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, m_size(other.m_size)
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, m_capacity(other.m_capacity)
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, m_deleted_count(other.m_deleted_count)
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{
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other.m_size = 0;
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other.m_capacity = 0;
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other.m_deleted_count = 0;
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other.m_buckets = nullptr;
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if constexpr (IsOrdered)
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other.m_collection_data = { nullptr, nullptr };
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}
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HashTable& operator=(HashTable&& other) noexcept
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{
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HashTable temporary { move(other) };
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swap(*this, temporary);
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return *this;
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}
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friend void swap(HashTable& a, HashTable& b) noexcept
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{
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swap(a.m_buckets, b.m_buckets);
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swap(a.m_size, b.m_size);
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swap(a.m_capacity, b.m_capacity);
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swap(a.m_deleted_count, b.m_deleted_count);
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if constexpr (IsOrdered)
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swap(a.m_collection_data, b.m_collection_data);
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}
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[[nodiscard]] bool is_empty() const { return !m_size; }
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[[nodiscard]] size_t size() const { return m_size; }
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[[nodiscard]] size_t capacity() const { return m_capacity; }
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template<typename U, size_t N>
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bool try_set_from(U (&from_array)[N])
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{
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for (size_t i = 0; i < N; ++i) {
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if (try_set(from_array[i]) == HashSetResult::Failed)
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return false;
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}
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return true;
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}
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template<typename U, size_t N>
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void set_from(U (&from_array)[N])
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{
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bool result = try_set_from(from_array);
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VERIFY(result);
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}
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void ensure_capacity(size_t capacity)
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{
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VERIFY(capacity >= size());
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rehash(capacity * 2);
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}
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[[nodiscard]] bool contains(T const& value) const
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{
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return find(value) != end();
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}
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using Iterator = Conditional<IsOrdered,
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OrderedHashTableIterator<HashTable, T, BucketType>,
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HashTableIterator<HashTable, T, BucketType>>;
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[[nodiscard]] Iterator begin()
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{
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if constexpr (IsOrdered)
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return Iterator(m_collection_data.head);
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for (size_t i = 0; i < m_capacity; ++i) {
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if (m_buckets[i].used)
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return Iterator(&m_buckets[i]);
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}
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return end();
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}
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[[nodiscard]] Iterator end()
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{
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return Iterator(nullptr);
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}
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using ConstIterator = Conditional<IsOrdered,
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OrderedHashTableIterator<const HashTable, const T, const BucketType>,
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HashTableIterator<const HashTable, const T, const BucketType>>;
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[[nodiscard]] ConstIterator begin() const
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{
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if constexpr (IsOrdered)
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return ConstIterator(m_collection_data.head);
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for (size_t i = 0; i < m_capacity; ++i) {
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if (m_buckets[i].used)
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return ConstIterator(&m_buckets[i]);
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}
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return end();
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}
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[[nodiscard]] ConstIterator end() const
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{
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return ConstIterator(nullptr);
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}
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void clear()
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{
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*this = HashTable();
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}
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template<typename U = T>
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HashSetResult try_set(U&& value, HashSetExistingEntryBehavior existing_entry_behavior = HashSetExistingEntryBehavior::Replace)
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{
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auto* bucket = try_lookup_for_writing(value);
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if (!bucket)
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return HashSetResult::Failed;
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if (bucket->used) {
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if (existing_entry_behavior == HashSetExistingEntryBehavior::Keep)
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return HashSetResult::KeptExistingEntry;
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(*bucket->slot()) = forward<U>(value);
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return HashSetResult::ReplacedExistingEntry;
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}
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new (bucket->slot()) T(forward<U>(value));
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bucket->used = true;
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if (bucket->deleted) {
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bucket->deleted = false;
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--m_deleted_count;
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}
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if constexpr (IsOrdered) {
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if (!m_collection_data.head) [[unlikely]] {
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m_collection_data.head = bucket;
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} else {
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bucket->previous = m_collection_data.tail;
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m_collection_data.tail->next = bucket;
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}
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m_collection_data.tail = bucket;
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}
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++m_size;
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return HashSetResult::InsertedNewEntry;
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}
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template<typename U = T>
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HashSetResult set(U&& value, HashSetExistingEntryBehavior existing_entry_behaviour = HashSetExistingEntryBehavior::Replace)
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{
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auto result = try_set(forward<U>(value), existing_entry_behaviour);
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VERIFY(result != HashSetResult::Failed);
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return result;
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}
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template<typename TUnaryPredicate>
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[[nodiscard]] Iterator find(unsigned hash, TUnaryPredicate predicate)
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{
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return Iterator(lookup_with_hash(hash, move(predicate)));
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}
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[[nodiscard]] Iterator find(T const& value)
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{
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return find(TraitsForT::hash(value), [&](auto& other) { return TraitsForT::equals(value, other); });
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}
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template<typename TUnaryPredicate>
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[[nodiscard]] ConstIterator find(unsigned hash, TUnaryPredicate predicate) const
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{
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return ConstIterator(lookup_with_hash(hash, move(predicate)));
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}
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[[nodiscard]] ConstIterator find(T const& value) const
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{
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return find(TraitsForT::hash(value), [&](auto& other) { return TraitsForT::equals(value, other); });
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}
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bool remove(const T& value)
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{
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auto it = find(value);
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if (it != end()) {
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remove(it);
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return true;
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}
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return false;
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}
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void remove(Iterator iterator)
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{
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VERIFY(iterator.m_bucket);
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auto& bucket = *iterator.m_bucket;
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VERIFY(bucket.used);
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VERIFY(!bucket.deleted);
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if constexpr (!IsOrdered)
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VERIFY(!bucket.end);
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bucket.slot()->~T();
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bucket.used = false;
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bucket.deleted = true;
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--m_size;
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++m_deleted_count;
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if constexpr (IsOrdered) {
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if (bucket.previous)
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bucket.previous->next = bucket.next;
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else
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m_collection_data.head = bucket.next;
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if (bucket.next)
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bucket.next->previous = bucket.previous;
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else
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m_collection_data.tail = bucket.previous;
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}
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}
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private:
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void insert_during_rehash(T&& value)
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{
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auto& bucket = lookup_for_writing(value);
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new (bucket.slot()) T(move(value));
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bucket.used = true;
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if constexpr (IsOrdered) {
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if (!m_collection_data.head) [[unlikely]] {
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m_collection_data.head = &bucket;
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} else {
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bucket.previous = m_collection_data.tail;
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m_collection_data.tail->next = &bucket;
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}
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m_collection_data.tail = &bucket;
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}
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}
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[[nodiscard]] static constexpr size_t size_in_bytes(size_t capacity)
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{
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if constexpr (IsOrdered) {
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return sizeof(BucketType) * capacity;
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} else {
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return sizeof(BucketType) * (capacity + 1);
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}
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}
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bool try_rehash(size_t new_capacity)
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{
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new_capacity = max(new_capacity, static_cast<size_t>(4));
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new_capacity = kmalloc_good_size(new_capacity * sizeof(BucketType)) / sizeof(BucketType);
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auto* old_buckets = m_buckets;
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auto old_capacity = m_capacity;
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Iterator old_iter = begin();
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auto new_buckets = kmalloc(size_in_bytes(new_capacity));
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if (!new_buckets)
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return false;
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m_buckets = (BucketType*)new_buckets;
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__builtin_memset(m_buckets, 0, size_in_bytes(new_capacity));
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m_capacity = new_capacity;
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m_deleted_count = 0;
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if constexpr (IsOrdered)
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m_collection_data = { nullptr, nullptr };
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else
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m_buckets[m_capacity].end = true;
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if (!old_buckets)
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return true;
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for (auto it = move(old_iter); it != end(); ++it) {
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insert_during_rehash(move(*it));
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it->~T();
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}
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kfree_sized(old_buckets, size_in_bytes(old_capacity));
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return true;
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}
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void rehash(size_t new_capacity)
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{
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bool result = try_rehash(new_capacity);
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VERIFY(result);
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}
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template<typename TUnaryPredicate>
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[[nodiscard]] BucketType* lookup_with_hash(unsigned hash, TUnaryPredicate predicate) const
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{
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if (is_empty())
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return nullptr;
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for (;;) {
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auto& bucket = m_buckets[hash % m_capacity];
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if (bucket.used && predicate(*bucket.slot()))
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return &bucket;
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if (!bucket.used && !bucket.deleted)
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return nullptr;
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hash = double_hash(hash);
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}
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}
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[[nodiscard]] BucketType* try_lookup_for_writing(T const& value)
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{
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// FIXME: Maybe overrun the "allowed" load factor to avoid OOM
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// If we are allowed to do that, separate that logic from
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// the normal lookup_for_writing
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if (should_grow()) {
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if (!try_rehash(capacity() * 2))
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return nullptr;
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}
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auto hash = TraitsForT::hash(value);
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BucketType* first_empty_bucket = nullptr;
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for (;;) {
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auto& bucket = m_buckets[hash % m_capacity];
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if (bucket.used && TraitsForT::equals(*bucket.slot(), value))
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return &bucket;
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if (!bucket.used) {
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if (!first_empty_bucket)
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first_empty_bucket = &bucket;
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if (!bucket.deleted)
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return const_cast<BucketType*>(first_empty_bucket);
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}
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hash = double_hash(hash);
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}
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}
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[[nodiscard]] BucketType& lookup_for_writing(T const& value)
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{
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auto* item = try_lookup_for_writing(value);
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VERIFY(item);
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return *item;
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}
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[[nodiscard]] size_t used_bucket_count() const { return m_size + m_deleted_count; }
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[[nodiscard]] bool should_grow() const { return ((used_bucket_count() + 1) * 100) >= (m_capacity * load_factor_in_percent); }
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BucketType* m_buckets { nullptr };
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[[no_unique_address]] CollectionDataType m_collection_data;
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size_t m_size { 0 };
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size_t m_capacity { 0 };
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size_t m_deleted_count { 0 };
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};
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}
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using AK::HashTable;
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using AK::OrderedHashTable;
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