Source/WTF/wtf/HashTraits.h - WebKit - Git at Google

 /*
  * Copyright (C) 2005-2019 Apple Inc. All rights reserved.
  *
  * This library is free software; you can redistribute it and/or
  * modify it under the terms of the GNU Library General Public
  * License as published by the Free Software Foundation; either
  * version 2 of the License, or (at your option) any later version.
  *
  * This library is distributed in the hope that it will be useful,
  * but WITHOUT ANY WARRANTY; without even the implied warranty of
  * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the GNU
  * Library General Public License for more details.
  *
  * You should have received a copy of the GNU Library General Public License
  * along with this library; see the file COPYING.LIB.  If not, write to
  * the Free Software Foundation, Inc., 51 Franklin Street, Fifth Floor,
  * Boston, MA 02110-1301, USA.
  *
  */

 #pragma once

 #include <limits>
 #include <utility>
 #include <wtf/Forward.h>
 #include <wtf/HashFunctions.h>
 #include <wtf/KeyValuePair.h>
 #include <wtf/StdLibExtras.h>

 #ifdef __OBJC__
 #include <CoreFoundation/CoreFoundation.h>
 #endif

 namespace WTF {

 template<bool isInteger, typename T> struct GenericHashTraitsBase;

 template<typename T> struct GenericHashTraitsBase<false, T> {
     // The emptyValueIsZero flag is used to optimize allocation of empty hash tables with zeroed memory.
     static constexpr bool emptyValueIsZero = false;

     // The hasIsEmptyValueFunction flag allows the hash table to automatically generate code to check
     // for the empty value when it can be done with the equality operator, but allows custom functions
     // for cases like String that need them.
     static constexpr bool hasIsEmptyValueFunction = false;

     // Used by WeakPtr to indicate that the value may become deleted without being explicitly removed.
     static constexpr bool hasIsReleasedWeakValueFunction = false;

     // The starting table size. Can be overridden when we know beforehand that
     // a hash table will have at least N entries.
     static constexpr unsigned minimumTableSize = 8;
 };

 // Default integer traits disallow both 0 and -1 as keys (max value instead of -1 for unsigned).
 template<typename T> struct GenericHashTraitsBase<true, T> : GenericHashTraitsBase<false, T> {
     static constexpr bool emptyValueIsZero = true;
     static void constructDeletedValue(T& slot) { slot = static_cast<T>(-1); }
     static bool isDeletedValue(T value) { return value == static_cast<T>(-1); }
 };

 template<typename T> struct GenericHashTraits : GenericHashTraitsBase<std::is_integral<T>::value, T> {
     typedef T TraitType;
     typedef T EmptyValueType;

     static T emptyValue() { return T(); }

     template<typename U, typename V>
     static void assignToEmpty(U& emptyValue, V&& value)
     {
         emptyValue = std::forward<V>(value);
     }

     template <typename Traits>
     static void constructEmptyValue(T& slot)
     {
         new (NotNull, std::addressof(slot)) T(Traits::emptyValue());
     }

     // Type for return value of functions that do not transfer ownership, such as get.
     typedef T PeekType;
     template<typename U> static U&& peek(U&& value) { return std::forward<U>(value); }

     typedef T TakeType;
     template<typename U> static TakeType take(U&& value) { return std::forward<U>(value); }
 };

 template<typename T> struct HashTraits : GenericHashTraits<T> { };

 template<typename T> struct FloatHashTraits : GenericHashTraits<T> {
     static T emptyValue() { return std::numeric_limits<T>::infinity(); }
     static void constructDeletedValue(T& slot) { slot = -std::numeric_limits<T>::infinity(); }
     static bool isDeletedValue(T value) { return value == -std::numeric_limits<T>::infinity(); }
 };

 template<> struct HashTraits<float> : FloatHashTraits<float> { };
 template<> struct HashTraits<double> : FloatHashTraits<double> { };

 // Default unsigned traits disallow both 0 and max as keys -- use these traits to allow zero and disallow max - 1.
 template<typename T> struct UnsignedWithZeroKeyHashTraits : GenericHashTraits<T> {
     static constexpr bool emptyValueIsZero = false;
     static T emptyValue() { return std::numeric_limits<T>::max(); }
     static void constructDeletedValue(T& slot) { slot = std::numeric_limits<T>::max() - 1; }
     static bool isDeletedValue(T value) { return value == std::numeric_limits<T>::max() - 1; }
 };

 template<typename T> struct SignedWithZeroKeyHashTraits : GenericHashTraits<T> {
     static constexpr bool emptyValueIsZero = false;
     static T emptyValue() { return std::numeric_limits<T>::min(); }
     static void constructDeletedValue(T& slot) { slot = std::numeric_limits<T>::max(); }
     static bool isDeletedValue(T value) { return value == std::numeric_limits<T>::max(); }
 };

 // Can be used with strong enums, allows zero as key.
 template<typename T> struct StrongEnumHashTraits : GenericHashTraits<T> {
     using UnderlyingType = typename std::underlying_type<T>::type;
     static constexpr bool emptyValueIsZero = false;
     static T emptyValue() { return static_cast<T>(std::numeric_limits<UnderlyingType>::max()); }
     static void constructDeletedValue(T& slot) { slot = static_cast<T>(std::numeric_limits<UnderlyingType>::max() - 1); }
     static bool isDeletedValue(T value) { return value == static_cast<T>(std::numeric_limits<UnderlyingType>::max() - 1); }
 };

 template<typename P> struct HashTraits<P*> : GenericHashTraits<P*> {
     static constexpr bool emptyValueIsZero = true;
     static void constructDeletedValue(P*& slot) { slot = reinterpret_cast<P*>(-1); }
     static bool isDeletedValue(P* value) { return value == reinterpret_cast<P*>(-1); }
 };

 #ifdef __OBJC__

 template<> struct HashTraits<__unsafe_unretained id> : GenericHashTraits<__unsafe_unretained id> {
     static constexpr bool emptyValueIsZero = true;
     static void constructDeletedValue(__unsafe_unretained id& slot) { slot = (__bridge __unsafe_unretained id)reinterpret_cast<CFTypeRef>(-1); }
     static bool isDeletedValue(__unsafe_unretained id value) { return (__bridge CFTypeRef)value == reinterpret_cast<CFTypeRef>(-1); }
 };

 #endif

 template<typename T> struct SimpleClassHashTraits : GenericHashTraits<T> {
     static constexpr bool emptyValueIsZero = true;
     static void constructDeletedValue(T& slot) { new (NotNull, std::addressof(slot)) T(HashTableDeletedValue); }
     static bool isDeletedValue(const T& value) { return value.isHashTableDeletedValue(); }
 };

 template<typename T, typename Deleter> struct HashTraits<std::unique_ptr<T, Deleter>> : SimpleClassHashTraits<std::unique_ptr<T, Deleter>> {
     typedef std::nullptr_t EmptyValueType;
     static EmptyValueType emptyValue() { return nullptr; }

     static void constructDeletedValue(std::unique_ptr<T, Deleter>& slot) { new (NotNull, std::addressof(slot)) std::unique_ptr<T, Deleter> { reinterpret_cast<T*>(-1) }; }
     static bool isDeletedValue(const std::unique_ptr<T, Deleter>& value) { return value.get() == reinterpret_cast<T*>(-1); }

     typedef T* PeekType;
     static T* peek(const std::unique_ptr<T, Deleter>& value) { return value.get(); }
     static T* peek(std::nullptr_t) { return nullptr; }

     static void customDeleteBucket(std::unique_ptr<T, Deleter>& value)
     {
         // The custom delete function exists to avoid a dead store before the value is destructed.
         // The normal destruction sequence of a bucket would be:
         // 1) Call the destructor of unique_ptr.
         // 2) unique_ptr store a zero for its internal pointer.
         // 3) unique_ptr destroys its value.
         // 4) Call constructDeletedValue() to set the bucket as destructed.
         //
         // The problem is the call in (3) prevents the compile from eliminating the dead store in (2)
         // becase a side effect of free() could be observing the value.
         //
         // This version of deleteBucket() ensures the dead 2 stores changing "value"
         // are on the same side of the function call.
         ASSERT(!isDeletedValue(value));
         T* pointer = value.release();
         constructDeletedValue(value);

         // The null case happens if a caller uses std::move() to remove the pointer before calling remove()
         // with an iterator. This is very uncommon.
         if (LIKELY(pointer))
             Deleter()(pointer);
     }
 };

 template<typename T> struct HashTraits<UniqueRef<T>> : SimpleClassHashTraits<UniqueRef<T>> {
     typedef std::nullptr_t EmptyValueType;
     static EmptyValueType emptyValue() { return nullptr; }

     static void constructDeletedValue(UniqueRef<T>& slot) { new (NotNull, std::addressof(slot)) UniqueRef<T> { reinterpret_cast<T*>(-1) }; }
     static bool isDeletedValue(const UniqueRef<T>& value) { return value.get() == reinterpret_cast<T*>(-1); }

     typedef T* PeekType;
     static const T* peek(const UniqueRef<T>& value) { return &value.get(); }
     static T* peek(UniqueRef<T>& value) { return &value.get(); }
     static T* peek(std::nullptr_t) { return nullptr; }

     using TakeType = std::unique_ptr<T>;
     static TakeType take(UniqueRef<T>&& value) { return value.moveToUniquePtr(); }
     static TakeType take(std::nullptr_t) { return nullptr; }
 };

 template<typename P> struct HashTraits<RefPtr<P>> : SimpleClassHashTraits<RefPtr<P>> {
     static P* emptyValue() { return nullptr; }

     typedef P* PeekType;
     static PeekType peek(const RefPtr<P>& value) { return value.get(); }
     static PeekType peek(P* value) { return value; }

     static void customDeleteBucket(RefPtr<P>& value)
     {
         // See unique_ptr's customDeleteBucket() for an explanation.
         ASSERT(!SimpleClassHashTraits<RefPtr<P>>::isDeletedValue(value));
         auto valueToBeDestroyed = WTFMove(value);
         SimpleClassHashTraits<RefPtr<P>>::constructDeletedValue(value);
     }
 };

 template<typename P> struct RefHashTraits : SimpleClassHashTraits<Ref<P>> {
     static constexpr bool emptyValueIsZero = true;
     static Ref<P> emptyValue() { return HashTableEmptyValue; }

     template <typename>
     static void constructEmptyValue(Ref<P>& slot)
     {
         new (NotNull, std::addressof(slot)) Ref<P>(HashTableEmptyValue);
     }

     static constexpr bool hasIsEmptyValueFunction = true;
     static bool isEmptyValue(const Ref<P>& value) { return value.isHashTableEmptyValue(); }

     using PeekType = P*;
     static PeekType peek(const Ref<P>& value) { return const_cast<PeekType>(value.ptrAllowingHashTableEmptyValue()); }
     static PeekType peek(P* value) { return value; }

     using TakeType = RefPtr<P>;
     static TakeType take(Ref<P>&& value) { return isEmptyValue(value) ? nullptr : RefPtr<P>(WTFMove(value)); }
 };

 template<typename P> struct HashTraits<Ref<P>> : RefHashTraits<P> { };

 template<typename P> struct HashTraits<Packed<P*>> : SimpleClassHashTraits<Packed<P*>> {
     static constexpr bool hasIsEmptyValueFunction = true;
     using TargetType = Packed<P*>;
     static_assert(TargetType::alignment < 4 * KB, "The first page is always unmapped since it includes nullptr.");

     static Packed<P*> emptyValue() { return nullptr; }
     static bool isEmptyValue(const TargetType& value) { return value.get() == nullptr; }

     using PeekType = P*;
     static PeekType peek(const TargetType& value) { return value.get(); }
     static PeekType peek(P* value) { return value; }
 };

 template<> struct HashTraits<String> : SimpleClassHashTraits<String> {
     static constexpr bool hasIsEmptyValueFunction = true;
     static bool isEmptyValue(const String&);

     static void customDeleteBucket(String&);
 };

 // This struct template is an implementation detail of the isHashTraitsEmptyValue function,
 // which selects either the emptyValue function or the isEmptyValue function to check for empty values.
 template<typename Traits, bool hasEmptyValueFunction> struct HashTraitsEmptyValueChecker;
 template<typename Traits> struct HashTraitsEmptyValueChecker<Traits, true> {
     template<typename T> static bool isEmptyValue(const T& value) { return Traits::isEmptyValue(value); }
 };
 template<typename Traits> struct HashTraitsEmptyValueChecker<Traits, false> {
     template<typename T> static bool isEmptyValue(const T& value) { return value == Traits::emptyValue(); }
 };
 template<typename Traits, typename T> inline bool isHashTraitsEmptyValue(const T& value)
 {
     return HashTraitsEmptyValueChecker<Traits, Traits::hasIsEmptyValueFunction>::isEmptyValue(value);
 }

 template<typename Traits, bool hasIsReleasedWeakValueFunction> struct HashTraitsReleasedWeakValueChecker;
 template<typename Traits> struct HashTraitsReleasedWeakValueChecker<Traits, true> {
     template<typename T> static bool isReleasedWeakValue(const T& value) { return Traits::isReleasedWeakValue(value); }
 };
 template<typename Traits> struct HashTraitsReleasedWeakValueChecker<Traits, false> {
     template<typename T> static bool isReleasedWeakValue(const T&) { return false; }
 };
 template<typename Traits, typename T> inline bool isHashTraitsReleasedWeakValue(const T& value)
 {
     return HashTraitsReleasedWeakValueChecker<Traits, Traits::hasIsReleasedWeakValueFunction>::isReleasedWeakValue(value);
 }

 template<typename Traits, typename T>
 struct HashTraitHasCustomDelete {
     static T& bucketArg;
     template<typename X> static std::true_type TestHasCustomDelete(X*, decltype(X::customDeleteBucket(bucketArg))* = nullptr);
     static std::false_type TestHasCustomDelete(...);
     typedef decltype(TestHasCustomDelete(static_cast<Traits*>(nullptr))) ResultType;
     static constexpr bool value = ResultType::value;
 };

 template<typename Traits, typename T>
 typename std::enable_if<HashTraitHasCustomDelete<Traits, T>::value>::type
 hashTraitsDeleteBucket(T& value)
 {
     Traits::customDeleteBucket(value);
 }

 template<typename Traits, typename T>
 typename std::enable_if<!HashTraitHasCustomDelete<Traits, T>::value>::type
 hashTraitsDeleteBucket(T& value)
 {
     value.~T();
     Traits::constructDeletedValue(value);
 }

 template<typename FirstTraitsArg, typename SecondTraitsArg>
 struct PairHashTraits : GenericHashTraits<std::pair<typename FirstTraitsArg::TraitType, typename SecondTraitsArg::TraitType>> {
     typedef FirstTraitsArg FirstTraits;
     typedef SecondTraitsArg SecondTraits;
     typedef std::pair<typename FirstTraits::TraitType, typename SecondTraits::TraitType> TraitType;
     typedef std::pair<typename FirstTraits::EmptyValueType, typename SecondTraits::EmptyValueType> EmptyValueType;

     static constexpr bool emptyValueIsZero = FirstTraits::emptyValueIsZero && SecondTraits::emptyValueIsZero;
     static EmptyValueType emptyValue() { return std::make_pair(FirstTraits::emptyValue(), SecondTraits::emptyValue()); }

     static constexpr unsigned minimumTableSize = FirstTraits::minimumTableSize;

     static void constructDeletedValue(TraitType& slot) { FirstTraits::constructDeletedValue(slot.first); }
     static bool isDeletedValue(const TraitType& value) { return FirstTraits::isDeletedValue(value.first); }
 };

 template<typename First, typename Second>
 struct HashTraits<std::pair<First, Second>> : public PairHashTraits<HashTraits<First>, HashTraits<Second>> { };

 template<typename FirstTrait, typename... Traits>
 struct TupleHashTraits : GenericHashTraits<std::tuple<typename FirstTrait::TraitType, typename Traits::TraitType...>> {
     typedef std::tuple<typename FirstTrait::TraitType, typename Traits::TraitType...> TraitType;
     typedef std::tuple<typename FirstTrait::EmptyValueType, typename Traits::EmptyValueType...> EmptyValueType;

     // We should use emptyValueIsZero = Traits::emptyValueIsZero &&... whenever we switch to C++17. We can't do anything
     // better here right now because GCC can't do C++.
     template<typename BoolType>
     static constexpr bool allTrue(BoolType value) { return value; }
     template<typename BoolType, typename... BoolTypes>
     static constexpr bool allTrue(BoolType value, BoolTypes... values) { return value && allTrue(values...); }
     static constexpr bool emptyValueIsZero = allTrue(FirstTrait::emptyValueIsZero, Traits::emptyValueIsZero...);
     static EmptyValueType emptyValue() { return std::make_tuple(FirstTrait::emptyValue(), Traits::emptyValue()...); }

     static constexpr unsigned minimumTableSize = FirstTrait::minimumTableSize;

     static void constructDeletedValue(TraitType& slot) { FirstTrait::constructDeletedValue(std::get<0>(slot)); }
     static bool isDeletedValue(const TraitType& value) { return FirstTrait::isDeletedValue(std::get<0>(value)); }
 };

 template<typename... Traits>
 struct HashTraits<std::tuple<Traits...>> : public TupleHashTraits<HashTraits<Traits>...> { };

 template<typename KeyTraitsArg, typename ValueTraitsArg>
 struct KeyValuePairHashTraits : GenericHashTraits<KeyValuePair<typename KeyTraitsArg::TraitType, typename ValueTraitsArg::TraitType>> {
     typedef KeyTraitsArg KeyTraits;
     typedef ValueTraitsArg ValueTraits;
     typedef KeyValuePair<typename KeyTraits::TraitType, typename ValueTraits::TraitType> TraitType;
     typedef KeyValuePair<typename KeyTraits::EmptyValueType, typename ValueTraits::EmptyValueType> EmptyValueType;
     typedef typename ValueTraitsArg::TraitType ValueType;

     static constexpr bool emptyValueIsZero = KeyTraits::emptyValueIsZero && ValueTraits::emptyValueIsZero;
     static EmptyValueType emptyValue() { return KeyValuePair<typename KeyTraits::EmptyValueType, typename ValueTraits::EmptyValueType>(KeyTraits::emptyValue(), ValueTraits::emptyValue()); }

     template <typename>
     static void constructEmptyValue(TraitType& slot)
     {
         KeyTraits::template constructEmptyValue<KeyTraits>(slot.key);
         ValueTraits::template constructEmptyValue<ValueTraits>(slot.value);
     }

     static constexpr unsigned minimumTableSize = KeyTraits::minimumTableSize;

     static void constructDeletedValue(TraitType& slot) { KeyTraits::constructDeletedValue(slot.key); }
     static bool isDeletedValue(const TraitType& value) { return KeyTraits::isDeletedValue(value.key); }

     static void customDeleteBucket(TraitType& value)
     {
         static_assert(std::is_trivially_destructible<KeyValuePair<int, int>>::value,
             "The wrapper itself has to be trivially destructible for customDeleteBucket() to make sense, since we do not destruct the wrapper itself.");

         hashTraitsDeleteBucket<KeyTraits>(value.key);
         value.value.~ValueType();
     }
 };

 template<typename Key, typename Value>
 struct HashTraits<KeyValuePair<Key, Value>> : public KeyValuePairHashTraits<HashTraits<Key>, HashTraits<Value>> { };

 template<typename T>
 struct NullableHashTraits : public HashTraits<T> {
     static constexpr bool emptyValueIsZero = false;
     static T emptyValue() { return reinterpret_cast<T>(1); }
 };

 template<typename T, size_t inlineCapacity>
 struct HashTraits<Vector<T, inlineCapacity>> : GenericHashTraits<Vector<T, inlineCapacity>> {
     static constexpr bool emptyValueIsZero = !inlineCapacity;

     static void constructDeletedValue(Vector<T, inlineCapacity>& slot) { new (NotNull, std::addressof(slot)) Vector<T, inlineCapacity>(WTF::HashTableDeletedValue); }
     static bool isDeletedValue(const Vector<T, inlineCapacity>& value) { return value.isHashTableDeletedValue(); }
 };

 // Useful for classes that want complete control over what is empty and what is deleted,
 // and how to construct both.
 template<typename T>
 struct CustomHashTraits : public GenericHashTraits<T> {
     static constexpr bool emptyValueIsZero = false;
     static constexpr bool hasIsEmptyValueFunction = true;

     static void constructDeletedValue(T& slot)
     {
         new (NotNull, std::addressof(slot)) T(T::DeletedValue);
     }

     static bool isDeletedValue(const T& value)
     {
         return value.isDeletedValue();
     }

     static T emptyValue()
     {
         return T(T::EmptyValue);
     }

     static bool isEmptyValue(const T& value)
     {
         return value.isEmptyValue();
     }
 };

 } // namespace WTF

 using WTF::HashTraits;
 using WTF::KeyValuePair;
 using WTF::PairHashTraits;
 using WTF::NullableHashTraits;
 using WTF::SimpleClassHashTraits;
	/*
	* Copyright (C) 2005-2019 Apple Inc. All rights reserved.
	*
	* This library is free software; you can redistribute it and/or
	* modify it under the terms of the GNU Library General Public
	* License as published by the Free Software Foundation; either
	* version 2 of the License, or (at your option) any later version.
	*
	* This library is distributed in the hope that it will be useful,
	* but WITHOUT ANY WARRANTY; without even the implied warranty of
	* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
	* Library General Public License for more details.
	*
	* You should have received a copy of the GNU Library General Public License
	* along with this library; see the file COPYING.LIB. If not, write to
	* the Free Software Foundation, Inc., 51 Franklin Street, Fifth Floor,
	* Boston, MA 02110-1301, USA.
	*
	*/

	#pragma once

	#include <limits>
	#include <utility>
	#include <wtf/Forward.h>
	#include <wtf/HashFunctions.h>
	#include <wtf/KeyValuePair.h>
	#include <wtf/StdLibExtras.h>

	#ifdef __OBJC__
	#include <CoreFoundation/CoreFoundation.h>
	#endif

	namespace WTF {

	template<bool isInteger, typename T> struct GenericHashTraitsBase;

	template<typename T> struct GenericHashTraitsBase<false, T> {
	// The emptyValueIsZero flag is used to optimize allocation of empty hash tables with zeroed memory.
	static constexpr bool emptyValueIsZero = false;

	// The hasIsEmptyValueFunction flag allows the hash table to automatically generate code to check
	// for the empty value when it can be done with the equality operator, but allows custom functions
	// for cases like String that need them.
	static constexpr bool hasIsEmptyValueFunction = false;

	// Used by WeakPtr to indicate that the value may become deleted without being explicitly removed.
	static constexpr bool hasIsReleasedWeakValueFunction = false;

	// The starting table size. Can be overridden when we know beforehand that
	// a hash table will have at least N entries.
	static constexpr unsigned minimumTableSize = 8;
	};

	// Default integer traits disallow both 0 and -1 as keys (max value instead of -1 for unsigned).
	template<typename T> struct GenericHashTraitsBase<true, T> : GenericHashTraitsBase<false, T> {
	static constexpr bool emptyValueIsZero = true;
	static void constructDeletedValue(T& slot) { slot = static_cast<T>(-1); }
	static bool isDeletedValue(T value) { return value == static_cast<T>(-1); }
	};

	template<typename T> struct GenericHashTraits : GenericHashTraitsBase<std::is_integral<T>::value, T> {
	typedef T TraitType;
	typedef T EmptyValueType;

	static T emptyValue() { return T(); }

	template<typename U, typename V>
	static void assignToEmpty(U& emptyValue, V&& value)
	{
	emptyValue = std::forward<V>(value);
	}

	template <typename Traits>
	static void constructEmptyValue(T& slot)
	{
	new (NotNull, std::addressof(slot)) T(Traits::emptyValue());
	}

	// Type for return value of functions that do not transfer ownership, such as get.
	typedef T PeekType;
	template<typename U> static U&& peek(U&& value) { return std::forward<U>(value); }

	typedef T TakeType;
	template<typename U> static TakeType take(U&& value) { return std::forward<U>(value); }
	};

	template<typename T> struct HashTraits : GenericHashTraits<T> { };

	template<typename T> struct FloatHashTraits : GenericHashTraits<T> {
	static T emptyValue() { return std::numeric_limits<T>::infinity(); }
	static void constructDeletedValue(T& slot) { slot = -std::numeric_limits<T>::infinity(); }
	static bool isDeletedValue(T value) { return value == -std::numeric_limits<T>::infinity(); }
	};

	template<> struct HashTraits<float> : FloatHashTraits<float> { };
	template<> struct HashTraits<double> : FloatHashTraits<double> { };

	// Default unsigned traits disallow both 0 and max as keys -- use these traits to allow zero and disallow max - 1.
	template<typename T> struct UnsignedWithZeroKeyHashTraits : GenericHashTraits<T> {
	static constexpr bool emptyValueIsZero = false;
	static T emptyValue() { return std::numeric_limits<T>::max(); }
	static void constructDeletedValue(T& slot) { slot = std::numeric_limits<T>::max() - 1; }
	static bool isDeletedValue(T value) { return value == std::numeric_limits<T>::max() - 1; }
	};

	template<typename T> struct SignedWithZeroKeyHashTraits : GenericHashTraits<T> {
	static constexpr bool emptyValueIsZero = false;
	static T emptyValue() { return std::numeric_limits<T>::min(); }
	static void constructDeletedValue(T& slot) { slot = std::numeric_limits<T>::max(); }
	static bool isDeletedValue(T value) { return value == std::numeric_limits<T>::max(); }
	};

	// Can be used with strong enums, allows zero as key.
	template<typename T> struct StrongEnumHashTraits : GenericHashTraits<T> {
	using UnderlyingType = typename std::underlying_type<T>::type;
	static constexpr bool emptyValueIsZero = false;
	static T emptyValue() { return static_cast<T>(std::numeric_limits<UnderlyingType>::max()); }
	static void constructDeletedValue(T& slot) { slot = static_cast<T>(std::numeric_limits<UnderlyingType>::max() - 1); }
	static bool isDeletedValue(T value) { return value == static_cast<T>(std::numeric_limits<UnderlyingType>::max() - 1); }
	};

	template<typename P> struct HashTraits<P> : GenericHashTraits<P> {
	static constexpr bool emptyValueIsZero = true;
	static void constructDeletedValue(P& slot) { slot = reinterpret_cast<P>(-1); }
	static bool isDeletedValue(P* value) { return value == reinterpret_cast<P*>(-1); }
	};

	#ifdef __OBJC__

	template<> struct HashTraits<__unsafe_unretained id> : GenericHashTraits<__unsafe_unretained id> {
	static constexpr bool emptyValueIsZero = true;
	static void constructDeletedValue(__unsafe_unretained id& slot) { slot = (__bridge __unsafe_unretained id)reinterpret_cast<CFTypeRef>(-1); }
	static bool isDeletedValue(__unsafe_unretained id value) { return (__bridge CFTypeRef)value == reinterpret_cast<CFTypeRef>(-1); }
	};

	#endif

	template<typename T> struct SimpleClassHashTraits : GenericHashTraits<T> {
	static constexpr bool emptyValueIsZero = true;
	static void constructDeletedValue(T& slot) { new (NotNull, std::addressof(slot)) T(HashTableDeletedValue); }
	static bool isDeletedValue(const T& value) { return value.isHashTableDeletedValue(); }
	};

	template<typename T, typename Deleter> struct HashTraits<std::unique_ptr<T, Deleter>> : SimpleClassHashTraits<std::unique_ptr<T, Deleter>> {
	typedef std::nullptr_t EmptyValueType;
	static EmptyValueType emptyValue() { return nullptr; }

	static void constructDeletedValue(std::unique_ptr<T, Deleter>& slot) { new (NotNull, std::addressof(slot)) std::unique_ptr<T, Deleter> { reinterpret_cast<T*>(-1) }; }
	static bool isDeletedValue(const std::unique_ptr<T, Deleter>& value) { return value.get() == reinterpret_cast<T*>(-1); }

	typedef T* PeekType;
	static T* peek(const std::unique_ptr<T, Deleter>& value) { return value.get(); }
	static T* peek(std::nullptr_t) { return nullptr; }

	static void customDeleteBucket(std::unique_ptr<T, Deleter>& value)
	{
	// The custom delete function exists to avoid a dead store before the value is destructed.
	// The normal destruction sequence of a bucket would be:
	// 1) Call the destructor of unique_ptr.
	// 2) unique_ptr store a zero for its internal pointer.
	// 3) unique_ptr destroys its value.
	// 4) Call constructDeletedValue() to set the bucket as destructed.
	//
	// The problem is the call in (3) prevents the compile from eliminating the dead store in (2)
	// becase a side effect of free() could be observing the value.
	//
	// This version of deleteBucket() ensures the dead 2 stores changing "value"
	// are on the same side of the function call.
	ASSERT(!isDeletedValue(value));
	T* pointer = value.release();
	constructDeletedValue(value);

	// The null case happens if a caller uses std::move() to remove the pointer before calling remove()
	// with an iterator. This is very uncommon.
	if (LIKELY(pointer))
	Deleter()(pointer);
	}
	};

	template<typename T> struct HashTraits<UniqueRef<T>> : SimpleClassHashTraits<UniqueRef<T>> {
	typedef std::nullptr_t EmptyValueType;
	static EmptyValueType emptyValue() { return nullptr; }

	static void constructDeletedValue(UniqueRef<T>& slot) { new (NotNull, std::addressof(slot)) UniqueRef<T> { reinterpret_cast<T*>(-1) }; }
	static bool isDeletedValue(const UniqueRef<T>& value) { return value.get() == reinterpret_cast<T*>(-1); }

	typedef T* PeekType;
	static const T* peek(const UniqueRef<T>& value) { return &value.get(); }
	static T* peek(UniqueRef<T>& value) { return &value.get(); }
	static T* peek(std::nullptr_t) { return nullptr; }

	using TakeType = std::unique_ptr<T>;
	static TakeType take(UniqueRef<T>&& value) { return value.moveToUniquePtr(); }
	static TakeType take(std::nullptr_t) { return nullptr; }
	};

	template<typename P> struct HashTraits<RefPtr<P>> : SimpleClassHashTraits<RefPtr<P>> {
	static P* emptyValue() { return nullptr; }

	typedef P* PeekType;
	static PeekType peek(const RefPtr<P>& value) { return value.get(); }
	static PeekType peek(P* value) { return value; }

	static void customDeleteBucket(RefPtr<P>& value)
	{
	// See unique_ptr's customDeleteBucket() for an explanation.
	ASSERT(!SimpleClassHashTraits<RefPtr<P>>::isDeletedValue(value));
	auto valueToBeDestroyed = WTFMove(value);
	SimpleClassHashTraits<RefPtr<P>>::constructDeletedValue(value);
	}
	};

	template<typename P> struct RefHashTraits : SimpleClassHashTraits<Ref<P>> {
	static constexpr bool emptyValueIsZero = true;
	static Ref<P> emptyValue() { return HashTableEmptyValue; }

	template <typename>
	static void constructEmptyValue(Ref<P>& slot)
	{
	new (NotNull, std::addressof(slot)) Ref<P>(HashTableEmptyValue);
	}

	static constexpr bool hasIsEmptyValueFunction = true;
	static bool isEmptyValue(const Ref<P>& value) { return value.isHashTableEmptyValue(); }

	using PeekType = P*;
	static PeekType peek(const Ref<P>& value) { return const_cast<PeekType>(value.ptrAllowingHashTableEmptyValue()); }
	static PeekType peek(P* value) { return value; }

	using TakeType = RefPtr<P>;
	static TakeType take(Ref<P>&& value) { return isEmptyValue(value) ? nullptr : RefPtr<P>(WTFMove(value)); }
	};

	template<typename P> struct HashTraits<Ref<P>> : RefHashTraits<P> { };

	template<typename P> struct HashTraits<Packed<P>> : SimpleClassHashTraits<Packed<P>> {
	static constexpr bool hasIsEmptyValueFunction = true;
	using TargetType = Packed<P*>;
	static_assert(TargetType::alignment < 4 * KB, "The first page is always unmapped since it includes nullptr.");

	static Packed<P*> emptyValue() { return nullptr; }
	static bool isEmptyValue(const TargetType& value) { return value.get() == nullptr; }

	using PeekType = P*;
	static PeekType peek(const TargetType& value) { return value.get(); }
	static PeekType peek(P* value) { return value; }
	};

	template<> struct HashTraits<String> : SimpleClassHashTraits<String> {
	static constexpr bool hasIsEmptyValueFunction = true;
	static bool isEmptyValue(const String&);

	static void customDeleteBucket(String&);
	};

	// This struct template is an implementation detail of the isHashTraitsEmptyValue function,
	// which selects either the emptyValue function or the isEmptyValue function to check for empty values.
	template<typename Traits, bool hasEmptyValueFunction> struct HashTraitsEmptyValueChecker;
	template<typename Traits> struct HashTraitsEmptyValueChecker<Traits, true> {
	template<typename T> static bool isEmptyValue(const T& value) { return Traits::isEmptyValue(value); }
	};
	template<typename Traits> struct HashTraitsEmptyValueChecker<Traits, false> {
	template<typename T> static bool isEmptyValue(const T& value) { return value == Traits::emptyValue(); }
	};
	template<typename Traits, typename T> inline bool isHashTraitsEmptyValue(const T& value)
	{
	return HashTraitsEmptyValueChecker<Traits, Traits::hasIsEmptyValueFunction>::isEmptyValue(value);
	}

	template<typename Traits, bool hasIsReleasedWeakValueFunction> struct HashTraitsReleasedWeakValueChecker;
	template<typename Traits> struct HashTraitsReleasedWeakValueChecker<Traits, true> {
	template<typename T> static bool isReleasedWeakValue(const T& value) { return Traits::isReleasedWeakValue(value); }
	};
	template<typename Traits> struct HashTraitsReleasedWeakValueChecker<Traits, false> {
	template<typename T> static bool isReleasedWeakValue(const T&) { return false; }
	};
	template<typename Traits, typename T> inline bool isHashTraitsReleasedWeakValue(const T& value)
	{
	return HashTraitsReleasedWeakValueChecker<Traits, Traits::hasIsReleasedWeakValueFunction>::isReleasedWeakValue(value);
	}

	template<typename Traits, typename T>
	struct HashTraitHasCustomDelete {
	static T& bucketArg;
	template<typename X> static std::true_type TestHasCustomDelete(X, decltype(X::customDeleteBucket(bucketArg)) = nullptr);
	static std::false_type TestHasCustomDelete(...);
	typedef decltype(TestHasCustomDelete(static_cast<Traits*>(nullptr))) ResultType;
	static constexpr bool value = ResultType::value;
	};

	template<typename Traits, typename T>
	typename std::enable_if<HashTraitHasCustomDelete<Traits, T>::value>::type
	hashTraitsDeleteBucket(T& value)
	{
	Traits::customDeleteBucket(value);
	}

	template<typename Traits, typename T>
	typename std::enable_if<!HashTraitHasCustomDelete<Traits, T>::value>::type
	hashTraitsDeleteBucket(T& value)
	{
	value.~T();
	Traits::constructDeletedValue(value);
	}

	template<typename FirstTraitsArg, typename SecondTraitsArg>
	struct PairHashTraits : GenericHashTraits<std::pair<typename FirstTraitsArg::TraitType, typename SecondTraitsArg::TraitType>> {
	typedef FirstTraitsArg FirstTraits;
	typedef SecondTraitsArg SecondTraits;
	typedef std::pair<typename FirstTraits::TraitType, typename SecondTraits::TraitType> TraitType;
	typedef std::pair<typename FirstTraits::EmptyValueType, typename SecondTraits::EmptyValueType> EmptyValueType;

	static constexpr bool emptyValueIsZero = FirstTraits::emptyValueIsZero && SecondTraits::emptyValueIsZero;
	static EmptyValueType emptyValue() { return std::make_pair(FirstTraits::emptyValue(), SecondTraits::emptyValue()); }

	static constexpr unsigned minimumTableSize = FirstTraits::minimumTableSize;

	static void constructDeletedValue(TraitType& slot) { FirstTraits::constructDeletedValue(slot.first); }
	static bool isDeletedValue(const TraitType& value) { return FirstTraits::isDeletedValue(value.first); }
	};

	template<typename First, typename Second>
	struct HashTraits<std::pair<First, Second>> : public PairHashTraits<HashTraits<First>, HashTraits<Second>> { };

	template<typename FirstTrait, typename... Traits>
	struct TupleHashTraits : GenericHashTraits<std::tuple<typename FirstTrait::TraitType, typename Traits::TraitType...>> {
	typedef std::tuple<typename FirstTrait::TraitType, typename Traits::TraitType...> TraitType;
	typedef std::tuple<typename FirstTrait::EmptyValueType, typename Traits::EmptyValueType...> EmptyValueType;

	// We should use emptyValueIsZero = Traits::emptyValueIsZero &&... whenever we switch to C++17. We can't do anything
	// better here right now because GCC can't do C++.
	template<typename BoolType>
	static constexpr bool allTrue(BoolType value) { return value; }
	template<typename BoolType, typename... BoolTypes>
	static constexpr bool allTrue(BoolType value, BoolTypes... values) { return value && allTrue(values...); }
	static constexpr bool emptyValueIsZero = allTrue(FirstTrait::emptyValueIsZero, Traits::emptyValueIsZero...);
	static EmptyValueType emptyValue() { return std::make_tuple(FirstTrait::emptyValue(), Traits::emptyValue()...); }

	static constexpr unsigned minimumTableSize = FirstTrait::minimumTableSize;

	static void constructDeletedValue(TraitType& slot) { FirstTrait::constructDeletedValue(std::get<0>(slot)); }
	static bool isDeletedValue(const TraitType& value) { return FirstTrait::isDeletedValue(std::get<0>(value)); }
	};

	template<typename... Traits>
	struct HashTraits<std::tuple<Traits...>> : public TupleHashTraits<HashTraits<Traits>...> { };

	template<typename KeyTraitsArg, typename ValueTraitsArg>
	struct KeyValuePairHashTraits : GenericHashTraits<KeyValuePair<typename KeyTraitsArg::TraitType, typename ValueTraitsArg::TraitType>> {
	typedef KeyTraitsArg KeyTraits;
	typedef ValueTraitsArg ValueTraits;
	typedef KeyValuePair<typename KeyTraits::TraitType, typename ValueTraits::TraitType> TraitType;
	typedef KeyValuePair<typename KeyTraits::EmptyValueType, typename ValueTraits::EmptyValueType> EmptyValueType;
	typedef typename ValueTraitsArg::TraitType ValueType;

	static constexpr bool emptyValueIsZero = KeyTraits::emptyValueIsZero && ValueTraits::emptyValueIsZero;
	static EmptyValueType emptyValue() { return KeyValuePair<typename KeyTraits::EmptyValueType, typename ValueTraits::EmptyValueType>(KeyTraits::emptyValue(), ValueTraits::emptyValue()); }

	template <typename>
	static void constructEmptyValue(TraitType& slot)
	{
	KeyTraits::template constructEmptyValue<KeyTraits>(slot.key);
	ValueTraits::template constructEmptyValue<ValueTraits>(slot.value);
	}

	static constexpr unsigned minimumTableSize = KeyTraits::minimumTableSize;

	static void constructDeletedValue(TraitType& slot) { KeyTraits::constructDeletedValue(slot.key); }
	static bool isDeletedValue(const TraitType& value) { return KeyTraits::isDeletedValue(value.key); }

	static void customDeleteBucket(TraitType& value)
	{
	static_assert(std::is_trivially_destructible<KeyValuePair<int, int>>::value,
	"The wrapper itself has to be trivially destructible for customDeleteBucket() to make sense, since we do not destruct the wrapper itself.");

	hashTraitsDeleteBucket<KeyTraits>(value.key);
	value.value.~ValueType();
	}
	};

	template<typename Key, typename Value>
	struct HashTraits<KeyValuePair<Key, Value>> : public KeyValuePairHashTraits<HashTraits<Key>, HashTraits<Value>> { };

	template<typename T>
	struct NullableHashTraits : public HashTraits<T> {
	static constexpr bool emptyValueIsZero = false;
	static T emptyValue() { return reinterpret_cast<T>(1); }
	};

	template<typename T, size_t inlineCapacity>
	struct HashTraits<Vector<T, inlineCapacity>> : GenericHashTraits<Vector<T, inlineCapacity>> {
	static constexpr bool emptyValueIsZero = !inlineCapacity;

	static void constructDeletedValue(Vector<T, inlineCapacity>& slot) { new (NotNull, std::addressof(slot)) Vector<T, inlineCapacity>(WTF::HashTableDeletedValue); }
	static bool isDeletedValue(const Vector<T, inlineCapacity>& value) { return value.isHashTableDeletedValue(); }
	};

	// Useful for classes that want complete control over what is empty and what is deleted,
	// and how to construct both.
	template<typename T>
	struct CustomHashTraits : public GenericHashTraits<T> {
	static constexpr bool emptyValueIsZero = false;
	static constexpr bool hasIsEmptyValueFunction = true;

	static void constructDeletedValue(T& slot)
	{
	new (NotNull, std::addressof(slot)) T(T::DeletedValue);
	}

	static bool isDeletedValue(const T& value)
	{
	return value.isDeletedValue();
	}

	static T emptyValue()
	{
	return T(T::EmptyValue);
	}

	static bool isEmptyValue(const T& value)
	{
	return value.isEmptyValue();
	}
	};

	} // namespace WTF

	using WTF::HashTraits;
	using WTF::KeyValuePair;
	using WTF::PairHashTraits;
	using WTF::NullableHashTraits;
	using WTF::SimpleClassHashTraits;