base/containers/enum_set.h - platform/external/cronet - Git at Google

 // Copyright 2012 The Chromium Authors
 // Use of this source code is governed by a BSD-style license that can be
 // found in the LICENSE file.

 #ifndef BASE_CONTAINERS_ENUM_SET_H_
 #define BASE_CONTAINERS_ENUM_SET_H_

 #include <bitset>
 #include <cstddef>
 #include <initializer_list>
 #include <type_traits>
 #include <utility>

 #include "base/check.h"
 #include "base/check_op.h"
 #include "base/memory/raw_ptr.h"
 #include "build/build_config.h"

 namespace base {

 // Forward declarations needed for friend declarations.
 template <typename E, E MinEnumValue, E MaxEnumValue>
 class EnumSet;

 template <typename E, E Min, E Max>
 constexpr EnumSet<E, Min, Max> Union(EnumSet<E, Min, Max> set1,
                                      EnumSet<E, Min, Max> set2);

 template <typename E, E Min, E Max>
 constexpr EnumSet<E, Min, Max> Intersection(EnumSet<E, Min, Max> set1,
                                             EnumSet<E, Min, Max> set2);

 template <typename E, E Min, E Max>
 constexpr EnumSet<E, Min, Max> Difference(EnumSet<E, Min, Max> set1,
                                           EnumSet<E, Min, Max> set2);

 // An EnumSet is a set that can hold enum values between a min and a
 // max value (inclusive of both).  It's essentially a wrapper around
 // std::bitset<> with stronger type enforcement, more descriptive
 // member function names, and an iterator interface.
 //
 // If you're working with enums with a small number of possible values
 // (say, fewer than 64), you can efficiently pass around an EnumSet
 // for that enum around by value.

 template <typename E, E MinEnumValue, E MaxEnumValue>
 class EnumSet {
  private:
   static_assert(
       std::is_enum_v<E>,
       "First template parameter of EnumSet must be an enumeration type");
   using enum_underlying_type = std::underlying_type_t<E>;

   static constexpr bool InRange(E value) {
     return (value >= MinEnumValue) && (value <= MaxEnumValue);
   }

   static constexpr enum_underlying_type GetUnderlyingValue(E value) {
     return static_cast<enum_underlying_type>(value);
   }

  public:
   using EnumType = E;
   static const E kMinValue = MinEnumValue;
   static const E kMaxValue = MaxEnumValue;
   static const size_t kValueCount =
       GetUnderlyingValue(kMaxValue) - GetUnderlyingValue(kMinValue) + 1;

   static_assert(kMinValue <= kMaxValue,
                 "min value must be no greater than max value");

  private:
   // Declaration needed by Iterator.
   using EnumBitSet = std::bitset<kValueCount>;

  public:
   // Iterator is a forward-only read-only iterator for EnumSet. It follows the
   // common STL input iterator interface (like std::unordered_set).
   //
   // Example usage, using a range-based for loop:
   //
   // EnumSet<SomeType> enums;
   // for (SomeType val : enums) {
   //   Process(val);
   // }
   //
   // Or using an explicit iterator (not recommended):
   //
   // for (EnumSet<...>::Iterator it = enums.begin(); it != enums.end(); it++) {
   //   Process(*it);
   // }
   //
   // The iterator must not be outlived by the set. In particular, the following
   // is an error:
   //
   // EnumSet<...> SomeFn() { ... }
   //
   // /* ERROR */
   // for (EnumSet<...>::Iterator it = SomeFun().begin(); ...
   //
   // Also, there are no guarantees as to what will happen if you
   // modify an EnumSet while traversing it with an iterator.
   class Iterator {
    public:
     Iterator() : enums_(nullptr), i_(kValueCount) {}
     ~Iterator() = default;

     friend bool operator==(const Iterator& lhs, const Iterator& rhs) {
       return lhs.i_ == rhs.i_;
     }

     E operator*() const {
       DCHECK(Good());
       return FromIndex(i_);
     }

     Iterator& operator++() {
       DCHECK(Good());
       // If there are no more set elements in the bitset, this will result in an
       // index equal to kValueCount, which is equivalent to EnumSet.end().
       i_ = FindNext(i_ + 1);

       return *this;
     }

     Iterator operator++(int) {
       DCHECK(Good());
       Iterator old(*this);

       // If there are no more set elements in the bitset, this will result in an
       // index equal to kValueCount, which is equivalent to EnumSet.end().
       i_ = FindNext(i_ + 1);

       return std::move(old);
     }

    private:
     friend Iterator EnumSet::begin() const;

     explicit Iterator(const EnumBitSet& enums)
         : enums_(&enums), i_(FindNext(0)) {}

     // Returns true iff the iterator points to an EnumSet and it
     // hasn't yet traversed the EnumSet entirely.
     bool Good() const { return enums_ && i_ < kValueCount && enums_->test(i_); }

     size_t FindNext(size_t i) {
       while ((i < kValueCount) && !enums_->test(i)) {
         ++i;
       }
       return i;
     }

     const raw_ptr<const EnumBitSet> enums_;
     size_t i_;
   };

   EnumSet() = default;

   ~EnumSet() = default;

   constexpr EnumSet(std::initializer_list<E> values) {
     if (std::is_constant_evaluated()) {
       enums_ = bitstring(values);
     } else {
       for (E value : values) {
         Put(value);
       }
     }
   }

   // Returns an EnumSet with all values between kMinValue and kMaxValue, which
   // also contains undefined enum values if the enum in question has gaps
   // between kMinValue and kMaxValue.
   static constexpr EnumSet All() {
     if (std::is_constant_evaluated()) {
       if (kValueCount == 0) {
         return EnumSet();
       }
       // Since `1 << kValueCount` may trigger shift-count-overflow warning if
       // the `kValueCount` is 64, instead of returning `(1 << kValueCount) - 1`,
       // the bitmask will be constructed from two parts: the most significant
       // bits and the remaining.
       uint64_t mask = 1ULL << (kValueCount - 1);
       return EnumSet(EnumBitSet(mask - 1 + mask));
     } else {
       // When `kValueCount` is greater than 64, we can't use the constexpr path,
       // and we will build an `EnumSet` value by value.
       EnumSet enum_set;
       for (size_t value = 0; value < kValueCount; ++value) {
         enum_set.Put(FromIndex(value));
       }
       return enum_set;
     }
   }

   // Returns an EnumSet with all the values from start to end, inclusive.
   static constexpr EnumSet FromRange(E start, E end) {
     CHECK_LE(start, end);
     return EnumSet(EnumBitSet(
         ((single_val_bitstring(end)) - (single_val_bitstring(start))) |
         (single_val_bitstring(end))));
   }

   // Copy constructor and assignment welcome.

   // Bitmask operations.
   //
   // This bitmask is 0-based and the value of the Nth bit depends on whether
   // the set contains an enum element of integer value N.
   //
   // These may only be used if Min >= 0 and Max < 64.

   // Returns an EnumSet constructed from |bitmask|.
   static constexpr EnumSet FromEnumBitmask(const uint64_t bitmask) {
     static_assert(GetUnderlyingValue(kMaxValue) < 64,
                   "The highest enum value must be < 64 for FromEnumBitmask ");
     static_assert(GetUnderlyingValue(kMinValue) >= 0,
                   "The lowest enum value must be >= 0 for FromEnumBitmask ");
     return EnumSet(EnumBitSet(bitmask >> GetUnderlyingValue(kMinValue)));
   }
   // Returns a bitmask for the EnumSet.
   uint64_t ToEnumBitmask() const {
     static_assert(GetUnderlyingValue(kMaxValue) < 64,
                   "The highest enum value must be < 64 for ToEnumBitmask ");
     static_assert(GetUnderlyingValue(kMinValue) >= 0,
                   "The lowest enum value must be >= 0 for FromEnumBitmask ");
     return enums_.to_ullong() << GetUnderlyingValue(kMinValue);
   }

   // Set operations.  Put, Retain, and Remove are basically
   // self-mutating versions of Union, Intersection, and Difference
   // (defined below).

   // Adds the given value (which must be in range) to our set.
   void Put(E value) { enums_.set(ToIndex(value)); }

   // Adds all values in the given set to our set.
   void PutAll(EnumSet other) { enums_ |= other.enums_; }

   // Adds all values in the given range to our set, inclusive.
   void PutRange(E start, E end) {
     CHECK_LE(start, end);
     size_t endIndexInclusive = ToIndex(end);
     for (size_t current = ToIndex(start); current <= endIndexInclusive;
          ++current) {
       enums_.set(current);
     }
   }

   // There's no real need for a Retain(E) member function.

   // Removes all values not in the given set from our set.
   void RetainAll(EnumSet other) { enums_ &= other.enums_; }

   // If the given value is in range, removes it from our set.
   void Remove(E value) {
     if (InRange(value)) {
       enums_.reset(ToIndex(value));
     }
   }

   // Removes all values in the given set from our set.
   void RemoveAll(EnumSet other) { enums_ &= ~other.enums_; }

   // Removes all values from our set.
   void Clear() { enums_.reset(); }

   // Conditionally puts or removes `value`, based on `should_be_present`.
   void PutOrRemove(E value, bool should_be_present) {
     if (should_be_present) {
       Put(value);
     } else {
       Remove(value);
     }
   }

   // Returns true iff the given value is in range and a member of our set.
   constexpr bool Has(E value) const {
     return InRange(value) && enums_[ToIndex(value)];
   }

   // Returns true iff the given set is a subset of our set.
   bool HasAll(EnumSet other) const {
     return (enums_ & other.enums_) == other.enums_;
   }

   // Returns true if the given set contains any value of our set.
   bool HasAny(EnumSet other) const {
     return (enums_ & other.enums_).count() > 0;
   }

   // Returns true iff our set is empty.
   bool Empty() const { return !enums_.any(); }

   // Returns how many values our set has.
   size_t Size() const { return enums_.count(); }

   // Returns an iterator pointing to the first element (if any).
   Iterator begin() const { return Iterator(enums_); }

   // Returns an iterator that does not point to any element, but to the position
   // that follows the last element in the set.
   Iterator end() const { return Iterator(); }

   // Returns true iff our set and the given set contain exactly the same values.
   friend bool operator==(const EnumSet&, const EnumSet&) = default;

  private:
   friend constexpr EnumSet Union<E, MinEnumValue, MaxEnumValue>(EnumSet set1,
                                                                 EnumSet set2);
   friend constexpr EnumSet Intersection<E, MinEnumValue, MaxEnumValue>(
       EnumSet set1,
       EnumSet set2);
   friend constexpr EnumSet Difference<E, MinEnumValue, MaxEnumValue>(
       EnumSet set1,
       EnumSet set2);

   static constexpr uint64_t bitstring(const std::initializer_list<E>& values) {
     uint64_t result = 0;
     for (E value : values) {
       result |= single_val_bitstring(value);
     }
     return result;
   }

   static constexpr uint64_t single_val_bitstring(E val) {
     const uint64_t bitstring = 1;
     const size_t shift_amount = ToIndex(val);
     CHECK_LT(shift_amount, sizeof(bitstring) * 8);
     return bitstring << shift_amount;
   }

   // A bitset can't be constexpr constructed if it has size > 64, since the
   // constexpr constructor uses a uint64_t. If your EnumSet has > 64 values, you
   // can safely remove the constepxr qualifiers from this file, at the cost of
   // some minor optimizations.
   explicit constexpr EnumSet(EnumBitSet enums) : enums_(enums) {
     if (std::is_constant_evaluated()) {
       CHECK(kValueCount <= 64)
           << "Max number of enum values is 64 for constexpr constructor";
     }
   }

   // Converts a value to/from an index into |enums_|.
   static constexpr size_t ToIndex(E value) {
     CHECK(InRange(value));
     return static_cast<size_t>(GetUnderlyingValue(value)) -
            static_cast<size_t>(GetUnderlyingValue(MinEnumValue));
   }

   static E FromIndex(size_t i) {
     DCHECK_LT(i, kValueCount);
     return static_cast<E>(GetUnderlyingValue(MinEnumValue) + i);
   }

   EnumBitSet enums_;
 };

 template <typename E, E MinEnumValue, E MaxEnumValue>
 const E EnumSet<E, MinEnumValue, MaxEnumValue>::kMinValue;

 template <typename E, E MinEnumValue, E MaxEnumValue>
 const E EnumSet<E, MinEnumValue, MaxEnumValue>::kMaxValue;

 template <typename E, E MinEnumValue, E MaxEnumValue>
 const size_t EnumSet<E, MinEnumValue, MaxEnumValue>::kValueCount;

 // The usual set operations.

 template <typename E, E Min, E Max>
 constexpr EnumSet<E, Min, Max> Union(EnumSet<E, Min, Max> set1,
                                      EnumSet<E, Min, Max> set2) {
   return EnumSet<E, Min, Max>(set1.enums_ | set2.enums_);
 }

 template <typename E, E Min, E Max>
 constexpr EnumSet<E, Min, Max> Intersection(EnumSet<E, Min, Max> set1,
                                             EnumSet<E, Min, Max> set2) {
   return EnumSet<E, Min, Max>(set1.enums_ & set2.enums_);
 }

 template <typename E, E Min, E Max>
 constexpr EnumSet<E, Min, Max> Difference(EnumSet<E, Min, Max> set1,
                                           EnumSet<E, Min, Max> set2) {
   return EnumSet<E, Min, Max>(set1.enums_ & ~set2.enums_);
 }

 }  // namespace base

 #endif  // BASE_CONTAINERS_ENUM_SET_H_
	// Copyright 2012 The Chromium Authors
	// Use of this source code is governed by a BSD-style license that can be
	// found in the LICENSE file.

	#ifndef BASE_CONTAINERS_ENUM_SET_H_
	#define BASE_CONTAINERS_ENUM_SET_H_

	#include <bitset>
	#include <cstddef>
	#include <initializer_list>
	#include <type_traits>
	#include <utility>

	#include "base/check.h"
	#include "base/check_op.h"
	#include "base/memory/raw_ptr.h"
	#include "build/build_config.h"

	namespace base {

	// Forward declarations needed for friend declarations.
	template <typename E, E MinEnumValue, E MaxEnumValue>
	class EnumSet;

	template <typename E, E Min, E Max>
	constexpr EnumSet<E, Min, Max> Union(EnumSet<E, Min, Max> set1,
	EnumSet<E, Min, Max> set2);

	template <typename E, E Min, E Max>
	constexpr EnumSet<E, Min, Max> Intersection(EnumSet<E, Min, Max> set1,
	EnumSet<E, Min, Max> set2);

	template <typename E, E Min, E Max>
	constexpr EnumSet<E, Min, Max> Difference(EnumSet<E, Min, Max> set1,
	EnumSet<E, Min, Max> set2);

	// An EnumSet is a set that can hold enum values between a min and a
	// max value (inclusive of both). It's essentially a wrapper around
	// std::bitset<> with stronger type enforcement, more descriptive
	// member function names, and an iterator interface.
	//
	// If you're working with enums with a small number of possible values
	// (say, fewer than 64), you can efficiently pass around an EnumSet
	// for that enum around by value.

	template <typename E, E MinEnumValue, E MaxEnumValue>
	class EnumSet {
	private:
	static_assert(
	std::is_enum_v<E>,
	"First template parameter of EnumSet must be an enumeration type");
	using enum_underlying_type = std::underlying_type_t<E>;

	static constexpr bool InRange(E value) {
	return (value >= MinEnumValue) && (value <= MaxEnumValue);
	}

	static constexpr enum_underlying_type GetUnderlyingValue(E value) {
	return static_cast<enum_underlying_type>(value);
	}

	public:
	using EnumType = E;
	static const E kMinValue = MinEnumValue;
	static const E kMaxValue = MaxEnumValue;
	static const size_t kValueCount =
	GetUnderlyingValue(kMaxValue) - GetUnderlyingValue(kMinValue) + 1;

	static_assert(kMinValue <= kMaxValue,
	"min value must be no greater than max value");

	private:
	// Declaration needed by Iterator.
	using EnumBitSet = std::bitset<kValueCount>;

	public:
	// Iterator is a forward-only read-only iterator for EnumSet. It follows the
	// common STL input iterator interface (like std::unordered_set).
	//
	// Example usage, using a range-based for loop:
	//
	// EnumSet<SomeType> enums;
	// for (SomeType val : enums) {
	// Process(val);
	// }
	//
	// Or using an explicit iterator (not recommended):
	//
	// for (EnumSet<...>::Iterator it = enums.begin(); it != enums.end(); it++) {
	// Process(*it);
	// }
	//
	// The iterator must not be outlived by the set. In particular, the following
	// is an error:
	//
	// EnumSet<...> SomeFn() { ... }
	//
	// /* ERROR */
	// for (EnumSet<...>::Iterator it = SomeFun().begin(); ...
	//
	// Also, there are no guarantees as to what will happen if you
	// modify an EnumSet while traversing it with an iterator.
	class Iterator {
	public:
	Iterator() : enums_(nullptr), i_(kValueCount) {}
	~Iterator() = default;

	friend bool operator==(const Iterator& lhs, const Iterator& rhs) {
	return lhs.i_ == rhs.i_;
	}

	E operator*() const {
	DCHECK(Good());
	return FromIndex(i_);
	}

	Iterator& operator++() {
	DCHECK(Good());
	// If there are no more set elements in the bitset, this will result in an
	// index equal to kValueCount, which is equivalent to EnumSet.end().
	i_ = FindNext(i_ + 1);

	return *this;
	}

	Iterator operator++(int) {
	DCHECK(Good());
	Iterator old(*this);

	// If there are no more set elements in the bitset, this will result in an
	// index equal to kValueCount, which is equivalent to EnumSet.end().
	i_ = FindNext(i_ + 1);

	return std::move(old);
	}

	private:
	friend Iterator EnumSet::begin() const;

	explicit Iterator(const EnumBitSet& enums)
	: enums_(&enums), i_(FindNext(0)) {}

	// Returns true iff the iterator points to an EnumSet and it
	// hasn't yet traversed the EnumSet entirely.
	bool Good() const { return enums_ && i_ < kValueCount && enums_->test(i_); }

	size_t FindNext(size_t i) {
	while ((i < kValueCount) && !enums_->test(i)) {
	++i;
	}
	return i;
	}

	const raw_ptr<const EnumBitSet> enums_;
	size_t i_;
	};

	EnumSet() = default;

	~EnumSet() = default;

	constexpr EnumSet(std::initializer_list<E> values) {
	if (std::is_constant_evaluated()) {
	enums_ = bitstring(values);
	} else {
	for (E value : values) {
	Put(value);
	}
	}
	}

	// Returns an EnumSet with all values between kMinValue and kMaxValue, which
	// also contains undefined enum values if the enum in question has gaps
	// between kMinValue and kMaxValue.
	static constexpr EnumSet All() {
	if (std::is_constant_evaluated()) {
	if (kValueCount == 0) {
	return EnumSet();
	}
	// Since `1 << kValueCount` may trigger shift-count-overflow warning if
	// the `kValueCount` is 64, instead of returning `(1 << kValueCount) - 1`,
	// the bitmask will be constructed from two parts: the most significant
	// bits and the remaining.
	uint64_t mask = 1ULL << (kValueCount - 1);
	return EnumSet(EnumBitSet(mask - 1 + mask));
	} else {
	// When `kValueCount` is greater than 64, we can't use the constexpr path,
	// and we will build an `EnumSet` value by value.
	EnumSet enum_set;
	for (size_t value = 0; value < kValueCount; ++value) {
	enum_set.Put(FromIndex(value));
	}
	return enum_set;
	}
	}

	// Returns an EnumSet with all the values from start to end, inclusive.
	static constexpr EnumSet FromRange(E start, E end) {
	CHECK_LE(start, end);
	return EnumSet(EnumBitSet(
	((single_val_bitstring(end)) - (single_val_bitstring(start))) \|
	(single_val_bitstring(end))));
	}

	// Copy constructor and assignment welcome.

	// Bitmask operations.
	//
	// This bitmask is 0-based and the value of the Nth bit depends on whether
	// the set contains an enum element of integer value N.
	//
	// These may only be used if Min >= 0 and Max < 64.

	// Returns an EnumSet constructed from \|bitmask\|.
	static constexpr EnumSet FromEnumBitmask(const uint64_t bitmask) {
	static_assert(GetUnderlyingValue(kMaxValue) < 64,
	"The highest enum value must be < 64 for FromEnumBitmask ");
	static_assert(GetUnderlyingValue(kMinValue) >= 0,
	"The lowest enum value must be >= 0 for FromEnumBitmask ");
	return EnumSet(EnumBitSet(bitmask >> GetUnderlyingValue(kMinValue)));
	}
	// Returns a bitmask for the EnumSet.
	uint64_t ToEnumBitmask() const {
	static_assert(GetUnderlyingValue(kMaxValue) < 64,
	"The highest enum value must be < 64 for ToEnumBitmask ");
	static_assert(GetUnderlyingValue(kMinValue) >= 0,
	"The lowest enum value must be >= 0 for FromEnumBitmask ");
	return enums_.to_ullong() << GetUnderlyingValue(kMinValue);
	}

	// Set operations. Put, Retain, and Remove are basically
	// self-mutating versions of Union, Intersection, and Difference
	// (defined below).

	// Adds the given value (which must be in range) to our set.
	void Put(E value) { enums_.set(ToIndex(value)); }

	// Adds all values in the given set to our set.
	void PutAll(EnumSet other) { enums_ \|= other.enums_; }

	// Adds all values in the given range to our set, inclusive.
	void PutRange(E start, E end) {
	CHECK_LE(start, end);
	size_t endIndexInclusive = ToIndex(end);
	for (size_t current = ToIndex(start); current <= endIndexInclusive;
	++current) {
	enums_.set(current);
	}
	}

	// There's no real need for a Retain(E) member function.

	// Removes all values not in the given set from our set.
	void RetainAll(EnumSet other) { enums_ &= other.enums_; }

	// If the given value is in range, removes it from our set.
	void Remove(E value) {
	if (InRange(value)) {
	enums_.reset(ToIndex(value));
	}
	}

	// Removes all values in the given set from our set.
	void RemoveAll(EnumSet other) { enums_ &= ~other.enums_; }

	// Removes all values from our set.
	void Clear() { enums_.reset(); }

	// Conditionally puts or removes `value`, based on `should_be_present`.
	void PutOrRemove(E value, bool should_be_present) {
	if (should_be_present) {
	Put(value);
	} else {
	Remove(value);
	}
	}

	// Returns true iff the given value is in range and a member of our set.
	constexpr bool Has(E value) const {
	return InRange(value) && enums_[ToIndex(value)];
	}

	// Returns true iff the given set is a subset of our set.
	bool HasAll(EnumSet other) const {
	return (enums_ & other.enums_) == other.enums_;
	}

	// Returns true if the given set contains any value of our set.
	bool HasAny(EnumSet other) const {
	return (enums_ & other.enums_).count() > 0;
	}

	// Returns true iff our set is empty.
	bool Empty() const { return !enums_.any(); }

	// Returns how many values our set has.
	size_t Size() const { return enums_.count(); }

	// Returns an iterator pointing to the first element (if any).
	Iterator begin() const { return Iterator(enums_); }

	// Returns an iterator that does not point to any element, but to the position
	// that follows the last element in the set.
	Iterator end() const { return Iterator(); }

	// Returns true iff our set and the given set contain exactly the same values.
	friend bool operator==(const EnumSet&, const EnumSet&) = default;

	private:
	friend constexpr EnumSet Union<E, MinEnumValue, MaxEnumValue>(EnumSet set1,
	EnumSet set2);
	friend constexpr EnumSet Intersection<E, MinEnumValue, MaxEnumValue>(
	EnumSet set1,
	EnumSet set2);
	friend constexpr EnumSet Difference<E, MinEnumValue, MaxEnumValue>(
	EnumSet set1,
	EnumSet set2);

	static constexpr uint64_t bitstring(const std::initializer_list<E>& values) {
	uint64_t result = 0;
	for (E value : values) {
	result \|= single_val_bitstring(value);
	}
	return result;
	}

	static constexpr uint64_t single_val_bitstring(E val) {
	const uint64_t bitstring = 1;
	const size_t shift_amount = ToIndex(val);
	CHECK_LT(shift_amount, sizeof(bitstring) * 8);
	return bitstring << shift_amount;
	}

	// A bitset can't be constexpr constructed if it has size > 64, since the
	// constexpr constructor uses a uint64_t. If your EnumSet has > 64 values, you
	// can safely remove the constepxr qualifiers from this file, at the cost of
	// some minor optimizations.
	explicit constexpr EnumSet(EnumBitSet enums) : enums_(enums) {
	if (std::is_constant_evaluated()) {
	CHECK(kValueCount <= 64)
	<< "Max number of enum values is 64 for constexpr constructor";
	}
	}

	// Converts a value to/from an index into \|enums_\|.
	static constexpr size_t ToIndex(E value) {
	CHECK(InRange(value));
	return static_cast<size_t>(GetUnderlyingValue(value)) -
	static_cast<size_t>(GetUnderlyingValue(MinEnumValue));
	}

	static E FromIndex(size_t i) {
	DCHECK_LT(i, kValueCount);
	return static_cast<E>(GetUnderlyingValue(MinEnumValue) + i);
	}

	EnumBitSet enums_;
	};

	template <typename E, E MinEnumValue, E MaxEnumValue>
	const E EnumSet<E, MinEnumValue, MaxEnumValue>::kMinValue;

	template <typename E, E MinEnumValue, E MaxEnumValue>
	const E EnumSet<E, MinEnumValue, MaxEnumValue>::kMaxValue;

	template <typename E, E MinEnumValue, E MaxEnumValue>
	const size_t EnumSet<E, MinEnumValue, MaxEnumValue>::kValueCount;

	// The usual set operations.

	template <typename E, E Min, E Max>
	constexpr EnumSet<E, Min, Max> Union(EnumSet<E, Min, Max> set1,
	EnumSet<E, Min, Max> set2) {
	return EnumSet<E, Min, Max>(set1.enums_ \| set2.enums_);
	}

	template <typename E, E Min, E Max>
	constexpr EnumSet<E, Min, Max> Intersection(EnumSet<E, Min, Max> set1,
	EnumSet<E, Min, Max> set2) {
	return EnumSet<E, Min, Max>(set1.enums_ & set2.enums_);
	}

	template <typename E, E Min, E Max>
	constexpr EnumSet<E, Min, Max> Difference(EnumSet<E, Min, Max> set1,
	EnumSet<E, Min, Max> set2) {
	return EnumSet<E, Min, Max>(set1.enums_ & ~set2.enums_);
	}

	} // namespace base

	#endif // BASE_CONTAINERS_ENUM_SET_H_