base/stl_util.h - gn.git - Git at Google

 // Copyright (c) 2011 The Chromium Authors. All rights reserved.
 // Use of this source code is governed by a BSD-style license that can be
 // found in the LICENSE file.

 // Derived from google3/util/gtl/stl_util.h

 #ifndef BASE_STL_UTIL_H_
 #define BASE_STL_UTIL_H_

 #include <algorithm>
 #include <deque>
 #include <forward_list>
 #include <functional>
 #include <initializer_list>
 #include <iterator>
 #include <list>
 #include <map>
 #include <set>
 #include <string>
 #include <unordered_map>
 #include <unordered_set>
 #include <vector>

 #include "base/logging.h"
 #include "base/optional.h"

 namespace base {

 namespace internal {

 // Calls erase on iterators of matching elements.
 template <typename Container, typename Predicate>
 void IterateAndEraseIf(Container& container, Predicate pred) {
   for (auto it = container.begin(); it != container.end();) {
     if (pred(*it))
       it = container.erase(it);
     else
       ++it;
   }
 }

 }  // namespace internal

 // C++14 implementation of C++17's std::size():
 // http://en.cppreference.com/w/cpp/iterator/size
 template <typename Container>
 constexpr auto size(const Container& c) -> decltype(c.size()) {
   return c.size();
 }

 template <typename T, size_t N>
 constexpr size_t size(const T (&array)[N]) noexcept {
   return N;
 }

 // C++14 implementation of C++17's std::empty():
 // http://en.cppreference.com/w/cpp/iterator/empty
 template <typename Container>
 constexpr auto empty(const Container& c) -> decltype(c.empty()) {
   return c.empty();
 }

 template <typename T, size_t N>
 constexpr bool empty(const T (&array)[N]) noexcept {
   return false;
 }

 template <typename T>
 constexpr bool empty(std::initializer_list<T> il) noexcept {
   return il.size() == 0;
 }

 // C++14 implementation of C++17's std::data():
 // http://en.cppreference.com/w/cpp/iterator/data
 template <typename Container>
 constexpr auto data(Container& c) -> decltype(c.data()) {
   return c.data();
 }

 // std::basic_string::data() had no mutable overload prior to C++17 [1].
 // Hence this overload is provided.
 // Note: str[0] is safe even for empty strings, as they are guaranteed to be
 // null-terminated [2].
 //
 // [1] http://en.cppreference.com/w/cpp/string/basic_string/data
 // [2] http://en.cppreference.com/w/cpp/string/basic_string/operator_at
 template <typename CharT, typename Traits, typename Allocator>
 CharT* data(std::basic_string<CharT, Traits, Allocator>& str) {
   return std::addressof(str[0]);
 }

 template <typename Container>
 constexpr auto data(const Container& c) -> decltype(c.data()) {
   return c.data();
 }

 template <typename T, size_t N>
 constexpr T* data(T (&array)[N]) noexcept {
   return array;
 }

 template <typename T>
 constexpr const T* data(std::initializer_list<T> il) noexcept {
   return il.begin();
 }

 // Returns a const reference to the underlying container of a container adapter.
 // Works for std::priority_queue, std::queue, and std::stack.
 template <class A>
 const typename A::container_type& GetUnderlyingContainer(const A& adapter) {
   struct ExposedAdapter : A {
     using A::c;
   };
   return adapter.*&ExposedAdapter::c;
 }

 // Clears internal memory of an STL object.
 // STL clear()/reserve(0) does not always free internal memory allocated
 // This function uses swap/destructor to ensure the internal memory is freed.
 template <class T>
 void STLClearObject(T* obj) {
   T tmp;
   tmp.swap(*obj);
   // Sometimes "T tmp" allocates objects with memory (arena implementation?).
   // Hence using additional reserve(0) even if it doesn't always work.
   obj->reserve(0);
 }

 // Counts the number of instances of val in a container.
 template <typename Container, typename T>
 typename std::iterator_traits<
     typename Container::const_iterator>::difference_type
 STLCount(const Container& container, const T& val) {
   return std::count(container.begin(), container.end(), val);
 }

 // Test to see if a set or map contains a particular key.
 // Returns true if the key is in the collection.
 template <typename Collection, typename Key>
 bool ContainsKey(const Collection& collection, const Key& key) {
   return collection.find(key) != collection.end();
 }

 namespace internal {

 template <typename Collection>
 class HasKeyType {
   template <typename C>
   static std::true_type test(typename C::key_type*);
   template <typename C>
   static std::false_type test(...);

  public:
   static constexpr bool value = decltype(test<Collection>(nullptr))::value;
 };

 }  // namespace internal

 // Test to see if a collection like a vector contains a particular value.
 // Returns true if the value is in the collection.
 // Don't use this on collections such as sets or maps. This is enforced by
 // disabling this method if the collection defines a key_type.
 template <typename Collection,
           typename Value,
           typename std::enable_if<!internal::HasKeyType<Collection>::value,
                                   int>::type = 0>
 bool ContainsValue(const Collection& collection, const Value& value) {
   return std::find(std::begin(collection), std::end(collection), value) !=
          std::end(collection);
 }

 // Returns true if the container is sorted.
 template <typename Container>
 bool STLIsSorted(const Container& cont) {
   // Note: Use reverse iterator on container to ensure we only require
   // value_type to implement operator<.
   return std::adjacent_find(cont.rbegin(), cont.rend(),
                             std::less<typename Container::value_type>()) ==
          cont.rend();
 }

 // Returns a new ResultType containing the difference of two sorted containers.
 template <typename ResultType, typename Arg1, typename Arg2>
 ResultType STLSetDifference(const Arg1& a1, const Arg2& a2) {
   DCHECK(STLIsSorted(a1));
   DCHECK(STLIsSorted(a2));
   ResultType difference;
   std::set_difference(a1.begin(), a1.end(), a2.begin(), a2.end(),
                       std::inserter(difference, difference.end()));
   return difference;
 }

 // Returns a new ResultType containing the union of two sorted containers.
 template <typename ResultType, typename Arg1, typename Arg2>
 ResultType STLSetUnion(const Arg1& a1, const Arg2& a2) {
   DCHECK(STLIsSorted(a1));
   DCHECK(STLIsSorted(a2));
   ResultType result;
   std::set_union(a1.begin(), a1.end(), a2.begin(), a2.end(),
                  std::inserter(result, result.end()));
   return result;
 }

 // Returns a new ResultType containing the intersection of two sorted
 // containers.
 template <typename ResultType, typename Arg1, typename Arg2>
 ResultType STLSetIntersection(const Arg1& a1, const Arg2& a2) {
   DCHECK(STLIsSorted(a1));
   DCHECK(STLIsSorted(a2));
   ResultType result;
   std::set_intersection(a1.begin(), a1.end(), a2.begin(), a2.end(),
                         std::inserter(result, result.end()));
   return result;
 }

 // Returns true if the sorted container |a1| contains all elements of the sorted
 // container |a2|.
 template <typename Arg1, typename Arg2>
 bool STLIncludes(const Arg1& a1, const Arg2& a2) {
   DCHECK(STLIsSorted(a1));
   DCHECK(STLIsSorted(a2));
   return std::includes(a1.begin(), a1.end(), a2.begin(), a2.end());
 }

 // Erase/EraseIf are based on library fundamentals ts v2 erase/erase_if
 // http://en.cppreference.com/w/cpp/experimental/lib_extensions_2
 // They provide a generic way to erase elements from a container.
 // The functions here implement these for the standard containers until those
 // functions are available in the C++ standard.
 // For Chromium containers overloads should be defined in their own headers
 // (like standard containers).
 // Note: there is no std::erase for standard associative containers so we don't
 // have it either.

 template <typename CharT, typename Traits, typename Allocator, typename Value>
 void Erase(std::basic_string<CharT, Traits, Allocator>& container,
            const Value& value) {
   container.erase(std::remove(container.begin(), container.end(), value),
                   container.end());
 }

 template <typename CharT, typename Traits, typename Allocator, class Predicate>
 void EraseIf(std::basic_string<CharT, Traits, Allocator>& container,
              Predicate pred) {
   container.erase(std::remove_if(container.begin(), container.end(), pred),
                   container.end());
 }

 template <class T, class Allocator, class Value>
 void Erase(std::deque<T, Allocator>& container, const Value& value) {
   container.erase(std::remove(container.begin(), container.end(), value),
                   container.end());
 }

 template <class T, class Allocator, class Predicate>
 void EraseIf(std::deque<T, Allocator>& container, Predicate pred) {
   container.erase(std::remove_if(container.begin(), container.end(), pred),
                   container.end());
 }

 template <class T, class Allocator, class Value>
 void Erase(std::vector<T, Allocator>& container, const Value& value) {
   container.erase(std::remove(container.begin(), container.end(), value),
                   container.end());
 }

 template <class T, class Allocator, class Predicate>
 void EraseIf(std::vector<T, Allocator>& container, Predicate pred) {
   container.erase(std::remove_if(container.begin(), container.end(), pred),
                   container.end());
 }

 template <class T, class Allocator, class Value>
 void Erase(std::forward_list<T, Allocator>& container, const Value& value) {
   // Unlike std::forward_list::remove, this function template accepts
   // heterogeneous types and does not force a conversion to the container's
   // value type before invoking the == operator.
   container.remove_if([&](const T& cur) { return cur == value; });
 }

 template <class T, class Allocator, class Predicate>
 void EraseIf(std::forward_list<T, Allocator>& container, Predicate pred) {
   container.remove_if(pred);
 }

 template <class T, class Allocator, class Value>
 void Erase(std::list<T, Allocator>& container, const Value& value) {
   // Unlike std::list::remove, this function template accepts heterogeneous
   // types and does not force a conversion to the container's value type before
   // invoking the == operator.
   container.remove_if([&](const T& cur) { return cur == value; });
 }

 template <class T, class Allocator, class Predicate>
 void EraseIf(std::list<T, Allocator>& container, Predicate pred) {
   container.remove_if(pred);
 }

 template <class Key, class T, class Compare, class Allocator, class Predicate>
 void EraseIf(std::map<Key, T, Compare, Allocator>& container, Predicate pred) {
   internal::IterateAndEraseIf(container, pred);
 }

 template <class Key, class T, class Compare, class Allocator, class Predicate>
 void EraseIf(std::multimap<Key, T, Compare, Allocator>& container,
              Predicate pred) {
   internal::IterateAndEraseIf(container, pred);
 }

 template <class Key, class Compare, class Allocator, class Predicate>
 void EraseIf(std::set<Key, Compare, Allocator>& container, Predicate pred) {
   internal::IterateAndEraseIf(container, pred);
 }

 template <class Key, class Compare, class Allocator, class Predicate>
 void EraseIf(std::multiset<Key, Compare, Allocator>& container,
              Predicate pred) {
   internal::IterateAndEraseIf(container, pred);
 }

 template <class Key,
           class T,
           class Hash,
           class KeyEqual,
           class Allocator,
           class Predicate>
 void EraseIf(std::unordered_map<Key, T, Hash, KeyEqual, Allocator>& container,
              Predicate pred) {
   internal::IterateAndEraseIf(container, pred);
 }

 template <class Key,
           class T,
           class Hash,
           class KeyEqual,
           class Allocator,
           class Predicate>
 void EraseIf(
     std::unordered_multimap<Key, T, Hash, KeyEqual, Allocator>& container,
     Predicate pred) {
   internal::IterateAndEraseIf(container, pred);
 }

 template <class Key,
           class Hash,
           class KeyEqual,
           class Allocator,
           class Predicate>
 void EraseIf(std::unordered_set<Key, Hash, KeyEqual, Allocator>& container,
              Predicate pred) {
   internal::IterateAndEraseIf(container, pred);
 }

 template <class Key,
           class Hash,
           class KeyEqual,
           class Allocator,
           class Predicate>
 void EraseIf(std::unordered_multiset<Key, Hash, KeyEqual, Allocator>& container,
              Predicate pred) {
   internal::IterateAndEraseIf(container, pred);
 }

 // A helper class to be used as the predicate with |EraseIf| to implement
 // in-place set intersection. Helps implement the algorithm of going through
 // each container an element at a time, erasing elements from the first
 // container if they aren't in the second container. Requires each container be
 // sorted. Note that the logic below appears inverted since it is returning
 // whether an element should be erased.
 template <class Collection>
 class IsNotIn {
  public:
   explicit IsNotIn(const Collection& collection)
       : i_(collection.begin()), end_(collection.end()) {}

   bool operator()(const typename Collection::value_type& x) {
     while (i_ != end_ && *i_ < x)
       ++i_;
     if (i_ == end_)
       return true;
     if (*i_ == x) {
       ++i_;
       return false;
     }
     return true;
   }

  private:
   typename Collection::const_iterator i_;
   const typename Collection::const_iterator end_;
 };

 // Helper for returning the optional value's address, or nullptr.
 template <class T>
 T* OptionalOrNullptr(base::Optional<T>& optional) {
   return optional.has_value() ? &optional.value() : nullptr;
 }

 template <class T>
 const T* OptionalOrNullptr(const base::Optional<T>& optional) {
   return optional.has_value() ? &optional.value() : nullptr;
 }

 }  // namespace base

 #endif  // BASE_STL_UTIL_H_
	// Copyright (c) 2011 The Chromium Authors. All rights reserved.
	// Use of this source code is governed by a BSD-style license that can be
	// found in the LICENSE file.

	// Derived from google3/util/gtl/stl_util.h

	#ifndef BASE_STL_UTIL_H_
	#define BASE_STL_UTIL_H_

	#include <algorithm>
	#include <deque>
	#include <forward_list>
	#include <functional>
	#include <initializer_list>
	#include <iterator>
	#include <list>
	#include <map>
	#include <set>
	#include <string>
	#include <unordered_map>
	#include <unordered_set>
	#include <vector>

	#include "base/logging.h"
	#include "base/optional.h"

	namespace base {

	namespace internal {

	// Calls erase on iterators of matching elements.
	template <typename Container, typename Predicate>
	void IterateAndEraseIf(Container& container, Predicate pred) {
	for (auto it = container.begin(); it != container.end();) {
	if (pred(*it))
	it = container.erase(it);
	else
	++it;
	}
	}

	} // namespace internal

	// C++14 implementation of C++17's std::size():
	// http://en.cppreference.com/w/cpp/iterator/size
	template <typename Container>
	constexpr auto size(const Container& c) -> decltype(c.size()) {
	return c.size();
	}

	template <typename T, size_t N>
	constexpr size_t size(const T (&array)[N]) noexcept {
	return N;
	}

	// C++14 implementation of C++17's std::empty():
	// http://en.cppreference.com/w/cpp/iterator/empty
	template <typename Container>
	constexpr auto empty(const Container& c) -> decltype(c.empty()) {
	return c.empty();
	}

	template <typename T, size_t N>
	constexpr bool empty(const T (&array)[N]) noexcept {
	return false;
	}

	template <typename T>
	constexpr bool empty(std::initializer_list<T> il) noexcept {
	return il.size() == 0;
	}

	// C++14 implementation of C++17's std::data():
	// http://en.cppreference.com/w/cpp/iterator/data
	template <typename Container>
	constexpr auto data(Container& c) -> decltype(c.data()) {
	return c.data();
	}

	// std::basic_string::data() had no mutable overload prior to C++17 [1].
	// Hence this overload is provided.
	// Note: str[0] is safe even for empty strings, as they are guaranteed to be
	// null-terminated [2].
	//
	// [1] http://en.cppreference.com/w/cpp/string/basic_string/data
	// [2] http://en.cppreference.com/w/cpp/string/basic_string/operator_at
	template <typename CharT, typename Traits, typename Allocator>
	CharT* data(std::basic_string<CharT, Traits, Allocator>& str) {
	return std::addressof(str[0]);
	}

	template <typename Container>
	constexpr auto data(const Container& c) -> decltype(c.data()) {
	return c.data();
	}

	template <typename T, size_t N>
	constexpr T* data(T (&array)[N]) noexcept {
	return array;
	}

	template <typename T>
	constexpr const T* data(std::initializer_list<T> il) noexcept {
	return il.begin();
	}

	// Returns a const reference to the underlying container of a container adapter.
	// Works for std::priority_queue, std::queue, and std::stack.
	template <class A>
	const typename A::container_type& GetUnderlyingContainer(const A& adapter) {
	struct ExposedAdapter : A {
	using A::c;
	};
	return adapter.*&ExposedAdapter::c;
	}

	// Clears internal memory of an STL object.
	// STL clear()/reserve(0) does not always free internal memory allocated
	// This function uses swap/destructor to ensure the internal memory is freed.
	template <class T>
	void STLClearObject(T* obj) {
	T tmp;
	tmp.swap(*obj);
	// Sometimes "T tmp" allocates objects with memory (arena implementation?).
	// Hence using additional reserve(0) even if it doesn't always work.
	obj->reserve(0);
	}

	// Counts the number of instances of val in a container.
	template <typename Container, typename T>
	typename std::iterator_traits<
	typename Container::const_iterator>::difference_type
	STLCount(const Container& container, const T& val) {
	return std::count(container.begin(), container.end(), val);
	}

	// Test to see if a set or map contains a particular key.
	// Returns true if the key is in the collection.
	template <typename Collection, typename Key>
	bool ContainsKey(const Collection& collection, const Key& key) {
	return collection.find(key) != collection.end();
	}

	namespace internal {

	template <typename Collection>
	class HasKeyType {
	template <typename C>
	static std::true_type test(typename C::key_type*);
	template <typename C>
	static std::false_type test(...);

	public:
	static constexpr bool value = decltype(test<Collection>(nullptr))::value;
	};

	} // namespace internal

	// Test to see if a collection like a vector contains a particular value.
	// Returns true if the value is in the collection.
	// Don't use this on collections such as sets or maps. This is enforced by
	// disabling this method if the collection defines a key_type.
	template <typename Collection,
	typename Value,
	typename std::enable_if<!internal::HasKeyType<Collection>::value,
	int>::type = 0>
	bool ContainsValue(const Collection& collection, const Value& value) {
	return std::find(std::begin(collection), std::end(collection), value) !=
	std::end(collection);
	}

	// Returns true if the container is sorted.
	template <typename Container>
	bool STLIsSorted(const Container& cont) {
	// Note: Use reverse iterator on container to ensure we only require
	// value_type to implement operator<.
	return std::adjacent_find(cont.rbegin(), cont.rend(),
	std::less<typename Container::value_type>()) ==
	cont.rend();
	}

	// Returns a new ResultType containing the difference of two sorted containers.
	template <typename ResultType, typename Arg1, typename Arg2>
	ResultType STLSetDifference(const Arg1& a1, const Arg2& a2) {
	DCHECK(STLIsSorted(a1));
	DCHECK(STLIsSorted(a2));
	ResultType difference;
	std::set_difference(a1.begin(), a1.end(), a2.begin(), a2.end(),
	std::inserter(difference, difference.end()));
	return difference;
	}

	// Returns a new ResultType containing the union of two sorted containers.
	template <typename ResultType, typename Arg1, typename Arg2>
	ResultType STLSetUnion(const Arg1& a1, const Arg2& a2) {
	DCHECK(STLIsSorted(a1));
	DCHECK(STLIsSorted(a2));
	ResultType result;
	std::set_union(a1.begin(), a1.end(), a2.begin(), a2.end(),
	std::inserter(result, result.end()));
	return result;
	}

	// Returns a new ResultType containing the intersection of two sorted
	// containers.
	template <typename ResultType, typename Arg1, typename Arg2>
	ResultType STLSetIntersection(const Arg1& a1, const Arg2& a2) {
	DCHECK(STLIsSorted(a1));
	DCHECK(STLIsSorted(a2));
	ResultType result;
	std::set_intersection(a1.begin(), a1.end(), a2.begin(), a2.end(),
	std::inserter(result, result.end()));
	return result;
	}

	// Returns true if the sorted container \|a1\| contains all elements of the sorted
	// container \|a2\|.
	template <typename Arg1, typename Arg2>
	bool STLIncludes(const Arg1& a1, const Arg2& a2) {
	DCHECK(STLIsSorted(a1));
	DCHECK(STLIsSorted(a2));
	return std::includes(a1.begin(), a1.end(), a2.begin(), a2.end());
	}

	// Erase/EraseIf are based on library fundamentals ts v2 erase/erase_if
	// http://en.cppreference.com/w/cpp/experimental/lib_extensions_2
	// They provide a generic way to erase elements from a container.
	// The functions here implement these for the standard containers until those
	// functions are available in the C++ standard.
	// For Chromium containers overloads should be defined in their own headers
	// (like standard containers).
	// Note: there is no std::erase for standard associative containers so we don't
	// have it either.

	template <typename CharT, typename Traits, typename Allocator, typename Value>
	void Erase(std::basic_string<CharT, Traits, Allocator>& container,
	const Value& value) {
	container.erase(std::remove(container.begin(), container.end(), value),
	container.end());
	}

	template <typename CharT, typename Traits, typename Allocator, class Predicate>
	void EraseIf(std::basic_string<CharT, Traits, Allocator>& container,
	Predicate pred) {
	container.erase(std::remove_if(container.begin(), container.end(), pred),
	container.end());
	}

	template <class T, class Allocator, class Value>
	void Erase(std::deque<T, Allocator>& container, const Value& value) {
	container.erase(std::remove(container.begin(), container.end(), value),
	container.end());
	}

	template <class T, class Allocator, class Predicate>
	void EraseIf(std::deque<T, Allocator>& container, Predicate pred) {
	container.erase(std::remove_if(container.begin(), container.end(), pred),
	container.end());
	}

	template <class T, class Allocator, class Value>
	void Erase(std::vector<T, Allocator>& container, const Value& value) {
	container.erase(std::remove(container.begin(), container.end(), value),
	container.end());
	}

	template <class T, class Allocator, class Predicate>
	void EraseIf(std::vector<T, Allocator>& container, Predicate pred) {
	container.erase(std::remove_if(container.begin(), container.end(), pred),
	container.end());
	}

	template <class T, class Allocator, class Value>
	void Erase(std::forward_list<T, Allocator>& container, const Value& value) {
	// Unlike std::forward_list::remove, this function template accepts
	// heterogeneous types and does not force a conversion to the container's
	// value type before invoking the == operator.
	container.remove_if([&](const T& cur) { return cur == value; });
	}

	template <class T, class Allocator, class Predicate>
	void EraseIf(std::forward_list<T, Allocator>& container, Predicate pred) {
	container.remove_if(pred);
	}

	template <class T, class Allocator, class Value>
	void Erase(std::list<T, Allocator>& container, const Value& value) {
	// Unlike std::list::remove, this function template accepts heterogeneous
	// types and does not force a conversion to the container's value type before
	// invoking the == operator.
	container.remove_if([&](const T& cur) { return cur == value; });
	}

	template <class T, class Allocator, class Predicate>
	void EraseIf(std::list<T, Allocator>& container, Predicate pred) {
	container.remove_if(pred);
	}

	template <class Key, class T, class Compare, class Allocator, class Predicate>
	void EraseIf(std::map<Key, T, Compare, Allocator>& container, Predicate pred) {
	internal::IterateAndEraseIf(container, pred);
	}

	template <class Key, class T, class Compare, class Allocator, class Predicate>
	void EraseIf(std::multimap<Key, T, Compare, Allocator>& container,
	Predicate pred) {
	internal::IterateAndEraseIf(container, pred);
	}

	template <class Key, class Compare, class Allocator, class Predicate>
	void EraseIf(std::set<Key, Compare, Allocator>& container, Predicate pred) {
	internal::IterateAndEraseIf(container, pred);
	}

	template <class Key, class Compare, class Allocator, class Predicate>
	void EraseIf(std::multiset<Key, Compare, Allocator>& container,
	Predicate pred) {
	internal::IterateAndEraseIf(container, pred);
	}

	template <class Key,
	class T,
	class Hash,
	class KeyEqual,
	class Allocator,
	class Predicate>
	void EraseIf(std::unordered_map<Key, T, Hash, KeyEqual, Allocator>& container,
	Predicate pred) {
	internal::IterateAndEraseIf(container, pred);
	}

	template <class Key,
	class T,
	class Hash,
	class KeyEqual,
	class Allocator,
	class Predicate>
	void EraseIf(
	std::unordered_multimap<Key, T, Hash, KeyEqual, Allocator>& container,
	Predicate pred) {
	internal::IterateAndEraseIf(container, pred);
	}

	template <class Key,
	class Hash,
	class KeyEqual,
	class Allocator,
	class Predicate>
	void EraseIf(std::unordered_set<Key, Hash, KeyEqual, Allocator>& container,
	Predicate pred) {
	internal::IterateAndEraseIf(container, pred);
	}

	template <class Key,
	class Hash,
	class KeyEqual,
	class Allocator,
	class Predicate>
	void EraseIf(std::unordered_multiset<Key, Hash, KeyEqual, Allocator>& container,
	Predicate pred) {
	internal::IterateAndEraseIf(container, pred);
	}

	// A helper class to be used as the predicate with \|EraseIf\| to implement
	// in-place set intersection. Helps implement the algorithm of going through
	// each container an element at a time, erasing elements from the first
	// container if they aren't in the second container. Requires each container be
	// sorted. Note that the logic below appears inverted since it is returning
	// whether an element should be erased.
	template <class Collection>
	class IsNotIn {
	public:
	explicit IsNotIn(const Collection& collection)
	: i_(collection.begin()), end_(collection.end()) {}

	bool operator()(const typename Collection::value_type& x) {
	while (i_ != end_ && *i_ < x)
	++i_;
	if (i_ == end_)
	return true;
	if (*i_ == x) {
	++i_;
	return false;
	}
	return true;
	}

	private:
	typename Collection::const_iterator i_;
	const typename Collection::const_iterator end_;
	};

	// Helper for returning the optional value's address, or nullptr.
	template <class T>
	T* OptionalOrNullptr(base::Optional<T>& optional) {
	return optional.has_value() ? &optional.value() : nullptr;
	}

	template <class T>
	const T* OptionalOrNullptr(const base::Optional<T>& optional) {
	return optional.has_value() ? &optional.value() : nullptr;
	}

	} // namespace base

	#endif // BASE_STL_UTIL_H_