base/containers/lru_cache.h - cobalt - Git at Google

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

 // This file contains a template for a Least Recently Used cache that allows
 // constant-time access to items, but easy identification of the
 // least-recently-used items for removal. Variations exist to support use as a
 // Map (`base::LRUCache`), HashMap (`base::HashingLRUCache`), Set
 // (`base::LRUCacheSet`), or HashSet (`base::HashingLRUCacheSet`). These are
 // implemented as aliases of `base::internal::LRUCacheBase`, defined at the
 // bottom of this file.
 //
 // The key object (which is identical to the value, in the Set variations) will
 // be stored twice, so it should support efficient copying.

 #ifndef BASE_CONTAINERS_LRU_CACHE_H_
 #define BASE_CONTAINERS_LRU_CACHE_H_

 #include <stddef.h>

 #include <algorithm>
 #include <functional>
 #include <list>
 #include <map>
 #include <type_traits>
 #include <unordered_map>
 #include <utility>

 #include "base/check.h"
 #include "base/functional/identity.h"

 namespace base {
 namespace trace_event::internal {

 template <class LruCacheType>
 size_t DoEstimateMemoryUsageForLruCache(const LruCacheType&);

 }  // namespace trace_event::internal

 namespace internal {

 struct GetKeyFromKVPair {
   template <typename T1, typename T2>
   constexpr const T1& operator()(const std::pair<T1, T2>& pair) {
     return pair.first;
   }
 };

 // Base class for the LRU cache specializations defined below.
 template <class ValueType, class GetKeyFromValue, class KeyIndexTemplate>
 class LRUCacheBase {
  public:
   // The contents of the list. This must contain a copy of the key (that may be
   // extracted via `GetKeyFromValue()(value)` so we can efficiently delete
   // things given an element of the list.
   using value_type = ValueType;

  private:
   using ValueList = std::list<value_type>;
   using KeyIndex =
       typename KeyIndexTemplate::template Type<typename ValueList::iterator>;

  public:
   using size_type = typename ValueList::size_type;
   using key_type = typename KeyIndex::key_type;

   using iterator = typename ValueList::iterator;
   using const_iterator = typename ValueList::const_iterator;
   using reverse_iterator = typename ValueList::reverse_iterator;
   using const_reverse_iterator = typename ValueList::const_reverse_iterator;

   enum { NO_AUTO_EVICT = 0 };

   // The max_size is the size at which the cache will prune its members to when
   // a new item is inserted. If the caller wants to manage this itself (for
   // example, maybe it has special work to do when something is evicted), it
   // can pass NO_AUTO_EVICT to not restrict the cache size.
   explicit LRUCacheBase(size_type max_size) : max_size_(max_size) {}

   LRUCacheBase(const LRUCacheBase&) = delete;
   LRUCacheBase& operator=(const LRUCacheBase&) = delete;

   ~LRUCacheBase() = default;

   size_type max_size() const { return max_size_; }

   // Inserts an item into the list. If an existing item has the same key, it is
   // removed prior to insertion. An iterator indicating the inserted item will
   // be returned (this will always be the front of the list).
   // In the map variations of this container, `value_type` is a `std::pair` and
   // it's preferred to use the `Put(k, v)` overload of this method.
   iterator Put(value_type&& value) {
     // Remove any existing item with that key.
     key_type key = GetKeyFromValue{}(value);
     typename KeyIndex::iterator index_iter = index_.find(key);
     if (index_iter != index_.end()) {
       // Erase the reference to it. The index reference will be replaced in the
       // code below.
       Erase(index_iter->second);
     } else if (max_size_ != NO_AUTO_EVICT) {
       // New item is being inserted which might make it larger than the maximum
       // size: kick the oldest thing out if necessary.
       ShrinkToSize(max_size_ - 1);
     }

     ordering_.push_front(std::move(value));
     index_.emplace(std::move(key), ordering_.begin());
     return ordering_.begin();
   }

   // Inserts an item into the list. If an existing item has the same key, it is
   // removed prior to insertion. An iterator indicating the inserted item will
   // be returned (this will always be the front of the list).
   template <
       class K,
       class V,
       class MapKeyGetter = GetKeyFromKVPair,
       class = std::enable_if_t<std::is_same_v<MapKeyGetter, GetKeyFromValue>>>
   iterator Put(K&& key, V&& value) {
     return Put(value_type{std::forward<K>(key), std::forward<V>(value)});
   }

   // Retrieves the contents of the given key, or end() if not found. This method
   // has the side effect of moving the requested item to the front of the
   // recency list.
   iterator Get(const key_type& key) {
     typename KeyIndex::iterator index_iter = index_.find(key);
     if (index_iter == index_.end())
       return end();
     typename ValueList::iterator iter = index_iter->second;

     // Move the touched item to the front of the recency ordering.
     ordering_.splice(ordering_.begin(), ordering_, iter);
     return ordering_.begin();
   }

   // Retrieves the item associated with a given key and returns it via
   // result without affecting the ordering (unlike Get()).
   iterator Peek(const key_type& key) {
     typename KeyIndex::const_iterator index_iter = index_.find(key);
     if (index_iter == index_.end())
       return end();
     return index_iter->second;
   }

   const_iterator Peek(const key_type& key) const {
     typename KeyIndex::const_iterator index_iter = index_.find(key);
     if (index_iter == index_.end())
       return end();
     return index_iter->second;
   }

   // Exchanges the contents of |this| by the contents of the |other|.
   void Swap(LRUCacheBase& other) {
     ordering_.swap(other.ordering_);
     index_.swap(other.index_);
     std::swap(max_size_, other.max_size_);
   }

   // Erases the item referenced by the given iterator. An iterator to the item
   // following it will be returned. The iterator must be valid.
   iterator Erase(iterator pos) {
     index_.erase(GetKeyFromValue()(*pos));
     return ordering_.erase(pos);
   }

   // LRUCache entries are often processed in reverse order, so we add this
   // convenience function (not typically defined by STL containers).
   reverse_iterator Erase(reverse_iterator pos) {
     // We have to actually give it the incremented iterator to delete, since
     // the forward iterator that base() returns is actually one past the item
     // being iterated over.
     return reverse_iterator(Erase((++pos).base()));
   }

   // Shrinks the cache so it only holds |new_size| items. If |new_size| is
   // bigger or equal to the current number of items, this will do nothing.
   void ShrinkToSize(size_type new_size) {
     for (size_type i = size(); i > new_size; i--)
       Erase(rbegin());
   }

   // Deletes everything from the cache.
   void Clear() {
     index_.clear();
     ordering_.clear();
   }

   // Returns the number of elements in the cache.
   size_type size() const {
     // We don't use ordering_.size() for the return value because
     // (as a linked list) it can be O(n).
     DCHECK(index_.size() == ordering_.size());
     return index_.size();
   }

   // Allows iteration over the list. Forward iteration starts with the most
   // recent item and works backwards.
   //
   // Note that since these iterators are actually iterators over a list, you
   // can keep them as you insert or delete things (as long as you don't delete
   // the one you are pointing to) and they will still be valid.
   iterator begin() { return ordering_.begin(); }
   const_iterator begin() const { return ordering_.begin(); }
   iterator end() { return ordering_.end(); }
   const_iterator end() const { return ordering_.end(); }

   reverse_iterator rbegin() { return ordering_.rbegin(); }
   const_reverse_iterator rbegin() const { return ordering_.rbegin(); }
   reverse_iterator rend() { return ordering_.rend(); }
   const_reverse_iterator rend() const { return ordering_.rend(); }

   bool empty() const { return ordering_.empty(); }

  private:
   template <class LruCacheType>
   friend size_t trace_event::internal::DoEstimateMemoryUsageForLruCache(
       const LruCacheType&);

   ValueList ordering_;
   KeyIndex index_;

   size_type max_size_;
 };

 template <class KeyType, class KeyCompare>
 struct LRUCacheKeyIndex {
   template <class ValueType>
   using Type = std::map<KeyType, ValueType, KeyCompare>;
 };

 template <class KeyType, class KeyHash, class KeyEqual>
 struct HashingLRUCacheKeyIndex {
   template <class ValueType>
   using Type = std::unordered_map<KeyType, ValueType, KeyHash, KeyEqual>;
 };

 }  // namespace internal

 // Implements an LRU cache of `ValueType`, where each value can be uniquely
 // referenced by `KeyType`. Entries can be iterated in order of
 // least-recently-used to most-recently-used by iterating from `rbegin()` to
 // `rend()`, where a "use" is defined as a call to `Put(k, v)` or `Get(k)`.
 template <class KeyType, class ValueType, class KeyCompare = std::less<KeyType>>
 using LRUCache =
     internal::LRUCacheBase<std::pair<KeyType, ValueType>,
                            internal::GetKeyFromKVPair,
                            internal::LRUCacheKeyIndex<KeyType, KeyCompare>>;

 // Implements an LRU cache of `ValueType`, where each value can be uniquely
 // referenced by `KeyType`, and `KeyType` may be hashed for O(1) insertion,
 // removal, and lookup. Entries can be iterated in order of least-recently-used
 // to most-recently-used by iterating from `rbegin()` to `rend()`, where a "use"
 // is defined as a call to `Put(k, v)` or `Get(k)`.
 template <class KeyType,
           class ValueType,
           class KeyHash = std::hash<KeyType>,
           class KeyEqual = std::equal_to<KeyType>>
 using HashingLRUCache = internal::LRUCacheBase<
     std::pair<KeyType, ValueType>,
     internal::GetKeyFromKVPair,
     internal::HashingLRUCacheKeyIndex<KeyType, KeyHash, KeyEqual>>;

 // Implements an LRU cache of `ValueType`, where each value is unique. Entries
 // can be iterated in order of least-recently-used to most-recently-used by
 // iterating from `rbegin()` to `rend()`, where a "use" is defined as a call to
 // `Put(v)` or `Get(v)`.
 template <class ValueType, class Compare = std::less<ValueType>>
 using LRUCacheSet =
     internal::LRUCacheBase<ValueType,
                            identity,
                            internal::LRUCacheKeyIndex<ValueType, Compare>>;

 // Implements an LRU cache of `ValueType`, where is value is unique, and may be
 // hashed for O(1) insertion, removal, and lookup. Entries can be iterated in
 // order of least-recently-used to most-recently-used by iterating from
 // `rbegin()` to `rend()`, where a "use" is defined as a call to `Put(v)` or
 // `Get(v)`.
 template <class ValueType,
           class Hash = std::hash<ValueType>,
           class Equal = std::equal_to<ValueType>>
 using HashingLRUCacheSet = internal::LRUCacheBase<
     ValueType,
     identity,
     internal::HashingLRUCacheKeyIndex<ValueType, Hash, Equal>>;

 }  // namespace base

 #endif  // BASE_CONTAINERS_LRU_CACHE_H_
	// Copyright 2011 The Chromium Authors
	// Use of this source code is governed by a BSD-style license that can be
	// found in the LICENSE file.

	// This file contains a template for a Least Recently Used cache that allows
	// constant-time access to items, but easy identification of the
	// least-recently-used items for removal. Variations exist to support use as a
	// Map (`base::LRUCache`), HashMap (`base::HashingLRUCache`), Set
	// (`base::LRUCacheSet`), or HashSet (`base::HashingLRUCacheSet`). These are
	// implemented as aliases of `base::internal::LRUCacheBase`, defined at the
	// bottom of this file.
	//
	// The key object (which is identical to the value, in the Set variations) will
	// be stored twice, so it should support efficient copying.

	#ifndef BASE_CONTAINERS_LRU_CACHE_H_
	#define BASE_CONTAINERS_LRU_CACHE_H_

	#include <stddef.h>

	#include <algorithm>
	#include <functional>
	#include <list>
	#include <map>
	#include <type_traits>
	#include <unordered_map>
	#include <utility>

	#include "base/check.h"
	#include "base/functional/identity.h"

	namespace base {
	namespace trace_event::internal {

	template <class LruCacheType>
	size_t DoEstimateMemoryUsageForLruCache(const LruCacheType&);

	} // namespace trace_event::internal

	namespace internal {

	struct GetKeyFromKVPair {
	template <typename T1, typename T2>
	constexpr const T1& operator()(const std::pair<T1, T2>& pair) {
	return pair.first;
	}
	};

	// Base class for the LRU cache specializations defined below.
	template <class ValueType, class GetKeyFromValue, class KeyIndexTemplate>
	class LRUCacheBase {
	public:
	// The contents of the list. This must contain a copy of the key (that may be
	// extracted via `GetKeyFromValue()(value)` so we can efficiently delete
	// things given an element of the list.
	using value_type = ValueType;

	private:
	using ValueList = std::list<value_type>;
	using KeyIndex =
	typename KeyIndexTemplate::template Type<typename ValueList::iterator>;

	public:
	using size_type = typename ValueList::size_type;
	using key_type = typename KeyIndex::key_type;

	using iterator = typename ValueList::iterator;
	using const_iterator = typename ValueList::const_iterator;
	using reverse_iterator = typename ValueList::reverse_iterator;
	using const_reverse_iterator = typename ValueList::const_reverse_iterator;

	enum { NO_AUTO_EVICT = 0 };

	// The max_size is the size at which the cache will prune its members to when
	// a new item is inserted. If the caller wants to manage this itself (for
	// example, maybe it has special work to do when something is evicted), it
	// can pass NO_AUTO_EVICT to not restrict the cache size.
	explicit LRUCacheBase(size_type max_size) : max_size_(max_size) {}

	LRUCacheBase(const LRUCacheBase&) = delete;
	LRUCacheBase& operator=(const LRUCacheBase&) = delete;

	~LRUCacheBase() = default;

	size_type max_size() const { return max_size_; }

	// Inserts an item into the list. If an existing item has the same key, it is
	// removed prior to insertion. An iterator indicating the inserted item will
	// be returned (this will always be the front of the list).
	// In the map variations of this container, `value_type` is a `std::pair` and
	// it's preferred to use the `Put(k, v)` overload of this method.
	iterator Put(value_type&& value) {
	// Remove any existing item with that key.
	key_type key = GetKeyFromValue{}(value);
	typename KeyIndex::iterator index_iter = index_.find(key);
	if (index_iter != index_.end()) {
	// Erase the reference to it. The index reference will be replaced in the
	// code below.
	Erase(index_iter->second);
	} else if (max_size_ != NO_AUTO_EVICT) {
	// New item is being inserted which might make it larger than the maximum
	// size: kick the oldest thing out if necessary.
	ShrinkToSize(max_size_ - 1);
	}

	ordering_.push_front(std::move(value));
	index_.emplace(std::move(key), ordering_.begin());
	return ordering_.begin();
	}

	// Inserts an item into the list. If an existing item has the same key, it is
	// removed prior to insertion. An iterator indicating the inserted item will
	// be returned (this will always be the front of the list).
	template <
	class K,
	class V,
	class MapKeyGetter = GetKeyFromKVPair,
	class = std::enable_if_t<std::is_same_v<MapKeyGetter, GetKeyFromValue>>>
	iterator Put(K&& key, V&& value) {
	return Put(value_type{std::forward<K>(key), std::forward<V>(value)});
	}

	// Retrieves the contents of the given key, or end() if not found. This method
	// has the side effect of moving the requested item to the front of the
	// recency list.
	iterator Get(const key_type& key) {
	typename KeyIndex::iterator index_iter = index_.find(key);
	if (index_iter == index_.end())
	return end();
	typename ValueList::iterator iter = index_iter->second;

	// Move the touched item to the front of the recency ordering.
	ordering_.splice(ordering_.begin(), ordering_, iter);
	return ordering_.begin();
	}

	// Retrieves the item associated with a given key and returns it via
	// result without affecting the ordering (unlike Get()).
	iterator Peek(const key_type& key) {
	typename KeyIndex::const_iterator index_iter = index_.find(key);
	if (index_iter == index_.end())
	return end();
	return index_iter->second;
	}

	const_iterator Peek(const key_type& key) const {
	typename KeyIndex::const_iterator index_iter = index_.find(key);
	if (index_iter == index_.end())
	return end();
	return index_iter->second;
	}

	// Exchanges the contents of \|this\| by the contents of the \|other\|.
	void Swap(LRUCacheBase& other) {
	ordering_.swap(other.ordering_);
	index_.swap(other.index_);
	std::swap(max_size_, other.max_size_);
	}

	// Erases the item referenced by the given iterator. An iterator to the item
	// following it will be returned. The iterator must be valid.
	iterator Erase(iterator pos) {
	index_.erase(GetKeyFromValue()(*pos));
	return ordering_.erase(pos);
	}

	// LRUCache entries are often processed in reverse order, so we add this
	// convenience function (not typically defined by STL containers).
	reverse_iterator Erase(reverse_iterator pos) {
	// We have to actually give it the incremented iterator to delete, since
	// the forward iterator that base() returns is actually one past the item
	// being iterated over.
	return reverse_iterator(Erase((++pos).base()));
	}

	// Shrinks the cache so it only holds \|new_size\| items. If \|new_size\| is
	// bigger or equal to the current number of items, this will do nothing.
	void ShrinkToSize(size_type new_size) {
	for (size_type i = size(); i > new_size; i--)
	Erase(rbegin());
	}

	// Deletes everything from the cache.
	void Clear() {
	index_.clear();
	ordering_.clear();
	}

	// Returns the number of elements in the cache.
	size_type size() const {
	// We don't use ordering_.size() for the return value because
	// (as a linked list) it can be O(n).
	DCHECK(index_.size() == ordering_.size());
	return index_.size();
	}

	// Allows iteration over the list. Forward iteration starts with the most
	// recent item and works backwards.
	//
	// Note that since these iterators are actually iterators over a list, you
	// can keep them as you insert or delete things (as long as you don't delete
	// the one you are pointing to) and they will still be valid.
	iterator begin() { return ordering_.begin(); }
	const_iterator begin() const { return ordering_.begin(); }
	iterator end() { return ordering_.end(); }
	const_iterator end() const { return ordering_.end(); }

	reverse_iterator rbegin() { return ordering_.rbegin(); }
	const_reverse_iterator rbegin() const { return ordering_.rbegin(); }
	reverse_iterator rend() { return ordering_.rend(); }
	const_reverse_iterator rend() const { return ordering_.rend(); }

	bool empty() const { return ordering_.empty(); }

	private:
	template <class LruCacheType>
	friend size_t trace_event::internal::DoEstimateMemoryUsageForLruCache(
	const LruCacheType&);

	ValueList ordering_;
	KeyIndex index_;

	size_type max_size_;
	};

	template <class KeyType, class KeyCompare>
	struct LRUCacheKeyIndex {
	template <class ValueType>
	using Type = std::map<KeyType, ValueType, KeyCompare>;
	};

	template <class KeyType, class KeyHash, class KeyEqual>
	struct HashingLRUCacheKeyIndex {
	template <class ValueType>
	using Type = std::unordered_map<KeyType, ValueType, KeyHash, KeyEqual>;
	};

	} // namespace internal

	// Implements an LRU cache of `ValueType`, where each value can be uniquely
	// referenced by `KeyType`. Entries can be iterated in order of
	// least-recently-used to most-recently-used by iterating from `rbegin()` to
	// `rend()`, where a "use" is defined as a call to `Put(k, v)` or `Get(k)`.
	template <class KeyType, class ValueType, class KeyCompare = std::less<KeyType>>
	using LRUCache =
	internal::LRUCacheBase<std::pair<KeyType, ValueType>,
	internal::GetKeyFromKVPair,
	internal::LRUCacheKeyIndex<KeyType, KeyCompare>>;

	// Implements an LRU cache of `ValueType`, where each value can be uniquely
	// referenced by `KeyType`, and `KeyType` may be hashed for O(1) insertion,
	// removal, and lookup. Entries can be iterated in order of least-recently-used
	// to most-recently-used by iterating from `rbegin()` to `rend()`, where a "use"
	// is defined as a call to `Put(k, v)` or `Get(k)`.
	template <class KeyType,
	class ValueType,
	class KeyHash = std::hash<KeyType>,
	class KeyEqual = std::equal_to<KeyType>>
	using HashingLRUCache = internal::LRUCacheBase<
	std::pair<KeyType, ValueType>,
	internal::GetKeyFromKVPair,
	internal::HashingLRUCacheKeyIndex<KeyType, KeyHash, KeyEqual>>;

	// Implements an LRU cache of `ValueType`, where each value is unique. Entries
	// can be iterated in order of least-recently-used to most-recently-used by
	// iterating from `rbegin()` to `rend()`, where a "use" is defined as a call to
	// `Put(v)` or `Get(v)`.
	template <class ValueType, class Compare = std::less<ValueType>>
	using LRUCacheSet =
	internal::LRUCacheBase<ValueType,
	identity,
	internal::LRUCacheKeyIndex<ValueType, Compare>>;

	// Implements an LRU cache of `ValueType`, where is value is unique, and may be
	// hashed for O(1) insertion, removal, and lookup. Entries can be iterated in
	// order of least-recently-used to most-recently-used by iterating from
	// `rbegin()` to `rend()`, where a "use" is defined as a call to `Put(v)` or
	// `Get(v)`.
	template <class ValueType,
	class Hash = std::hash<ValueType>,
	class Equal = std::equal_to<ValueType>>
	using HashingLRUCacheSet = internal::LRUCacheBase<
	ValueType,
	identity,
	internal::HashingLRUCacheKeyIndex<ValueType, Hash, Equal>>;

	} // namespace base

	#endif // BASE_CONTAINERS_LRU_CACHE_H_