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Least Recently Used (LRU) Cache is to discard the least recently used items first How do you design and implement such a cache class? The design requirements are as follows:

1) find the item as fast as we can

2) Once a cache misses and a cache is full, we need to replace the least recently used item as fast as possible.

How to analyze and implement this question in terms of design pattern and algorithm design?

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5 Answers 5

up vote 62 down vote accepted

A linked list + hashtable of pointers to the linked list nodes is the usual way to implement LRU caches. This gives O(1) operations (assuming a decent hash). Advantage of this (being O(1)): you can do a multithreaded version by just locking the whole structure. You don't have to worry about granular locking etc.

Briefly, the way it works:

On an access of a value, you move the corresponding node in the linked list to the head.

When you need to remove a value from the cache, you remove from the tail end.

When you add a value to cache, you just place it at the head of the linked list.

Thanks to doublep, here is site with a C++ implementation: Miscellaneous Container Templates.

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3  
@Moron: I would use a doubly-linked list. –  Matthieu N. Mar 24 '10 at 3:03
    
@darid: I think you can also use a singly-linked list and make the hash table point to the previous node to the one that contains the hashed value. –  Rafał Dowgird Mar 24 '10 at 9:38
    
@darid: Just 'linked list' does not imply singly linked list. Besides, for singly linked list, making a random node the head is not O(1). –  Aryabhatta Mar 24 '10 at 18:07
3  
@Rafal: Why complicate matters? Given a doubly linked list implementation and a hashtable implementation, you can put them together easily to create a LRU implementaiton. Trying to maintain the linked list structure in the hashtable will make you implement the linked list methods yourself and you will not be able to use off the shelf ones... –  Aryabhatta Mar 24 '10 at 18:09
1  
By the way, there a linked hash table implementation for C++ in Miscellaneous Container Templates. Its documentation contains example exactly for this usecase. –  doublep Jun 20 '10 at 21:57

This is my simple sample c++ implementation for LRU cache, with the combination of hash(unordered_map), and list. Items on list have key to access map, and items on map have iterator of list to access list.

#include <list>
#include <unordered_map>
#include <assert.h>

using namespace std;

template <class KEY_T, class VAL_T> class LRUCache{
private:
        list< pair<KEY_T,VAL_T> > item_list;
        unordered_map<KEY_T, decltype(item_list.begin()) > item_map;
        size_t cache_size;
private:
        void clean(void){
                while(item_map.size()>cache_size){
                        auto last_it = item_list.end(); last_it --;
                        item_map.erase(last_it->first);
                        item_list.pop_back();
                }
        };
public:
        LRUCache(int cache_size_):cache_size(cache_size_){
                ;
        };

        void put(const KEY_T &key, const VAL_T &val){
                auto it = item_map.find(key);
                if(it != item_map.end()){
                        item_list.erase(it->second);
                        item_map.erase(it);
                }
                item_list.push_front(make_pair(key,val));
                item_map.insert(make_pair(key, item_list.begin()));
                clean();
        };
        bool exist(const KEY_T &key){
                return (item_map.count(key)>0);
        };
        VAL_T get(const KEY_T &key){
                assert(exist(key));
                auto it = item_map.find(key);
                item_list.splice(item_list.begin(), item_list, it->second);
                return it->second->second;
        };

};
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I have a LRU implementation here. The interface follows std::map so it should not be that hard to use. Additionally you can provide a custom backup handler, that is used if data is invalidated in the cache.

sweet::Cache<std::string,std::vector<int>, 48> c1;
c1.insert("key1", std::vector<int>());
c1.insert("key2", std::vector<int>());
assert(c1.contains("key1"));
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Is cache a data structure that supports retrieval value by key like hash table? LRU means the cache has certain size limitation that we need drop least used entries periodically.

If you implement with linked-list + hashtable of pointers how can you do O(1) retrieval of value by key?

I would implement LRU cache with a hash table that the value of each entry is value + pointers to prev/next entry.

Regarding the multi-threading access, I would prefer reader-writer lock (ideally implemented by spin lock since contention is usually fast) to monitor.

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2  
What you are saying is pretty much the Linked List + Hash Table method. –  sprite Mar 30 '11 at 16:09

Here is my implementation for a basic, simple LRU cache.

//LRU Cache
#include <cassert>
#include <list>

template <typename K,
          typename V
          >
class LRUCache
    {
    // Key access history, most recent at back
    typedef std::list<K> List;

    // Key to value and key history iterator
    typedef unordered_map< K,
                           std::pair<
                                     V,
                                     typename std::list<K>::iterator
                                    >
                         > Cache;

    typedef V (*Fn)(const K&);

public:
    LRUCache( size_t aCapacity, Fn aFn ) 
        : mFn( aFn )
        , mCapacity( aCapacity )
        {}

    //get value for key aKey
    V operator()( const K& aKey )
        {
        typename Cache::iterator it = mCache.find( aKey );
        if( it == mCache.end() ) //cache-miss: did not find the key
            {
            V v = mFn( aKey );
            insert( aKey, v );
            return v;
            }

        // cache-hit
        // Update access record by moving accessed key to back of the list
        mList.splice( mList.end(), mList, (it)->second.second );

        // return the retrieved value
        return (it)->second.first;
        }

private:
        // insert a new key-value pair in the cache
    void insert( const K& aKey, V aValue )
        {
        //method should be called only when cache-miss happens
        assert( mCache.find( aKey ) == mCache.end() );

        // make space if necessary
        if( mList.size() == mCapacity )
            {
            evict();
            }

        // record k as most-recently-used key
        typename std::list<K>::iterator it = mList.insert( mList.end(), aKey );

        // create key-value entry, linked to the usage record
        mCache.insert( std::make_pair( aKey, std::make_pair( aValue, it ) ) );
        }

        //Purge the least-recently used element in the cache
    void evict()
        {
        assert( !mList.empty() );

        // identify least-recently-used key
        const typename Cache::iterator it = mCache.find( mList.front() );

        //erase both elements to completely purge record
        mCache.erase( it );
        mList.pop_front();
        }

private:
    List mList;
    Cache mCache;
    Fn mFn;
    size_t mCapacity;
    };
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