¿Cómo implementar el esquema de almacenamiento en caché LRU? ¿Qué estructuras de datos se deben utilizar?
Se nos da el número total de páginas posibles que se pueden referir. También se nos da un tamaño de caché (o memoria) (la cantidad de marcos de página que el caché puede contener a la vez). El esquema de almacenamiento en caché de LRU consiste en eliminar el marco utilizado menos recientemente cuando el caché está lleno y se hace referencia a una nueva página que no está en el caché. Consulte el libro de Galvin para obtener más detalles (consulte la diapositiva de reemplazo de la página LRU aquí ).
Usamos dos estructuras de datos para implementar una caché LRU.
C++
// We can use stl container list as a double
// ended queue to store the cache keys, with
// the descending time of reference from front
// to back and a set container to check presence
// of a key. But to fetch the address of the key
// in the list using find(), it takes O(N) time.
// This can be optimized by storing a reference
// (iterator) to each key in a hash map.
#include <bits/stdc++.h>
using namespace std;
class LRUCache {
// store keys of cache
list<int> dq;
// store references of key in cache
unordered_map<int, list<int>::iterator> ma;
int csize; // maximum capacity of cache
public:
LRUCache(int);
void refer(int);
void display();
};
// Declare the size
LRUCache::LRUCache(int n)
{
csize = n;
}
// Refers key x with in the LRU cache
void LRUCache::refer(int x)
{
// not present in cache
if (ma.find(x) == ma.end()) {
// cache is full
if (dq.size() == csize) {
// delete least recently used element
int last = dq.back();
// Pops the last element
dq.pop_back();
// Erase the last
ma.erase(last);
}
}
// present in cache
else
dq.erase(ma[x]);
// update reference
dq.push_front(x);
ma[x] = dq.begin();
}
// Function to display contents of cache
void LRUCache::display()
{
// Iterate in the deque and print
// all the elements in it
for (auto it = dq.begin(); it != dq.end();
it++)
cout << (*it) << " ";
cout << endl;
}
// Driver Code
int main()
{
LRUCache ca(4);
ca.refer(1);
ca.refer(2);
ca.refer(3);
ca.refer(1);
ca.refer(4);
ca.refer(5);
ca.display();
return 0;
}
// This code is contributed by Satish Srinivas
C
// A C program to show implementation of LRU cache
#include <stdio.h>
#include <stdlib.h>
// A Queue Node (Queue is implemented using Doubly Linked List)
typedef struct QNode {
struct QNode *prev, *next;
unsigned pageNumber; // the page number stored in this QNode
} QNode;
// A Queue (A FIFO collection of Queue Nodes)
typedef struct Queue {
unsigned count; // Number of filled frames
unsigned numberOfFrames; // total number of frames
QNode *front, *rear;
} Queue;
// A hash (Collection of pointers to Queue Nodes)
typedef struct Hash {
int capacity; // how many pages can be there
QNode** array; // an array of queue nodes
} Hash;
// A utility function to create a new Queue Node. The queue Node
// will store the given 'pageNumber'
QNode* newQNode(unsigned pageNumber)
{
// Allocate memory and assign 'pageNumber'
QNode* temp = (QNode*)malloc(sizeof(QNode));
temp->pageNumber = pageNumber;
// Initialize prev and next as NULL
temp->prev = temp->next = NULL;
return temp;
}
// A utility function to create an empty Queue.
// The queue can have at most 'numberOfFrames' nodes
Queue* createQueue(int numberOfFrames)
{
Queue* queue = (Queue*)malloc(sizeof(Queue));
// The queue is empty
queue->count = 0;
queue->front = queue->rear = NULL;
// Number of frames that can be stored in memory
queue->numberOfFrames = numberOfFrames;
return queue;
}
// A utility function to create an empty Hash of given capacity
Hash* createHash(int capacity)
{
// Allocate memory for hash
Hash* hash = (Hash*)malloc(sizeof(Hash));
hash->capacity = capacity;
// Create an array of pointers for referring queue nodes
hash->array = (QNode**)malloc(hash->capacity * sizeof(QNode*));
// Initialize all hash entries as empty
int i;
for (i = 0; i < hash->capacity; ++i)
hash->array[i] = NULL;
return hash;
}
// A function to check if there is slot available in memory
int AreAllFramesFull(Queue* queue)
{
return queue->count == queue->numberOfFrames;
}
// A utility function to check if queue is empty
int isQueueEmpty(Queue* queue)
{
return queue->rear == NULL;
}
// A utility function to delete a frame from queue
void deQueue(Queue* queue)
{
if (isQueueEmpty(queue))
return;
// If this is the only node in list, then change front
if (queue->front == queue->rear)
queue->front = NULL;
// Change rear and remove the previous rear
QNode* temp = queue->rear;
queue->rear = queue->rear->prev;
if (queue->rear)
queue->rear->next = NULL;
free(temp);
// decrement the number of full frames by 1
queue->count--;
}
// A function to add a page with given 'pageNumber' to both queue
// and hash
void Enqueue(Queue* queue, Hash* hash, unsigned pageNumber)
{
// If all frames are full, remove the page at the rear
if (AreAllFramesFull(queue)) {
// remove page from hash
hash->array[queue->rear->pageNumber] = NULL;
deQueue(queue);
}
// Create a new node with given page number,
// And add the new node to the front of queue
QNode* temp = newQNode(pageNumber);
temp->next = queue->front;
// If queue is empty, change both front and rear pointers
if (isQueueEmpty(queue))
queue->rear = queue->front = temp;
else // Else change the front
{
queue->front->prev = temp;
queue->front = temp;
}
// Add page entry to hash also
hash->array[pageNumber] = temp;
// increment number of full frames
queue->count++;
}
// This function is called when a page with given 'pageNumber' is referenced
// from cache (or memory). There are two cases:
// 1. Frame is not there in memory, we bring it in memory and add to the front
// of queue
// 2. Frame is there in memory, we move the frame to front of queue
void ReferencePage(Queue* queue, Hash* hash, unsigned pageNumber)
{
QNode* reqPage = hash->array[pageNumber];
// the page is not in cache, bring it
if (reqPage == NULL)
Enqueue(queue, hash, pageNumber);
// page is there and not at front, change pointer
else if (reqPage != queue->front) {
// Unlink rquested page from its current location
// in queue.
reqPage->prev->next = reqPage->next;
if (reqPage->next)
reqPage->next->prev = reqPage->prev;
// If the requested page is rear, then change rear
// as this node will be moved to front
if (reqPage == queue->rear) {
queue->rear = reqPage->prev;
queue->rear->next = NULL;
}
// Put the requested page before current front
reqPage->next = queue->front;
reqPage->prev = NULL;
// Change prev of current front
reqPage->next->prev = reqPage;
// Change front to the requested page
queue->front = reqPage;
}
}
// Driver program to test above functions
int main()
{
// Let cache can hold 4 pages
Queue* q = createQueue(4);
// Let 10 different pages can be requested (pages to be
// referenced are numbered from 0 to 9
Hash* hash = createHash(10);
// Let us refer pages 1, 2, 3, 1, 4, 5
ReferencePage(q, hash, 1);
ReferencePage(q, hash, 2);
ReferencePage(q, hash, 3);
ReferencePage(q, hash, 1);
ReferencePage(q, hash, 4);
ReferencePage(q, hash, 5);
// Let us print cache frames after the above referenced pages
printf("%d ", q->front->pageNumber);
printf("%d ", q->front->next->pageNumber);
printf("%d ", q->front->next->next->pageNumber);
printf("%d ", q->front->next->next->next->pageNumber);
return 0;
}
Java
/* We can use Java inbuilt Deque as a double
ended queue to store the cache keys, with
the descending time of reference from front
to back and a set container to check presence
of a key. But remove a key from the Deque using
remove(), it takes O(N) time. This can be
optimized by storing a reference (iterator) to
each key in a hash map. */
import java.util.Deque;
import java.util.HashSet;
import java.util.LinkedList;
import java.util.Iterator;
public class LRUCache {
// store keys of cache
private Deque<Integer> doublyQueue;
// store references of key in cache
private HashSet<Integer> hashSet;
// maximum capacity of cache
private final int CACHE_SIZE;
LRUCache(int capacity) {
doublyQueue = new LinkedList<>();
hashSet = new HashSet<>();
CACHE_SIZE = capacity;
}
/* Refer the page within the LRU cache */
public void refer(int page) {
if (!hashSet.contains(page)) {
if (doublyQueue.size() == CACHE_SIZE) {
int last = doublyQueue.removeLast();
hashSet.remove(last);
}
}
else {/* The found page may not be always the last element, even if it's an
intermediate element that needs to be removed and added to the start
of the Queue */
doublyQueue.remove(page);
}
doublyQueue.push(page);
hashSet.add(page);
}
// display contents of cache
public void display() {
Iterator<Integer> itr = doublyQueue.iterator();
while (itr.hasNext()) {
System.out.print(itr.next() + " ");
}
}
public static void main(String[] args) {
LRUCache cache = new LRUCache(4);
cache.refer(1);
cache.refer(2);
cache.refer(3);
cache.refer(1);
cache.refer(4);
cache.refer(5);
cache.display();
}
}
// This code is contributed by Niraj Kumar
Java
// Java program to implement LRU cache
// using LinkedHashSet
import java.util.*;
class LRUCache {
Set<Integer> cache;
int capacity;
public LRUCache(int capacity)
{
this.cache = new LinkedHashSet<Integer>(capacity);
this.capacity = capacity;
}
// This function returns false if key is not
// present in cache. Else it moves the key to
// front by first removing it and then adding
// it, and returns true.
public boolean get(int key)
{
if (!cache.contains(key))
return false;
cache.remove(key);
cache.add(key);
return true;
}
/* Refers key x with in the LRU cache */
public void refer(int key)
{
if (get(key) == false)
put(key);
}
// displays contents of cache in Reverse Order
public void display()
{
LinkedList<Integer> list = new LinkedList<>(cache);
// The descendingIterator() method of java.util.LinkedList
// class is used to return an iterator over the elements
// in this LinkedList in reverse sequential order
Iterator<Integer> itr = list.descendingIterator();
while (itr.hasNext())
System.out.print(itr.next() + " ");
}
public void put(int key)
{
if (cache.size() == capacity) {
int firstKey = cache.iterator().next();
cache.remove(firstKey);
}
cache.add(key);
}
public static void main(String[] args)
{
LRUCache ca = new LRUCache(4);
ca.refer(1);
ca.refer(2);
ca.refer(3);
ca.refer(1);
ca.refer(4);
ca.refer(5);
ca.display();
}
}
Publicación traducida automáticamente
Artículo escrito por GeeksforGeeks-1 y traducido por Barcelona Geeks. The original can be accessed here. Licence: CCBY-SA