程序运行过程中,有时要访问的页面不在内存中,而需要将其调入内存。但是内存已经无空闲空间存储页面,为保证程序正常运行,系统必须从内存中调出一页程序或数据送到磁盘对换区,此时需要一定的算法来决定到低需要调出那个页面。通常将这种算法称为“页面置换算法”。
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先进先出FIFO页面置换算法 原理:淘汰最先进入内存的页面,即选择在页面待的时间最长的页面淘汰
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最近最久未使用LRU置换算法 原理:选择最近且最久未被使用的页面进行淘汰
import java.util.LinkedHashMap;
import java.util.Map;
public LRUCache<K, V> extends LinkedHashMap<K, V> {
private int cacheSize;
public LRUCache(int cacheSize) {
super(3, 0.75, true);
this.cacheSize = cacheSize;
}
protected boolean removeEldestEntry(Map.Entry<K, V> eldest) {
return size() >= cacheSize;
}
}
public class Cached<K, V> {
private final int MAX_CACHE_SIZE;
private final float DEFAULT_LOAD_FACTORY = 0.75f;
LinkedHashMap<K, V> map;
public Cached(int cacheSize) {
MAX_CACHE_SIZE = cacheSize;
int capacity = (int)Math.ceil(MAX_CACHE_SIZE / DEFAULT_LOAD_FACTORY) + 1;
/*
* 第三个参数设置为true,代表linkedlist按访问顺序排序,可作为LRU缓存
* 第三个参数设置为false,代表按插入顺序排序,可作为FIFO缓存
*/
map = new LinkedHashMap<K, V>(capacity, DEFAULT_LOAD_FACTORY, true) {
@Override
protected boolean removeEldestEntry(Map.Entry<K, V> eldest) {
return size() > MAX_CACHE_SIZE;
}
};
}
}
public class FIFO {
private final Queue<Integer> queue = new LinkedList<>();
private final int[] array;
private static int count = 0;
private int page_size;
public FIFO(int page_size, int[] array) {
this.page_size = page_size;
this.array = array;
}
public int fifoPageReplace() {
if (page_size <= 0 || array == null || array.length == 0) {
throw new IllegalArgumentException("The parameter is invalid!");
}
for (int element : array) {
//页面中已经包含此元素
if (queue.contains(element)) {
System.out.println(queue.toString());
}
//页面大小未达到指定的值
else if (queue.size() < page_size) {
queue.offer(element);
System.out.println(queue.toString());
} else {
//移出最早的元素,并加入新元素
queue.poll();
queue.offer(element);
count++;
System.out.println(queue.toString());
}
}
return count;
}
}
数据结构定义
public class LRUNode {
Integer key;
Object value;
LRUNode prev;
LRUNode next;
public LRUNode(Integer key, Object value){
this.key = key;
this.value = value;
}
}
具体实现
public class LRU {
private HashMap<Integer, LRUNode> map;
private LRUNode head;
private LRUNode tail;
private final int[] array;
private static int count = 0;
private int page_size;
public LRU(int page_size, int[] array) {
this.page_size = page_size;
this.array = array;
this.map = new HashMap<>();
}
public int lruPageReplace() {
if (page_size <= 0 || array == null || array.length == 0) {
throw new IllegalArgumentException("The parameter is invalid!");
}
for(int element:array){
if(map.containsKey(element)){
//已经存在的
LRUNode node = map.get(element);
remove(node);
//放在头部
setHead(node);
print(map);
}else if(map.size()<page_size){
//元素个数少于page_size,直接放入
LRUNode node = new LRUNode(element, null);
map.put(element, node);
//放在头部
setHead(node);
print(map);
}else{
//元素不存在,并且超出页面的大小,需要移出最久未使用的元素,加入新元素
map.remove(tail.key);
remove(tail);
LRUNode node = new LRUNode(element, null);
map.put(element, node);
setHead(node);
count++;
print(map);
}
}
return count;
}
private void print(HashMap<Integer, LRUNode> map){
StringBuilder sb = new StringBuilder();
sb.append("[");
for(int i : map.keySet()){
sb.append(i+", ");
}
sb.deleteCharAt(sb.length()-1);
sb.deleteCharAt(sb.length()-1);
sb.append("]");
System.out.println(sb.toString());
}
private void setHead(LRUNode node){
if(head!=null){
node.next = head;
head.prev = node;
}
head = node;
if(tail==null){
tail = node;
}
}
private void remove(LRUNode node){
if(node.prev!=null){
node.prev.next = node.next;
}else{
head = node.next;
}
if(node.next!=null){
node.next.prev=node.prev;
}else{
tail = node.prev;
}
node.next = null;
node.prev = null;
}
}