Hashtable源码分析
Hashtable简介
Hashtable声明
Hashtable基本数据结构
键值对/Entry
Hashtable方法分析
public synchronized boolean contains(Object value)
public synchronized boolean containsKey(Object key)
public synchronized V put(K key, V value)
private void addEntry(int hash, K key, V value, int index)
public synchronized V remove(Object key)
public synchronized Object clone()
protected void rehash()
Hashtable声明
public class Hashtable extends Dictionary implements Map, Cloneable, java.io.Serializable
Hashtable和HashMap一样也是散列表,存储元素也是键值对;
Hashtable继承于Dictionary类(Dictionary类声明了操作键值对的接口方法),实现Map接口(定义键值对接口);
Hashtable大部分类用synchronized修饰,证明Hashtable是线程安全的;
Hashtable基本数据结构
private transient Entry<?,?>[] table:键值对/Entry数组,每个Entry本质上是一个单向链表的表头private int threshold:rehash阈值private float loadFactor:装填因子private transient int modCount = 0: Hashtable结构化修改次数,用来实现fail-fast机制;private transient volatile Set<Map.Entry<K,V>> entrySet:Hastable视图,键值对集合;private transient volatile Set<K> keySet:Hastable视图,key集,Hashtable中key不可重复;private transient volatile Collection<V> values:Hastable视图,value集合,可重复;- Hashtable中key和value是一对多关系;
键值对/Entry
1 private static class Entry<K,V> implements Map.Entry<K,V> { 2 final int hash; 3 final K key; 4 V value; 5 Entry<K, V> next; 6 ... 7 // 计算键值对的hashCode 8 public int hashCode() { 9 // "^" 按位异或, hash在调用构造器时传入 10 return hash ^ Objects.hashCode(value); 11 } 12 }
Hashtable方法分析
public synchronized boolean contains(Object value)
public boolean containsValue(Object value)内部调用contains(value);
判断是否含有该value的键值对,在Hashtable中hashCode相同的Entry用链表组织,hashCode不同的存储在Entry数组table中;
// in contains() method. Entry<?,?> tab[] = table; // 查找:遍历所有Entry链表 for (int i = tab.length ; i-- > 0 ;) { for (Entry<?,?> e = tab[i] ; e != null ; e = e.next) { if (e.value.equals(value)) { return true; } } } return false;
public synchronized boolean containsKey(Object key)
根据key的hashCode计算对应entry在table中的index;
1 Entry<?,?> tab[] = table; 2 int hash = key.hashCode(); 3 /** 4 * 计算index, % tab.length防止数组越界 5 * index表示key对应entry所在链表表头 6 */ 7 int index = (hash & 0x7FFFFFFF) % tab.length; 8 for (Entry<?,?> e = tab[index] ; e != null ; e = e.next) { 9 if ((e.hash == hash) && e.key.equals(key)) { 10 return true; 11 } 12 } 13 return false;
public synchronized V get(Object key):根据指定key查找对应value,查找原理与containsKey相同,查找成功返回value,否则返回null;
public synchronized V put(K key, V value)
设置键值对,key和value都不可为null,设置顺序:
- 如果Hashtable含有key,设置(key, oldValue) -> (key, newValue);
- 如果Hashtable不含有key, 调用
addEntry(...)添加新的键值对;
private void addEntry(int hash, K key, V value, int index)
当键值对个数超过阈值,先进行rehash然后添加entry,否则直接添加entry;
public synchronized V remove(Object key)
remove操作,计算key所在链表表头table[index],然后进行单向链表的节点删除操作
public synchronized Object clone()
对Hashtable的浅拷贝操作,浅拷贝所有bucket(单向链表组织形式)的表头;
protected void rehash()
当Hashtable中键值对总数超过阈值(容量*装载因子)后,内部自动调用rehash()增加容量,重新计算每个键值对的hashCode;
int newCapacity = (oldCapacity << 1) + 1计算新容量 = 2 * 旧容量 + 1;并且根据新容量更新阈值;
... for (int i = oldCapacity ; i-- > 0 ;) { // 拷贝每个Entry链表 for (Entry<K,V> old = (Entry<K,V>)oldMap[i] ; old != null ; ) { Entry<K,V> e = old; old = old.next; // 重新计算每个Entry链表的表头索引(rehash) int index = (e.hash & 0x7FFFFFFF) % newCapacity; // 开辟链表节点 e.next = (Entry<K,V>)newMap[index]; // 拷贝 newMap[index] = e; } }
