1.读写锁原理
2.利用读写锁写一个安全的HashMap
读写锁原理
ReadWriteLock:维护一对关联锁,一个读锁一个写锁,读锁可以由多个线程同时获得,写锁只能被一个线程获得。同一时间,读锁和写锁不能被不同线程同时获得。
1.th1想获取写锁,检查readCount==0,满足,说明读锁未被占用,此时可抢写锁;检查writeCount==0说明写锁未被占用,采用CAS修改writeCount为1,若修改成功再将owner改为th1的引用
2.某线程想获取读锁,先检查writeCount是否为0,此时不为0,则不能去获取读锁,直接进入waiters,接下来的两个获取读锁的操作类似,都进了waiters
3.th2想获取写锁,检查readCount==0,满足,说明读锁未被占用,此时可抢写锁;检查writeCount==1说明写锁以被占用,进而查看owner是不是自己,结果发现不是自己,进waiters
4.th1又想获取写锁,检查readCount==0,满足,说明读锁未被占用,此时可抢写锁;检查writeCount==1说明写锁以被占用,进而查看owner是不是自己,结果发现是自己,修改writeCount为2
5.此时假如th1开始释放握有的2个写锁,释放时先判断owner是不是自己,是,将writeCount变为1,继续释放第二个锁writeCount变为0,owner变为null,这是waiters中的第一个线程会被唤醒,唤醒后开始抢读锁,首先判断writeCount==0,满足,然后将读锁给它,readCount加1,然后它会继续判断waiters里的头部是不是还是获取读锁的线程,若是则继续出队列获取读锁,直到队列头部不是获取读锁的线程
6.假如这3个获取到读锁的线程开始逐一释放读锁,readCount一旦等于0,则会唤醒队列头部想获取写锁的线程去尝试获取写锁
锁降级
ReadWriteLock中的读锁和写锁,如果某线程已经拿到写锁,在释放写锁之前它可以再次拿到读锁,等写锁释放后,该线程将继续占有读锁。
通俗一点就是说:既然你已经拿到写锁了,而且当前只有你自己在写,也没有其他线程在读,那你自己读也是可以的;但是如果你拿到读锁了,你想去写,对不起不可以,因为拿到读锁的不止你一个,其他人也在读,所以你不能写。
HashMap、HashTable、ConcurrentHashMap
HashMap线程不安全,HashTable利用synchronized保证线程安全,但效率太低,不能多并发,ConcurrentHashMap使用读写锁保证读的高并发和写的单并发,同一时间可以有多条线程读,提高了读效率
手写ConcurrentHashMap
package com.study.lock;
import java.util.HashMap;
import java.util.Map;
import java.util.concurrent.locks.Lock;
import java.util.concurrent.locks.ReadWriteLock;
import java.util.concurrent.locks.ReentrantReadWriteLock;
// 将hashmap 改造一个并发安全的
// 这是ReentrantReadWriteLock注释中给出的一个示例
public class Demo7_Map {
private final Map<String, Object> m = new HashMap<>();
private final ReentrantReadWriteLock rwl = new ReentrantReadWriteLock();
private final Lock r = rwl.readLock();
private final Lock w = rwl.writeLock();
public Object get(String key){
r.lock();
try {
return m.get(key);
}finally {
r.unlock();
}
}
public Object allKeys(){
r.lock();
try {
return m.keySet().toArray();
}finally {
r.unlock();
}
}
public Object put(String key, Object value){
w.lock();
try {
return m.put(key, value);
}finally {
w.unlock();
}
}
public void clear(){
w.lock();
try {
m.clear();
}finally {
w.unlock();
}
}
}
利用 读写锁+数据库+REDIS 解决高并发场景下数据读写安全问题
import java.util.HashMap;
import java.util.Map;
import java.util.concurrent.locks.ReentrantReadWriteLock;
/*
// 缓存示例
这是ReentrantReadWriteLock注释中给出的一个示例
用于构建一个缓存,该缓存在读取并使用值的时候,不允许修改缓存值
目前还没找到适用场景,有同学有适用场景的,可以推荐给老师
*/
public class Demo8_CacheData {
public static void main(String args[]) {
System.out.println(TeacherInfoCache.get("Kody"));
}
}
class TeacherInfoCache {
static volatile boolean cacheValid;
static final ReentrantReadWriteLock rwl = new ReentrantReadWriteLock();
static Object get(String dataKey) {
Object data = null;
// 读数据,加读锁
rwl.readLock().lock();
try {
if (cacheValid) {
data = Redis.data.get(dataKey);
} else {
// 缓存取不到,从数据库获取,但如果多条线程瞬间多次查询数据库,数据库可能宕机,利用锁解决
// data= DataBase.queryUserInfo();
rwl.readLock().unlock();
// 加写锁之后,并不会马上获取到所,会等到所有的读锁释放
rwl.writeLock().lock();
try {
if (!cacheValid) {
data = DataBase.queryUserInfo();
Redis.data.put(dataKey, data);
cacheValid = true;
}
// 此处加读锁是为了与最后的finally中释放读锁组成一对
// 在释放写锁之前获取读锁,等写锁释放后,该线程仍占有读锁,不用再去抢读锁
rwl.readLock().lock();//此处发生锁降级,在释放写锁之前再次拿到读锁
} finally {
rwl.writeLock().unlock();
}
}
return data;
} finally {
rwl.readLock().unlock();
}
}
}
class DataBase {
static String queryUserInfo() {
System.out.println("查询数据库。。。");
return "name:Kody,age:40,gender:true,";
}
}
class Redis {
static Map<String, Object> data = new HashMap<>();
}
手写ReadWriteLock
package com.study.lock.locks1;
import java.util.concurrent.LinkedBlockingQueue;
import java.util.concurrent.atomic.AtomicInteger;
import java.util.concurrent.atomic.AtomicReference;
import java.util.concurrent.locks.LockSupport;
public class JamesReadWriteLock {
private AtomicInteger readCount = new AtomicInteger(0);
private AtomicInteger writeCount = new AtomicInteger(0);
// 独占锁 拥有者
private AtomicReference<Thread> owner = new AtomicReference<>();
// 等待队列
public volatile LinkedBlockingQueue<WaitNode> waiters = new LinkedBlockingQueue<WaitNode>();
class WaitNode {
int type = 0; // 0 为想获取独占锁的线程, 1为想获取共享锁的线程
Thread thread = null;
int arg = 0;
public WaitNode(Thread thread, int type, int arg) {
this.thread = thread;
this.type = type;
this.arg = arg;
}
}
// 获取独占锁
public void lock() {
int arg = 1;
// 尝试获取独占锁,若成功,退出方法, 若失败...
if (!tryLock(arg)) {
// 标记为独占锁
WaitNode waitNode = new WaitNode(Thread.currentThread(), 0, arg);
waiters.offer(waitNode); // 进入等待队列
// 循环尝试拿锁
for (;;) {
// 若队列头部是当前线程
WaitNode head = waiters.peek();
if (head != null && head.thread == Thread.currentThread()) {
if (!tryLock(arg)) { // 再次尝试获取 独占锁
LockSupport.park(); // 若失败,挂起线程
} else { // 若成功获取
waiters.poll(); // 将当前线程从队列头部移除
return; // 并退出方法
}
} else { // 若不是队列头部元素
LockSupport.park(); // 将当前线程挂起
}
}
}
}
// 释放独占锁
public boolean unlock() {
int arg = 1;
// 尝试释放独占锁 若失败返回true,若失败...
if (tryUnlock(arg)) {
WaitNode next = waiters.peek(); // 取出队列头部的元素
if (next != null) {
Thread th = next.thread;
LockSupport.unpark(th); // 唤醒队列头部的线程
}
return true; // 返回true
}
return false;
}
// 尝试获取独占锁
public boolean tryLock(int acquires) {
// 如果read count !=0 返回false
if (readCount.get() != 0)
return false;
int wct = writeCount.get(); // 拿到 独占锁 当前状态
if (wct == 0) {
if (writeCount.compareAndSet(wct, wct + acquires)) { // 通过修改state来抢锁
owner.set(Thread.currentThread()); // 抢到锁后,直接修改owner为当前线程
return true;
}
} else if (owner.get() == Thread.currentThread()) {
writeCount.set(wct + acquires); // 修改count值
return true;
}
return false;
}
// 尝试释放独占锁
public boolean tryUnlock(int releases) {
// 若当前线程没有 持有独占锁
if (owner.get() != Thread.currentThread()) {
throw new IllegalMonitorStateException(); // 抛IllegalMonitorStateException
}
int wc = writeCount.get();
int nextc = wc - releases; // 计算 独占锁剩余占用
writeCount.set(nextc); // 不管是否完全释放,都更新count值
if (nextc == 0) { // 是否完全释放
owner.compareAndSet(Thread.currentThread(), null);
return true;
} else {
return false;
}
}
// 获取共享锁
public void lockShared() {
int arg = 1;
if (tryLockShared(arg) < 0) { // 如果tryAcquireShare失败
// 将当前进程放入队列
WaitNode node = new WaitNode(Thread.currentThread(), 1, arg);
waiters.offer(node); // 加入队列
for (;;) {
// 若队列头部的元素是当前线程
WaitNode head = waiters.peek();
if (head != null && head.thread == Thread.currentThread()) {
if (tryLockShared(arg) >= 0) { // 尝试获取共享锁, 若成功
waiters.poll(); // 将当前线程从队列中移除
WaitNode next = waiters.peek();
if (next != null && next.type == 1) { // 如果下一个线程也是等待共享锁
LockSupport.unpark(next.thread); // 将其唤醒
}
return; // 退出方法
} else { // 若尝试失败
LockSupport.park(); // 挂起线程
}
} else { // 若不是头部元素
LockSupport.park();
}
}
}
}
// 解锁共享锁
public boolean unLockShared() {
int arg = 1;
if (tryUnLockShared(arg)) { // 当read count变为0,才叫release share成功
WaitNode next = waiters.peek();
if (next != null) {
LockSupport.unpark(next.thread);
}
return true;
}
return false;
}
// 尝试获取共享锁
public int tryLockShared(int acquires) {
for (;;) {
if (writeCount.get() != 0 && owner.get() != Thread.currentThread())
return -1;
int rct = readCount.get();
if (readCount.compareAndSet(rct, rct + acquires)) {
return 1;
}
}
}
// 尝试解锁共享锁
public boolean tryUnLockShared(int releases) {
for (;;) {
int rc = readCount.get();
int nextc = rc - releases;
if (readCount.compareAndSet(rc, nextc)) {
return nextc == 0;
}
}
}
}
模板方法模式:提取 ReentrantLock 和 ReadWriteLock公共部分=>AQS
用上面手写的ReadWriteLock替换上一节手写的ReentrantLock中的相同方法后,ReentrantLock可以继续使用,
因此可将上面ReadWriteLock的代码作为一个公共类JamsAQS来使用,
为了实现公平锁(在等待队列头部才进行抢锁,而不是上面写的先抢锁->如果没抢到->放到等待队列,这段逻辑都是在try方法中写的),JamsAQS中的tryxx方法均不实现,放到锁的匿名内部类中实现:
匿名内部类重写方法:https://blog.csdn.net/shenhaiyushitiaoyu/article/details/84142618
package com.study.lock.locks5;
import java.util.concurrent.LinkedBlockingQueue;
import java.util.concurrent.atomic.AtomicInteger;
import java.util.concurrent.atomic.AtomicReference;
import java.util.concurrent.locks.LockSupport;
public class JamesAQS {
AtomicInteger readCount = new AtomicInteger(0);
AtomicInteger writeCount = new AtomicInteger(0);
// 独占锁 拥有者
AtomicReference<Thread> owner = new AtomicReference<>();
// 等待队列
public volatile LinkedBlockingQueue<WaitNode> waiters = new LinkedBlockingQueue<WaitNode>();
class WaitNode {
int type = 0; // 0 为想获取独占锁的线程, 1为想获取共享锁的线程
Thread thread = null;
int arg = 0;
public WaitNode(Thread thread, int type, int arg) {
this.thread = thread;
this.type = type;
this.arg = arg;
}
}
// 获取独占锁
public void lock() {
int arg = 1;
// 尝试获取独占锁,若成功,退出方法, 若失败...
if (!tryLock(arg)) {
// 标记为独占锁
WaitNode waitNode = new WaitNode(Thread.currentThread(), 0, arg);
waiters.offer(waitNode); // 进入等待队列
// 循环尝试拿锁
for (;;) {
// 若队列头部是当前线程
WaitNode head = waiters.peek();
if (head != null && head.thread == Thread.currentThread()) {
if (!tryLock(arg)) { // 再次尝试获取 独占锁
LockSupport.park(); // 若失败,挂起线程
} else { // 若成功获取
waiters.poll(); // 将当前线程从队列头部移除
return; // 并退出方法
}
} else { // 若不是队列头部元素
LockSupport.park(); // 将当前线程挂起
}
}
}
}
// 释放独占锁
public boolean unlock() {
int arg = 1;
// 尝试释放独占锁 若失败返回true,若失败...
if (tryUnlock(arg)) {
WaitNode next = waiters.peek(); // 取出队列头部的元素
if (next != null) {
Thread th = next.thread;
LockSupport.unpark(th); // 唤醒队列头部的线程
}
return true; // 返回true
}
return false;
}
// 获取共享锁
public void lockShared() {
int arg = 1;
if (tryLockShared(arg) < 0) { // 如果tryAcquireShare失败
// 将当前进程放入队列
WaitNode node = new WaitNode(Thread.currentThread(), 1, arg);
waiters.offer(node); // 加入队列
for (;;) {
// 若队列头部的元素是当前线程
WaitNode head = waiters.peek();
if (head != null && head.thread == Thread.currentThread()) {
if (tryLockShared(arg) >= 0) { // 尝试获取共享锁, 若成功
waiters.poll(); // 将当前线程从队列中移除
WaitNode next = waiters.peek();
if (next != null && next.type == 1) { // 如果下一个线程也是等待共享锁
LockSupport.unpark(next.thread); // 将其唤醒
}
return; // 退出方法
} else { // 若尝试失败
LockSupport.park(); // 挂起线程
}
} else { // 若不是头部元素
LockSupport.park();
}
}
}
}
// 解锁共享锁
public boolean unLockShared() {
int arg = 1;
if (tryUnLockShared(arg)) { // 当read count变为0,才叫release share成功
WaitNode next = waiters.peek();
if (next != null) {
LockSupport.unpark(next.thread);
}
return true;
}
return false;
}
// 尝试获取独占锁
public boolean tryLock(int acquires) {
throw new UnsupportedOperationException();
}
// 尝试释放独占锁
public boolean tryUnlock(int releases) {
throw new UnsupportedOperationException();
}
// 尝试获取共享锁
public int tryLockShared(int acquires) {
throw new UnsupportedOperationException();
}
// 尝试解锁共享锁
public boolean tryUnLockShared(int releases) {
throw new UnsupportedOperationException();
}
}
package com.study.lock.locks5;
import java.util.concurrent.TimeUnit;
import java.util.concurrent.locks.Condition;
import java.util.concurrent.locks.Lock;
import java.util.concurrent.locks.ReadWriteLock;
public class JamesReadWriteLock implements ReadWriteLock {
JamesAQS mask = new JamesAQS(){
//尝试获取独占锁
public boolean tryLock(int acquires) {
//如果read count !=0 返回false
if (readCount.get() !=0)
return false;
int wct = writeCount.get(); //拿到 独占锁 当前状态
if (wct==0){
if (writeCount.compareAndSet(wct, wct + acquires)){ //通过修改state来抢锁
owner.set(Thread.currentThread()); // 抢到锁后,直接修改owner为当前线程
return true;
}
}else if (owner.get() == Thread.currentThread()){
writeCount.set(wct + acquires); //修改count值
return true;
}
return false;
}
//尝试释放独占锁
public boolean tryUnlock(int releases) {
//若当前线程没有 持有独占锁
if(owner.get()!= Thread.currentThread()){
throw new IllegalMonitorStateException(); //抛IllegalMonitorStateException
}
int wc= writeCount.get();
int nextc = wc - releases; //计算 独占锁剩余占用
writeCount.set(nextc); //不管是否完全释放,都更新count值
if (nextc==0){ //是否完全释放
owner.compareAndSet(Thread.currentThread(), null);
return true;
}else{
return false;
}
}
//尝试获取共享锁
public int tryLockShared(int acquires) {
for (;;){
if (writeCount.get()!=0 &&
owner.get() != Thread.currentThread())
return -1;
int rct = readCount.get();
if (readCount.compareAndSet(rct, rct + acquires)){
return 1;
}
}
}
//尝试解锁共享锁
public boolean tryUnLockShared(int releases) {
for(;;){
int rc = readCount.get();
int nextc = rc - releases;
if (readCount.compareAndSet(rc, nextc)){
return nextc==0;
}
}
}
};
@Override
public Lock readLock() {
return new Lock() {
@Override
public void lock() {
mask.lockShared();
}
@Override
public void lockInterruptibly() throws InterruptedException {
}
@Override
public boolean tryLock() {
return mask.tryLockShared(1) == 1;
}
@Override
public void unlock() {
mask.unLockShared();
}
@Override
public boolean tryLock(long time, TimeUnit unit) throws InterruptedException {
return false;
}
@Override
public Condition newCondition() {
return null;
}
};
}
@Override
public Lock writeLock() {
return new Lock() {
@Override
public void lock() {
mask.lock();
}
@Override
public boolean tryLock() {
return mask.tryLock(1);
}
@Override
public void unlock() {
mask.unlock();
}
@Override
public void lockInterruptibly() throws InterruptedException {
}
@Override
public boolean tryLock(long time, TimeUnit unit) throws InterruptedException {
return false;
}
@Override
public Condition newCondition() {
return null;
}
};
}
}
package com.study.lock.locks5;
import java.util.concurrent.TimeUnit;
import java.util.concurrent.locks.Condition;
import java.util.concurrent.locks.Lock;
public class JamesReentrantLock implements Lock {
private boolean isFair;
public JamesReentrantLock(boolean isFair){
this.isFair = isFair;
}
JamesAQS mask = new JamesAQS(){
public boolean tryLock(int acquires){
if (isFair){
return tryFairLock(acquires);
}else{
return tryNonFairLock(acquires);
}
}
//尝试获取独占锁
public boolean tryNonFairLock(int acquires) {
//如果read count !=0 返回false
if (readCount.get() !=0)
return false;
int wct = writeCount.get(); //拿到 独占锁 当前状态
if (wct==0){
if (writeCount.compareAndSet(wct, wct + acquires)){ //通过修改state来抢锁
owner.set(Thread.currentThread()); // 抢到锁后,直接修改owner为当前线程
return true;
}
}else if (owner.get() == Thread.currentThread()){
writeCount.set(wct + acquires); //修改count值
return true;
}
return false;
}
public boolean tryFairLock(int acquires){
//如果read count !=0 返回false
if (readCount.get() !=0)
return false;
int wct = writeCount.get(); //拿到 独占锁 当前状态
if (wct==0){
JamesAQS.WaitNode head = waiters.peek();
if (head!=null && head.thread == Thread.currentThread()&&
writeCount.compareAndSet(wct, wct + acquires)){ //通过修改state来抢锁
owner.set(Thread.currentThread()); // 抢到锁后,直接修改owner为当前线程
return true;
}
}else if (owner.get() == Thread.currentThread()){
writeCount.set(wct + acquires); //修改count值
return true;
}
return false;
}
//尝试释放独占锁
public boolean tryUnlock(int releases) {
//若当前线程没有 持有独占锁
if(owner.get()!= Thread.currentThread()){
throw new IllegalMonitorStateException(); //抛IllegalMonitorStateException
}
int wc= writeCount.get();
int nextc = wc - releases; //计算 独占锁剩余占用
writeCount.set(nextc); //不管是否完全释放,都更新count值
if (nextc==0){ //是否完全释放
owner.compareAndSet(Thread.currentThread(), null);
return true;
}else{
return false;
}
}
};
public void lock(){
mask.lock();
}
@Override
public boolean tryLock(long time, TimeUnit unit) throws InterruptedException {
return false;
}
@Override
public Condition newCondition() {
return null;
}
@Override
public boolean tryLock(){
return mask.tryLock(1);
}
@Override
public void unlock(){
mask.unlock();
}
@Override
public void lockInterruptibly() throws InterruptedException {
}
}