长文慎入-探索Java并发编程与高并发解决方案

所有示例代码,请见/下载于
https://github.com/Wasabi1234/concurrency

#1 基本概念
##1.1 并发
同时拥有两个或者多个线程，如果程序在单核处理器上运行多个线程将交替地换入或者换出内存,这些线程是同时“存在"的，每个线程都处于执行过程中的某个状态，如果运行在多核处理器上,此时，程序中的每个线程都将分配到一个处理器核上，因此可以同时运行.
##1.2 高并发( High Concurrency)
互联网分布式系统架构设计中必须考虑的因素之一，通常是指，通过设计保证系统能够同时并行处理很多请求.
##1.3 区别与联系

• 并发: 多个线程操作相同的资源，保证线程安全，合理使用资源
• 高并发:服务能同时处理很多请求，提高程序性能
  #2 CPU
  ##2.1 CPU 多级缓存
  
• 为什么需要CPU cache
  CPU的频率太快了，快到主存跟不上
  如此,在处理器时钟周期内，CPU常常需要等待主存，浪费资源。所以cache的出现，是为了缓解CPU和内存之间速度的不匹配问题(结构:cpu-> cache-> memory ).
• CPU cache的意义
  1) 时间局部性
  如果某个数据被访问，那么在不久的将来它很可能被再次访问
  2) 空间局部性
  如果某个数据被访问，那么与它相邻的数据很快也可能被访问
  ##2.2 缓存一致性(MESI)
  用于保证多个 CPU cache 之间缓存共享数据的一致
• M-modified被修改
  该缓存行只被缓存在该 CPU 的缓存中,并且是被修改过的,与主存中数据是不一致的,需在未来某个时间点写回主存,该时间是允许在其他CPU 读取主存中相应的内存之前,当这里的值被写入主存之后,该缓存行状态变为 E
• E-exclusive独享
  缓存行只被缓存在该 CPU 的缓存中,未被修改过,与主存中数据一致
  可在任何时刻当被其他 CPU读取该内存时变成 S 态,被修改时变为 M态
• S-shared共享
  该缓存行可被多个 CPU 缓存,与主存中数据一致
• I-invalid无效
  
• 乱序执行优化
  处理器为提高运算速度而做出违背代码原有顺序的优化
  ##并发的优势与风险
  
  #3 项目准备
  ##3.1 项目初始化
  
  
  
  ##3.2 并发模拟-Jmeter压测
  
  
  
  
  
  ##3.3 并发模拟-代码
  ###CountDownLatch
  
  ###Semaphore(信号量)
  
  以上二者通常和线程池搭配

下面开始做并发模拟

package com.mmall.concurrency;

import com.mmall.concurrency.annoations.NotThreadSafe;
import lombok.extern.slf4j.Slf4j;

import java.util.concurrent.CountDownLatch;
import java.util.concurrent.ExecutorService;
import java.util.concurrent.Executors;
import java.util.concurrent.Semaphore;

/**
 * @author shishusheng
 * @date 18/4/1
 */
@Slf4j
@NotThreadSafe
public class ConcurrencyTest {

    /**
     * 请求总数
     */
    public static int clientTotal = 5000;

    /**
     * 同时并发执行的线程数
     */
    public static int threadTotal = 200;

    public static int count = 0;

    public static void main(String[] args) throws Exception {
        //定义线程池
        ExecutorService executorService = Executors.newCachedThreadPool();
        //定义信号量,给出允许并发的线程数目
        final Semaphore semaphore = new Semaphore(threadTotal);
        //统计计数结果
        final CountDownLatch countDownLatch = new CountDownLatch(clientTotal);
        //将请求放入线程池
        for (int i = 0; i < clientTotal ; i++) {
            executorService.execute(() -> {
                try {
                    //信号量的获取
                    semaphore.acquire();
                    add();
                    //释放
                    semaphore.release();
                } catch (Exception e) {
                    log.error("exception", e);
                }
                countDownLatch.countDown();
            });
        }
        countDownLatch.await();
        //关闭线程池
        executorService.shutdown();
        log.info("count:{}", count);
    }

    /**
     * 统计方法
     */
    private static void add() {
        count++;
    }
}

运行发现结果随机,所以非线程安全
#4线程安全性
##4.1 线程安全性
当多个线程访问某个类时，不管运行时环境采用何种调度方式或者这些进程将如何交替执行，并且在主调代码中不需要任何额外的同步或协同，这个类都能表现出正确的行为，那么就称这个类是线程安全的
##4.2 原子性
###4.2.1 Atomic 包

• AtomicXXX:CAS,Unsafe.compareAndSwapInt
  提供了互斥访问，同一时刻只能有一个线程来对它进行操作

  
  package com.mmall.concurrency.example.atomic;

import com.mmall.concurrency.annoations.ThreadSafe;
import lombok.extern.slf4j.Slf4j;

import java.util.concurrent.CountDownLatch;
import java.util.concurrent.ExecutorService;
import java.util.concurrent.Executors;
import java.util.concurrent.Semaphore;
import java.util.concurrent.atomic.AtomicLong;

/**

• @author shishushengbr/>*/
  @Slf4j
  @ThreadSafe
  public class AtomicExample2 {

  /**

  • 请求总数
    */
    public static int clientTotal = 5000;

  /**

  • 同时并发执行的线程数
    */
    public static int threadTotal = 200;

  /**

  • 工作内存
    */
    public static AtomicLong count = new AtomicLong(0);

  public static void main(String[] args) throws Exception {
  ExecutorService executorService = Executors.newCachedThreadPool();
  final Semaphore semaphore = new Semaphore(threadTotal);
  final CountDownLatch countDownLatch = new CountDownLatch(clientTotal);
  for (int i = 0; i < clientTotal ; i++) {
  executorService.execute(() -> {
  try {
  System.out.println();
  semaphore.acquire();
  add();
  semaphore.release();
  } catch (Exception e) {
  log.error("exception", e);
  }
  countDownLatch.countDown();
  });
  }
  countDownLatch.await();
  executorService.shutdown();
  //主内存
  log.info("count:{}", count.get());
  }

  private static void add() {
  count.incrementAndGet();
  // count.getAndIncrement();
  }
  }

package com.mmall.concurrency.example.atomic;

import com.mmall.concurrency.annoations.ThreadSafe;
import lombok.extern.slf4j.Slf4j;
import java.util.concurrent.atomic.AtomicReference;

/**
 * @author shishusheng
 * @date 18/4/3
 */
@Slf4j
@ThreadSafe
public class AtomicExample4 {

    private static AtomicReference<Integer> count = new AtomicReference<>(0);

    public static void main(String[] args) {
        // 2
        count.compareAndSet(0, 2);
        // no
        count.compareAndSet(0, 1);
        // no
        count.compareAndSet(1, 3);
        // 4
        count.compareAndSet(2, 4);
        // no
        count.compareAndSet(3, 5); 
        log.info("count:{}", count.get());
    }
}

• AtomicReference,AtomicReferenceFieldUpdater
  

• AtomicBoolean
  

• AtomicStampReference : CAS的 ABA 问题
  ###4.2.2 锁
  synchronized:依赖 JVM
• 修饰代码块:大括号括起来的代码，作用于调用的对象
• 修饰方法: 整个方法，作用于调用的对象
  
• 修饰静态方法:整个静态方法，作用于所有对象
  

  
  package com.mmall.concurrency.example.count;

import com.mmall.concurrency.annoations.ThreadSafe;
import lombok.extern.slf4j.Slf4j;

import java.util.concurrent.CountDownLatch;
import java.util.concurrent.ExecutorService;
import java.util.concurrent.Executors;
import java.util.concurrent.Semaphore;

/**

• @author shishushengbr/>*/
  @Slf4j
  @ThreadSafe
  public class CountExample3 {

  /**

  • 请求总数
    */
    public static int clientTotal = 5000;

  /**

  • 同时并发执行的线程数
    */
    public static int threadTotal = 200;

  public static int count = 0;

  public static void main(String[] args) throws Exception {
  ExecutorService executorService = Executors.newCachedThreadPool();
  final Semaphore semaphore = new Semaphore(threadTotal);
  final CountDownLatch countDownLatch = new CountDownLatch(clientTotal);
  for (int i = 0; i < clientTotal ; i++) {
  executorService.execute(() -> {
  try {
  semaphore.acquire();
  add();
  semaphore.release();
  } catch (Exception e) {
  log.error("exception", e);
  }
  countDownLatch.countDown();
  });
  }
  countDownLatch.await();
  executorService.shutdown();
  log.info("count:{}", count);
  }

  private synchronized static void add() {
  count++;
  }
  }

  
  synchronized 修正计数类方法
  - 修饰类:括号括起来的部分，作用于所有对象
  子类继承父类的被 synchronized 修饰方法时,是没有 synchronized 修饰的!!!

Lock: 依赖特殊的 CPU 指令,代码实现
###4.2.3 对比

• synchronized: 不可中断锁，适合竞争不激烈，可读性好
• Lock: 可中断锁，多样化同步，竞争激烈时能维持常态
• Atomic: 竞争激烈时能维持常态，比Lock性能好; 只能同步一
  个值
  ##4.3 可见性
  一个线程对主内存的修改可以及时的被其他线程观察到
  ###4.3.1 导致共享变量在线程间不可见的原因
• 线程交叉执行
• 重排序结合线程交叉执行
• 共享变量更新后的值没有在工作内存与主存间及时更新
  ###4.3.2 可见性之synchronized
  JMM关于synchronized的规定
• 线程解锁前，必须把共享变量的最新值刷新到主内存
• 线程加锁时，将清空工作内存中共享变量的值，从而使
  用共享变量时需要从主内存中重新读取最新的值(加锁与解锁是同一把锁)
  ###4.3.3 可见性之volatile
  通过加入内存屏障和禁止重排序优化来实现
• 对volatile变量写操作时，会在写操作后加入一条store
  屏障指令，将本地内存中的共享变量值刷新到主内存
• 对volatile变量读操作时，会在读操作前加入一条load
  屏障指令，从主内存中读取共享变量
  
  
  
• volatile使用

  
  volatile boolean inited = false;

//线程1:
context = loadContext();
inited= true;

// 线程2:
while( !inited ){
sleep();
}
doSomethingWithConfig(context)

##4.4 有序性
一个线程观察其他线程中的指令执行顺序，由于指令重排序的存在，该观察结果一般杂乱无序

JMM允许编译器和处理器对指令进行重排序，但是重排序过程不会影响到单线程程序的执行，却会影响到多线程并发执行的正确性
###4.4.1 happens-before 规则
#5发布对象
![](https://upload-images.jianshu.io/upload_images/4685968-ed313a1caed24223.png?imageMogr2/auto-orient/strip%7CimageView2/2/w/1240)
![发布对象](https://upload-images.jianshu.io/upload_images/4685968-b368f6fe5b350cbe.png?imageMogr2/auto-orient/strip%7CimageView2/2/w/1240)
![对象逸出](https://upload-images.jianshu.io/upload_images/4685968-88d207fcc6bf1866.png?imageMogr2/auto-orient/strip%7CimageView2/2/w/1240)
##5.1 安全发布对象
![](https://upload-images.jianshu.io/upload_images/4685968-7400ab2abe1dbbfb.png?imageMogr2/auto-orient/strip%7CimageView2/2/w/1240)
![非线程安全的懒汉模式](https://upload-images.jianshu.io/upload_images/4685968-ba18bdbe3a3c4ed1.png?imageMogr2/auto-orient/strip%7CimageView2/2/w/1240)
![饿汉模式](https://upload-images.jianshu.io/upload_images/4685968-be2854c290143094.png?imageMogr2/auto-orient/strip%7CimageView2/2/w/1240)
![线程安全的懒汉模式](https://upload-images.jianshu.io/upload_images/4685968-e632243a5a97281a.png?imageMogr2/auto-orient/strip%7CimageView2/2/w/1240)

package com.mmall.concurrency.example.singleton;

import com.mmall.concurrency.annoations.NotThreadSafe;

/**

• 懒汉模式 -》 双重同步锁单例模式
• 单例实例在第一次使用时进行创建

• @author shishushengbr/>*/
  @NotThreadSafe
  public class SingletonExample4 {

  /**

  • 私有构造函数
    */
    private SingletonExample4() {

  }

  // 1、memory = allocate() 分配对象的内存空间
  // 2、ctorInstance() 初始化对象
  // 3、instance = memory 设置instance指向刚分配的内存

  // JVM和cpu优化，发生了指令重排

  // 1、memory = allocate() 分配对象的内存空间
  // 3、instance = memory 设置instance指向刚分配的内存
  // 2、ctorInstance() 初始化对象

  /**

  • 单例对象
    */
    private static SingletonExample4 instance = null;

  /**

  • 静态的工厂方法
  • @return
    */
    public static SingletonExample4 getInstance() {
    // 双重检测机制 // B
    if (instance == null) {
    // 同步锁
    synchronized (SingletonExample4.class) {
    if (instance == null) {
    // A - 3
    instance = new SingletonExample4();
    }
    }
    }
    return instance;
    }
    }

    ![](https://upload-images.jianshu.io/upload_images/4685968-823166cdf7936293.png?imageMogr2/auto-orient/strip%7CimageView2/2/w/1240)
    ![](https://upload-images.jianshu.io/upload_images/4685968-9002671b71096f6c.png?imageMogr2/auto-orient/strip%7CimageView2/2/w/1240)
    #7 AQS
    ##7.1 介绍
    ![数据结构](https://upload-images.jianshu.io/upload_images/4685968-918dcaea77d556e9.png?imageMogr2/auto-orient/strip%7CimageView2/2/w/1240)
    - 使用Node实现FIFO队列，可以用于构建锁或者其他同步装置的基础框架
    - 利用了一个int类型表示状态
    - 使用方法是继承
    - 子类通过继承并通过实现它的方法管理其状态{acquire 和release} 的方法操纵状态
    - 可以同时实现排它锁和共享锁模式(独占、共享)
    同步组件
    ###CountDownLatch

    package com.mmall.concurrency.example.aqs;

import lombok.extern.slf4j.Slf4j;

import java.util.concurrent.CountDownLatch;
import java.util.concurrent.ExecutorService;
import java.util.concurrent.Executors;

/**

• @author shishushengbr/>*/
  @Slf4j
  public class CountDownLatchExample1 {

  private final static int threadCount = 200;

  public static void main(String[] args) throws Exception {

  ExecutorService exec = Executors.newCachedThreadPool();
  
  final CountDownLatch countDownLatch = new CountDownLatch(threadCount);
  
  for (int i = 0; i < threadCount; i++) {
      final int threadNum = i;
      exec.execute(() -> {
          try {
              test(threadNum);
          } catch (Exception e) {
              log.error("exception", e);
          } finally {
              countDownLatch.countDown();
          }
      });
  }
  countDownLatch.await();
  log.info("finish");
  exec.shutdown();

  }

  private static void test(int threadNum) throws Exception {
  Thread.sleep(100);
  log.info("{}", threadNum);
  Thread.sleep(100);
  }
  }

  package com.mmall.concurrency.example.aqs;

import lombok.extern.slf4j.Slf4j;

import java.util.concurrent.CountDownLatch;
import java.util.concurrent.ExecutorService;
import java.util.concurrent.Executors;
import java.util.concurrent.TimeUnit;

/**

• 指定时间内处理任务
• @author shishusheng

• */br/>@Slf4j
  public class CountDownLatchExample2 {

  private final static int threadCount = 200;

  public static void main(String[] args) throws Exception {

  ExecutorService exec = Executors.newCachedThreadPool();
  
  final CountDownLatch countDownLatch = new CountDownLatch(threadCount);
  
  for (int i = 0; i < threadCount; i++) {
      final int threadNum = i;
      exec.execute(() -> {
          try {
              test(threadNum);
          } catch (Exception e) {
              log.error("exception", e);
          } finally {
              countDownLatch.countDown();
          }
      });
  }
  countDownLatch.await(10, TimeUnit.MILLISECONDS);
  log.info("finish");
  exec.shutdown();

  }

  private static void test(int threadNum) throws Exception {
  Thread.sleep(100);
  log.info("{}", threadNum);
  }
  }

  ##Semaphore用法
  ![](https://upload-images.jianshu.io/upload_images/4685968-e6cbcd4254c642c5.png?imageMogr2/auto-orient/strip%7CimageView2/2/w/1240)
  ![](https://upload-images.jianshu.io/upload_images/4685968-dbefbf2c76ad5a2a.png?imageMogr2/auto-orient/strip%7CimageView2/2/w/1240)
  ![](https://upload-images.jianshu.io/upload_images/4685968-41f5f5a5fd135804.png?imageMogr2/auto-orient/strip%7CimageView2/2/w/1240)
  ##CycliBarrier

  package com.mmall.concurrency.example.aqs;

import lombok.extern.slf4j.Slf4j;

import java.util.concurrent.CyclicBarrier;
import java.util.concurrent.ExecutorService;
import java.util.concurrent.Executors;

/**

• @author shishushengbr/>*/
  @Slf4j
  public class CyclicBarrierExample1 {

  private static CyclicBarrier barrier = new CyclicBarrier(5);

  public static void main(String[] args) throws Exception {

  ExecutorService executor = Executors.newCachedThreadPool();
  
  for (int i = 0; i < 10; i++) {
      final int threadNum = i;
      Thread.sleep(1000);
      executor.execute(() -> {
          try {
              race(threadNum);
          } catch (Exception e) {
              log.error("exception", e);
          }
      });
  }
  executor.shutdown();

  }

  private static void race(int threadNum) throws Exception {
  Thread.sleep(1000);
  log.info("{} is ready", threadNum);
  barrier.await();
  log.info("{} continue", threadNum);
  }
  }

  ![](https://upload-images.jianshu.io/upload_images/4685968-4fb51fa4926fd70e.png?imageMogr2/auto-orient/strip%7CimageView2/2/w/1240)

  package com.mmall.concurrency.example.aqs;

import lombok.extern.slf4j.Slf4j;

import java.util.concurrent.CyclicBarrier;
import java.util.concurrent.ExecutorService;
import java.util.concurrent.Executors;
import java.util.concurrent.TimeUnit;

/**

• @author shishushengbr/>*/
  @Slf4j
  public class CyclicBarrierExample2 {

  private static CyclicBarrier barrier = new CyclicBarrier(5);

  public static void main(String[] args) throws Exception {

  ExecutorService executor = Executors.newCachedThreadPool();
  
  for (int i = 0; i < 10; i++) {
      final int threadNum = i;
      Thread.sleep(1000);
      executor.execute(() -> {
          try {
              race(threadNum);
          } catch (Exception e) {
              log.error("exception", e);
          }
      });
  }
  executor.shutdown();

  }

  private static void race(int threadNum) throws Exception {
  Thread.sleep(1000);
  log.info("{} is ready", threadNum);
  try {
  barrier.await(2000, TimeUnit.MILLISECONDS);
  } catch (Exception e) {
  log.warn("BarrierException", e);
  }
  log.info("{} continue", threadNum);
  }
  }

  ![await 超时导致程序抛异常](https://upload-images.jianshu.io/upload_images/4685968-0f899c23531f8ee8.png?imageMogr2/auto-orient/strip%7CimageView2/2/w/1240)

  package com.mmall.concurrency.example.aqs;

import lombok.extern.slf4j.Slf4j;

import java.util.concurrent.ExecutorService;
import java.util.concurrent.Executors;
import java.util.concurrent.Semaphore;
/**

• @author shishushengbr/>*/
  @Slf4j
  public class SemaphoreExample3 {

  private final static int threadCount = 20;

  public static void main(String[] args) throws Exception {

  ExecutorService exec = Executors.newCachedThreadPool();
  
  final Semaphore semaphore = new Semaphore(3);
  
  for (int i = 0; i < threadCount; i++) {
      final int threadNum = i;
      exec.execute(() -> {
          try {
              // 尝试获取一个许可
              if (semaphore.tryAcquire()) {
                  test(threadNum);
                  // 释放一个许可
                  semaphore.release();
              }
          } catch (Exception e) {
              log.error("exception", e);
          }
      });
  }
  exec.shutdown();

  }

  private static void test(int threadNum) throws Exception {
  log.info("{}", threadNum);
  Thread.sleep(1000);
  }

}

#9 线程池
##9.1 newCachedThreadPool
![](https://upload-images.jianshu.io/upload_images/4685968-1122da7a48223ba1.png?imageMogr2/auto-orient/strip%7CimageView2/2/w/1240)
##9.2 newFixedThreadPool
![](https://upload-images.jianshu.io/upload_images/4685968-0ea942bf12e5210f.png?imageMogr2/auto-orient/strip%7CimageView2/2/w/1240)
##9.3 newSingleThreadExecutor
看出是顺序执行的
![](https://upload-images.jianshu.io/upload_images/4685968-989d59429f589403.png?imageMogr2/auto-orient/strip%7CimageView2/2/w/1240)
##9.4 newScheduledThreadPool
![](https://upload-images.jianshu.io/upload_images/4685968-f7536ec7a1cf6ecc.png?imageMogr2/auto-orient/strip%7CimageView2/2/w/1240)
![](https://upload-images.jianshu.io/upload_images/4685968-c90e09d5bfe707e6.png?imageMogr2/auto-orient/strip%7CimageView2/2/w/1240)
#10 死锁
![](https://upload-images.jianshu.io/upload_images/4685968-461f6a4251ae8ca4.png?imageMogr2/auto-orient/strip%7CimageView2/2/w/1240)
![](https://upload-images.jianshu.io/upload_images/4685968-46d58773e597195f.png?imageMogr2/auto-orient/strip%7CimageView2/2/w/1240)