201771010101 白玛次仁 《2018面向对象程序设计(Java)》第十七周学习总结

实验十七  线程同步控制

实验时间 2018-12-10

1. 知识总结:

多线程并发运行不确定性问题解决方案:引入线程同步机制,使得另一线程要使用该方法,就只能等待。

 Java中解决多线程同步问题的方法有两种:

- Java SE 5.0中引入ReentrantLock类。

- 在共享内存的类方法前加synchronized修饰符。

解决方案一:锁对象与条件对象:

ReentrantLock保护代码块的基本结构。

有关锁对象和条件对象的关键要点:

➢ 锁用来保护代码片段,保证任何时刻只能有一

个线程执行被保护的代码。

➢ 锁管理试图进入被保护代码段的线程。

➢ 锁可拥有一个或多个相关条件对象。

➢ 每个条件对象管理那些已经进入被保护的代码段但还不能运行的线程。

解决方案二: synchronized关键字。

synchronized关键字作用:

➢ 某个类内方法用synchronized 修饰后,该方法被称为同步方法;

➢ 只要某个线程正在访问同步方法,其他线程欲要访问同步方法就被阻塞,直至线程从同

步方法返回前唤醒被阻塞线程,其他线程方可能进入同步方法。

在同步方法中使用wait()notify notifyAll()方法。

➢ 一个线程在使用的同步方法中时,可能根据问题的需要,必须使用wait()方法使本线程等待,暂时让出CPU的使用权,并允许其它线程使用这个同步方法。

➢ 线程如果用完同步方法,应当执行notifyAll()方法通知所有由于使用这个同步方法而处于等待的线程结束等待。

 

2、实验目的与要求

(1) 掌握线程同步的概念及实现技术;

(2) 线程综合编程练习

3、实验内容和步骤

实验1:测试程序并进行代码注释。

测试程序1:

Elipse环境下调试教材651页程序14-7,结合程序运行结果理解程序;

掌握利用锁对象和条件对象实现的多线程同步技术。

 

package synch;

import java.util.*;
import java.util.concurrent.locks.*;

/**
 * A bank with a number of bank accounts that uses locks for serializing access.
 * @version 1.30 2004-08-01
 * @author Cay Horstmann
 */
public class Bank
{
   private final double[] accounts;
   private Lock bankLock;
   private Condition sufficientFunds;

   /**
    * Constructs the bank.
    * @param n the number of accounts
    * @param initialBalance the initial balance for each account
    */
   public Bank(int n, double initialBalance)
   {
      accounts = new double[n];
      Arrays.fill(accounts, initialBalance);
      bankLock = new ReentrantLock();//锁对象初始化 
      sufficientFunds = bankLock.newCondition();//newCondition方法生成了锁对象的条件对象
   }

   /**
    * Transfers money from one account to another.
    * @param from the account to transfer from
    * @param to the account to transfer to
    * @param amount the amount to transfer
    */
   public void transfer(int from, int to, double amount) throws InterruptedException
   {//加锁
      bankLock.lock();
      try
      {
         while (accounts[from] < amount)
            sufficientFunds.await();//将线程放到条件的等待集中
         System.out.print(Thread.currentThread());
         accounts[from] -= amount;
         System.out.printf(" %10.2f from %d to %d", amount, from, to);
         accounts[to] += amount;
         System.out.printf(" Total Balance: %10.2f%n", getTotalBalance());
         sufficientFunds.signalAll();//解除该条件的等待集中随机的所有线程的阻塞状态
      }
      finally
      {
         bankLock.unlock();//释放锁
      }
   }

   /**
    * Gets the sum of all account balances.
    * @return the total balance
    */
   public double getTotalBalance()
   {
      bankLock.lock();
      try
      {
         double sum = 0;

         for (double a : accounts)
            sum += a;

         return sum;
      }
      finally
      {
         bankLock.unlock();
      }
   }

   /**
    * Gets the number of accounts in the bank.
    * @return the number of accounts
    */
   public int size()
   {
      return accounts.length;
   }
}

 

package synch;

/**
 * This program shows how multiple threads can safely access a data structure.
 * @version 1.31 2015-06-21
 * @author Cay Horstmann
 */
public class SynchBankTest
{//定义四个公共属性
   public static final int NACCOUNTS = 100;
   public static final double INITIAL_BALANCE = 1000;
   public static final double MAX_AMOUNT = 1000;
   public static final int DELAY = 10;
   
   public static void main(String[] args)
   {
      Bank bank = new Bank(NACCOUNTS, INITIAL_BALANCE);
      for (int i = 0; i < NACCOUNTS; i++)
      {
         int fromAccount = i;
         Runnable r = () -> {
            try//抛出异常
            {
               while (true)
               {
                  int toAccount = (int) (bank.size() * Math.random());
                  double amount = MAX_AMOUNT * Math.random();
                  bank.transfer(fromAccount, toAccount, amount);
                  Thread.sleep((int) (DELAY * Math.random()));
               }
            }
            catch (InterruptedException e)
            {
            }            
         };
         Thread t = new Thread(r);
         t.start();
      }
   }
}

 

 测试程序2

Elipse环境下调试教材655页程序14-8,结合程序运行结果理解程序;

掌握synchronized在多线程同步中的应用。

 

package synch2;

import java.util.*;

/**
 * A bank with a number of bank accounts that uses synchronization primitives.
 * @version 1.30 2004-08-01
 * @author Cay Horstmann
 */
public class Bank
{
   private final double[] accounts;

   /**
    * Constructs the bank.
    * @param n the number of accounts
    * @param initialBalance the initial balance for each account
    */
   public Bank(int n, double initialBalance)
   {
      accounts = new double[n];
      Arrays.fill(accounts, initialBalance);
   }

   /**
    * Transfers money from one account to another.
    * @param from the account to transfer from
    * @param to the account to transfer to
    * @param amount the amount to transfer
    */
   public synchronized void transfer(int from, int to, double amount) throws InterruptedException
   {
      while (accounts[from] < amount)
         wait();
      System.out.print(Thread.currentThread());
      accounts[from] -= amount;
      System.out.printf(" %10.2f from %d to %d", amount, from, to);
      accounts[to] += amount;
      System.out.printf(" Total Balance: %10.2f%n", getTotalBalance());
      notifyAll();
   }

   /**
    * Gets the sum of all account balances.
    * @return the total balance
    */
   public synchronized double getTotalBalance()
   {//计算过程
      double sum = 0;

      for (double a : accounts)
         sum += a;

      return sum;
   }

   /**
    * Gets the number of accounts in the bank.
    * @return the number of accounts
    */
   public int size()
   {
      return accounts.length;
   }
}

 

package synch2;

/**
 * This program shows how multiple threads can safely access a data structure,
 * using synchronized methods.
 * @version 1.31 2015-06-21
 * @author Cay Horstmann
 */
public class SynchBankTest2
{
   public static final int NACCOUNTS = 100;
   public static final double INITIAL_BALANCE = 1000;
   public static final double MAX_AMOUNT = 1000;
   public static final int DELAY = 10;

   public static void main(String[] args)
   {
      Bank bank = new Bank(NACCOUNTS, INITIAL_BALANCE);
      for (int i = 0; i < NACCOUNTS; i++)
      {
         int fromAccount = i;
         Runnable r = () -> {
            try
            {
               while (true)
               {
                  int toAccount = (int) (bank.size() * Math.random());
                  double amount = MAX_AMOUNT * Math.random();
                  bank.transfer(fromAccount, toAccount, amount);
                  Thread.sleep((int) (DELAY * Math.random()));
               }
            }
            catch (InterruptedException e)
            {
            }
         };
         Thread t = new Thread(r);
         t.start();
      }
   }
}

 

测试程序3

Elipse环境下运行以下程序,结合程序运行结果分析程序存在问题;

尝试解决程序中存在问题。

class Cbank

{

     private static int s=2000;

     public   static void sub(int m)

 

     {

           int temp=s;

           temp=temp-m;

          try {

     Thread.sleep((int)(1000*Math.random()));

   }

           catch (InterruptedException e)  {              }

          s=temp;

          System.out.println("s="+s);

  }

}

 

 

class Customer extends Thread

{

  public void run()

  {

   for( int i=1; i<=4; i++)

     Cbank.sub(100);

    }

 }

public class Thread3

{

 public static void main(String args[])

  {

   Customer customer1 = new Customer();

   Customer customer2 = new Customer();

   customer1.start();

   customer2.start();

  }

}

 

class Cbank {
    private static int s = 2000;

    public synchronized static void sub(int m) {
        int temp = s;
        temp = temp - m;
        try {
            Thread.sleep((int) (1000 * Math.random()));
        } catch (InterruptedException e) {
        }
        s = temp;
        System.out.println("s=" + s);
    }
}

class Customer extends Thread {
    public void run() {
        for (int i = 1; i <= 4; i++)
            Cbank.sub(100);
    }
}

public class Thread3 {
    public static void main(String args[]) {
        Customer customer1 = new Customer();
        Customer customer2 = new Customer();
        customer1.start();
        customer2.start();
    }
}

 

实验编程练习

利用多线程及同步方法,编写一个程序模拟火车票售票系统,共3个窗口,卖10张票,程序输出结果类似(程序输出不唯一,可以是其他类似结果)。

Thread-0窗口售:第1张票

Thread-0窗口售:第2张票

Thread-1窗口售:第3张票

Thread-2窗口售:第4张票

Thread-2窗口售:第5张票

Thread-1窗口售:第6张票

Thread-0窗口售:第7张票

Thread-2窗口售:第8张票

Thread-1窗口售:第9张票

Thread-0窗口售:第10张票

 

package DFDF;

public class DFDF {
    public class Demo {
        public void main(String[] args) {
            Mythread mythread = new Mythread();
            Thread t1 = new Thread(mythread);
            Thread t2 = new Thread(mythread);
            Thread t3 = new Thread(mythread);
            t1.start();
            t2.start();
            t3.start();
        }
    }

    class Mythread implements Runnable {
        int t = 1;
        boolean flag = true;

        @Override
        public void run() {
            // TODO Auto-generated method stub
            while (flag) {
                try {
                    Thread.sleep(500);
                } catch (Exception e) {
                    // TODO: handle exception
                    e.printStackTrace();
                }

                synchronized (this) {
                    if (t <= 10) {
                        System.out.println(Thread.currentThread().getName() + "窗口售:第" + t + "张票");
                        t++;
                    }
                    if (t > 10) {
                        flag = false;
                    }
                }

            }

        }
    }
}

    

 

4、实验总结:这次实验中学会了在Java中解决多线程同步问题。

掌握利用锁对象和条件对象实现的多线程同步技术。

掌握synchronized在多线程同步中的应用。

posted @ 2018-12-23 12:40  白玛次仁  阅读(132)  评论(0编辑  收藏  举报