在 Java 的并发编程中，有一个问题需要特别注意，那就是死锁，如果发生了死锁，基本就是重启，而重启将会丢失运行中的数据。所以，了解死锁的形成并排查死锁到预防死锁成了一个重要的问题。
1.什么是死锁

[Java] 纯文本查看 复制代码

public class DeadLock {

  public static void main(String[] args) {

    new Thread(() -> {
      try {
         new DeadLock().resource1();
      } catch (InterruptedException e) {
      }
    }
    ).start();

    new Thread(() -> {
      try {
         new DeadLock().resource2();
      } catch (InterruptedException e) {
      }
    }
    ).start();
  }

  void resource1() throws InterruptedException {

    synchronized ("resource1") {
      System.out.println("获取资源1");
       // 等待 1 秒让另一个线程拿到锁
      Thread.sleep(1000);
      resource2();
    }


  }

  void resource2() throws InterruptedException {
    synchronized ("resource2") {
      System.out.println("获取资源2");
      // 等待 1 秒让另一个线程拿到锁
      Thread.sleep(1000);
      resource1();
    }
  }
}

  上面的代码中，我们启用了两个线程，分别抢占2个资源，但这两个资源又分别被不同的对象（字符串）锁住了。当第一个线程调用 resource1 方法，进入同步块，拿到锁，并等待 1 秒钟让另一个线程进入 resource2 同步块，当第二个线程进入同步块后，注意：此时， 拿着 resourec1 锁的线程企图拿到 resource2 的锁，但这个时候，拿着 resource2 的线程也想去拿 resource1 的锁。于是就出现了互相僵持的情况，谁也无法拿到对方的锁，整个系统就卡死了。
2.如何检测死锁

[Java] 纯文本查看 复制代码

Full thread dump Java HotSpot(TM) Client VM (25.131-b11 mixed mode):

"DestroyJavaVM" #11 prio=5 os_prio=0 tid=0x051fe800 nid=0x1e0c waiting on condition [0x00000000]
   java.lang.Thread.State: RUNNABLE

"Thread-1" #10 prio=5 os_prio=0 tid=0x18777800 nid=0x5664 waiting for monitor entry [0x18e0f000]
   java.lang.Thread.State: BLOCKED (on object monitor)
        at hello.DeadLock.resource1(DeadLock.java:31)
        - waiting to lock <0x07415a50> (a java.lang.String)
        at hello.DeadLock.resource2(DeadLock.java:43)
        - locked <0x0742bd18> (a java.lang.String)
        at hello.DeadLock.lambda$main$1(DeadLock.java:20)
        at hello.DeadLock$$Lambda$2/4983748.run(Unknown Source)
        at java.lang.Thread.run(Thread.java:748)

"Thread-0" #9 prio=5 os_prio=0 tid=0x18776c00 nid=0x4dc4 waiting for monitor entry [0x18d7f000]
   java.lang.Thread.State: BLOCKED (on object monitor)
        at hello.DeadLock.resource2(DeadLock.java:41)
        - waiting to lock <0x0742bd18> (a java.lang.String)
        at hello.DeadLock.resource1(DeadLock.java:33)
        - locked <0x07415a50> (a java.lang.String)
        at hello.DeadLock.lambda$main$0(DeadLock.java:11)
        at hello.DeadLock$$Lambda$1/5592464.run(Unknown Source)
        at java.lang.Thread.run(Thread.java:748)

"Service Thread" #8 daemon prio=9 os_prio=0 tid=0x186e4c00 nid=0x172c runnable [0x00000000]
   java.lang.Thread.State: RUNNABLE

"C1 CompilerThread0" #7 daemon prio=9 os_prio=2 tid=0x186af000 nid=0x53f8 waiting on condition [0x00000000]
   java.lang.Thread.State: RUNNABLE

"Monitor Ctrl-Break" #6 daemon prio=5 os_prio=0 tid=0x1861e800 nid=0x3928 runnable [0x18b3f000]
   java.lang.Thread.State: RUNNABLE
        at java.net.SocketInputStream.socketRead0(Native Method)
        at java.net.SocketInputStream.socketRead(SocketInputStream.java:116)
        at java.net.SocketInputStream.read(SocketInputStream.java:171)
        at java.net.SocketInputStream.read(SocketInputStream.java:141)
        at sun.nio.cs.StreamDecoder.readBytes(StreamDecoder.java:284)
        at sun.nio.cs.StreamDecoder.implRead(StreamDecoder.java:326)
        at sun.nio.cs.StreamDecoder.read(StreamDecoder.java:178)
        - locked <0x07861da0> (a java.io.InputStreamReader)
        at java.io.InputStreamReader.read(InputStreamReader.java:184)
        at java.io.BufferedReader.fill(BufferedReader.java:161)
        at java.io.BufferedReader.readLine(BufferedReader.java:324)
        - locked <0x07861da0> (a java.io.InputStreamReader)
        at java.io.BufferedReader.readLine(BufferedReader.java:389)
        at com.intellij.rt.execution.application.AppMainV2$1.run(AppMainV2.java:64)

"Attach Listener" #5 daemon prio=5 os_prio=2 tid=0x179c0800 nid=0x40a0 waiting on condition [0x00000000]
   java.lang.Thread.State: RUNNABLE

"Signal Dispatcher" #4 daemon prio=9 os_prio=2 tid=0x17985c00 nid=0x5004 runnable [0x00000000]
   java.lang.Thread.State: RUNNABLE

"Finalizer" #3 daemon prio=8 os_prio=1 tid=0x17972400 nid=0x41a8 in Object.wait() [0x17cff000]
   java.lang.Thread.State: WAITING (on object monitor)
        at java.lang.Object.wait(Native Method)
        - waiting on <0x0ca1b830> (a java.lang.ref.ReferenceQueue$Lock)
        at java.lang.ref.ReferenceQueue.remove(ReferenceQueue.java:143)
        - locked <0x0ca1b830> (a java.lang.ref.ReferenceQueue$Lock)
        at java.lang.ref.ReferenceQueue.remove(ReferenceQueue.java:164)
        at java.lang.ref.Finalizer$FinalizerThread.run(Finalizer.java:209)

"Reference Handler" #2 daemon prio=10 os_prio=2 tid=0x17960000 nid=0x4ef0 in Object.wait() [0x17c6f000]
   java.lang.Thread.State: WAITING (on object monitor)
        at java.lang.Object.wait(Native Method)
        - waiting on <0x0ca1b9d0> (a java.lang.ref.Reference$Lock)
        at java.lang.Object.wait(Object.java:502)
        at java.lang.ref.Reference.tryHandlePending(Reference.java:191)
        - locked <0x0ca1b9d0> (a java.lang.ref.Reference$Lock)
        at java.lang.ref.Reference$ReferenceHandler.run(Reference.java:153)

"VM Thread" os_prio=2 tid=0x1795a800 nid=0x3f54 runnable

"VM Periodic Task Thread" os_prio=2 tid=0x18739400 nid=0x4a14 waiting on condition

JNI global references: 229

// 找到一个死锁
Found one Java-level deadlock:
=============================
"Thread-1":
  waiting to lock monitor 0x17978de4 (object 0x07415a50, a java.lang.String),
  which is held by "Thread-0"
"Thread-0":
  waiting to lock monitor 0x1797a974 (object 0x0742bd18, a java.lang.String),
  which is held by "Thread-1"

Java stack information for the threads listed above:
===================================================
"Thread-1":
        at hello.DeadLock.resource1(DeadLock.java:31)
         // 等待 0x07415a50 锁
        - waiting to lock <0x07415a50> (a java.lang.String)
        at hello.DeadLock.resource2(DeadLock.java:43)
        // 持有 0x0742bd18
        - locked <0x0742bd18> (a java.lang.String)
        at hello.DeadLock.lambda$main$1(DeadLock.java:20)
        at hello.DeadLock$$Lambda$2/4983748.run(Unknown Source)
        at java.lang.Thread.run(Thread.java:748)
"Thread-0":
        at hello.DeadLock.resource2(DeadLock.java:41)
        // 等待 0x0742bd18 锁
        - waiting to lock <0x0742bd18> (a java.lang.String)
        at hello.DeadLock.resource1(DeadLock.java:33)
        // 持有 0x07415a50
        - locked <0x07415a50> (a java.lang.String)
        at hello.DeadLock.lambda$main$0(DeadLock.java:11)
        at hello.DeadLock$$Lambda$1/5592464.run(Unknown Source)
        at java.lang.Thread.run(Thread.java:748)

// 发现了一个死锁
Found 1 deadlock.

3.死锁形成的原因

• 互斥条件：一个资源每次只能被一个线程使用。
• 请求与保持条件：一个进程因请求资源而阻塞时，对已获得的资源保持不放。
• 不剥夺条件：进程已获得的资源，在未使用完之前，不能强行剥夺。
• 循环等待条件：若干进程之间形成一种头尾相接的循环等待资源关系。
  
  

  死锁是由四个必要条件导致的，所以一般来说，只要破坏这四个必要条件中的一个条件，死锁情况就应该不会发生。如果想要打破互斥条件，我们需要允许进程同时访问某些资源，这种方法受制于实际场景，不太容易实现条件；打破不可抢占条件，这样需要允许进程强行从占有者那里夺取某些资源，或者简单一点理解，占有资源的进程不能再申请占有其他资源，必须释放手上的资源之后才能发起申请，这个其实也很难找到适用场景；进程在运行前申请得到所有的资源，否则该进程不能进入准备执行状态。这个方法看似有点用处，但是它的缺点是可能导致资源利用率和进程并发性降低；避免出现资源申请环路，即对资源事先分类编号，按号分配。这种方式可以有效提高资源的利用率和系统吞吐量，但是增加了系统开销，增大了进程对资源的占用时间。

在 Java 的并发编程中，有一个问题需要特别注意，那就是死锁，如果发生了死锁，基本就是重启，而重启将会丢失运行中的数据。所以，了解死锁的形成并排查死锁到预防死锁成了一个重要的问题。
1.什么是死锁

[Java] 纯文本查看 复制代码

public class DeadLock {

  public static void main(String[] args) {

    new Thread(() -> {
      try {
         new DeadLock().resource1();
      } catch (InterruptedException e) {
      }
    }
    ).start();

    new Thread(() -> {
      try {
         new DeadLock().resource2();
      } catch (InterruptedException e) {
      }
    }
    ).start();
  }

  void resource1() throws InterruptedException {

    synchronized ("resource1") {
      System.out.println("获取资源1");
       // 等待 1 秒让另一个线程拿到锁
      Thread.sleep(1000);
      resource2();
    }


  }

  void resource2() throws InterruptedException {
    synchronized ("resource2") {
      System.out.println("获取资源2");
      // 等待 1 秒让另一个线程拿到锁
      Thread.sleep(1000);
      resource1();
    }
  }
}

  上面的代码中，我们启用了两个线程，分别抢占2个资源，但这两个资源又分别被不同的对象（字符串）锁住了。当第一个线程调用 resource1 方法，进入同步块，拿到锁，并等待 1 秒钟让另一个线程进入 resource2 同步块，当第二个线程进入同步块后，注意：此时， 拿着 resourec1 锁的线程企图拿到 resource2 的锁，但这个时候，拿着 resource2 的线程也想去拿 resource1 的锁。于是就出现了互相僵持的情况，谁也无法拿到对方的锁，整个系统就卡死了。
2.如何检测死锁

[Java] 纯文本查看 复制代码

Full thread dump Java HotSpot(TM) Client VM (25.131-b11 mixed mode):

"DestroyJavaVM" #11 prio=5 os_prio=0 tid=0x051fe800 nid=0x1e0c waiting on condition [0x00000000]
   java.lang.Thread.State: RUNNABLE

"Thread-1" #10 prio=5 os_prio=0 tid=0x18777800 nid=0x5664 waiting for monitor entry [0x18e0f000]
   java.lang.Thread.State: BLOCKED (on object monitor)
        at hello.DeadLock.resource1(DeadLock.java:31)
        - waiting to lock <0x07415a50> (a java.lang.String)
        at hello.DeadLock.resource2(DeadLock.java:43)
        - locked <0x0742bd18> (a java.lang.String)
        at hello.DeadLock.lambda$main$1(DeadLock.java:20)
        at hello.DeadLock$$Lambda$2/4983748.run(Unknown Source)
        at java.lang.Thread.run(Thread.java:748)

"Thread-0" #9 prio=5 os_prio=0 tid=0x18776c00 nid=0x4dc4 waiting for monitor entry [0x18d7f000]
   java.lang.Thread.State: BLOCKED (on object monitor)
        at hello.DeadLock.resource2(DeadLock.java:41)
        - waiting to lock <0x0742bd18> (a java.lang.String)
        at hello.DeadLock.resource1(DeadLock.java:33)
        - locked <0x07415a50> (a java.lang.String)
        at hello.DeadLock.lambda$main$0(DeadLock.java:11)
        at hello.DeadLock$$Lambda$1/5592464.run(Unknown Source)
        at java.lang.Thread.run(Thread.java:748)

"Service Thread" #8 daemon prio=9 os_prio=0 tid=0x186e4c00 nid=0x172c runnable [0x00000000]
   java.lang.Thread.State: RUNNABLE

"C1 CompilerThread0" #7 daemon prio=9 os_prio=2 tid=0x186af000 nid=0x53f8 waiting on condition [0x00000000]
   java.lang.Thread.State: RUNNABLE

"Monitor Ctrl-Break" #6 daemon prio=5 os_prio=0 tid=0x1861e800 nid=0x3928 runnable [0x18b3f000]
   java.lang.Thread.State: RUNNABLE
        at java.net.SocketInputStream.socketRead0(Native Method)
        at java.net.SocketInputStream.socketRead(SocketInputStream.java:116)
        at java.net.SocketInputStream.read(SocketInputStream.java:171)
        at java.net.SocketInputStream.read(SocketInputStream.java:141)
        at sun.nio.cs.StreamDecoder.readBytes(StreamDecoder.java:284)
        at sun.nio.cs.StreamDecoder.implRead(StreamDecoder.java:326)
        at sun.nio.cs.StreamDecoder.read(StreamDecoder.java:178)
        - locked <0x07861da0> (a java.io.InputStreamReader)
        at java.io.InputStreamReader.read(InputStreamReader.java:184)
        at java.io.BufferedReader.fill(BufferedReader.java:161)
        at java.io.BufferedReader.readLine(BufferedReader.java:324)
        - locked <0x07861da0> (a java.io.InputStreamReader)
        at java.io.BufferedReader.readLine(BufferedReader.java:389)
        at com.intellij.rt.execution.application.AppMainV2$1.run(AppMainV2.java:64)

"Attach Listener" #5 daemon prio=5 os_prio=2 tid=0x179c0800 nid=0x40a0 waiting on condition [0x00000000]
   java.lang.Thread.State: RUNNABLE

"Signal Dispatcher" #4 daemon prio=9 os_prio=2 tid=0x17985c00 nid=0x5004 runnable [0x00000000]
   java.lang.Thread.State: RUNNABLE

"Finalizer" #3 daemon prio=8 os_prio=1 tid=0x17972400 nid=0x41a8 in Object.wait() [0x17cff000]
   java.lang.Thread.State: WAITING (on object monitor)
        at java.lang.Object.wait(Native Method)
        - waiting on <0x0ca1b830> (a java.lang.ref.ReferenceQueue$Lock)
        at java.lang.ref.ReferenceQueue.remove(ReferenceQueue.java:143)
        - locked <0x0ca1b830> (a java.lang.ref.ReferenceQueue$Lock)
        at java.lang.ref.ReferenceQueue.remove(ReferenceQueue.java:164)
        at java.lang.ref.Finalizer$FinalizerThread.run(Finalizer.java:209)

"Reference Handler" #2 daemon prio=10 os_prio=2 tid=0x17960000 nid=0x4ef0 in Object.wait() [0x17c6f000]
   java.lang.Thread.State: WAITING (on object monitor)
        at java.lang.Object.wait(Native Method)
        - waiting on <0x0ca1b9d0> (a java.lang.ref.Reference$Lock)
        at java.lang.Object.wait(Object.java:502)
        at java.lang.ref.Reference.tryHandlePending(Reference.java:191)
        - locked <0x0ca1b9d0> (a java.lang.ref.Reference$Lock)
        at java.lang.ref.Reference$ReferenceHandler.run(Reference.java:153)

"VM Thread" os_prio=2 tid=0x1795a800 nid=0x3f54 runnable

"VM Periodic Task Thread" os_prio=2 tid=0x18739400 nid=0x4a14 waiting on condition

JNI global references: 229

// 找到一个死锁
Found one Java-level deadlock:
=============================
"Thread-1":
  waiting to lock monitor 0x17978de4 (object 0x07415a50, a java.lang.String),
  which is held by "Thread-0"
"Thread-0":
  waiting to lock monitor 0x1797a974 (object 0x0742bd18, a java.lang.String),
  which is held by "Thread-1"

Java stack information for the threads listed above:
===================================================
"Thread-1":
        at hello.DeadLock.resource1(DeadLock.java:31)
         // 等待 0x07415a50 锁
        - waiting to lock <0x07415a50> (a java.lang.String)
        at hello.DeadLock.resource2(DeadLock.java:43)
        // 持有 0x0742bd18
        - locked <0x0742bd18> (a java.lang.String)
        at hello.DeadLock.lambda$main$1(DeadLock.java:20)
        at hello.DeadLock$$Lambda$2/4983748.run(Unknown Source)
        at java.lang.Thread.run(Thread.java:748)
"Thread-0":
        at hello.DeadLock.resource2(DeadLock.java:41)
        // 等待 0x0742bd18 锁
        - waiting to lock <0x0742bd18> (a java.lang.String)
        at hello.DeadLock.resource1(DeadLock.java:33)
        // 持有 0x07415a50
        - locked <0x07415a50> (a java.lang.String)
        at hello.DeadLock.lambda$main$0(DeadLock.java:11)
        at hello.DeadLock$$Lambda$1/5592464.run(Unknown Source)
        at java.lang.Thread.run(Thread.java:748)

// 发现了一个死锁
Found 1 deadlock.

3.死锁形成的原因

• 互斥条件：一个资源每次只能被一个线程使用。
• 请求与保持条件：一个进程因请求资源而阻塞时，对已获得的资源保持不放。
• 不剥夺条件：进程已获得的资源，在未使用完之前，不能强行剥夺。
• 循环等待条件：若干进程之间形成一种头尾相接的循环等待资源关系。
  
  

  死锁是由四个必要条件导致的，所以一般来说，只要破坏这四个必要条件中的一个条件，死锁情况就应该不会发生。如果想要打破互斥条件，我们需要允许进程同时访问某些资源，这种方法受制于实际场景，不太容易实现条件；打破不可抢占条件，这样需要允许进程强行从占有者那里夺取某些资源，或者简单一点理解，占有资源的进程不能再申请占有其他资源，必须释放手上的资源之后才能发起申请，这个其实也很难找到适用场景；进程在运行前申请得到所有的资源，否则该进程不能进入准备执行状态。这个方法看似有点用处，但是它的缺点是可能导致资源利用率和进程并发性降低；避免出现资源申请环路，即对资源事先分类编号，按号分配。这种方式可以有效提高资源的利用率和系统吞吐量，但是增加了系统开销，增大了进程对资源的占用时间。