JUC同步锁原理源码解析二--ReentrantReadWriteLock

JUC同步锁原理源码解析二----ReentrantReadWriteLock

1.读写锁的来源

​ 在开发场景下,对于写操作我们为了保证原子性所以需要上锁,但是对于读操作,由于其不改变数据,只是单纯对数据进行读取,但是每次都上一把互斥锁,阻塞所有请求。这个明显不符合读多写少的场景。所以将锁分为两把:读锁和写锁。

2.读写锁的底层实现

​ 读写锁的底层实现依旧依赖于AQS。具体底层实现,请查看上一篇文章的介绍

2.AQS源码

Node节点

 static final class Node {
        /** Marker to indicate a node is waiting in shared mode */
        static final Node SHARED = new Node();
        /** Marker to indicate a node is waiting in exclusive mode */
        static final Node EXCLUSIVE = null;

        /** waitStatus value to indicate thread has cancelled */
        static final int CANCELLED =  1;
        /** waitStatus value to indicate successor's thread needs unparking */
        static final int SIGNAL    = -1;
        /** waitStatus value to indicate thread is waiting on condition */
        static final int CONDITION = -2;
 
        static final int PROPAGATE = -3;

        volatile int waitStatus;

        volatile Node prev;

        volatile Node next;
       
        volatile Thread thread;

        Node nextWaiter;
}

AbstractQueuedSynchronizer类

public abstract class AbstractQueuedSynchronizer
    extends AbstractOwnableSynchronizer
    implements java.io.Serializable {
    
 	private transient volatile Node head;

    /**
     * Tail of the wait queue, lazily initialized.  Modified only via
     * method enq to add new wait node.
     */
    private transient volatile Node tail;

    /**
     * The synchronization state.
     */
    private volatile int state;//最重要的一个变量
       
}

ConditionObject类

public class ConditionObject implements Condition, java.io.Serializable {
        private static final long serialVersionUID = 1173984872572414699L;
        /** First node of condition queue. */
        private transient Node firstWaiter;
        /** Last node of condition queue. */
        private transient Node lastWaiter;
}

accquire方法

public final void acquire(int arg) {
    if (!tryAcquire(arg) &&//尝试获取锁
        acquireQueued(addWaiter(Node.EXCLUSIVE), arg))//如果获取锁失败,添加到队列中,由于ReentrantLock是独占锁所以节点必须是EXCLUSIVE类型
        selfInterrupt();//添加中断标识位
}

addWaiter方法

private Node addWaiter(Node mode) {
     Node node = new Node(Thread.currentThread(), mode);//新建节点
     // Try the fast path of enq; backup to full enq on failure
     Node pred = tail;//获取到尾指针
     if (pred != null) {//尾指针不等于空,将当前节点替换为尾指针
         node.prev = pred;
         if (compareAndSetTail(pred, node)) {//采用尾插法,充分利用时间局部性和空间局部性。尾插的节点一般不容易被取消。
             pred.next = node;
             return node;
         }
     }
     enq(node);//cas失败后执行入队操作,继续尝试
     return node;
 }

private Node enq(final Node node) {
    for (;;) {
        Node t = tail;//获取尾指针
        if (t == null) { //代表当前队列没有节点
            if (compareAndSetHead(new Node()))//将当前节点置为头结点
                tail = head;
        } else {//当前队列有节点
            node.prev = t;//
            if (compareAndSetTail(t, node)) {//将当前节点置为尾结点
                t.next = node;
                return t;
            }
        }
    }
}

acquireQueued方法

final boolean acquireQueued(final Node node, int arg) {
    boolean failed = true;
    try {
        boolean interrupted = false;
        for (;;) {
            final Node p = node.predecessor();//找到当前节点的前驱节点
            if (p == head && tryAcquire(arg)) {//前驱节点等于头节点尝试cas抢锁。
                setHead(node);//抢锁成功将当前节点设置为头节点
                p.next = null; // help GC  当头结点置空
                failed = false;
                return interrupted;
            }
            if (shouldParkAfterFailedAcquire(p, node) &&//当队列中有节点在等待,判断是否应该阻塞
                parkAndCheckInterrupt())//阻塞等待,检查中断标识位
                interrupted = true;//将中断标识位置为true
        }
    } finally {
        if (failed)//
            cancelAcquire(node);//取消当前节点
    }
}


 private void cancelAcquire(Node node) {
     // Ignore if node doesn't exist
     if (node == null)//当前节点为空直接返回
         return;

     node.thread = null;//要取消了将当前节点的线程置为空
     // Skip cancelled predecessors
     Node pred = node.prev;//获取到当前节点的前驱节点
     while (pred.waitStatus > 0)//如果当前节点的前驱节点的状态大于0,代表是取消状态,一直找到不是取消状态的节点
         node.prev = pred = pred.prev;
     Node predNext = pred.next;//将当前要取消的节点断链

     node.waitStatus = Node.CANCELLED;//将当前节点的等待状态置为CANCELLED
     // If we are the tail, remove ourselves.
     if (node == tail && compareAndSetTail(node, pred)) {//如果当前节点是尾结点,将尾结点替换为浅语节点
         compareAndSetNext(pred, predNext, null);//将当前节点的下一个节点置为空,因为当前节点是最后一个节点没有next指针
     } else {
         // If successor needs signal, try to set pred's next-link
         // so it will get one. Otherwise wake it up to propagate.
         int ws;
         if (pred != head &&//前驱节点不等于头结点
             ((ws = pred.waitStatus) == Node.SIGNAL ||//前驱节点的状态不等于SIGNAL
              (ws <= 0 && compareAndSetWaitStatus(pred, ws, Node.SIGNAL))) &&//前驱节点的状态小于0,并且cas将前驱节点的等待置为SIGNAL
             pred.thread != null) {//前驱节点的线程补位空
             Node next = node.next;//获取当前节点的next指针
             if (next != null && next.waitStatus <= 0)//如果next指针不等于空并且等待状态小于等于0,标识节点有效
                 compareAndSetNext(pred, predNext, next);//将前驱节点的next指针指向下一个有效节点
         } else {
             unparkSuccessor(node);//唤醒后续节点 条件:1.前驱节点是头结点 2.当前节点不是signal,在ReentransLock中基本不会出现,在读写锁时就会出现
         }

         node.next = node; // help GC 将引用指向自身
     }
 }

 private void unparkSuccessor(Node node) {
     /*
         * If status is negative (i.e., possibly needing signal) try
         * to clear in anticipation of signalling.  It is OK if this
         * fails or if status is changed by waiting thread.
         */
     int ws = node.waitStatus;//获取当前节点状态
     if (ws < 0)//如果节点为负数也即不是取消节点
         compareAndSetWaitStatus(node, ws, 0);//cas将当前节点置为0

     /*
         * Thread to unpark is held in successor, which is normally
         * just the next node.  But if cancelled or apparently null,
         * traverse backwards from tail to find the actual
         * non-cancelled successor.
         */
     Node s = node.next;//获取到下一个节点
     if (s == null || s.waitStatus > 0) {//下一个节点等于空或者下一个节点是取消节点
         s = null;//将s置为空
         for (Node t = tail; t != null && t != node; t = t.prev)//从尾结点遍历找到一个不是取消状态的节点
             if (t.waitStatus <= 0)
                 s = t;
     }
     if (s != null)//如果s不等于空
         LockSupport.unpark(s.thread);//唤醒当前节点s
 }

shouldParkAfterFailedAcquire方法


private static boolean shouldParkAfterFailedAcquire(Node pred, Node node) {
    int ws = pred.waitStatus;//获取上一个节点的等待状态
    if (ws == Node.SIGNAL)//如果状态为SIGNAL,代表后续节点有节点可以唤醒,可以安心阻塞去
        /*
             * This node has already set status asking a release
             * to signal it, so it can safely park.
             */
        return true;
    if (ws > 0) {//如果当前状态大于0,代表节点为CANCELLED状态
        /*
             * Predecessor was cancelled. Skip over predecessors and
             * indicate retry.
             */
        do {
            node.prev = pred = pred.prev;//从尾节点开始遍历,找到下一个状态不是CANCELLED的节点。将取消节点断链移除
        } while (pred.waitStatus > 0);
        pred.next = node;
    } else {
        /*
             * waitStatus must be 0 or PROPAGATE.  Indicate that we
             * need a signal, but don't park yet.  Caller will need to
             * retry to make sure it cannot acquire before parking.
             */
        //这里需要注意ws>0时,已经找到了一个不是取消状态的前驱节点。
        compareAndSetWaitStatus(pred, ws, Node.SIGNAL);//将找到的不是CANCELLED节点的前驱节点,将其等待状态置为SIGNAL
    }
    return false;
}

cancelAcquire方法

 private void cancelAcquire(Node node) {
     // Ignore if node doesn't exist
     if (node == null)//当前节点为空直接返回
         return;

     node.thread = null;//要取消了将当前节点的线程置为空
     // Skip cancelled predecessors
     Node pred = node.prev;//获取到当前节点的前驱节点
     while (pred.waitStatus > 0)//如果当前节点的前驱节点的状态大于0,代表是取消状态,一直找到不是取消状态的节点
         node.prev = pred = pred.prev;
     Node predNext = pred.next;//将当前要取消的节点断链

     node.waitStatus = Node.CANCELLED;//将当前节点的等待状态置为CANCELLED
     // If we are the tail, remove ourselves.
     if (node == tail && compareAndSetTail(node, pred)) {//如果当前节点是尾结点,将尾结点替换为浅语节点
         compareAndSetNext(pred, predNext, null);//将当前节点的下一个节点置为空,因为当前节点是最后一个节点没有next指针
     } else {
         // If successor needs signal, try to set pred's next-link
         // so it will get one. Otherwise wake it up to propagate.
         int ws;
         if (pred != head &&//前驱节点不等于头结点
             ((ws = pred.waitStatus) == Node.SIGNAL ||//前驱节点的状态不等于SIGNAL
              (ws <= 0 && compareAndSetWaitStatus(pred, ws, Node.SIGNAL))) &&//前驱节点的状态小于0,并且cas将前驱节点的等待置为SIGNAL
             pred.thread != null) {//前驱节点的线程补位空
             Node next = node.next;//获取当前节点的next指针
             if (next != null && next.waitStatus <= 0)//如果next指针不等于空并且等待状态小于等于0,标识节点有效
                 compareAndSetNext(pred, predNext, next);//将前驱节点的next指针指向下一个有效节点
         } else {
             unparkSuccessor(node);//唤醒后续节点 条件:1.前驱节点是头结点 2.当前节点不是signal,在ReentransLock中基本不会出现,在读写锁时就会出现
         }

         node.next = node; // help GC 将引用指向自身
     }
 }

unparkSuccessor方法

 private void unparkSuccessor(Node node) {
     /*
         * If status is negative (i.e., possibly needing signal) try
         * to clear in anticipation of signalling.  It is OK if this
         * fails or if status is changed by waiting thread.
         */
     int ws = node.waitStatus;//获取当前节点状态
     if (ws < 0)//如果节点为负数也即不是取消节点
         compareAndSetWaitStatus(node, ws, 0);//cas将当前节点置为0

     /*
         * Thread to unpark is held in successor, which is normally
         * just the next node.  But if cancelled or apparently null,
         * traverse backwards from tail to find the actual
         * non-cancelled successor.
         */
     Node s = node.next;//获取到下一个节点
     if (s == null || s.waitStatus > 0) {//下一个节点等于空或者下一个节点是取消节点
         s = null;//将s置为空
         for (Node t = tail; t != null && t != node; t = t.prev)//从尾结点遍历找到一个不是取消状态的节点
             if (t.waitStatus <= 0)
                 s = t;
     }
     if (s != null)//如果s不等于空
         LockSupport.unpark(s.thread);//唤醒当前节点s
 }

release方法

public final boolean release(int arg) {
    if (tryRelease(arg)) {//子类实现如何释放锁
        Node h = head;//获取到头结点
        if (h != null && h.waitStatus != 0)//获取到头结点,如果头结点不为空,等待状态不为0,唤醒后续节点
            unparkSuccessor(h);
        return true;
    }
    return false;
}

private void unparkSuccessor(Node node) {
    /*
         * If status is negative (i.e., possibly needing signal) try
         * to clear in anticipation of signalling.  It is OK if this
         * fails or if status is changed by waiting thread.
         */
    int ws = node.waitStatus;//获取节点的等待状态
    if (ws < 0)//如果等待状态小于0,标识节点属于有效节点
        compareAndSetWaitStatus(node, ws, 0);//将当前节点的等待状态置为0

    /*
         * Thread to unpark is held in successor, which is normally
         * just the next node.  But if cancelled or apparently null,
         * traverse backwards from tail to find the actual
         * non-cancelled successor.
         */
    Node s = node.next;//获取到下一个节点
    if (s == null || s.waitStatus > 0) {//如果节点是空,或者是取消状态的节点,就找到一个非取消状态的节点,将取消状态的节点断链后由垃圾回收器进行回收
        s = null;
        for (Node t = tail; t != null && t != node; t = t.prev)
            if (t.waitStatus <= 0)
                s = t;
    }
    if (s != null)//节点不用空
        LockSupport.unpark(s.thread);//唤醒当前等待的有效节点S
}

acquireShared方法

public final void acquireShared(int arg) {
    if (tryAcquireShared(arg) < 0)//由子类实现
        doAcquireShared(arg);
}

doAcquireShared方法

private void doAcquireShared(int arg) {
    final Node node = addWaiter(Node.SHARED);//将共享节点也即读线程入队并返回
    boolean failed = true;
    try {
        boolean interrupted = false;
        for (;;) {
            final Node p = node.predecessor();//找到节点的前驱节点
            if (p == head) {//如果前驱节点等于头结点
                int r = tryAcquireShared(arg);//尝试获取共享锁数量
                if (r >= 0) {//如果锁的数量大于0,表示还有多余的共享锁。这里等于0也需要进一步判断。由于如果当执行到这里时,有另外的线程释放了共享锁,如果不进行判断,将会导致释放锁的线程没办法唤醒其他线程。所以这里会伪唤醒一个节点,唤醒的节点后续如果没有锁释放,依旧阻塞在当前parkAndCheckInterrupt方法中
                    setHeadAndPropagate(node, r);//将当前节点的等待状态设置为Propagate。
                    p.next = null; // help GC
                    if (interrupted)//判断是会否中断过
                        selfInterrupt();//设置中断标识位
                    failed = false;
                    return;
                }
            }
            if (shouldParkAfterFailedAcquire(p, node) &&//判断是否应该阻塞等待
                parkAndCheckInterrupt方法中())//阻塞并检查中断标识
                interrupted = true;//重置中断标识位
        }
    } finally {
        if (failed)//如果失败
            cancelAcquire(node);//取消节点
    }
}

setHeadAndPropagate方法

private void setHeadAndPropagate(Node node, int propagate) {
        Node h = head; // Record old head for check below
        setHead(node);//将当前节点置为头结点
        /*
         * Try to signal next queued node if:
         *   Propagation was indicated by caller,
         *     or was recorded (as h.waitStatus either before
         *     or after setHead) by a previous operation
         *     (note: this uses sign-check of waitStatus because
         *      PROPAGATE status may transition to SIGNAL.)
         * and
         *   The next node is waiting in shared mode,
         *     or we don't know, because it appears null
         *
         * The conservatism in both of these checks may cause
         * unnecessary wake-ups, but only when there are multiple
         * racing acquires/releases, so most need signals now or soon
         * anyway.
         */
        if (propagate > 0 //可获取的共享锁也即读锁的数量,对于ReentrantReadWriteLock而言,永远都是1,所以会继续唤醒下一个读线程
            || h == null //如果旧的头结点为空
            || h.waitStatus < 0 ||//头结点的等待状态不为0
            (h = head) == null || h.waitStatus < 0) {//旧头节点不为空并且等待状态小于0也即是有效节点
            Node s = node.next;//获取到node的下一个节点
            if (s == null || s.isShared())//如果node的下一个节点为空或者是共享节点
                doReleaseShared();//唤醒下一个线程
        }
    }

releaseShared方法

public final boolean releaseShared(int arg) {
    if (tryReleaseShared(arg)) {//子类实现释放锁
        doReleaseShared();//唤醒后续线程
        return true;//释放成功
    }
    return false;//释放是吧
}

doReleaseShared方法

private void doReleaseShared() {
    /*
         * Ensure that a release propagates, even if there are other
         * in-progress acquires/releases.  This proceeds in the usual
         * way of trying to unparkSuccessor of head if it needs
         * signal. But if it does not, status is set to PROPAGATE to
         * ensure that upon release, propagation continues.
         * Additionally, we must loop in case a new node is added
         * while we are doing this. Also, unlike other uses of
         * unparkSuccessor, we need to know if CAS to reset status
         * fails, if so rechecking.
         */
    for (;;) {
        Node h = head;//获取到当前头结点
        if (h != null && h != tail) {//如果头结点不为空并且不等于尾结点
            int ws = h.waitStatus;//获取当前节点的等待状态
            if (ws == Node.SIGNAL) {//如果状态为SIGNAL
                if (!compareAndSetWaitStatus(h, Node.SIGNAL, 0))//cas将SIGNAL状态置为0。SIGNAL标识后续有线程需要唤醒
                    continue;            // loop to recheck cases
                unparkSuccessor(h);//唤醒后续线程
            }
            else if (ws == 0 &&//如果当前状态为0。表示有线程将其置为0
                     !compareAndSetWaitStatus(h, 0, Node.PROPAGATE))//cas将0状态置为PROPAGATE。在多个共享锁同时释放时,方便继续进行读传播,唤醒后续节点
                continue;                // loop on failed CAS
        }
        if (h == head)//如果头结点没有改变,证明没有必要继续循环等待了,直接退出吧,如果头结点放生变化,可能有其他线程释放了锁。
            break;
    }
}

总结:AQS提供了统一的模板,对于如何入队出队以及线程的唤醒都由AQS提供默认的实现,只需要子类实现自己上锁和解锁的逻辑。

3.ReentrantReadWriteLock

基本使用


import java.util.Map;
import java.util.TreeMap;
import java.util.concurrent.locks.Lock;
import java.util.concurrent.locks.ReentrantReadWriteLock;

public class RWDictionary {
    private final Map<String, String> m = new TreeMap<String, String>();
    private final ReentrantReadWriteLock rwl = new ReentrantReadWriteLock();
    private final Lock r = rwl.readLock();
    private final Lock w = rwl.writeLock();
 
    public String get(String key) {
      r.lock();
      try { return m.get(key); }
      finally { r.unlock(); }
    }
    public String[] allKeys() {
      r.lock();
      try {
          return (String[])m.keySet().toArray();
      }
      finally { r.unlock(); }
    }
    public String put(String key, String value) {
      w.lock();
      try { return m.put(key, value); }
      finally { w.unlock(); }
    }
    public void clear() {
      w.lock();
      try { m.clear(); }
      finally { w.unlock(); }
    }
}

Sync类

abstract static class Sync extends AbstractQueuedSynchronizer {
        private static final long serialVersionUID = 6317671515068378041L;

        /*
         * Read vs write count extraction constants and functions.
         * Lock state is logically divided into two unsigned shorts:
         * The lower one representing the exclusive (writer) lock hold count,
         * and the upper the shared (reader) hold count.
         */

        static final int SHARED_SHIFT   = 16;
        static final int SHARED_UNIT    = (1 << SHARED_SHIFT);
        static final int MAX_COUNT      = (1 << SHARED_SHIFT) - 1;
        static final int EXCLUSIVE_MASK = (1 << SHARED_SHIFT) - 1;

        /** Returns the number of shared holds represented in count  */
        static int sharedCount(int c)    { return c >>> SHARED_SHIFT; }//高16位代表共享锁也即读锁
        /** Returns the number of exclusive holds represented in count  */
        static int exclusiveCount(int c) { return c & EXCLUSIVE_MASK; }//低16位代表独占锁也即写锁
}

公平锁的FairSync类实现

//读写锁中公平锁的实现:如果后续队列中有等待的节点,那么进行排队。但是这样的性能并不高,可能造成写饥饿。 
static final class FairSync extends Sync {
        private static final long serialVersionUID = -2274990926593161451L;
        final boolean writerShouldBlock() {
            return hasQueuedPredecessors();
        }
        final boolean readerShouldBlock() {
            return hasQueuedPredecessors();
        }
    }

//如果队列中有节点在排队,那么就进行等待
 public final boolean hasQueuedPredecessors() {
        // The correctness of this depends on head being initialized
        // before tail and on head.next being accurate if the current
        // thread is first in queue.
        Node t = tail; // Read fields in reverse initialization order
        Node h = head;
        Node s;
        return h != t &&
            ((s = h.next) == null || s.thread != Thread.currentThread());
    }

非公平锁的NonfairSync类实现

//非公平锁的实现相对来说性能较高,不阻塞,可以直接抢锁,防止写饥饿。同时有写线程排队,那么后续的所有读操作都需要进行排队
static final class NonfairSync extends Sync {
        private static final long serialVersionUID = -8159625535654395037L;
        final boolean writerShouldBlock() {
            return false; // writers can always barge //非公平锁写锁永远不阻塞,防止写饥饿
        }
        final boolean readerShouldBlock() {
            /* As a heuristic to avoid indefinite writer starvation,
             * block if the thread that momentarily appears to be head
             * of queue, if one exists, is a waiting writer.  This is
             * only a probabilistic effect since a new reader will not
             * block if there is a waiting writer behind other enabled
             * readers that have not yet drained from the queue.
             */
            return apparentlyFirstQueuedIsExclusive();
        }
}

//如果队列中有任务并且不是共享节点也即不是读操作,那么返回true,进行阻塞
 final boolean apparentlyFirstQueuedIsExclusive() {
        Node h, s;
        return (h = head) != null &&//头结点不等于空
            (s = h.next)  != null &&//头结点的下一个节点补位空
            !s.isShared()         &&//并且当前节点不是共享节点,也即读线程
            s.thread != null;//线程不为空
    }

写锁的lock方法:

public void lock() {
    sync.acquire(1);
}

//同样调用acquire的方法,请参考上文AQS的acquire方法的实现。同样都是获取失败进行排队

//子类获取锁的过程
protected final boolean tryAcquire(int acquires) {
    /*
             * Walkthrough:
             * 1. If read count nonzero or write count nonzero
             *    and owner is a different thread, fail.
             * 2. If count would saturate, fail. (This can only
             *    happen if count is already nonzero.)
             * 3. Otherwise, this thread is eligible for lock if
             *    it is either a reentrant acquire or
             *    queue policy allows it. If so, update state
             *    and set owner.
             */
    Thread current = Thread.currentThread();//获取当前线程
    int c = getState();//获取当前state状态值
    int w = exclusiveCount(c);//获取读锁的数量,这里doug lea一直都是使用二进制的风格
    if (c != 0) {//代表持有锁
        // (Note: if c != 0 and w == 0 then shared count != 0)
        if (w == 0 || current != getExclusiveOwnerThread())//如果写锁为0,或则当前线程不是写锁的持有线程
            return false;//返回false
        if (w + exclusiveCount(acquires) > MAX_COUNT)//当前锁重入次数大于最大值,抛出异常
            throw new Error("Maximum lock count exceeded");
        // Reentrant acquire
        setState(c + acquires);//直接设置状态,代表锁重入次数加1
        return true;//返回获取锁成功
    }
    if (writerShouldBlock() ||//写锁是否应该阻塞
        !compareAndSetState(c, c + acquires))//cas尝试获取锁
        return false;
    setExclusiveOwnerThread(current);//cas抢锁成功,直接将写锁的持有线程设置为当前线程
    return true;//返回true代表获取锁成功
}

writerShouldBlock的实现

//writerShouldBlock的实现请参考上面的公平锁和非公平锁的实现

写锁的unlock方法:

public void unlock() {
    sync.release(1);
}

//这里是AQS的模板方法
public final boolean release(int arg) {
    if (tryRelease(arg)) {//子类实现如何释放锁
        Node h = head;
        if (h != null && h.waitStatus != 0)
            unparkSuccessor(h);
        return true;
    }
    return false;
}

protected final boolean tryRelease(int releases) {
    if (!isHeldExclusively())//如果不是独占锁也即写锁,直接抛异常
        throw new IllegalMonitorStateException();
    int nextc = getState() - releases;//将锁的数量减少
    boolean free = exclusiveCount(nextc) == 0;//如果独占锁也即写锁数量为0,标识已经释放。大于1是因为锁重入的问题
    if (free)
        setExclusiveOwnerThread(null);
    setState(nextc);
    return free;
}

读锁的lock方法:

public void lock() {
    sync.acquireShared(1);
}

//acquireShared方法请看上面AQS的实现
public final void acquireShared(int arg) {
    if (tryAcquireShared(arg) < 0)
        doAcquireShared(arg);
}


protected final int tryAcquireShared(int unused) {
    /*
             * Walkthrough:
             * 1. If write lock held by another thread, fail.
             * 2. Otherwise, this thread is eligible for
             *    lock wrt state, so ask if it should block
             *    because of queue policy. If not, try
             *    to grant by CASing state and updating count.
             *    Note that step does not check for reentrant
             *    acquires, which is postponed to full version
             *    to avoid having to check hold count in
             *    the more typical non-reentrant case.
             * 3. If step 2 fails either because thread
             *    apparently not eligible or CAS fails or count
             *    saturated, chain to version with full retry loop.
             */
    Thread current = Thread.currentThread();//获取当前线程
    int c = getState();//获取当前state状态
    if (exclusiveCount(c) != 0 &&//如果独占锁也即写锁的数量不等于0
        getExclusiveOwnerThread() != current)//独占锁的拥有线程不是当前线程
        return -1;//直接返回-1,获取失败
    int r = sharedCount(c);//获取共享锁的数量
    if (!readerShouldBlock() &&//读锁是否应该被阻塞
        r < MAX_COUNT &&//读锁数量是否小于最大数量
        compareAndSetState(c, c + SHARED_UNIT)) {//cas将读锁+1
        if (r == 0) {//当前共享锁也即读锁数量为0
            firstReader = current;//标记为第一个读线程
            firstReaderHoldCount = 1;//将第一个读线程持有锁数量置为1,主要为了判断读锁的重入
        } else if (firstReader == current) {//第一个线程读等于当前线程
            firstReaderHoldCount++;//第一个读线程持有锁数量
        } else {
            HoldCounter rh = cachedHoldCounter;//先读取到最后一个线程持有共享锁的数量
            if (rh == null || rh.tid != getThreadId(current))//如果为空或者最后一个线程不是当前线程
                cachedHoldCounter = rh = readHolds.get();//从缓存中获取当前线程持有读锁的数量
            else if (rh.count == 0)//如果读锁持有数量为0
                readHolds.set(rh);//将值设置并保存
            rh.count++;//持有线程数+1
        }
        return 1;//返回1标识获取锁成功
    }
    return fullTryAcquireShared(current);
}

final int fullTryAcquireShared(Thread current) {
    /*
             * This code is in part redundant with that in
             * tryAcquireShared but is simpler overall by not
             * complicating tryAcquireShared with interactions between
             * retries and lazily reading hold counts.
             */
    HoldCounter rh = null;//
    for (;;) {
        int c = getState();//获取当前状态值
        if (exclusiveCount(c) != 0) {//如果持有写锁的线程数补位0
            if (getExclusiveOwnerThread() != current)//持有写锁的线程不是当前线程
                return -1;
            // else we hold the exclusive lock; blocking here
            // would cause deadlock.
        } else if (readerShouldBlock()) {//读锁是否应该被阻塞
            // Make sure we're not acquiring read lock reentrantly
            if (firstReader == current) {
                // assert firstReaderHoldCount > 0;
            } else {
                if (rh == null) {
                    rh = cachedHoldCounter;
                    if (rh == null || rh.tid != getThreadId(current)) {
                        rh = readHolds.get();
                        if (rh.count == 0)
                            readHolds.remove();
                    }
                }
                if (rh.count == 0)
                    return -1;
            }
        }
        if (sharedCount(c) == MAX_COUNT)//如果读线程的数量等于最大数量,抛出异常
            throw new Error("Maximum lock count exceeded");
        if (compareAndSetState(c, c + SHARED_UNIT)) {//cas尝试抢锁
            if (sharedCount(c) == 0) {
                firstReader = current;
                firstReaderHoldCount = 1;
            } else if (firstReader == current) {
                firstReaderHoldCount++;
            } else {
                if (rh == null)
                    rh = cachedHoldCounter;
                if (rh == null || rh.tid != getThreadId(current))
                    rh = readHolds.get();
                else if (rh.count == 0)
                    readHolds.set(rh);
                rh.count++;
                cachedHoldCounter = rh; // cache for release
            }
            return 1;
        }
    }
}

读锁的unlock方法

public void unlock() {
    sync.releaseShared(1);
}

//详情请查看上面AQS的实现
public final boolean releaseShared(int arg) {
    if (tryReleaseShared(arg)) {
        doReleaseShared();
        return true;
    }
    return false;
}

protected final boolean tryReleaseShared(int unused) {
    Thread current = Thread.currentThread();
    if (firstReader == current) {//如果当前线程是第一个读线程
        // assert firstReaderHoldCount > 0;
        if (firstReaderHoldCount == 1)//当前第一个读线程持有的读锁的数量是1
            firstReader = null;//直接置位空
        else
            firstReaderHoldCount--;//否则将持有读锁的数量减1
    } else {
        HoldCounter rh = cachedHoldCounter;//先获取最后一个读线程的持有信息
        if (rh == null || rh.tid != getThreadId(current))//如果rh为空或者最后一个读线程不是当前线程
            rh = readHolds.get();//从缓存中获取当前线程的持有锁的信息
        int count = rh.count;//获取到数量
        if (count <= 1) {//如果持有读锁的数量小于等于1
            readHolds.remove();//直接清空缓存
            if (count <= 0)
                throw unmatchedUnlockException();
        }
        --rh.count;//减去持有读锁的数量
    }
    for (;;) {
        int c = getState();//获取当前状态
        int nextc = c - SHARED_UNIT;//将读锁的数量减1
        if (compareAndSetState(c, nextc))//cas原子性赋值
            // Releasing the read lock has no effect on readers,
            // but it may allow waiting writers to proceed if
            // both read and write locks are now free.
            return nextc == 0;//如果为0表示当前线程已经释放了所有读锁。
    }
}

4.留言

本文章只是JUC 中AQS的一部分,后续的文章会对基于AQS锁实现的子类进行拓展讲解,以上文章内容基于个人以及结合别人文章的理解,如果有问题或者不当之处欢迎大家留言交流。由于为了保证观看流畅性,其中一部分源码有重复的地方。请见谅

posted @ 2023-06-16 00:13  bug的自我救赎  阅读(49)  评论(3编辑  收藏  举报