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  • Java多线程系列--“JUC锁”04之 公平锁(二)

     

    概要

    前面一章,我们学习了“公平锁”获取锁的详细流程;这里,我们再来看看“公平锁”释放锁的过程。内容包括:
    参考代码
    释放公平锁(基于JDK1.7.0_40)

    “公平锁”的获取过程请参考“Java多线程系列--“JUC锁”03之 公平锁(一)”,锁的使用示例请参考“Java多线程系列--“JUC锁”02之 互斥锁ReentrantLock”。

    注意
    (01) 这里是以“公平锁”来进行说明。
    (02) 关于本章的术语,如“AQS”,“CAS函数”,“CLH队列”,“公平锁”,“非公平锁”,“独占锁”,“共享锁”等内容,请参考Java多线程系列--“JUC锁”03之 公平锁(一)基本概念

    转载请注明出处:http://www.cnblogs.com/skywang12345/p/3496609.html 

    参考代码

    下面给出Java1.7.0_40版本中,ReentrantLock和AQS的源码,仅供参考!

    ReentranLock.java

      1 /*
      2  * ORACLE PROPRIETARY/CONFIDENTIAL. Use is subject to license terms.
      3  *
      4  *
      5  *
      6  *
      7  *
      8  *
      9  *
     10  *
     11  *
     12  *
     13  *
     14  *
     15  *
     16  *
     17  *
     18  *
     19  *
     20  *
     21  *
     22  *
     23  */
     24 
     25 /*
     26  *
     27  *
     28  *
     29  *
     30  *
     31  * Written by Doug Lea with assistance from members of JCP JSR-166
     32  * Expert Group and released to the public domain, as explained at
     33  * http://creativecommons.org/publicdomain/zero/1.0/
     34  */
     35 
     36 package java.util.concurrent.locks;
     37 import java.util.*;
     38 import java.util.concurrent.*;
     39 import java.util.concurrent.atomic.*;
     40 
     41 /**
     42  * A reentrant mutual exclusion {@link Lock} with the same basic
     43  * behavior and semantics as the implicit monitor lock accessed using
     44  * {@code synchronized} methods and statements, but with extended
     45  * capabilities.
     46  *
     47  * <p>A {@code ReentrantLock} is <em>owned</em> by the thread last
     48  * successfully locking, but not yet unlocking it. A thread invoking
     49  * {@code lock} will return, successfully acquiring the lock, when
     50  * the lock is not owned by another thread. The method will return
     51  * immediately if the current thread already owns the lock. This can
     52  * be checked using methods {@link #isHeldByCurrentThread}, and {@link
     53  * #getHoldCount}.
     54  *
     55  * <p>The constructor for this class accepts an optional
     56  * <em>fairness</em> parameter.  When set {@code true}, under
     57  * contention, locks favor granting access to the longest-waiting
     58  * thread.  Otherwise this lock does not guarantee any particular
     59  * access order.  Programs using fair locks accessed by many threads
     60  * may display lower overall throughput (i.e., are slower; often much
     61  * slower) than those using the default setting, but have smaller
     62  * variances in times to obtain locks and guarantee lack of
     63  * starvation. Note however, that fairness of locks does not guarantee
     64  * fairness of thread scheduling. Thus, one of many threads using a
     65  * fair lock may obtain it multiple times in succession while other
     66  * active threads are not progressing and not currently holding the
     67  * lock.
     68  * Also note that the untimed {@link #tryLock() tryLock} method does not
     69  * honor the fairness setting. It will succeed if the lock
     70  * is available even if other threads are waiting.
     71  *
     72  * <p>It is recommended practice to <em>always</em> immediately
     73  * follow a call to {@code lock} with a {@code try} block, most
     74  * typically in a before/after construction such as:
     75  *
     76  * <pre>
     77  * class X {
     78  *   private final ReentrantLock lock = new ReentrantLock();
     79  *   // ...
     80  *
     81  *   public void m() {
     82  *     lock.lock();  // block until condition holds
     83  *     try {
     84  *       // ... method body
     85  *     } finally {
     86  *       lock.unlock()
     87  *     }
     88  *   }
     89  * }
     90  * </pre>
     91  *
     92  * <p>In addition to implementing the {@link Lock} interface, this
     93  * class defines methods {@code isLocked} and
     94  * {@code getLockQueueLength}, as well as some associated
     95  * {@code protected} access methods that may be useful for
     96  * instrumentation and monitoring.
     97  *
     98  * <p>Serialization of this class behaves in the same way as built-in
     99  * locks: a deserialized lock is in the unlocked state, regardless of
    100  * its state when serialized.
    101  *
    102  * <p>This lock supports a maximum of 2147483647 recursive locks by
    103  * the same thread. Attempts to exceed this limit result in
    104  * {@link Error} throws from locking methods.
    105  *
    106  * @since 1.5
    107  * @author Doug Lea
    108  */
    109 public class ReentrantLock implements Lock, java.io.Serializable {
    110     private static final long serialVersionUID = 7373984872572414699L;
    111     /** Synchronizer providing all implementation mechanics */
    112     private final Sync sync;
    113 
    114     /**
    115      * Base of synchronization control for this lock. Subclassed
    116      * into fair and nonfair versions below. Uses AQS state to
    117      * represent the number of holds on the lock.
    118      */
    119     abstract static class Sync extends AbstractQueuedSynchronizer {
    120         private static final long serialVersionUID = -5179523762034025860L;
    121 
    122         /**
    123          * Performs {@link Lock#lock}. The main reason for subclassing
    124          * is to allow fast path for nonfair version.
    125          */
    126         abstract void lock();
    127 
    128         /**
    129          * Performs non-fair tryLock.  tryAcquire is
    130          * implemented in subclasses, but both need nonfair
    131          * try for trylock method.
    132          */
    133         final boolean nonfairTryAcquire(int acquires) {
    134             final Thread current = Thread.currentThread();
    135             int c = getState();
    136             if (c == 0) {
    137                 if (compareAndSetState(0, acquires)) {
    138                     setExclusiveOwnerThread(current);
    139                     return true;
    140                 }
    141             }
    142             else if (current == getExclusiveOwnerThread()) {
    143                 int nextc = c + acquires;
    144                 if (nextc < 0) // overflow
    145                     throw new Error("Maximum lock count exceeded");
    146                 setState(nextc);
    147                 return true;
    148             }
    149             return false;
    150         }
    151 
    152         protected final boolean tryRelease(int releases) {
    153             int c = getState() - releases;
    154             if (Thread.currentThread() != getExclusiveOwnerThread())
    155                 throw new IllegalMonitorStateException();
    156             boolean free = false;
    157             if (c == 0) {
    158                 free = true;
    159                 setExclusiveOwnerThread(null);
    160             }
    161             setState(c);
    162             return free;
    163         }
    164 
    165         protected final boolean isHeldExclusively() {
    166             // While we must in general read state before owner,
    167             // we don't need to do so to check if current thread is owner
    168             return getExclusiveOwnerThread() == Thread.currentThread();
    169         }
    170 
    171         final ConditionObject newCondition() {
    172             return new ConditionObject();
    173         }
    174 
    175         // Methods relayed from outer class
    176 
    177         final Thread getOwner() {
    178             return getState() == 0 ? null : getExclusiveOwnerThread();
    179         }
    180 
    181         final int getHoldCount() {
    182             return isHeldExclusively() ? getState() : 0;
    183         }
    184 
    185         final boolean isLocked() {
    186             return getState() != 0;
    187         }
    188 
    189         /**
    190          * Reconstitutes this lock instance from a stream.
    191          * @param s the stream
    192          */
    193         private void readObject(java.io.ObjectInputStream s)
    194             throws java.io.IOException, ClassNotFoundException {
    195             s.defaultReadObject();
    196             setState(0); // reset to unlocked state
    197         }
    198     }
    199 
    200     /**
    201      * Sync object for non-fair locks
    202      */
    203     static final class NonfairSync extends Sync {
    204         private static final long serialVersionUID = 7316153563782823691L;
    205 
    206         /**
    207          * Performs lock.  Try immediate barge, backing up to normal
    208          * acquire on failure.
    209          */
    210         final void lock() {
    211             if (compareAndSetState(0, 1))
    212                 setExclusiveOwnerThread(Thread.currentThread());
    213             else
    214                 acquire(1);
    215         }
    216 
    217         protected final boolean tryAcquire(int acquires) {
    218             return nonfairTryAcquire(acquires);
    219         }
    220     }
    221 
    222     /**
    223      * Sync object for fair locks
    224      */
    225     static final class FairSync extends Sync {
    226         private static final long serialVersionUID = -3000897897090466540L;
    227 
    228         final void lock() {
    229             acquire(1);
    230         }
    231 
    232         /**
    233          * Fair version of tryAcquire.  Don't grant access unless
    234          * recursive call or no waiters or is first.
    235          */
    236         protected final boolean tryAcquire(int acquires) {
    237             final Thread current = Thread.currentThread();
    238             int c = getState();
    239             if (c == 0) {
    240                 if (!hasQueuedPredecessors() &&
    241                     compareAndSetState(0, acquires)) {
    242                     setExclusiveOwnerThread(current);
    243                     return true;
    244                 }
    245             }
    246             else if (current == getExclusiveOwnerThread()) {
    247                 int nextc = c + acquires;
    248                 if (nextc < 0)
    249                     throw new Error("Maximum lock count exceeded");
    250                 setState(nextc);
    251                 return true;
    252             }
    253             return false;
    254         }
    255     }
    256 
    257     /**
    258      * Creates an instance of {@code ReentrantLock}.
    259      * This is equivalent to using {@code ReentrantLock(false)}.
    260      */
    261     public ReentrantLock() {
    262         sync = new NonfairSync();
    263     }
    264 
    265     /**
    266      * Creates an instance of {@code ReentrantLock} with the
    267      * given fairness policy.
    268      *
    269      * @param fair {@code true} if this lock should use a fair ordering policy
    270      */
    271     public ReentrantLock(boolean fair) {
    272         sync = fair ? new FairSync() : new NonfairSync();
    273     }
    274 
    275     /**
    276      * Acquires the lock.
    277      *
    278      * <p>Acquires the lock if it is not held by another thread and returns
    279      * immediately, setting the lock hold count to one.
    280      *
    281      * <p>If the current thread already holds the lock then the hold
    282      * count is incremented by one and the method returns immediately.
    283      *
    284      * <p>If the lock is held by another thread then the
    285      * current thread becomes disabled for thread scheduling
    286      * purposes and lies dormant until the lock has been acquired,
    287      * at which time the lock hold count is set to one.
    288      */
    289     public void lock() {
    290         sync.lock();
    291     }
    292 
    293     /**
    294      * Acquires the lock unless the current thread is
    295      * {@linkplain Thread#interrupt interrupted}.
    296      *
    297      * <p>Acquires the lock if it is not held by another thread and returns
    298      * immediately, setting the lock hold count to one.
    299      *
    300      * <p>If the current thread already holds this lock then the hold count
    301      * is incremented by one and the method returns immediately.
    302      *
    303      * <p>If the lock is held by another thread then the
    304      * current thread becomes disabled for thread scheduling
    305      * purposes and lies dormant until one of two things happens:
    306      *
    307      * <ul>
    308      *
    309      * <li>The lock is acquired by the current thread; or
    310      *
    311      * <li>Some other thread {@linkplain Thread#interrupt interrupts} the
    312      * current thread.
    313      *
    314      * </ul>
    315      *
    316      * <p>If the lock is acquired by the current thread then the lock hold
    317      * count is set to one.
    318      *
    319      * <p>If the current thread:
    320      *
    321      * <ul>
    322      *
    323      * <li>has its interrupted status set on entry to this method; or
    324      *
    325      * <li>is {@linkplain Thread#interrupt interrupted} while acquiring
    326      * the lock,
    327      *
    328      * </ul>
    329      *
    330      * then {@link InterruptedException} is thrown and the current thread's
    331      * interrupted status is cleared.
    332      *
    333      * <p>In this implementation, as this method is an explicit
    334      * interruption point, preference is given to responding to the
    335      * interrupt over normal or reentrant acquisition of the lock.
    336      *
    337      * @throws InterruptedException if the current thread is interrupted
    338      */
    339     public void lockInterruptibly() throws InterruptedException {
    340         sync.acquireInterruptibly(1);
    341     }
    342 
    343     /**
    344      * Acquires the lock only if it is not held by another thread at the time
    345      * of invocation.
    346      *
    347      * <p>Acquires the lock if it is not held by another thread and
    348      * returns immediately with the value {@code true}, setting the
    349      * lock hold count to one. Even when this lock has been set to use a
    350      * fair ordering policy, a call to {@code tryLock()} <em>will</em>
    351      * immediately acquire the lock if it is available, whether or not
    352      * other threads are currently waiting for the lock.
    353      * This &quot;barging&quot; behavior can be useful in certain
    354      * circumstances, even though it breaks fairness. If you want to honor
    355      * the fairness setting for this lock, then use
    356      * {@link #tryLock(long, TimeUnit) tryLock(0, TimeUnit.SECONDS) }
    357      * which is almost equivalent (it also detects interruption).
    358      *
    359      * <p> If the current thread already holds this lock then the hold
    360      * count is incremented by one and the method returns {@code true}.
    361      *
    362      * <p>If the lock is held by another thread then this method will return
    363      * immediately with the value {@code false}.
    364      *
    365      * @return {@code true} if the lock was free and was acquired by the
    366      *         current thread, or the lock was already held by the current
    367      *         thread; and {@code false} otherwise
    368      */
    369     public boolean tryLock() {
    370         return sync.nonfairTryAcquire(1);
    371     }
    372 
    373     /**
    374      * Acquires the lock if it is not held by another thread within the given
    375      * waiting time and the current thread has not been
    376      * {@linkplain Thread#interrupt interrupted}.
    377      *
    378      * <p>Acquires the lock if it is not held by another thread and returns
    379      * immediately with the value {@code true}, setting the lock hold count
    380      * to one. If this lock has been set to use a fair ordering policy then
    381      * an available lock <em>will not</em> be acquired if any other threads
    382      * are waiting for the lock. This is in contrast to the {@link #tryLock()}
    383      * method. If you want a timed {@code tryLock} that does permit barging on
    384      * a fair lock then combine the timed and un-timed forms together:
    385      *
    386      * <pre>if (lock.tryLock() || lock.tryLock(timeout, unit) ) { ... }
    387      * </pre>
    388      *
    389      * <p>If the current thread
    390      * already holds this lock then the hold count is incremented by one and
    391      * the method returns {@code true}.
    392      *
    393      * <p>If the lock is held by another thread then the
    394      * current thread becomes disabled for thread scheduling
    395      * purposes and lies dormant until one of three things happens:
    396      *
    397      * <ul>
    398      *
    399      * <li>The lock is acquired by the current thread; or
    400      *
    401      * <li>Some other thread {@linkplain Thread#interrupt interrupts}
    402      * the current thread; or
    403      *
    404      * <li>The specified waiting time elapses
    405      *
    406      * </ul>
    407      *
    408      * <p>If the lock is acquired then the value {@code true} is returned and
    409      * the lock hold count is set to one.
    410      *
    411      * <p>If the current thread:
    412      *
    413      * <ul>
    414      *
    415      * <li>has its interrupted status set on entry to this method; or
    416      *
    417      * <li>is {@linkplain Thread#interrupt interrupted} while
    418      * acquiring the lock,
    419      *
    420      * </ul>
    421      * then {@link InterruptedException} is thrown and the current thread's
    422      * interrupted status is cleared.
    423      *
    424      * <p>If the specified waiting time elapses then the value {@code false}
    425      * is returned.  If the time is less than or equal to zero, the method
    426      * will not wait at all.
    427      *
    428      * <p>In this implementation, as this method is an explicit
    429      * interruption point, preference is given to responding to the
    430      * interrupt over normal or reentrant acquisition of the lock, and
    431      * over reporting the elapse of the waiting time.
    432      *
    433      * @param timeout the time to wait for the lock
    434      * @param unit the time unit of the timeout argument
    435      * @return {@code true} if the lock was free and was acquired by the
    436      *         current thread, or the lock was already held by the current
    437      *         thread; and {@code false} if the waiting time elapsed before
    438      *         the lock could be acquired
    439      * @throws InterruptedException if the current thread is interrupted
    440      * @throws NullPointerException if the time unit is null
    441      *
    442      */
    443     public boolean tryLock(long timeout, TimeUnit unit)
    444             throws InterruptedException {
    445         return sync.tryAcquireNanos(1, unit.toNanos(timeout));
    446     }
    447 
    448     /**
    449      * Attempts to release this lock.
    450      *
    451      * <p>If the current thread is the holder of this lock then the hold
    452      * count is decremented.  If the hold count is now zero then the lock
    453      * is released.  If the current thread is not the holder of this
    454      * lock then {@link IllegalMonitorStateException} is thrown.
    455      *
    456      * @throws IllegalMonitorStateException if the current thread does not
    457      *         hold this lock
    458      */
    459     public void unlock() {
    460         sync.release(1);
    461     }
    462 
    463     /**
    464      * Returns a {@link Condition} instance for use with this
    465      * {@link Lock} instance.
    466      *
    467      * <p>The returned {@link Condition} instance supports the same
    468      * usages as do the {@link Object} monitor methods ({@link
    469      * Object#wait() wait}, {@link Object#notify notify}, and {@link
    470      * Object#notifyAll notifyAll}) when used with the built-in
    471      * monitor lock.
    472      *
    473      * <ul>
    474      *
    475      * <li>If this lock is not held when any of the {@link Condition}
    476      * {@linkplain Condition#await() waiting} or {@linkplain
    477      * Condition#signal signalling} methods are called, then an {@link
    478      * IllegalMonitorStateException} is thrown.
    479      *
    480      * <li>When the condition {@linkplain Condition#await() waiting}
    481      * methods are called the lock is released and, before they
    482      * return, the lock is reacquired and the lock hold count restored
    483      * to what it was when the method was called.
    484      *
    485      * <li>If a thread is {@linkplain Thread#interrupt interrupted}
    486      * while waiting then the wait will terminate, an {@link
    487      * InterruptedException} will be thrown, and the thread's
    488      * interrupted status will be cleared.
    489      *
    490      * <li> Waiting threads are signalled in FIFO order.
    491      *
    492      * <li>The ordering of lock reacquisition for threads returning
    493      * from waiting methods is the same as for threads initially
    494      * acquiring the lock, which is in the default case not specified,
    495      * but for <em>fair</em> locks favors those threads that have been
    496      * waiting the longest.
    497      *
    498      * </ul>
    499      *
    500      * @return the Condition object
    501      */
    502     public Condition newCondition() {
    503         return sync.newCondition();
    504     }
    505 
    506     /**
    507      * Queries the number of holds on this lock by the current thread.
    508      *
    509      * <p>A thread has a hold on a lock for each lock action that is not
    510      * matched by an unlock action.
    511      *
    512      * <p>The hold count information is typically only used for testing and
    513      * debugging purposes. For example, if a certain section of code should
    514      * not be entered with the lock already held then we can assert that
    515      * fact:
    516      *
    517      * <pre>
    518      * class X {
    519      *   ReentrantLock lock = new ReentrantLock();
    520      *   // ...
    521      *   public void m() {
    522      *     assert lock.getHoldCount() == 0;
    523      *     lock.lock();
    524      *     try {
    525      *       // ... method body
    526      *     } finally {
    527      *       lock.unlock();
    528      *     }
    529      *   }
    530      * }
    531      * </pre>
    532      *
    533      * @return the number of holds on this lock by the current thread,
    534      *         or zero if this lock is not held by the current thread
    535      */
    536     public int getHoldCount() {
    537         return sync.getHoldCount();
    538     }
    539 
    540     /**
    541      * Queries if this lock is held by the current thread.
    542      *
    543      * <p>Analogous to the {@link Thread#holdsLock} method for built-in
    544      * monitor locks, this method is typically used for debugging and
    545      * testing. For example, a method that should only be called while
    546      * a lock is held can assert that this is the case:
    547      *
    548      * <pre>
    549      * class X {
    550      *   ReentrantLock lock = new ReentrantLock();
    551      *   // ...
    552      *
    553      *   public void m() {
    554      *       assert lock.isHeldByCurrentThread();
    555      *       // ... method body
    556      *   }
    557      * }
    558      * </pre>
    559      *
    560      * <p>It can also be used to ensure that a reentrant lock is used
    561      * in a non-reentrant manner, for example:
    562      *
    563      * <pre>
    564      * class X {
    565      *   ReentrantLock lock = new ReentrantLock();
    566      *   // ...
    567      *
    568      *   public void m() {
    569      *       assert !lock.isHeldByCurrentThread();
    570      *       lock.lock();
    571      *       try {
    572      *           // ... method body
    573      *       } finally {
    574      *           lock.unlock();
    575      *       }
    576      *   }
    577      * }
    578      * </pre>
    579      *
    580      * @return {@code true} if current thread holds this lock and
    581      *         {@code false} otherwise
    582      */
    583     public boolean isHeldByCurrentThread() {
    584         return sync.isHeldExclusively();
    585     }
    586 
    587     /**
    588      * Queries if this lock is held by any thread. This method is
    589      * designed for use in monitoring of the system state,
    590      * not for synchronization control.
    591      *
    592      * @return {@code true} if any thread holds this lock and
    593      *         {@code false} otherwise
    594      */
    595     public boolean isLocked() {
    596         return sync.isLocked();
    597     }
    598 
    599     /**
    600      * Returns {@code true} if this lock has fairness set true.
    601      *
    602      * @return {@code true} if this lock has fairness set true
    603      */
    604     public final boolean isFair() {
    605         return sync instanceof FairSync;
    606     }
    607 
    608     /**
    609      * Returns the thread that currently owns this lock, or
    610      * {@code null} if not owned. When this method is called by a
    611      * thread that is not the owner, the return value reflects a
    612      * best-effort approximation of current lock status. For example,
    613      * the owner may be momentarily {@code null} even if there are
    614      * threads trying to acquire the lock but have not yet done so.
    615      * This method is designed to facilitate construction of
    616      * subclasses that provide more extensive lock monitoring
    617      * facilities.
    618      *
    619      * @return the owner, or {@code null} if not owned
    620      */
    621     protected Thread getOwner() {
    622         return sync.getOwner();
    623     }
    624 
    625     /**
    626      * Queries whether any threads are waiting to acquire this lock. Note that
    627      * because cancellations may occur at any time, a {@code true}
    628      * return does not guarantee that any other thread will ever
    629      * acquire this lock.  This method is designed primarily for use in
    630      * monitoring of the system state.
    631      *
    632      * @return {@code true} if there may be other threads waiting to
    633      *         acquire the lock
    634      */
    635     public final boolean hasQueuedThreads() {
    636         return sync.hasQueuedThreads();
    637     }
    638 
    639 
    640     /**
    641      * Queries whether the given thread is waiting to acquire this
    642      * lock. Note that because cancellations may occur at any time, a
    643      * {@code true} return does not guarantee that this thread
    644      * will ever acquire this lock.  This method is designed primarily for use
    645      * in monitoring of the system state.
    646      *
    647      * @param thread the thread
    648      * @return {@code true} if the given thread is queued waiting for this lock
    649      * @throws NullPointerException if the thread is null
    650      */
    651     public final boolean hasQueuedThread(Thread thread) {
    652         return sync.isQueued(thread);
    653     }
    654 
    655 
    656     /**
    657      * Returns an estimate of the number of threads waiting to
    658      * acquire this lock.  The value is only an estimate because the number of
    659      * threads may change dynamically while this method traverses
    660      * internal data structures.  This method is designed for use in
    661      * monitoring of the system state, not for synchronization
    662      * control.
    663      *
    664      * @return the estimated number of threads waiting for this lock
    665      */
    666     public final int getQueueLength() {
    667         return sync.getQueueLength();
    668     }
    669 
    670     /**
    671      * Returns a collection containing threads that may be waiting to
    672      * acquire this lock.  Because the actual set of threads may change
    673      * dynamically while constructing this result, the returned
    674      * collection is only a best-effort estimate.  The elements of the
    675      * returned collection are in no particular order.  This method is
    676      * designed to facilitate construction of subclasses that provide
    677      * more extensive monitoring facilities.
    678      *
    679      * @return the collection of threads
    680      */
    681     protected Collection<Thread> getQueuedThreads() {
    682         return sync.getQueuedThreads();
    683     }
    684 
    685     /**
    686      * Queries whether any threads are waiting on the given condition
    687      * associated with this lock. Note that because timeouts and
    688      * interrupts may occur at any time, a {@code true} return does
    689      * not guarantee that a future {@code signal} will awaken any
    690      * threads.  This method is designed primarily for use in
    691      * monitoring of the system state.
    692      *
    693      * @param condition the condition
    694      * @return {@code true} if there are any waiting threads
    695      * @throws IllegalMonitorStateException if this lock is not held
    696      * @throws IllegalArgumentException if the given condition is
    697      *         not associated with this lock
    698      * @throws NullPointerException if the condition is null
    699      */
    700     public boolean hasWaiters(Condition condition) {
    701         if (condition == null)
    702             throw new NullPointerException();
    703         if (!(condition instanceof AbstractQueuedSynchronizer.ConditionObject))
    704             throw new IllegalArgumentException("not owner");
    705         return sync.hasWaiters((AbstractQueuedSynchronizer.ConditionObject)condition);
    706     }
    707 
    708     /**
    709      * Returns an estimate of the number of threads waiting on the
    710      * given condition associated with this lock. Note that because
    711      * timeouts and interrupts may occur at any time, the estimate
    712      * serves only as an upper bound on the actual number of waiters.
    713      * This method is designed for use in monitoring of the system
    714      * state, not for synchronization control.
    715      *
    716      * @param condition the condition
    717      * @return the estimated number of waiting threads
    718      * @throws IllegalMonitorStateException if this lock is not held
    719      * @throws IllegalArgumentException if the given condition is
    720      *         not associated with this lock
    721      * @throws NullPointerException if the condition is null
    722      */
    723     public int getWaitQueueLength(Condition condition) {
    724         if (condition == null)
    725             throw new NullPointerException();
    726         if (!(condition instanceof AbstractQueuedSynchronizer.ConditionObject))
    727             throw new IllegalArgumentException("not owner");
    728         return sync.getWaitQueueLength((AbstractQueuedSynchronizer.ConditionObject)condition);
    729     }
    730 
    731     /**
    732      * Returns a collection containing those threads that may be
    733      * waiting on the given condition associated with this lock.
    734      * Because the actual set of threads may change dynamically while
    735      * constructing this result, the returned collection is only a
    736      * best-effort estimate. The elements of the returned collection
    737      * are in no particular order.  This method is designed to
    738      * facilitate construction of subclasses that provide more
    739      * extensive condition monitoring facilities.
    740      *
    741      * @param condition the condition
    742      * @return the collection of threads
    743      * @throws IllegalMonitorStateException if this lock is not held
    744      * @throws IllegalArgumentException if the given condition is
    745      *         not associated with this lock
    746      * @throws NullPointerException if the condition is null
    747      */
    748     protected Collection<Thread> getWaitingThreads(Condition condition) {
    749         if (condition == null)
    750             throw new NullPointerException();
    751         if (!(condition instanceof AbstractQueuedSynchronizer.ConditionObject))
    752             throw new IllegalArgumentException("not owner");
    753         return sync.getWaitingThreads((AbstractQueuedSynchronizer.ConditionObject)condition);
    754     }
    755 
    756     /**
    757      * Returns a string identifying this lock, as well as its lock state.
    758      * The state, in brackets, includes either the String {@code "Unlocked"}
    759      * or the String {@code "Locked by"} followed by the
    760      * {@linkplain Thread#getName name} of the owning thread.
    761      *
    762      * @return a string identifying this lock, as well as its lock state
    763      */
    764     public String toString() {
    765         Thread o = sync.getOwner();
    766         return super.toString() + ((o == null) ?
    767                                    "[Unlocked]" :
    768                                    "[Locked by thread " + o.getName() + "]");
    769     }
    770 }
    View Code


    AQS(AbstractQueuedSynchronizer.java)

       1 /*
       2  * ORACLE PROPRIETARY/CONFIDENTIAL. Use is subject to license terms.
       3  *
       4  *
       5  *
       6  *
       7  *
       8  *
       9  *
      10  *
      11  *
      12  *
      13  *
      14  *
      15  *
      16  *
      17  *
      18  *
      19  *
      20  *
      21  *
      22  *
      23  */
      24 
      25 /*
      26  *
      27  *
      28  *
      29  *
      30  *
      31  * Written by Doug Lea with assistance from members of JCP JSR-166
      32  * Expert Group and released to the public domain, as explained at
      33  * http://creativecommons.org/publicdomain/zero/1.0/
      34  */
      35 
      36 package java.util.concurrent.locks;
      37 import java.util.*;
      38 import java.util.concurrent.*;
      39 import java.util.concurrent.atomic.*;
      40 import sun.misc.Unsafe;
      41 
      42 /**
      43  * Provides a framework for implementing blocking locks and related
      44  * synchronizers (semaphores, events, etc) that rely on
      45  * first-in-first-out (FIFO) wait queues.  This class is designed to
      46  * be a useful basis for most kinds of synchronizers that rely on a
      47  * single atomic <tt>int</tt> value to represent state. Subclasses
      48  * must define the protected methods that change this state, and which
      49  * define what that state means in terms of this object being acquired
      50  * or released.  Given these, the other methods in this class carry
      51  * out all queuing and blocking mechanics. Subclasses can maintain
      52  * other state fields, but only the atomically updated <tt>int</tt>
      53  * value manipulated using methods {@link #getState}, {@link
      54  * #setState} and {@link #compareAndSetState} is tracked with respect
      55  * to synchronization.
      56  *
      57  * <p>Subclasses should be defined as non-public internal helper
      58  * classes that are used to implement the synchronization properties
      59  * of their enclosing class.  Class
      60  * <tt>AbstractQueuedSynchronizer</tt> does not implement any
      61  * synchronization interface.  Instead it defines methods such as
      62  * {@link #acquireInterruptibly} that can be invoked as
      63  * appropriate by concrete locks and related synchronizers to
      64  * implement their public methods.
      65  *
      66  * <p>This class supports either or both a default <em>exclusive</em>
      67  * mode and a <em>shared</em> mode. When acquired in exclusive mode,
      68  * attempted acquires by other threads cannot succeed. Shared mode
      69  * acquires by multiple threads may (but need not) succeed. This class
      70  * does not &quot;understand&quot; these differences except in the
      71  * mechanical sense that when a shared mode acquire succeeds, the next
      72  * waiting thread (if one exists) must also determine whether it can
      73  * acquire as well. Threads waiting in the different modes share the
      74  * same FIFO queue. Usually, implementation subclasses support only
      75  * one of these modes, but both can come into play for example in a
      76  * {@link ReadWriteLock}. Subclasses that support only exclusive or
      77  * only shared modes need not define the methods supporting the unused mode.
      78  *
      79  * <p>This class defines a nested {@link ConditionObject} class that
      80  * can be used as a {@link Condition} implementation by subclasses
      81  * supporting exclusive mode for which method {@link
      82  * #isHeldExclusively} reports whether synchronization is exclusively
      83  * held with respect to the current thread, method {@link #release}
      84  * invoked with the current {@link #getState} value fully releases
      85  * this object, and {@link #acquire}, given this saved state value,
      86  * eventually restores this object to its previous acquired state.  No
      87  * <tt>AbstractQueuedSynchronizer</tt> method otherwise creates such a
      88  * condition, so if this constraint cannot be met, do not use it.  The
      89  * behavior of {@link ConditionObject} depends of course on the
      90  * semantics of its synchronizer implementation.
      91  *
      92  * <p>This class provides inspection, instrumentation, and monitoring
      93  * methods for the internal queue, as well as similar methods for
      94  * condition objects. These can be exported as desired into classes
      95  * using an <tt>AbstractQueuedSynchronizer</tt> for their
      96  * synchronization mechanics.
      97  *
      98  * <p>Serialization of this class stores only the underlying atomic
      99  * integer maintaining state, so deserialized objects have empty
     100  * thread queues. Typical subclasses requiring serializability will
     101  * define a <tt>readObject</tt> method that restores this to a known
     102  * initial state upon deserialization.
     103  *
     104  * <h3>Usage</h3>
     105  *
     106  * <p>To use this class as the basis of a synchronizer, redefine the
     107  * following methods, as applicable, by inspecting and/or modifying
     108  * the synchronization state using {@link #getState}, {@link
     109  * #setState} and/or {@link #compareAndSetState}:
     110  *
     111  * <ul>
     112  * <li> {@link #tryAcquire}
     113  * <li> {@link #tryRelease}
     114  * <li> {@link #tryAcquireShared}
     115  * <li> {@link #tryReleaseShared}
     116  * <li> {@link #isHeldExclusively}
     117  *</ul>
     118  *
     119  * Each of these methods by default throws {@link
     120  * UnsupportedOperationException}.  Implementations of these methods
     121  * must be internally thread-safe, and should in general be short and
     122  * not block. Defining these methods is the <em>only</em> supported
     123  * means of using this class. All other methods are declared
     124  * <tt>final</tt> because they cannot be independently varied.
     125  *
     126  * <p>You may also find the inherited methods from {@link
     127  * AbstractOwnableSynchronizer} useful to keep track of the thread
     128  * owning an exclusive synchronizer.  You are encouraged to use them
     129  * -- this enables monitoring and diagnostic tools to assist users in
     130  * determining which threads hold locks.
     131  *
     132  * <p>Even though this class is based on an internal FIFO queue, it
     133  * does not automatically enforce FIFO acquisition policies.  The core
     134  * of exclusive synchronization takes the form:
     135  *
     136  * <pre>
     137  * Acquire:
     138  *     while (!tryAcquire(arg)) {
     139  *        <em>enqueue thread if it is not already queued</em>;
     140  *        <em>possibly block current thread</em>;
     141  *     }
     142  *
     143  * Release:
     144  *     if (tryRelease(arg))
     145  *        <em>unblock the first queued thread</em>;
     146  * </pre>
     147  *
     148  * (Shared mode is similar but may involve cascading signals.)
     149  *
     150  * <p><a name="barging">Because checks in acquire are invoked before
     151  * enqueuing, a newly acquiring thread may <em>barge</em> ahead of
     152  * others that are blocked and queued.  However, you can, if desired,
     153  * define <tt>tryAcquire</tt> and/or <tt>tryAcquireShared</tt> to
     154  * disable barging by internally invoking one or more of the inspection
     155  * methods, thereby providing a <em>fair</em> FIFO acquisition order.
     156  * In particular, most fair synchronizers can define <tt>tryAcquire</tt>
     157  * to return <tt>false</tt> if {@link #hasQueuedPredecessors} (a method
     158  * specifically designed to be used by fair synchronizers) returns
     159  * <tt>true</tt>.  Other variations are possible.
     160  *
     161  * <p>Throughput and scalability are generally highest for the
     162  * default barging (also known as <em>greedy</em>,
     163  * <em>renouncement</em>, and <em>convoy-avoidance</em>) strategy.
     164  * While this is not guaranteed to be fair or starvation-free, earlier
     165  * queued threads are allowed to recontend before later queued
     166  * threads, and each recontention has an unbiased chance to succeed
     167  * against incoming threads.  Also, while acquires do not
     168  * &quot;spin&quot; in the usual sense, they may perform multiple
     169  * invocations of <tt>tryAcquire</tt> interspersed with other
     170  * computations before blocking.  This gives most of the benefits of
     171  * spins when exclusive synchronization is only briefly held, without
     172  * most of the liabilities when it isn't. If so desired, you can
     173  * augment this by preceding calls to acquire methods with
     174  * "fast-path" checks, possibly prechecking {@link #hasContended}
     175  * and/or {@link #hasQueuedThreads} to only do so if the synchronizer
     176  * is likely not to be contended.
     177  *
     178  * <p>This class provides an efficient and scalable basis for
     179  * synchronization in part by specializing its range of use to
     180  * synchronizers that can rely on <tt>int</tt> state, acquire, and
     181  * release parameters, and an internal FIFO wait queue. When this does
     182  * not suffice, you can build synchronizers from a lower level using
     183  * {@link java.util.concurrent.atomic atomic} classes, your own custom
     184  * {@link java.util.Queue} classes, and {@link LockSupport} blocking
     185  * support.
     186  *
     187  * <h3>Usage Examples</h3>
     188  *
     189  * <p>Here is a non-reentrant mutual exclusion lock class that uses
     190  * the value zero to represent the unlocked state, and one to
     191  * represent the locked state. While a non-reentrant lock
     192  * does not strictly require recording of the current owner
     193  * thread, this class does so anyway to make usage easier to monitor.
     194  * It also supports conditions and exposes
     195  * one of the instrumentation methods:
     196  *
     197  * <pre>
     198  * class Mutex implements Lock, java.io.Serializable {
     199  *
     200  *   // Our internal helper class
     201  *   private static class Sync extends AbstractQueuedSynchronizer {
     202  *     // Report whether in locked state
     203  *     protected boolean isHeldExclusively() {
     204  *       return getState() == 1;
     205  *     }
     206  *
     207  *     // Acquire the lock if state is zero
     208  *     public boolean tryAcquire(int acquires) {
     209  *       assert acquires == 1; // Otherwise unused
     210  *       if (compareAndSetState(0, 1)) {
     211  *         setExclusiveOwnerThread(Thread.currentThread());
     212  *         return true;
     213  *       }
     214  *       return false;
     215  *     }
     216  *
     217  *     // Release the lock by setting state to zero
     218  *     protected boolean tryRelease(int releases) {
     219  *       assert releases == 1; // Otherwise unused
     220  *       if (getState() == 0) throw new IllegalMonitorStateException();
     221  *       setExclusiveOwnerThread(null);
     222  *       setState(0);
     223  *       return true;
     224  *     }
     225  *
     226  *     // Provide a Condition
     227  *     Condition newCondition() { return new ConditionObject(); }
     228  *
     229  *     // Deserialize properly
     230  *     private void readObject(ObjectInputStream s)
     231  *         throws IOException, ClassNotFoundException {
     232  *       s.defaultReadObject();
     233  *       setState(0); // reset to unlocked state
     234  *     }
     235  *   }
     236  *
     237  *   // The sync object does all the hard work. We just forward to it.
     238  *   private final Sync sync = new Sync();
     239  *
     240  *   public void lock()                { sync.acquire(1); }
     241  *   public boolean tryLock()          { return sync.tryAcquire(1); }
     242  *   public void unlock()              { sync.release(1); }
     243  *   public Condition newCondition()   { return sync.newCondition(); }
     244  *   public boolean isLocked()         { return sync.isHeldExclusively(); }
     245  *   public boolean hasQueuedThreads() { return sync.hasQueuedThreads(); }
     246  *   public void lockInterruptibly() throws InterruptedException {
     247  *     sync.acquireInterruptibly(1);
     248  *   }
     249  *   public boolean tryLock(long timeout, TimeUnit unit)
     250  *       throws InterruptedException {
     251  *     return sync.tryAcquireNanos(1, unit.toNanos(timeout));
     252  *   }
     253  * }
     254  * </pre>
     255  *
     256  * <p>Here is a latch class that is like a {@link CountDownLatch}
     257  * except that it only requires a single <tt>signal</tt> to
     258  * fire. Because a latch is non-exclusive, it uses the <tt>shared</tt>
     259  * acquire and release methods.
     260  *
     261  * <pre>
     262  * class BooleanLatch {
     263  *
     264  *   private static class Sync extends AbstractQueuedSynchronizer {
     265  *     boolean isSignalled() { return getState() != 0; }
     266  *
     267  *     protected int tryAcquireShared(int ignore) {
     268  *       return isSignalled() ? 1 : -1;
     269  *     }
     270  *
     271  *     protected boolean tryReleaseShared(int ignore) {
     272  *       setState(1);
     273  *       return true;
     274  *     }
     275  *   }
     276  *
     277  *   private final Sync sync = new Sync();
     278  *   public boolean isSignalled() { return sync.isSignalled(); }
     279  *   public void signal()         { sync.releaseShared(1); }
     280  *   public void await() throws InterruptedException {
     281  *     sync.acquireSharedInterruptibly(1);
     282  *   }
     283  * }
     284  * </pre>
     285  *
     286  * @since 1.5
     287  * @author Doug Lea
     288  */
     289 public abstract class AbstractQueuedSynchronizer
     290     extends AbstractOwnableSynchronizer
     291     implements java.io.Serializable {
     292 
     293     private static final long serialVersionUID = 7373984972572414691L;
     294 
     295     /**
     296      * Creates a new <tt>AbstractQueuedSynchronizer</tt> instance
     297      * with initial synchronization state of zero.
     298      */
     299     protected AbstractQueuedSynchronizer() { }
     300 
     301     /**
     302      * Wait queue node class.
     303      *
     304      * <p>The wait queue is a variant of a "CLH" (Craig, Landin, and
     305      * Hagersten) lock queue. CLH locks are normally used for
     306      * spinlocks.  We instead use them for blocking synchronizers, but
     307      * use the same basic tactic of holding some of the control
     308      * information about a thread in the predecessor of its node.  A
     309      * "status" field in each node keeps track of whether a thread
     310      * should block.  A node is signalled when its predecessor
     311      * releases.  Each node of the queue otherwise serves as a
     312      * specific-notification-style monitor holding a single waiting
     313      * thread. The status field does NOT control whether threads are
     314      * granted locks etc though.  A thread may try to acquire if it is
     315      * first in the queue. But being first does not guarantee success;
     316      * it only gives the right to contend.  So the currently released
     317      * contender thread may need to rewait.
     318      *
     319      * <p>To enqueue into a CLH lock, you atomically splice it in as new
     320      * tail. To dequeue, you just set the head field.
     321      * <pre>
     322      *      +------+  prev +-----+       +-----+
     323      * head |      | <---- |     | <---- |     |  tail
     324      *      +------+       +-----+       +-----+
     325      * </pre>
     326      *
     327      * <p>Insertion into a CLH queue requires only a single atomic
     328      * operation on "tail", so there is a simple atomic point of
     329      * demarcation from unqueued to queued. Similarly, dequeing
     330      * involves only updating the "head". However, it takes a bit
     331      * more work for nodes to determine who their successors are,
     332      * in part to deal with possible cancellation due to timeouts
     333      * and interrupts.
     334      *
     335      * <p>The "prev" links (not used in original CLH locks), are mainly
     336      * needed to handle cancellation. If a node is cancelled, its
     337      * successor is (normally) relinked to a non-cancelled
     338      * predecessor. For explanation of similar mechanics in the case
     339      * of spin locks, see the papers by Scott and Scherer at
     340      * http://www.cs.rochester.edu/u/scott/synchronization/
     341      *
     342      * <p>We also use "next" links to implement blocking mechanics.
     343      * The thread id for each node is kept in its own node, so a
     344      * predecessor signals the next node to wake up by traversing
     345      * next link to determine which thread it is.  Determination of
     346      * successor must avoid races with newly queued nodes to set
     347      * the "next" fields of their predecessors.  This is solved
     348      * when necessary by checking backwards from the atomically
     349      * updated "tail" when a node's successor appears to be null.
     350      * (Or, said differently, the next-links are an optimization
     351      * so that we don't usually need a backward scan.)
     352      *
     353      * <p>Cancellation introduces some conservatism to the basic
     354      * algorithms.  Since we must poll for cancellation of other
     355      * nodes, we can miss noticing whether a cancelled node is
     356      * ahead or behind us. This is dealt with by always unparking
     357      * successors upon cancellation, allowing them to stabilize on
     358      * a new predecessor, unless we can identify an uncancelled
     359      * predecessor who will carry this responsibility.
     360      *
     361      * <p>CLH queues need a dummy header node to get started. But
     362      * we don't create them on construction, because it would be wasted
     363      * effort if there is never contention. Instead, the node
     364      * is constructed and head and tail pointers are set upon first
     365      * contention.
     366      *
     367      * <p>Threads waiting on Conditions use the same nodes, but
     368      * use an additional link. Conditions only need to link nodes
     369      * in simple (non-concurrent) linked queues because they are
     370      * only accessed when exclusively held.  Upon await, a node is
     371      * inserted into a condition queue.  Upon signal, the node is
     372      * transferred to the main queue.  A special value of status
     373      * field is used to mark which queue a node is on.
     374      *
     375      * <p>Thanks go to Dave Dice, Mark Moir, Victor Luchangco, Bill
     376      * Scherer and Michael Scott, along with members of JSR-166
     377      * expert group, for helpful ideas, discussions, and critiques
     378      * on the design of this class.
     379      */
     380     static final class Node {
     381         /** Marker to indicate a node is waiting in shared mode */
     382         static final Node SHARED = new Node();
     383         /** Marker to indicate a node is waiting in exclusive mode */
     384         static final Node EXCLUSIVE = null;
     385 
     386         /** waitStatus value to indicate thread has cancelled */
     387         static final int CANCELLED =  1;
     388         /** waitStatus value to indicate successor's thread needs unparking */
     389         static final int SIGNAL    = -1;
     390         /** waitStatus value to indicate thread is waiting on condition */
     391         static final int CONDITION = -2;
     392         /**
     393          * waitStatus value to indicate the next acquireShared should
     394          * unconditionally propagate
     395          */
     396         static final int PROPAGATE = -3;
     397 
     398         /**
     399          * Status field, taking on only the values:
     400          *   SIGNAL:     The successor of this node is (or will soon be)
     401          *               blocked (via park), so the current node must
     402          *               unpark its successor when it releases or
     403          *               cancels. To avoid races, acquire methods must
     404          *               first indicate they need a signal,
     405          *               then retry the atomic acquire, and then,
     406          *               on failure, block.
     407          *   CANCELLED:  This node is cancelled due to timeout or interrupt.
     408          *               Nodes never leave this state. In particular,
     409          *               a thread with cancelled node never again blocks.
     410          *   CONDITION:  This node is currently on a condition queue.
     411          *               It will not be used as a sync queue node
     412          *               until transferred, at which time the status
     413          *               will be set to 0. (Use of this value here has
     414          *               nothing to do with the other uses of the
     415          *               field, but simplifies mechanics.)
     416          *   PROPAGATE:  A releaseShared should be propagated to other
     417          *               nodes. This is set (for head node only) in
     418          *               doReleaseShared to ensure propagation
     419          *               continues, even if other operations have
     420          *               since intervened.
     421          *   0:          None of the above
     422          *
     423          * The values are arranged numerically to simplify use.
     424          * Non-negative values mean that a node doesn't need to
     425          * signal. So, most code doesn't need to check for particular
     426          * values, just for sign.
     427          *
     428          * The field is initialized to 0 for normal sync nodes, and
     429          * CONDITION for condition nodes.  It is modified using CAS
     430          * (or when possible, unconditional volatile writes).
     431          */
     432         volatile int waitStatus;
     433 
     434         /**
     435          * Link to predecessor node that current node/thread relies on
     436          * for checking waitStatus. Assigned during enqueing, and nulled
     437          * out (for sake of GC) only upon dequeuing.  Also, upon
     438          * cancellation of a predecessor, we short-circuit while
     439          * finding a non-cancelled one, which will always exist
     440          * because the head node is never cancelled: A node becomes
     441          * head only as a result of successful acquire. A
     442          * cancelled thread never succeeds in acquiring, and a thread only
     443          * cancels itself, not any other node.
     444          */
     445         volatile Node prev;
     446 
     447         /**
     448          * Link to the successor node that the current node/thread
     449          * unparks upon release. Assigned during enqueuing, adjusted
     450          * when bypassing cancelled predecessors, and nulled out (for
     451          * sake of GC) when dequeued.  The enq operation does not
     452          * assign next field of a predecessor until after attachment,
     453          * so seeing a null next field does not necessarily mean that
     454          * node is at end of queue. However, if a next field appears
     455          * to be null, we can scan prev's from the tail to
     456          * double-check.  The next field of cancelled nodes is set to
     457          * point to the node itself instead of null, to make life
     458          * easier for isOnSyncQueue.
     459          */
     460         volatile Node next;
     461 
     462         /**
     463          * The thread that enqueued this node.  Initialized on
     464          * construction and nulled out after use.
     465          */
     466         volatile Thread thread;
     467 
     468         /**
     469          * Link to next node waiting on condition, or the special
     470          * value SHARED.  Because condition queues are accessed only
     471          * when holding in exclusive mode, we just need a simple
     472          * linked queue to hold nodes while they are waiting on
     473          * conditions. They are then transferred to the queue to
     474          * re-acquire. And because conditions can only be exclusive,
     475          * we save a field by using special value to indicate shared
     476          * mode.
     477          */
     478         Node nextWaiter;
     479 
     480         /**
     481          * Returns true if node is waiting in shared mode
     482          */
     483         final boolean isShared() {
     484             return nextWaiter == SHARED;
     485         }
     486 
     487         /**
     488          * Returns previous node, or throws NullPointerException if null.
     489          * Use when predecessor cannot be null.  The null check could
     490          * be elided, but is present to help the VM.
     491          *
     492          * @return the predecessor of this node
     493          */
     494         final Node predecessor() throws NullPointerException {
     495             Node p = prev;
     496             if (p == null)
     497                 throw new NullPointerException();
     498             else
     499                 return p;
     500         }
     501 
     502         Node() {    // Used to establish initial head or SHARED marker
     503         }
     504 
     505         Node(Thread thread, Node mode) {     // Used by addWaiter
     506             this.nextWaiter = mode;
     507             this.thread = thread;
     508         }
     509 
     510         Node(Thread thread, int waitStatus) { // Used by Condition
     511             this.waitStatus = waitStatus;
     512             this.thread = thread;
     513         }
     514     }
     515 
     516     /**
     517      * Head of the wait queue, lazily initialized.  Except for
     518      * initialization, it is modified only via method setHead.  Note:
     519      * If head exists, its waitStatus is guaranteed not to be
     520      * CANCELLED.
     521      */
     522     private transient volatile Node head;
     523 
     524     /**
     525      * Tail of the wait queue, lazily initialized.  Modified only via
     526      * method enq to add new wait node.
     527      */
     528     private transient volatile Node tail;
     529 
     530     /**
     531      * The synchronization state.
     532      */
     533     private volatile int state;
     534 
     535     /**
     536      * Returns the current value of synchronization state.
     537      * This operation has memory semantics of a <tt>volatile</tt> read.
     538      * @return current state value
     539      */
     540     protected final int getState() {
     541         return state;
     542     }
     543 
     544     /**
     545      * Sets the value of synchronization state.
     546      * This operation has memory semantics of a <tt>volatile</tt> write.
     547      * @param newState the new state value
     548      */
     549     protected final void setState(int newState) {
     550         state = newState;
     551     }
     552 
     553     /**
     554      * Atomically sets synchronization state to the given updated
     555      * value if the current state value equals the expected value.
     556      * This operation has memory semantics of a <tt>volatile</tt> read
     557      * and write.
     558      *
     559      * @param expect the expected value
     560      * @param update the new value
     561      * @return true if successful. False return indicates that the actual
     562      *         value was not equal to the expected value.
     563      */
     564     protected final boolean compareAndSetState(int expect, int update) {
     565         // See below for intrinsics setup to support this
     566         return unsafe.compareAndSwapInt(this, stateOffset, expect, update);
     567     }
     568 
     569     // Queuing utilities
     570 
     571     /**
     572      * The number of nanoseconds for which it is faster to spin
     573      * rather than to use timed park. A rough estimate suffices
     574      * to improve responsiveness with very short timeouts.
     575      */
     576     static final long spinForTimeoutThreshold = 1000L;
     577 
     578     /**
     579      * Inserts node into queue, initializing if necessary. See picture above.
     580      * @param node the node to insert
     581      * @return node's predecessor
     582      */
     583     private Node enq(final Node node) {
     584         for (;;) {
     585             Node t = tail;
     586             if (t == null) { // Must initialize
     587                 if (compareAndSetHead(new Node()))
     588                     tail = head;
     589             } else {
     590                 node.prev = t;
     591                 if (compareAndSetTail(t, node)) {
     592                     t.next = node;
     593                     return t;
     594                 }
     595             }
     596         }
     597     }
     598 
     599     /**
     600      * Creates and enqueues node for current thread and given mode.
     601      *
     602      * @param mode Node.EXCLUSIVE for exclusive, Node.SHARED for shared
     603      * @return the new node
     604      */
     605     private Node addWaiter(Node mode) {
     606         Node node = new Node(Thread.currentThread(), mode);
     607         // Try the fast path of enq; backup to full enq on failure
     608         Node pred = tail;
     609         if (pred != null) {
     610             node.prev = pred;
     611             if (compareAndSetTail(pred, node)) {
     612                 pred.next = node;
     613                 return node;
     614             }
     615         }
     616         enq(node);
     617         return node;
     618     }
     619 
     620     /**
     621      * Sets head of queue to be node, thus dequeuing. Called only by
     622      * acquire methods.  Also nulls out unused fields for sake of GC
     623      * and to suppress unnecessary signals and traversals.
     624      *
     625      * @param node the node
     626      */
     627     private void setHead(Node node) {
     628         head = node;
     629         node.thread = null;
     630         node.prev = null;
     631     }
     632 
     633     /**
     634      * Wakes up node's successor, if one exists.
     635      *
     636      * @param node the node
     637      */
     638     private void unparkSuccessor(Node node) {
     639         /*
     640          * If status is negative (i.e., possibly needing signal) try
     641          * to clear in anticipation of signalling.  It is OK if this
     642          * fails or if status is changed by waiting thread.
     643          */
     644         int ws = node.waitStatus;
     645         if (ws < 0)
     646             compareAndSetWaitStatus(node, ws, 0);
     647 
     648         /*
     649          * Thread to unpark is held in successor, which is normally
     650          * just the next node.  But if cancelled or apparently null,
     651          * traverse backwards from tail to find the actual
     652          * non-cancelled successor.
     653          */
     654         Node s = node.next;
     655         if (s == null || s.waitStatus > 0) {
     656             s = null;
     657             for (Node t = tail; t != null && t != node; t = t.prev)
     658                 if (t.waitStatus <= 0)
     659                     s = t;
     660         }
     661         if (s != null)
     662             LockSupport.unpark(s.thread);
     663     }
     664 
     665     /**
     666      * Release action for shared mode -- signal successor and ensure
     667      * propagation. (Note: For exclusive mode, release just amounts
     668      * to calling unparkSuccessor of head if it needs signal.)
     669      */
     670     private void doReleaseShared() {
     671         /*
     672          * Ensure that a release propagates, even if there are other
     673          * in-progress acquires/releases.  This proceeds in the usual
     674          * way of trying to unparkSuccessor of head if it needs
     675          * signal. But if it does not, status is set to PROPAGATE to
     676          * ensure that upon release, propagation continues.
     677          * Additionally, we must loop in case a new node is added
     678          * while we are doing this. Also, unlike other uses of
     679          * unparkSuccessor, we need to know if CAS to reset status
     680          * fails, if so rechecking.
     681          */
     682         for (;;) {
     683             Node h = head;
     684             if (h != null && h != tail) {
     685                 int ws = h.waitStatus;
     686                 if (ws == Node.SIGNAL) {
     687                     if (!compareAndSetWaitStatus(h, Node.SIGNAL, 0))
     688                         continue;            // loop to recheck cases
     689                     unparkSuccessor(h);
     690                 }
     691                 else if (ws == 0 &&
     692                          !compareAndSetWaitStatus(h, 0, Node.PROPAGATE))
     693                     continue;                // loop on failed CAS
     694             }
     695             if (h == head)                   // loop if head changed
     696                 break;
     697         }
     698     }
     699 
     700     /**
     701      * Sets head of queue, and checks if successor may be waiting
     702      * in shared mode, if so propagating if either propagate > 0 or
     703      * PROPAGATE status was set.
     704      *
     705      * @param node the node
     706      * @param propagate the return value from a tryAcquireShared
     707      */
     708     private void setHeadAndPropagate(Node node, int propagate) {
     709         Node h = head; // Record old head for check below
     710         setHead(node);
     711         /*
     712          * Try to signal next queued node if:
     713          *   Propagation was indicated by caller,
     714          *     or was recorded (as h.waitStatus) by a previous operation
     715          *     (note: this uses sign-check of waitStatus because
     716          *      PROPAGATE status may transition to SIGNAL.)
     717          * and
     718          *   The next node is waiting in shared mode,
     719          *     or we don't know, because it appears null
     720          *
     721          * The conservatism in both of these checks may cause
     722          * unnecessary wake-ups, but only when there are multiple
     723          * racing acquires/releases, so most need signals now or soon
     724          * anyway.
     725          */
     726         if (propagate > 0 || h == null || h.waitStatus < 0) {
     727             Node s = node.next;
     728             if (s == null || s.isShared())
     729                 doReleaseShared();
     730         }
     731     }
     732 
     733     // Utilities for various versions of acquire
     734 
     735     /**
     736      * Cancels an ongoing attempt to acquire.
     737      *
     738      * @param node the node
     739      */
     740     private void cancelAcquire(Node node) {
     741         // Ignore if node doesn't exist
     742         if (node == null)
     743             return;
     744 
     745         node.thread = null;
     746 
     747         // Skip cancelled predecessors
     748         Node pred = node.prev;
     749         while (pred.waitStatus > 0)
     750             node.prev = pred = pred.prev;
     751 
     752         // predNext is the apparent node to unsplice. CASes below will
     753         // fail if not, in which case, we lost race vs another cancel
     754         // or signal, so no further action is necessary.
     755         Node predNext = pred.next;
     756 
     757         // Can use unconditional write instead of CAS here.
     758         // After this atomic step, other Nodes can skip past us.
     759         // Before, we are free of interference from other threads.
     760         node.waitStatus = Node.CANCELLED;
     761 
     762         // If we are the tail, remove ourselves.
     763         if (node == tail && compareAndSetTail(node, pred)) {
     764             compareAndSetNext(pred, predNext, null);
     765         } else {
     766             // If successor needs signal, try to set pred's next-link
     767             // so it will get one. Otherwise wake it up to propagate.
     768             int ws;
     769             if (pred != head &&
     770                 ((ws = pred.waitStatus) == Node.SIGNAL ||
     771                  (ws <= 0 && compareAndSetWaitStatus(pred, ws, Node.SIGNAL))) &&
     772                 pred.thread != null) {
     773                 Node next = node.next;
     774                 if (next != null && next.waitStatus <= 0)
     775                     compareAndSetNext(pred, predNext, next);
     776             } else {
     777                 unparkSuccessor(node);
     778             }
     779 
     780             node.next = node; // help GC
     781         }
     782     }
     783 
     784     /**
     785      * Checks and updates status for a node that failed to acquire.
     786      * Returns true if thread should block. This is the main signal
     787      * control in all acquire loops.  Requires that pred == node.prev
     788      *
     789      * @param pred node's predecessor holding status
     790      * @param node the node
     791      * @return {@code true} if thread should block
     792      */
     793     private static boolean shouldParkAfterFailedAcquire(Node pred, Node node) {
     794         int ws = pred.waitStatus;
     795         if (ws == Node.SIGNAL)
     796             /*
     797              * This node has already set status asking a release
     798              * to signal it, so it can safely park.
     799              */
     800             return true;
     801         if (ws > 0) {
     802             /*
     803              * Predecessor was cancelled. Skip over predecessors and
     804              * indicate retry.
     805              */
     806             do {
     807                 node.prev = pred = pred.prev;
     808             } while (pred.waitStatus > 0);
     809             pred.next = node;
     810         } else {
     811             /*
     812              * waitStatus must be 0 or PROPAGATE.  Indicate that we
     813              * need a signal, but don't park yet.  Caller will need to
     814              * retry to make sure it cannot acquire before parking.
     815              */
     816             compareAndSetWaitStatus(pred, ws, Node.SIGNAL);
     817         }
     818         return false;
     819     }
     820 
     821     /**
     822      * Convenience method to interrupt current thread.
     823      */
     824     private static void selfInterrupt() {
     825         Thread.currentThread().interrupt();
     826     }
     827 
     828     /**
     829      * Convenience method to park and then check if interrupted
     830      *
     831      * @return {@code true} if interrupted
     832      */
     833     private final boolean parkAndCheckInterrupt() {
     834         LockSupport.park(this);
     835         return Thread.interrupted();
     836     }
     837 
     838     /*
     839      * Various flavors of acquire, varying in exclusive/shared and
     840      * control modes.  Each is mostly the same, but annoyingly
     841      * different.  Only a little bit of factoring is possible due to
     842      * interactions of exception mechanics (including ensuring that we
     843      * cancel if tryAcquire throws exception) and other control, at
     844      * least not without hurting performance too much.
     845      */
     846 
     847     /**
     848      * Acquires in exclusive uninterruptible mode for thread already in
     849      * queue. Used by condition wait methods as well as acquire.
     850      *
     851      * @param node the node
     852      * @param arg the acquire argument
     853      * @return {@code true} if interrupted while waiting
     854      */
     855     final boolean acquireQueued(final Node node, int arg) {
     856         boolean failed = true;
     857         try {
     858             boolean interrupted = false;
     859             for (;;) {
     860                 final Node p = node.predecessor();
     861                 if (p == head && tryAcquire(arg)) {
     862                     setHead(node);
     863                     p.next = null; // help GC
     864                     failed = false;
     865                     return interrupted;
     866                 }
     867                 if (shouldParkAfterFailedAcquire(p, node) &&
     868                     parkAndCheckInterrupt())
     869                     interrupted = true;
     870             }
     871         } finally {
     872             if (failed)
     873                 cancelAcquire(node);
     874         }
     875     }
     876 
     877     /**
     878      * Acquires in exclusive interruptible mode.
     879      * @param arg the acquire argument
     880      */
     881     private void doAcquireInterruptibly(int arg)
     882         throws InterruptedException {
     883         final Node node = addWaiter(Node.EXCLUSIVE);
     884         boolean failed = true;
     885         try {
     886             for (;;) {
     887                 final Node p = node.predecessor();
     888                 if (p == head && tryAcquire(arg)) {
     889                     setHead(node);
     890                     p.next = null; // help GC
     891                     failed = false;
     892                     return;
     893                 }
     894                 if (shouldParkAfterFailedAcquire(p, node) &&
     895                     parkAndCheckInterrupt())
     896                     throw new InterruptedException();
     897             }
     898         } finally {
     899             if (failed)
     900                 cancelAcquire(node);
     901         }
     902     }
     903 
     904     /**
     905      * Acquires in exclusive timed mode.
     906      *
     907      * @param arg the acquire argument
     908      * @param nanosTimeout max wait time
     909      * @return {@code true} if acquired
     910      */
     911     private boolean doAcquireNanos(int arg, long nanosTimeout)
     912         throws InterruptedException {
     913         long lastTime = System.nanoTime();
     914         final Node node = addWaiter(Node.EXCLUSIVE);
     915         boolean failed = true;
     916         try {
     917             for (;;) {
     918                 final Node p = node.predecessor();
     919                 if (p == head && tryAcquire(arg)) {
     920                     setHead(node);
     921                     p.next = null; // help GC
     922                     failed = false;
     923                     return true;
     924                 }
     925                 if (nanosTimeout <= 0)
     926                     return false;
     927                 if (shouldParkAfterFailedAcquire(p, node) &&
     928                     nanosTimeout > spinForTimeoutThreshold)
     929                     LockSupport.parkNanos(this, nanosTimeout);
     930                 long now = System.nanoTime();
     931                 nanosTimeout -= now - lastTime;
     932                 lastTime = now;
     933                 if (Thread.interrupted())
     934                     throw new InterruptedException();
     935             }
     936         } finally {
     937             if (failed)
     938                 cancelAcquire(node);
     939         }
     940     }
     941 
     942     /**
     943      * Acquires in shared uninterruptible mode.
     944      * @param arg the acquire argument
     945      */
     946     private void doAcquireShared(int arg) {
     947         final Node node = addWaiter(Node.SHARED);
     948         boolean failed = true;
     949         try {
     950             boolean interrupted = false;
     951             for (;;) {
     952                 final Node p = node.predecessor();
     953                 if (p == head) {
     954                     int r = tryAcquireShared(arg);
     955                     if (r >= 0) {
     956                         setHeadAndPropagate(node, r);
     957                         p.next = null; // help GC
     958                         if (interrupted)
     959                             selfInterrupt();
     960                         failed = false;
     961                         return;
     962                     }
     963                 }
     964                 if (shouldParkAfterFailedAcquire(p, node) &&
     965                     parkAndCheckInterrupt())
     966                     interrupted = true;
     967             }
     968         } finally {
     969             if (failed)
     970                 cancelAcquire(node);
     971         }
     972     }
     973 
     974     /**
     975      * Acquires in shared interruptible mode.
     976      * @param arg the acquire argument
     977      */
     978     private void doAcquireSharedInterruptibly(int arg)
     979         throws InterruptedException {
     980         final Node node = addWaiter(Node.SHARED);
     981         boolean failed = true;
     982         try {
     983             for (;;) {
     984                 final Node p = node.predecessor();
     985                 if (p == head) {
     986                     int r = tryAcquireShared(arg);
     987                     if (r >= 0) {
     988                         setHeadAndPropagate(node, r);
     989                         p.next = null; // help GC
     990                         failed = false;
     991                         return;
     992                     }
     993                 }
     994                 if (shouldParkAfterFailedAcquire(p, node) &&
     995                     parkAndCheckInterrupt())
     996                     throw new InterruptedException();
     997             }
     998         } finally {
     999             if (failed)
    1000                 cancelAcquire(node);
    1001         }
    1002     }
    1003 
    1004     /**
    1005      * Acquires in shared timed mode.
    1006      *
    1007      * @param arg the acquire argument
    1008      * @param nanosTimeout max wait time
    1009      * @return {@code true} if acquired
    1010      */
    1011     private boolean doAcquireSharedNanos(int arg, long nanosTimeout)
    1012         throws InterruptedException {
    1013 
    1014         long lastTime = System.nanoTime();
    1015         final Node node = addWaiter(Node.SHARED);
    1016         boolean failed = true;
    1017         try {
    1018             for (;;) {
    1019                 final Node p = node.predecessor();
    1020                 if (p == head) {
    1021                     int r = tryAcquireShared(arg);
    1022                     if (r >= 0) {
    1023                         setHeadAndPropagate(node, r);
    1024                         p.next = null; // help GC
    1025                         failed = false;
    1026                         return true;
    1027                     }
    1028                 }
    1029                 if (nanosTimeout <= 0)
    1030                     return false;
    1031                 if (shouldParkAfterFailedAcquire(p, node) &&
    1032                     nanosTimeout > spinForTimeoutThreshold)
    1033                     LockSupport.parkNanos(this, nanosTimeout);
    1034                 long now = System.nanoTime();
    1035                 nanosTimeout -= now - lastTime;
    1036                 lastTime = now;
    1037                 if (Thread.interrupted())
    1038                     throw new InterruptedException();
    1039             }
    1040         } finally {
    1041             if (failed)
    1042                 cancelAcquire(node);
    1043         }
    1044     }
    1045 
    1046     // Main exported methods
    1047 
    1048     /**
    1049      * Attempts to acquire in exclusive mode. This method should query
    1050      * if the state of the object permits it to be acquired in the
    1051      * exclusive mode, and if so to acquire it.
    1052      *
    1053      * <p>This method is always invoked by the thread performing
    1054      * acquire.  If this method reports failure, the acquire method
    1055      * may queue the thread, if it is not already queued, until it is
    1056      * signalled by a release from some other thread. This can be used
    1057      * to implement method {@link Lock#tryLock()}.
    1058      *
    1059      * <p>The default
    1060      * implementation throws {@link UnsupportedOperationException}.
    1061      *
    1062      * @param arg the acquire argument. This value is always the one
    1063      *        passed to an acquire method, or is the value saved on entry
    1064      *        to a condition wait.  The value is otherwise uninterpreted
    1065      *        and can represent anything you like.
    1066      * @return {@code true} if successful. Upon success, this object has
    1067      *         been acquired.
    1068      * @throws IllegalMonitorStateException if acquiring would place this
    1069      *         synchronizer in an illegal state. This exception must be
    1070      *         thrown in a consistent fashion for synchronization to work
    1071      *         correctly.
    1072      * @throws UnsupportedOperationException if exclusive mode is not supported
    1073      */
    1074     protected boolean tryAcquire(int arg) {
    1075         throw new UnsupportedOperationException();
    1076     }
    1077 
    1078     /**
    1079      * Attempts to set the state to reflect a release in exclusive
    1080      * mode.
    1081      *
    1082      * <p>This method is always invoked by the thread performing release.
    1083      *
    1084      * <p>The default implementation throws
    1085      * {@link UnsupportedOperationException}.
    1086      *
    1087      * @param arg the release argument. This value is always the one
    1088      *        passed to a release method, or the current state value upon
    1089      *        entry to a condition wait.  The value is otherwise
    1090      *        uninterpreted and can represent anything you like.
    1091      * @return {@code true} if this object is now in a fully released
    1092      *         state, so that any waiting threads may attempt to acquire;
    1093      *         and {@code false} otherwise.
    1094      * @throws IllegalMonitorStateException if releasing would place this
    1095      *         synchronizer in an illegal state. This exception must be
    1096      *         thrown in a consistent fashion for synchronization to work
    1097      *         correctly.
    1098      * @throws UnsupportedOperationException if exclusive mode is not supported
    1099      */
    1100     protected boolean tryRelease(int arg) {
    1101         throw new UnsupportedOperationException();
    1102     }
    1103 
    1104     /**
    1105      * Attempts to acquire in shared mode. This method should query if
    1106      * the state of the object permits it to be acquired in the shared
    1107      * mode, and if so to acquire it.
    1108      *
    1109      * <p>This method is always invoked by the thread performing
    1110      * acquire.  If this method reports failure, the acquire method
    1111      * may queue the thread, if it is not already queued, until it is
    1112      * signalled by a release from some other thread.
    1113      *
    1114      * <p>The default implementation throws {@link
    1115      * UnsupportedOperationException}.
    1116      *
    1117      * @param arg the acquire argument. This value is always the one
    1118      *        passed to an acquire method, or is the value saved on entry
    1119      *        to a condition wait.  The value is otherwise uninterpreted
    1120      *        and can represent anything you like.
    1121      * @return a negative value on failure; zero if acquisition in shared
    1122      *         mode succeeded but no subsequent shared-mode acquire can
    1123      *         succeed; and a positive value if acquisition in shared
    1124      *         mode succeeded and subsequent shared-mode acquires might
    1125      *         also succeed, in which case a subsequent waiting thread
    1126      *         must check availability. (Support for three different
    1127      *         return values enables this method to be used in contexts
    1128      *         where acquires only sometimes act exclusively.)  Upon
    1129      *         success, this object has been acquired.
    1130      * @throws IllegalMonitorStateException if acquiring would place this
    1131      *         synchronizer in an illegal state. This exception must be
    1132      *         thrown in a consistent fashion for synchronization to work
    1133      *         correctly.
    1134      * @throws UnsupportedOperationException if shared mode is not supported
    1135      */
    1136     protected int tryAcquireShared(int arg) {
    1137         throw new UnsupportedOperationException();
    1138     }
    1139 
    1140     /**
    1141      * Attempts to set the state to reflect a release in shared mode.
    1142      *
    1143      * <p>This method is always invoked by the thread performing release.
    1144      *
    1145      * <p>The default implementation throws
    1146      * {@link UnsupportedOperationException}.
    1147      *
    1148      * @param arg the release argument. This value is always the one
    1149      *        passed to a release method, or the current state value upon
    1150      *        entry to a condition wait.  The value is otherwise
    1151      *        uninterpreted and can represent anything you like.
    1152      * @return {@code true} if this release of shared mode may permit a
    1153      *         waiting acquire (shared or exclusive) to succeed; and
    1154      *         {@code false} otherwise
    1155      * @throws IllegalMonitorStateException if releasing would place this
    1156      *         synchronizer in an illegal state. This exception must be
    1157      *         thrown in a consistent fashion for synchronization to work
    1158      *         correctly.
    1159      * @throws UnsupportedOperationException if shared mode is not supported
    1160      */
    1161     protected boolean tryReleaseShared(int arg) {
    1162         throw new UnsupportedOperationException();
    1163     }
    1164 
    1165     /**
    1166      * Returns {@code true} if synchronization is held exclusively with
    1167      * respect to the current (calling) thread.  This method is invoked
    1168      * upon each call to a non-waiting {@link ConditionObject} method.
    1169      * (Waiting methods instead invoke {@link #release}.)
    1170      *
    1171      * <p>The default implementation throws {@link
    1172      * UnsupportedOperationException}. This method is invoked
    1173      * internally only within {@link ConditionObject} methods, so need
    1174      * not be defined if conditions are not used.
    1175      *
    1176      * @return {@code true} if synchronization is held exclusively;
    1177      *         {@code false} otherwise
    1178      * @throws UnsupportedOperationException if conditions are not supported
    1179      */
    1180     protected boolean isHeldExclusively() {
    1181         throw new UnsupportedOperationException();
    1182     }
    1183 
    1184     /**
    1185      * Acquires in exclusive mode, ignoring interrupts.  Implemented
    1186      * by invoking at least once {@link #tryAcquire},
    1187      * returning on success.  Otherwise the thread is queued, possibly
    1188      * repeatedly blocking and unblocking, invoking {@link
    1189      * #tryAcquire} until success.  This method can be used
    1190      * to implement method {@link Lock#lock}.
    1191      *
    1192      * @param arg the acquire argument.  This value is conveyed to
    1193      *        {@link #tryAcquire} but is otherwise uninterpreted and
    1194      *        can represent anything you like.
    1195      */
    1196     public final void acquire(int arg) {
    1197         if (!tryAcquire(arg) &&
    1198             acquireQueued(addWaiter(Node.EXCLUSIVE), arg))
    1199             selfInterrupt();
    1200     }
    1201 
    1202     /**
    1203      * Acquires in exclusive mode, aborting if interrupted.
    1204      * Implemented by first checking interrupt status, then invoking
    1205      * at least once {@link #tryAcquire}, returning on
    1206      * success.  Otherwise the thread is queued, possibly repeatedly
    1207      * blocking and unblocking, invoking {@link #tryAcquire}
    1208      * until success or the thread is interrupted.  This method can be
    1209      * used to implement method {@link Lock#lockInterruptibly}.
    1210      *
    1211      * @param arg the acquire argument.  This value is conveyed to
    1212      *        {@link #tryAcquire} but is otherwise uninterpreted and
    1213      *        can represent anything you like.
    1214      * @throws InterruptedException if the current thread is interrupted
    1215      */
    1216     public final void acquireInterruptibly(int arg)
    1217             throws InterruptedException {
    1218         if (Thread.interrupted())
    1219             throw new InterruptedException();
    1220         if (!tryAcquire(arg))
    1221             doAcquireInterruptibly(arg);
    1222     }
    1223 
    1224     /**
    1225      * Attempts to acquire in exclusive mode, aborting if interrupted,
    1226      * and failing if the given timeout elapses.  Implemented by first
    1227      * checking interrupt status, then invoking at least once {@link
    1228      * #tryAcquire}, returning on success.  Otherwise, the thread is
    1229      * queued, possibly repeatedly blocking and unblocking, invoking
    1230      * {@link #tryAcquire} until success or the thread is interrupted
    1231      * or the timeout elapses.  This method can be used to implement
    1232      * method {@link Lock#tryLock(long, TimeUnit)}.
    1233      *
    1234      * @param arg the acquire argument.  This value is conveyed to
    1235      *        {@link #tryAcquire} but is otherwise uninterpreted and
    1236      *        can represent anything you like.
    1237      * @param nanosTimeout the maximum number of nanoseconds to wait
    1238      * @return {@code true} if acquired; {@code false} if timed out
    1239      * @throws InterruptedException if the current thread is interrupted
    1240      */
    1241     public final boolean tryAcquireNanos(int arg, long nanosTimeout)
    1242             throws InterruptedException {
    1243         if (Thread.interrupted())
    1244             throw new InterruptedException();
    1245         return tryAcquire(arg) ||
    1246             doAcquireNanos(arg, nanosTimeout);
    1247     }
    1248 
    1249     /**
    1250      * Releases in exclusive mode.  Implemented by unblocking one or
    1251      * more threads if {@link #tryRelease} returns true.
    1252      * This method can be used to implement method {@link Lock#unlock}.
    1253      *
    1254      * @param arg the release argument.  This value is conveyed to
    1255      *        {@link #tryRelease} but is otherwise uninterpreted and
    1256      *        can represent anything you like.
    1257      * @return the value returned from {@link #tryRelease}
    1258      */
    1259     public final boolean release(int arg) {
    1260         if (tryRelease(arg)) {
    1261             Node h = head;
    1262             if (h != null && h.waitStatus != 0)
    1263                 unparkSuccessor(h);
    1264             return true;
    1265         }
    1266         return false;
    1267     }
    1268 
    1269     /**
    1270      * Acquires in shared mode, ignoring interrupts.  Implemented by
    1271      * first invoking at least once {@link #tryAcquireShared},
    1272      * returning on success.  Otherwise the thread is queued, possibly
    1273      * repeatedly blocking and unblocking, invoking {@link
    1274      * #tryAcquireShared} until success.
    1275      *
    1276      * @param arg the acquire argument.  This value is conveyed to
    1277      *        {@link #tryAcquireShared} but is otherwise uninterpreted
    1278      *        and can represent anything you like.
    1279      */
    1280     public final void acquireShared(int arg) {
    1281         if (tryAcquireShared(arg) < 0)
    1282             doAcquireShared(arg);
    1283     }
    1284 
    1285     /**
    1286      * Acquires in shared mode, aborting if interrupted.  Implemented
    1287      * by first checking interrupt status, then invoking at least once
    1288      * {@link #tryAcquireShared}, returning on success.  Otherwise the
    1289      * thread is queued, possibly repeatedly blocking and unblocking,
    1290      * invoking {@link #tryAcquireShared} until success or the thread
    1291      * is interrupted.
    1292      * @param arg the acquire argument
    1293      * This value is conveyed to {@link #tryAcquireShared} but is
    1294      * otherwise uninterpreted and can represent anything
    1295      * you like.
    1296      * @throws InterruptedException if the current thread is interrupted
    1297      */
    1298     public final void acquireSharedInterruptibly(int arg)
    1299             throws InterruptedException {
    1300         if (Thread.interrupted())
    1301             throw new InterruptedException();
    1302         if (tryAcquireShared(arg) < 0)
    1303             doAcquireSharedInterruptibly(arg);
    1304     }
    1305 
    1306     /**
    1307      * Attempts to acquire in shared mode, aborting if interrupted, and
    1308      * failing if the given timeout elapses.  Implemented by first
    1309      * checking interrupt status, then invoking at least once {@link
    1310      * #tryAcquireShared}, returning on success.  Otherwise, the
    1311      * thread is queued, possibly repeatedly blocking and unblocking,
    1312      * invoking {@link #tryAcquireShared} until success or the thread
    1313      * is interrupted or the timeout elapses.
    1314      *
    1315      * @param arg the acquire argument.  This value is conveyed to
    1316      *        {@link #tryAcquireShared} but is otherwise uninterpreted
    1317      *        and can represent anything you like.
    1318      * @param nanosTimeout the maximum number of nanoseconds to wait
    1319      * @return {@code true} if acquired; {@code false} if timed out
    1320      * @throws InterruptedException if the current thread is interrupted
    1321      */
    1322     public final boolean tryAcquireSharedNanos(int arg, long nanosTimeout)
    1323             throws InterruptedException {
    1324         if (Thread.interrupted())
    1325             throw new InterruptedException();
    1326         return tryAcquireShared(arg) >= 0 ||
    1327             doAcquireSharedNanos(arg, nanosTimeout);
    1328     }
    1329 
    1330     /**
    1331      * Releases in shared mode.  Implemented by unblocking one or more
    1332      * threads if {@link #tryReleaseShared} returns true.
    1333      *
    1334      * @param arg the release argument.  This value is conveyed to
    1335      *        {@link #tryReleaseShared} but is otherwise uninterpreted
    1336      *        and can represent anything you like.
    1337      * @return the value returned from {@link #tryReleaseShared}
    1338      */
    1339     public final boolean releaseShared(int arg) {
    1340         if (tryReleaseShared(arg)) {
    1341             doReleaseShared();
    1342             return true;
    1343         }
    1344         return false;
    1345     }
    1346 
    1347     // Queue inspection methods
    1348 
    1349     /**
    1350      * Queries whether any threads are waiting to acquire. Note that
    1351      * because cancellations due to interrupts and timeouts may occur
    1352      * at any time, a {@code true} return does not guarantee that any
    1353      * other thread will ever acquire.
    1354      *
    1355      * <p>In this implementation, this operation returns in
    1356      * constant time.
    1357      *
    1358      * @return {@code true} if there may be other threads waiting to acquire
    1359      */
    1360     public final boolean hasQueuedThreads() {
    1361         return head != tail;
    1362     }
    1363 
    1364     /**
    1365      * Queries whether any threads have ever contended to acquire this
    1366      * synchronizer; that is if an acquire method has ever blocked.
    1367      *
    1368      * <p>In this implementation, this operation returns in
    1369      * constant time.
    1370      *
    1371      * @return {@code true} if there has ever been contention
    1372      */
    1373     public final boolean hasContended() {
    1374         return head != null;
    1375     }
    1376 
    1377     /**
    1378      * Returns the first (longest-waiting) thread in the queue, or
    1379      * {@code null} if no threads are currently queued.
    1380      *
    1381      * <p>In this implementation, this operation normally returns in
    1382      * constant time, but may iterate upon contention if other threads are
    1383      * concurrently modifying the queue.
    1384      *
    1385      * @return the first (longest-waiting) thread in the queue, or
    1386      *         {@code null} if no threads are currently queued
    1387      */
    1388     public final Thread getFirstQueuedThread() {
    1389         // handle only fast path, else relay
    1390         return (head == tail) ? null : fullGetFirstQueuedThread();
    1391     }
    1392 
    1393     /**
    1394      * Version of getFirstQueuedThread called when fastpath fails
    1395      */
    1396     private Thread fullGetFirstQueuedThread() {
    1397         /*
    1398          * The first node is normally head.next. Try to get its
    1399          * thread field, ensuring consistent reads: If thread
    1400          * field is nulled out or s.prev is no longer head, then
    1401          * some other thread(s) concurrently performed setHead in
    1402          * between some of our reads. We try this twice before
    1403          * resorting to traversal.
    1404          */
    1405         Node h, s;
    1406         Thread st;
    1407         if (((h = head) != null && (s = h.next) != null &&
    1408              s.prev == head && (st = s.thread) != null) ||
    1409             ((h = head) != null && (s = h.next) != null &&
    1410              s.prev == head && (st = s.thread) != null))
    1411             return st;
    1412 
    1413         /*
    1414          * Head's next field might not have been set yet, or may have
    1415          * been unset after setHead. So we must check to see if tail
    1416          * is actually first node. If not, we continue on, safely
    1417          * traversing from tail back to head to find first,
    1418          * guaranteeing termination.
    1419          */
    1420 
    1421         Node t = tail;
    1422         Thread firstThread = null;
    1423         while (t != null && t != head) {
    1424             Thread tt = t.thread;
    1425             if (tt != null)
    1426                 firstThread = tt;
    1427             t = t.prev;
    1428         }
    1429         return firstThread;
    1430     }
    1431 
    1432     /**
    1433      * Returns true if the given thread is currently queued.
    1434      *
    1435      * <p>This implementation traverses the queue to determine
    1436      * presence of the given thread.
    1437      *
    1438      * @param thread the thread
    1439      * @return {@code true} if the given thread is on the queue
    1440      * @throws NullPointerException if the thread is null
    1441      */
    1442     public final boolean isQueued(Thread thread) {
    1443         if (thread == null)
    1444             throw new NullPointerException();
    1445         for (Node p = tail; p != null; p = p.prev)
    1446             if (p.thread == thread)
    1447                 return true;
    1448         return false;
    1449     }
    1450 
    1451     /**
    1452      * Returns {@code true} if the apparent first queued thread, if one
    1453      * exists, is waiting in exclusive mode.  If this method returns
    1454      * {@code true}, and the current thread is attempting to acquire in
    1455      * shared mode (that is, this method is invoked from {@link
    1456      * #tryAcquireShared}) then it is guaranteed that the current thread
    1457      * is not the first queued thread.  Used only as a heuristic in
    1458      * ReentrantReadWriteLock.
    1459      */
    1460     final boolean apparentlyFirstQueuedIsExclusive() {
    1461         Node h, s;
    1462         return (h = head) != null &&
    1463             (s = h.next)  != null &&
    1464             !s.isShared()         &&
    1465             s.thread != null;
    1466     }
    1467 
    1468     /**
    1469      * Queries whether any threads have been waiting to acquire longer
    1470      * than the current thread.
    1471      *
    1472      * <p>An invocation of this method is equivalent to (but may be
    1473      * more efficient than):
    1474      *  <pre> {@code
    1475      * getFirstQueuedThread() != Thread.currentThread() &&
    1476      * hasQueuedThreads()}</pre>
    1477      *
    1478      * <p>Note that because cancellations due to interrupts and
    1479      * timeouts may occur at any time, a {@code true} return does not
    1480      * guarantee that some other thread will acquire before the current
    1481      * thread.  Likewise, it is possible for another thread to win a
    1482      * race to enqueue after this method has returned {@code false},
    1483      * due to the queue being empty.
    1484      *
    1485      * <p>This method is designed to be used by a fair synchronizer to
    1486      * avoid <a href="AbstractQueuedSynchronizer#barging">barging</a>.
    1487      * Such a synchronizer's {@link #tryAcquire} method should return
    1488      * {@code false}, and its {@link #tryAcquireShared} method should
    1489      * return a negative value, if this method returns {@code true}
    1490      * (unless this is a reentrant acquire).  For example, the {@code
    1491      * tryAcquire} method for a fair, reentrant, exclusive mode
    1492      * synchronizer might look like this:
    1493      *
    1494      *  <pre> {@code
    1495      * protected boolean tryAcquire(int arg) {
    1496      *   if (isHeldExclusively()) {
    1497      *     // A reentrant acquire; increment hold count
    1498      *     return true;
    1499      *   } else if (hasQueuedPredecessors()) {
    1500      *     return false;
    1501      *   } else {
    1502      *     // try to acquire normally
    1503      *   }
    1504      * }}</pre>
    1505      *
    1506      * @return {@code true} if there is a queued thread preceding the
    1507      *         current thread, and {@code false} if the current thread
    1508      *         is at the head of the queue or the queue is empty
    1509      * @since 1.7
    1510      */
    1511     public final boolean hasQueuedPredecessors() {
    1512         // The correctness of this depends on head being initialized
    1513         // before tail and on head.next being accurate if the current
    1514         // thread is first in queue.
    1515         Node t = tail; // Read fields in reverse initialization order
    1516         Node h = head;
    1517         Node s;
    1518         return h != t &&
    1519             ((s = h.next) == null || s.thread != Thread.currentThread());
    1520     }
    1521 
    1522 
    1523     // Instrumentation and monitoring methods
    1524 
    1525     /**
    1526      * Returns an estimate of the number of threads waiting to
    1527      * acquire.  The value is only an estimate because the number of
    1528      * threads may change dynamically while this method traverses
    1529      * internal data structures.  This method is designed for use in
    1530      * monitoring system state, not for synchronization
    1531      * control.
    1532      *
    1533      * @return the estimated number of threads waiting to acquire
    1534      */
    1535     public final int getQueueLength() {
    1536         int n = 0;
    1537         for (Node p = tail; p != null; p = p.prev) {
    1538             if (p.thread != null)
    1539                 ++n;
    1540         }
    1541         return n;
    1542     }
    1543 
    1544     /**
    1545      * Returns a collection containing threads that may be waiting to
    1546      * acquire.  Because the actual set of threads may change
    1547      * dynamically while constructing this result, the returned
    1548      * collection is only a best-effort estimate.  The elements of the
    1549      * returned collection are in no particular order.  This method is
    1550      * designed to facilitate construction of subclasses that provide
    1551      * more extensive monitoring facilities.
    1552      *
    1553      * @return the collection of threads
    1554      */
    1555     public final Collection<Thread> getQueuedThreads() {
    1556         ArrayList<Thread> list = new ArrayList<Thread>();
    1557         for (Node p = tail; p != null; p = p.prev) {
    1558             Thread t = p.thread;
    1559             if (t != null)
    1560                 list.add(t);
    1561         }
    1562         return list;
    1563     }
    1564 
    1565     /**
    1566      * Returns a collection containing threads that may be waiting to
    1567      * acquire in exclusive mode. This has the same properties
    1568      * as {@link #getQueuedThreads} except that it only returns
    1569      * those threads waiting due to an exclusive acquire.
    1570      *
    1571      * @return the collection of threads
    1572      */
    1573     public final Collection<Thread> getExclusiveQueuedThreads() {
    1574         ArrayList<Thread> list = new ArrayList<Thread>();
    1575         for (Node p = tail; p != null; p = p.prev) {
    1576             if (!p.isShared()) {
    1577                 Thread t = p.thread;
    1578                 if (t != null)
    1579                     list.add(t);
    1580             }
    1581         }
    1582         return list;
    1583     }
    1584 
    1585     /**
    1586      * Returns a collection containing threads that may be waiting to
    1587      * acquire in shared mode. This has the same properties
    1588      * as {@link #getQueuedThreads} except that it only returns
    1589      * those threads waiting due to a shared acquire.
    1590      *
    1591      * @return the collection of threads
    1592      */
    1593     public final Collection<Thread> getSharedQueuedThreads() {
    1594         ArrayList<Thread> list = new ArrayList<Thread>();
    1595         for (Node p = tail; p != null; p = p.prev) {
    1596             if (p.isShared()) {
    1597                 Thread t = p.thread;
    1598                 if (t != null)
    1599                     list.add(t);
    1600             }
    1601         }
    1602         return list;
    1603     }
    1604 
    1605     /**
    1606      * Returns a string identifying this synchronizer, as well as its state.
    1607      * The state, in brackets, includes the String {@code "State ="}
    1608      * followed by the current value of {@link #getState}, and either
    1609      * {@code "nonempty"} or {@code "empty"} depending on whether the
    1610      * queue is empty.
    1611      *
    1612      * @return a string identifying this synchronizer, as well as its state
    1613      */
    1614     public String toString() {
    1615         int s = getState();
    1616         String q  = hasQueuedThreads() ? "non" : "";
    1617         return super.toString() +
    1618             "[State = " + s + ", " + q + "empty queue]";
    1619     }
    1620 
    1621 
    1622     // Internal support methods for Conditions
    1623 
    1624     /**
    1625      * Returns true if a node, always one that was initially placed on
    1626      * a condition queue, is now waiting to reacquire on sync queue.
    1627      * @param node the node
    1628      * @return true if is reacquiring
    1629      */
    1630     final boolean isOnSyncQueue(Node node) {
    1631         if (node.waitStatus == Node.CONDITION || node.prev == null)
    1632             return false;
    1633         if (node.next != null) // If has successor, it must be on queue
    1634             return true;
    1635         /*
    1636          * node.prev can be non-null, but not yet on queue because
    1637          * the CAS to place it on queue can fail. So we have to
    1638          * traverse from tail to make sure it actually made it.  It
    1639          * will always be near the tail in calls to this method, and
    1640          * unless the CAS failed (which is unlikely), it will be
    1641          * there, so we hardly ever traverse much.
    1642          */
    1643         return findNodeFromTail(node);
    1644     }
    1645 
    1646     /**
    1647      * Returns true if node is on sync queue by searching backwards from tail.
    1648      * Called only when needed by isOnSyncQueue.
    1649      * @return true if present
    1650      */
    1651     private boolean findNodeFromTail(Node node) {
    1652         Node t = tail;
    1653         for (;;) {
    1654             if (t == node)
    1655                 return true;
    1656             if (t == null)
    1657                 return false;
    1658             t = t.prev;
    1659         }
    1660     }
    1661 
    1662     /**
    1663      * Transfers a node from a condition queue onto sync queue.
    1664      * Returns true if successful.
    1665      * @param node the node
    1666      * @return true if successfully transferred (else the node was
    1667      * cancelled before signal).
    1668      */
    1669     final boolean transferForSignal(Node node) {
    1670         /*
    1671          * If cannot change waitStatus, the node has been cancelled.
    1672          */
    1673         if (!compareAndSetWaitStatus(node, Node.CONDITION, 0))
    1674             return false;
    1675 
    1676         /*
    1677          * Splice onto queue and try to set waitStatus of predecessor to
    1678          * indicate that thread is (probably) waiting. If cancelled or
    1679          * attempt to set waitStatus fails, wake up to resync (in which
    1680          * case the waitStatus can be transiently and harmlessly wrong).
    1681          */
    1682         Node p = enq(node);
    1683         int ws = p.waitStatus;
    1684         if (ws > 0 || !compareAndSetWaitStatus(p, ws, Node.SIGNAL))
    1685             LockSupport.unpark(node.thread);
    1686         return true;
    1687     }
    1688 
    1689     /**
    1690      * Transfers node, if necessary, to sync queue after a cancelled
    1691      * wait. Returns true if thread was cancelled before being
    1692      * signalled.
    1693      * @param current the waiting thread
    1694      * @param node its node
    1695      * @return true if cancelled before the node was signalled
    1696      */
    1697     final boolean transferAfterCancelledWait(Node node) {
    1698         if (compareAndSetWaitStatus(node, Node.CONDITION, 0)) {
    1699             enq(node);
    1700             return true;
    1701         }
    1702         /*
    1703          * If we lost out to a signal(), then we can't proceed
    1704          * until it finishes its enq().  Cancelling during an
    1705          * incomplete transfer is both rare and transient, so just
    1706          * spin.
    1707          */
    1708         while (!isOnSyncQueue(node))
    1709             Thread.yield();
    1710         return false;
    1711     }
    1712 
    1713     /**
    1714      * Invokes release with current state value; returns saved state.
    1715      * Cancels node and throws exception on failure.
    1716      * @param node the condition node for this wait
    1717      * @return previous sync state
    1718      */
    1719     final int fullyRelease(Node node) {
    1720         boolean failed = true;
    1721         try {
    1722             int savedState = getState();
    1723             if (release(savedState)) {
    1724                 failed = false;
    1725                 return savedState;
    1726             } else {
    1727                 throw new IllegalMonitorStateException();
    1728             }
    1729         } finally {
    1730             if (failed)
    1731                 node.waitStatus = Node.CANCELLED;
    1732         }
    1733     }
    1734 
    1735     // Instrumentation methods for conditions
    1736 
    1737     /**
    1738      * Queries whether the given ConditionObject
    1739      * uses this synchronizer as its lock.
    1740      *
    1741      * @param condition the condition
    1742      * @return <tt>true</tt> if owned
    1743      * @throws NullPointerException if the condition is null
    1744      */
    1745     public final boolean owns(ConditionObject condition) {
    1746         if (condition == null)
    1747             throw new NullPointerException();
    1748         return condition.isOwnedBy(this);
    1749     }
    1750 
    1751     /**
    1752      * Queries whether any threads are waiting on the given condition
    1753      * associated with this synchronizer. Note that because timeouts
    1754      * and interrupts may occur at any time, a <tt>true</tt> return
    1755      * does not guarantee that a future <tt>signal</tt> will awaken
    1756      * any threads.  This method is designed primarily for use in
    1757      * monitoring of the system state.
    1758      *
    1759      * @param condition the condition
    1760      * @return <tt>true</tt> if there are any waiting threads
    1761      * @throws IllegalMonitorStateException if exclusive synchronization
    1762      *         is not held
    1763      * @throws IllegalArgumentException if the given condition is
    1764      *         not associated with this synchronizer
    1765      * @throws NullPointerException if the condition is null
    1766      */
    1767     public final boolean hasWaiters(ConditionObject condition) {
    1768         if (!owns(condition))
    1769             throw new IllegalArgumentException("Not owner");
    1770         return condition.hasWaiters();
    1771     }
    1772 
    1773     /**
    1774      * Returns an estimate of the number of threads waiting on the
    1775      * given condition associated with this synchronizer. Note that
    1776      * because timeouts and interrupts may occur at any time, the
    1777      * estimate serves only as an upper bound on the actual number of
    1778      * waiters.  This method is designed for use in monitoring of the
    1779      * system state, not for synchronization control.
    1780      *
    1781      * @param condition the condition
    1782      * @return the estimated number of waiting threads
    1783      * @throws IllegalMonitorStateException if exclusive synchronization
    1784      *         is not held
    1785      * @throws IllegalArgumentException if the given condition is
    1786      *         not associated with this synchronizer
    1787      * @throws NullPointerException if the condition is null
    1788      */
    1789     public final int getWaitQueueLength(ConditionObject condition) {
    1790         if (!owns(condition))
    1791             throw new IllegalArgumentException("Not owner");
    1792         return condition.getWaitQueueLength();
    1793     }
    1794 
    1795     /**
    1796      * Returns a collection containing those threads that may be
    1797      * waiting on the given condition associated with this
    1798      * synchronizer.  Because the actual set of threads may change
    1799      * dynamically while constructing this result, the returned
    1800      * collection is only a best-effort estimate. The elements of the
    1801      * returned collection are in no particular order.
    1802      *
    1803      * @param condition the condition
    1804      * @return the collection of threads
    1805      * @throws IllegalMonitorStateException if exclusive synchronization
    1806      *         is not held
    1807      * @throws IllegalArgumentException if the given condition is
    1808      *         not associated with this synchronizer
    1809      * @throws NullPointerException if the condition is null
    1810      */
    1811     public final Collection<Thread> getWaitingThreads(ConditionObject condition) {
    1812         if (!owns(condition))
    1813             throw new IllegalArgumentException("Not owner");
    1814         return condition.getWaitingThreads();
    1815     }
    1816 
    1817     /**
    1818      * Condition implementation for a {@link
    1819      * AbstractQueuedSynchronizer} serving as the basis of a {@link
    1820      * Lock} implementation.
    1821      *
    1822      * <p>Method documentation for this class describes mechanics,
    1823      * not behavioral specifications from the point of view of Lock
    1824      * and Condition users. Exported versions of this class will in
    1825      * general need to be accompanied by documentation describing
    1826      * condition semantics that rely on those of the associated
    1827      * <tt>AbstractQueuedSynchronizer</tt>.
    1828      *
    1829      * <p>This class is Serializable, but all fields are transient,
    1830      * so deserialized conditions have no waiters.
    1831      */
    1832     public class ConditionObject implements Condition, java.io.Serializable {
    1833         private static final long serialVersionUID = 1173984872572414699L;
    1834         /** First node of condition queue. */
    1835         private transient Node firstWaiter;
    1836         /** Last node of condition queue. */
    1837         private transient Node lastWaiter;
    1838 
    1839         /**
    1840          * Creates a new <tt>ConditionObject</tt> instance.
    1841          */
    1842         public ConditionObject() { }
    1843 
    1844         // Internal methods
    1845 
    1846         /**
    1847          * Adds a new waiter to wait queue.
    1848          * @return its new wait node
    1849          */
    1850         private Node addConditionWaiter() {
    1851             Node t = lastWaiter;
    1852             // If lastWaiter is cancelled, clean out.
    1853             if (t != null && t.waitStatus != Node.CONDITION) {
    1854                 unlinkCancelledWaiters();
    1855                 t = lastWaiter;
    1856             }
    1857             Node node = new Node(Thread.currentThread(), Node.CONDITION);
    1858             if (t == null)
    1859                 firstWaiter = node;
    1860             else
    1861                 t.nextWaiter = node;
    1862             lastWaiter = node;
    1863             return node;
    1864         }
    1865 
    1866         /**
    1867          * Removes and transfers nodes until hit non-cancelled one or
    1868          * null. Split out from signal in part to encourage compilers
    1869          * to inline the case of no waiters.
    1870          * @param first (non-null) the first node on condition queue
    1871          */
    1872         private void doSignal(Node first) {
    1873             do {
    1874                 if ( (firstWaiter = first.nextWaiter) == null)
    1875                     lastWaiter = null;
    1876                 first.nextWaiter = null;
    1877             } while (!transferForSignal(first) &&
    1878                      (first = firstWaiter) != null);
    1879         }
    1880 
    1881         /**
    1882          * Removes and transfers all nodes.
    1883          * @param first (non-null) the first node on condition queue
    1884          */
    1885         private void doSignalAll(Node first) {
    1886             lastWaiter = firstWaiter = null;
    1887             do {
    1888                 Node next = first.nextWaiter;
    1889                 first.nextWaiter = null;
    1890                 transferForSignal(first);
    1891                 first = next;
    1892             } while (first != null);
    1893         }
    1894 
    1895         /**
    1896          * Unlinks cancelled waiter nodes from condition queue.
    1897          * Called only while holding lock. This is called when
    1898          * cancellation occurred during condition wait, and upon
    1899          * insertion of a new waiter when lastWaiter is seen to have
    1900          * been cancelled. This method is needed to avoid garbage
    1901          * retention in the absence of signals. So even though it may
    1902          * require a full traversal, it comes into play only when
    1903          * timeouts or cancellations occur in the absence of
    1904          * signals. It traverses all nodes rather than stopping at a
    1905          * particular target to unlink all pointers to garbage nodes
    1906          * without requiring many re-traversals during cancellation
    1907          * storms.
    1908          */
    1909         private void unlinkCancelledWaiters() {
    1910             Node t = firstWaiter;
    1911             Node trail = null;
    1912             while (t != null) {
    1913                 Node next = t.nextWaiter;
    1914                 if (t.waitStatus != Node.CONDITION) {
    1915                     t.nextWaiter = null;
    1916                     if (trail == null)
    1917                         firstWaiter = next;
    1918                     else
    1919                         trail.nextWaiter = next;
    1920                     if (next == null)
    1921                         lastWaiter = trail;
    1922                 }
    1923                 else
    1924                     trail = t;
    1925                 t = next;
    1926             }
    1927         }
    1928 
    1929         // public methods
    1930 
    1931         /**
    1932          * Moves the longest-waiting thread, if one exists, from the
    1933          * wait queue for this condition to the wait queue for the
    1934          * owning lock.
    1935          *
    1936          * @throws IllegalMonitorStateException if {@link #isHeldExclusively}
    1937          *         returns {@code false}
    1938          */
    1939         public final void signal() {
    1940             if (!isHeldExclusively())
    1941                 throw new IllegalMonitorStateException();
    1942             Node first = firstWaiter;
    1943             if (first != null)
    1944                 doSignal(first);
    1945         }
    1946 
    1947         /**
    1948          * Moves all threads from the wait queue for this condition to
    1949          * the wait queue for the owning lock.
    1950          *
    1951          * @throws IllegalMonitorStateException if {@link #isHeldExclusively}
    1952          *         returns {@code false}
    1953          */
    1954         public final void signalAll() {
    1955             if (!isHeldExclusively())
    1956                 throw new IllegalMonitorStateException();
    1957             Node first = firstWaiter;
    1958             if (first != null)
    1959                 doSignalAll(first);
    1960         }
    1961 
    1962         /**
    1963          * Implements uninterruptible condition wait.
    1964          * <ol>
    1965          * <li> Save lock state returned by {@link #getState}.
    1966          * <li> Invoke {@link #release} with
    1967          *      saved state as argument, throwing
    1968          *      IllegalMonitorStateException if it fails.
    1969          * <li> Block until signalled.
    1970          * <li> Reacquire by invoking specialized version of
    1971          *      {@link #acquire} with saved state as argument.
    1972          * </ol>
    1973          */
    1974         public final void awaitUninterruptibly() {
    1975             Node node = addConditionWaiter();
    1976             int savedState = fullyRelease(node);
    1977             boolean interrupted = false;
    1978             while (!isOnSyncQueue(node)) {
    1979                 LockSupport.park(this);
    1980                 if (Thread.interrupted())
    1981                     interrupted = true;
    1982             }
    1983             if (acquireQueued(node, savedState) || interrupted)
    1984                 selfInterrupt();
    1985         }
    1986 
    1987         /*
    1988          * For interruptible waits, we need to track whether to throw
    1989          * InterruptedException, if interrupted while blocked on
    1990          * condition, versus reinterrupt current thread, if
    1991          * interrupted while blocked waiting to re-acquire.
    1992          */
    1993 
    1994         /** Mode meaning to reinterrupt on exit from wait */
    1995         private static final int REINTERRUPT =  1;
    1996         /** Mode meaning to throw InterruptedException on exit from wait */
    1997         private static final int THROW_IE    = -1;
    1998 
    1999         /**
    2000          * Checks for interrupt, returning THROW_IE if interrupted
    2001          * before signalled, REINTERRUPT if after signalled, or
    2002          * 0 if not interrupted.
    2003          */
    2004         private int checkInterruptWhileWaiting(Node node) {
    2005             return Thread.interrupted() ?
    2006                 (transferAfterCancelledWait(node) ? THROW_IE : REINTERRUPT) :
    2007                 0;
    2008         }
    2009 
    2010         /**
    2011          * Throws InterruptedException, reinterrupts current thread, or
    2012          * does nothing, depending on mode.
    2013          */
    2014         private void reportInterruptAfterWait(int interruptMode)
    2015             throws InterruptedException {
    2016             if (interruptMode == THROW_IE)
    2017                 throw new InterruptedException();
    2018             else if (interruptMode == REINTERRUPT)
    2019                 selfInterrupt();
    2020         }
    2021 
    2022         /**
    2023          * Implements interruptible condition wait.
    2024          * <ol>
    2025          * <li> If current thread is interrupted, throw InterruptedException.
    2026          * <li> Save lock state returned by {@link #getState}.
    2027          * <li> Invoke {@link #release} with
    2028          *      saved state as argument, throwing
    2029          *      IllegalMonitorStateException if it fails.
    2030          * <li> Block until signalled or interrupted.
    2031          * <li> Reacquire by invoking specialized version of
    2032          *      {@link #acquire} with saved state as argument.
    2033          * <li> If interrupted while blocked in step 4, throw InterruptedException.
    2034          * </ol>
    2035          */
    2036         public final void await() throws InterruptedException {
    2037             if (Thread.interrupted())
    2038                 throw new InterruptedException();
    2039             Node node = addConditionWaiter();
    2040             int savedState = fullyRelease(node);
    2041             int interruptMode = 0;
    2042             while (!isOnSyncQueue(node)) {
    2043                 LockSupport.park(this);
    2044                 if ((interruptMode = checkInterruptWhileWaiting(node)) != 0)
    2045                     break;
    2046             }
    2047             if (acquireQueued(node, savedState) && interruptMode != THROW_IE)
    2048                 interruptMode = REINTERRUPT;
    2049             if (node.nextWaiter != null) // clean up if cancelled
    2050                 unlinkCancelledWaiters();
    2051             if (interruptMode != 0)
    2052                 reportInterruptAfterWait(interruptMode);
    2053         }
    2054 
    2055         /**
    2056          * Implements timed condition wait.
    2057          * <ol>
    2058          * <li> If current thread is interrupted, throw InterruptedException.
    2059          * <li> Save lock state returned by {@link #getState}.
    2060          * <li> Invoke {@link #release} with
    2061          *      saved state as argument, throwing
    2062          *      IllegalMonitorStateException if it fails.
    2063          * <li> Block until signalled, interrupted, or timed out.
    2064          * <li> Reacquire by invoking specialized version of
    2065          *      {@link #acquire} with saved state as argument.
    2066          * <li> If interrupted while blocked in step 4, throw InterruptedException.
    2067          * </ol>
    2068          */
    2069         public final long awaitNanos(long nanosTimeout)
    2070                 throws InterruptedException {
    2071             if (Thread.interrupted())
    2072                 throw new InterruptedException();
    2073             Node node = addConditionWaiter();
    2074             int savedState = fullyRelease(node);
    2075             long lastTime = System.nanoTime();
    2076             int interruptMode = 0;
    2077             while (!isOnSyncQueue(node)) {
    2078                 if (nanosTimeout <= 0L) {
    2079                     transferAfterCancelledWait(node);
    2080                     break;
    2081                 }
    2082                 LockSupport.parkNanos(this, nanosTimeout);
    2083                 if ((interruptMode = checkInterruptWhileWaiting(node)) != 0)
    2084                     break;
    2085 
    2086                 long now = System.nanoTime();
    2087                 nanosTimeout -= now - lastTime;
    2088                 lastTime = now;
    2089             }
    2090             if (acquireQueued(node, savedState) && interruptMode != THROW_IE)
    2091                 interruptMode = REINTERRUPT;
    2092             if (node.nextWaiter != null)
    2093                 unlinkCancelledWaiters();
    2094             if (interruptMode != 0)
    2095                 reportInterruptAfterWait(interruptMode);
    2096             return nanosTimeout - (System.nanoTime() - lastTime);
    2097         }
    2098 
    2099         /**
    2100          * Implements absolute timed condition wait.
    2101          * <ol>
    2102          * <li> If current thread is interrupted, throw InterruptedException.
    2103          * <li> Save lock state returned by {@link #getState}.
    2104          * <li> Invoke {@link #release} with
    2105          *      saved state as argument, throwing
    2106          *      IllegalMonitorStateException if it fails.
    2107          * <li> Block until signalled, interrupted, or timed out.
    2108          * <li> Reacquire by invoking specialized version of
    2109          *      {@link #acquire} with saved state as argument.
    2110          * <li> If interrupted while blocked in step 4, throw InterruptedException.
    2111          * <li> If timed out while blocked in step 4, return false, else true.
    2112          * </ol>
    2113          */
    2114         public final boolean awaitUntil(Date deadline)
    2115                 throws InterruptedException {
    2116             if (deadline == null)
    2117                 throw new NullPointerException();
    2118             long abstime = deadline.getTime();
    2119             if (Thread.interrupted())
    2120                 throw new InterruptedException();
    2121             Node node = addConditionWaiter();
    2122             int savedState = fullyRelease(node);
    2123             boolean timedout = false;
    2124             int interruptMode = 0;
    2125             while (!isOnSyncQueue(node)) {
    2126                 if (System.currentTimeMillis() > abstime) {
    2127                     timedout = transferAfterCancelledWait(node);
    2128                     break;
    2129                 }
    2130                 LockSupport.parkUntil(this, abstime);
    2131                 if ((interruptMode = checkInterruptWhileWaiting(node)) != 0)
    2132                     break;
    2133             }
    2134             if (acquireQueued(node, savedState) && interruptMode != THROW_IE)
    2135                 interruptMode = REINTERRUPT;
    2136             if (node.nextWaiter != null)
    2137                 unlinkCancelledWaiters();
    2138             if (interruptMode != 0)
    2139                 reportInterruptAfterWait(interruptMode);
    2140             return !timedout;
    2141         }
    2142 
    2143         /**
    2144          * Implements timed condition wait.
    2145          * <ol>
    2146          * <li> If current thread is interrupted, throw InterruptedException.
    2147          * <li> Save lock state returned by {@link #getState}.
    2148          * <li> Invoke {@link #release} with
    2149          *      saved state as argument, throwing
    2150          *      IllegalMonitorStateException if it fails.
    2151          * <li> Block until signalled, interrupted, or timed out.
    2152          * <li> Reacquire by invoking specialized version of
    2153          *      {@link #acquire} with saved state as argument.
    2154          * <li> If interrupted while blocked in step 4, throw InterruptedException.
    2155          * <li> If timed out while blocked in step 4, return false, else true.
    2156          * </ol>
    2157          */
    2158         public final boolean await(long time, TimeUnit unit)
    2159                 throws InterruptedException {
    2160             if (unit == null)
    2161                 throw new NullPointerException();
    2162             long nanosTimeout = unit.toNanos(time);
    2163             if (Thread.interrupted())
    2164                 throw new InterruptedException();
    2165             Node node = addConditionWaiter();
    2166             int savedState = fullyRelease(node);
    2167             long lastTime = System.nanoTime();
    2168             boolean timedout = false;
    2169             int interruptMode = 0;
    2170             while (!isOnSyncQueue(node)) {
    2171                 if (nanosTimeout <= 0L) {
    2172                     timedout = transferAfterCancelledWait(node);
    2173                     break;
    2174                 }
    2175                 if (nanosTimeout >= spinForTimeoutThreshold)
    2176                     LockSupport.parkNanos(this, nanosTimeout);
    2177                 if ((interruptMode = checkInterruptWhileWaiting(node)) != 0)
    2178                     break;
    2179                 long now = System.nanoTime();
    2180                 nanosTimeout -= now - lastTime;
    2181                 lastTime = now;
    2182             }
    2183             if (acquireQueued(node, savedState) && interruptMode != THROW_IE)
    2184                 interruptMode = REINTERRUPT;
    2185             if (node.nextWaiter != null)
    2186                 unlinkCancelledWaiters();
    2187             if (interruptMode != 0)
    2188                 reportInterruptAfterWait(interruptMode);
    2189             return !timedout;
    2190         }
    2191 
    2192         //  support for instrumentation
    2193 
    2194         /**
    2195          * Returns true if this condition was created by the given
    2196          * synchronization object.
    2197          *
    2198          * @return {@code true} if owned
    2199          */
    2200         final boolean isOwnedBy(AbstractQueuedSynchronizer sync) {
    2201             return sync == AbstractQueuedSynchronizer.this;
    2202         }
    2203 
    2204         /**
    2205          * Queries whether any threads are waiting on this condition.
    2206          * Implements {@link AbstractQueuedSynchronizer#hasWaiters}.
    2207          *
    2208          * @return {@code true} if there are any waiting threads
    2209          * @throws IllegalMonitorStateException if {@link #isHeldExclusively}
    2210          *         returns {@code false}
    2211          */
    2212         protected final boolean hasWaiters() {
    2213             if (!isHeldExclusively())
    2214                 throw new IllegalMonitorStateException();
    2215             for (Node w = firstWaiter; w != null; w = w.nextWaiter) {
    2216                 if (w.waitStatus == Node.CONDITION)
    2217                     return true;
    2218             }
    2219             return false;
    2220         }
    2221 
    2222         /**
    2223          * Returns an estimate of the number of threads waiting on
    2224          * this condition.
    2225          * Implements {@link AbstractQueuedSynchronizer#getWaitQueueLength}.
    2226          *
    2227          * @return the estimated number of waiting threads
    2228          * @throws IllegalMonitorStateException if {@link #isHeldExclusively}
    2229          *         returns {@code false}
    2230          */
    2231         protected final int getWaitQueueLength() {
    2232             if (!isHeldExclusively())
    2233                 throw new IllegalMonitorStateException();
    2234             int n = 0;
    2235             for (Node w = firstWaiter; w != null; w = w.nextWaiter) {
    2236                 if (w.waitStatus == Node.CONDITION)
    2237                     ++n;
    2238             }
    2239             return n;
    2240         }
    2241 
    2242         /**
    2243          * Returns a collection containing those threads that may be
    2244          * waiting on this Condition.
    2245          * Implements {@link AbstractQueuedSynchronizer#getWaitingThreads}.
    2246          *
    2247          * @return the collection of threads
    2248          * @throws IllegalMonitorStateException if {@link #isHeldExclusively}
    2249          *         returns {@code false}
    2250          */
    2251         protected final Collection<Thread> getWaitingThreads() {
    2252             if (!isHeldExclusively())
    2253                 throw new IllegalMonitorStateException();
    2254             ArrayList<Thread> list = new ArrayList<Thread>();
    2255             for (Node w = firstWaiter; w != null; w = w.nextWaiter) {
    2256                 if (w.waitStatus == Node.CONDITION) {
    2257                     Thread t = w.thread;
    2258                     if (t != null)
    2259                         list.add(t);
    2260                 }
    2261             }
    2262             return list;
    2263         }
    2264     }
    2265 
    2266     /**
    2267      * Setup to support compareAndSet. We need to natively implement
    2268      * this here: For the sake of permitting future enhancements, we
    2269      * cannot explicitly subclass AtomicInteger, which would be
    2270      * efficient and useful otherwise. So, as the lesser of evils, we
    2271      * natively implement using hotspot intrinsics API. And while we
    2272      * are at it, we do the same for other CASable fields (which could
    2273      * otherwise be done with atomic field updaters).
    2274      */
    2275     private static final Unsafe unsafe = Unsafe.getUnsafe();
    2276     private static final long stateOffset;
    2277     private static final long headOffset;
    2278     private static final long tailOffset;
    2279     private static final long waitStatusOffset;
    2280     private static final long nextOffset;
    2281 
    2282     static {
    2283         try {
    2284             stateOffset = unsafe.objectFieldOffset
    2285                 (AbstractQueuedSynchronizer.class.getDeclaredField("state"));
    2286             headOffset = unsafe.objectFieldOffset
    2287                 (AbstractQueuedSynchronizer.class.getDeclaredField("head"));
    2288             tailOffset = unsafe.objectFieldOffset
    2289                 (AbstractQueuedSynchronizer.class.getDeclaredField("tail"));
    2290             waitStatusOffset = unsafe.objectFieldOffset
    2291                 (Node.class.getDeclaredField("waitStatus"));
    2292             nextOffset = unsafe.objectFieldOffset
    2293                 (Node.class.getDeclaredField("next"));
    2294 
    2295         } catch (Exception ex) { throw new Error(ex); }
    2296     }
    2297 
    2298     /**
    2299      * CAS head field. Used only by enq.
    2300      */
    2301     private final boolean compareAndSetHead(Node update) {
    2302         return unsafe.compareAndSwapObject(this, headOffset, null, update);
    2303     }
    2304 
    2305     /**
    2306      * CAS tail field. Used only by enq.
    2307      */
    2308     private final boolean compareAndSetTail(Node expect, Node update) {
    2309         return unsafe.compareAndSwapObject(this, tailOffset, expect, update);
    2310     }
    2311 
    2312     /**
    2313      * CAS waitStatus field of a node.
    2314      */
    2315     private static final boolean compareAndSetWaitStatus(Node node,
    2316                                                          int expect,
    2317                                                          int update) {
    2318         return unsafe.compareAndSwapInt(node, waitStatusOffset,
    2319                                         expect, update);
    2320     }
    2321 
    2322     /**
    2323      * CAS next field of a node.
    2324      */
    2325     private static final boolean compareAndSetNext(Node node,
    2326                                                    Node expect,
    2327                                                    Node update) {
    2328         return unsafe.compareAndSwapObject(node, nextOffset, expect, update);
    2329     }
    2330 }
    View Code

    释放公平锁(基于JDK1.7.0_40)

    1. unlock()

    unlock()在ReentrantLock.java中实现的,源码如下:

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

    说明
    unlock()是解锁函数,它是通过AQS的release()函数来实现的。
    在这里,“1”的含义和“获取锁的函数acquire(1)的含义”一样,它是设置“释放锁的状态”的参数。由于“公平锁”是可重入的,所以对于同一个线程,每释放锁一次,锁的状态-1。

    关于AQS, ReentrantLock 和 sync的关系如下:

    public class ReentrantLock implements Lock, java.io.Serializable {
    
        private final Sync sync;
    
        abstract static class Sync extends AbstractQueuedSynchronizer {
            ...
        }
    
        ...
    }

    从中,我们发现:sync是ReentrantLock.java中的成员对象,而Sync是AQS的子类。

    2. release()

    release()在AQS中实现的,源码如下:

    public final boolean release(int arg) {
        if (tryRelease(arg)) {
            Node h = head;
            if (h != null && h.waitStatus != 0)
                unparkSuccessor(h);
            return true;
        }
        return false;
    }

    说明
    release()会先调用tryRelease()来尝试释放当前线程锁持有的锁。成功的话,则唤醒后继等待线程,并返回true。否则,直接返回false。

    3. tryRelease()

    tryRelease()在ReentrantLock.java的Sync类中实现,源码如下:

    protected final boolean tryRelease(int releases) {
        // c是本次释放锁之后的状态
        int c = getState() - releases;
        // 如果“当前线程”不是“锁的持有者”,则抛出异常!
        if (Thread.currentThread() != getExclusiveOwnerThread())
            throw new IllegalMonitorStateException();
    
        boolean free = false;
        // 如果“锁”已经被当前线程彻底释放,则设置“锁”的持有者为null,即锁是可获取状态。
        if (c == 0) {
            free = true;
            setExclusiveOwnerThread(null);
        }
        // 设置当前线程的锁的状态。
        setState(c);
        return free;
    }

    说明
    tryRelease()的作用是尝试释放锁。
    (01) 如果“当前线程”不是“锁的持有者”,则抛出异常。
    (02) 如果“当前线程”在本次释放锁操作之后,对锁的拥有状态是0(即,当前线程彻底释放该“锁”),则设置“锁”的持有者为null,即锁是可获取状态。同时,更新当前线程的锁的状态为0。
    getState(), setState()在前一章已经介绍过,这里不再说明。
    getExclusiveOwnerThread(), setExclusiveOwnerThread()在AQS的父类AbstractOwnableSynchronizer.java中定义,源码如下:

    public abstract class AbstractOwnableSynchronizer
        implements java.io.Serializable {
    
        // “锁”的持有线程
        private transient Thread exclusiveOwnerThread;
    
        // 设置“锁的持有线程”为t
        protected final void setExclusiveOwnerThread(Thread t) {
            exclusiveOwnerThread = t;
        }
    
        // 获取“锁的持有线程”
        protected final Thread getExclusiveOwnerThread() {
            return exclusiveOwnerThread;
        }
       
        ...
    }

    4. unparkSuccessor()

    在release()中“当前线程”释放锁成功的话,会唤醒当前线程的后继线程。
    根据CLH队列的FIFO规则,“当前线程”(即已经获取锁的线程)肯定是head;如果CLH队列非空的话,则唤醒锁的下一个等待线程。
    下面看看unparkSuccessor()的源码,它在AQS中实现。

    private void unparkSuccessor(Node node) {
        // 获取当前线程的状态
        int ws = node.waitStatus;
        // 如果状态<0,则设置状态=0
        if (ws < 0)
            compareAndSetWaitStatus(node, ws, 0);
    
        //获取当前节点的“有效的后继节点”,无效的话,则通过for循环进行获取。
        // 这里的有效,是指“后继节点对应的线程状态<=0”
        Node s = node.next;
        if (s == null || s.waitStatus > 0) {
            s = null;
            for (Node t = tail; t != null && t != node; t = t.prev)
                if (t.waitStatus <= 0)
                    s = t;
        }
        // 唤醒“后继节点对应的线程”
        if (s != null)
            LockSupport.unpark(s.thread);
    }

    说明
    unparkSuccessor()的作用是“唤醒当前线程的后继线程”。后继线程被唤醒之后,就可以获取该锁并恢复运行了。
    关于node.waitStatus的说明,请参考“上一章关于Node类的介绍”。

    总结

    “释放锁”的过程相对“获取锁”的过程比较简单。释放锁时,主要进行的操作,是更新当前线程对应的锁的状态。如果当前线程对锁已经彻底释放,则设置“锁”的持有线程为null,设置当前线程的状态为空,然后唤醒后继线程。


    更多内容

    1. Java多线程系列--“JUC锁”01之 框架 

    2. Java多线程系列--“JUC锁”02之 互斥锁ReentrantLock 

    3. Java多线程系列--“JUC锁”03之 公平锁(一) 

    4. Java多线程系列目录(共xx篇) 

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  • 原文地址:https://www.cnblogs.com/skywang12345/p/3496609.html
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