src/java.base/share/classes/java/lang/ref/Reference.java - platform/libcore - Gitiles

 /*
  * Copyright (c) 1997, 2017, Oracle and/or its affiliates. All rights reserved.
  * DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER.
  *
  * This code is free software; you can redistribute it and/or modify it
  * under the terms of the GNU General Public License version 2 only, as
  * published by the Free Software Foundation.  Oracle designates this
  * particular file as subject to the "Classpath" exception as provided
  * by Oracle in the LICENSE file that accompanied this code.
  *
  * This code is distributed in the hope that it will be useful, but WITHOUT
  * ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
  * FITNESS FOR A PARTICULAR PURPOSE.  See the GNU General Public License
  * version 2 for more details (a copy is included in the LICENSE file that
  * accompanied this code).
  *
  * You should have received a copy of the GNU General Public License version
  * 2 along with this work; if not, write to the Free Software Foundation,
  * Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA.
  *
  * Please contact Oracle, 500 Oracle Parkway, Redwood Shores, CA 94065 USA
  * or visit www.oracle.com if you need additional information or have any
  * questions.
  */

 package java.lang.ref;

 import jdk.internal.vm.annotation.DontInline;
 import jdk.internal.HotSpotIntrinsicCandidate;
 import jdk.internal.misc.JavaLangRefAccess;
 import jdk.internal.misc.SharedSecrets;
 import jdk.internal.ref.Cleaner;

 /**
  * Abstract base class for reference objects.  This class defines the
  * operations common to all reference objects.  Because reference objects are
  * implemented in close cooperation with the garbage collector, this class may
  * not be subclassed directly.
  *
  * @author   Mark Reinhold
  * @since    1.2
  */

 public abstract class Reference<T> {

     /* A Reference instance is in one of four possible internal states:
      *
      *     Active: Subject to special treatment by the garbage collector.  Some
      *     time after the collector detects that the reachability of the
      *     referent has changed to the appropriate state, it changes the
      *     instance's state to either Pending or Inactive, depending upon
      *     whether or not the instance was registered with a queue when it was
      *     created.  In the former case it also adds the instance to the
      *     pending-Reference list.  Newly-created instances are Active.
      *
      *     Pending: An element of the pending-Reference list, waiting to be
      *     enqueued by the Reference-handler thread.  Unregistered instances
      *     are never in this state.
      *
      *     Enqueued: An element of the queue with which the instance was
      *     registered when it was created.  When an instance is removed from
      *     its ReferenceQueue, it is made Inactive.  Unregistered instances are
      *     never in this state.
      *
      *     Inactive: Nothing more to do.  Once an instance becomes Inactive its
      *     state will never change again.
      *
      * The state is encoded in the queue and next fields as follows:
      *
      *     Active: queue = ReferenceQueue with which instance is registered, or
      *     ReferenceQueue.NULL if it was not registered with a queue; next =
      *     null.
      *
      *     Pending: queue = ReferenceQueue with which instance is registered;
      *     next = this
      *
      *     Enqueued: queue = ReferenceQueue.ENQUEUED; next = Following instance
      *     in queue, or this if at end of list.
      *
      *     Inactive: queue = ReferenceQueue.NULL; next = this.
      *
      * With this scheme the collector need only examine the next field in order
      * to determine whether a Reference instance requires special treatment: If
      * the next field is null then the instance is active; if it is non-null,
      * then the collector should treat the instance normally.
      *
      * To ensure that a concurrent collector can discover active Reference
      * objects without interfering with application threads that may apply
      * the enqueue() method to those objects, collectors should link
      * discovered objects through the discovered field. The discovered
      * field is also used for linking Reference objects in the pending list.
      */

     private T referent;         /* Treated specially by GC */

     volatile ReferenceQueue<? super T> queue;

     /* When active:   NULL
      *     pending:   this
      *    Enqueued:   next reference in queue (or this if last)
      *    Inactive:   this
      */
     @SuppressWarnings("rawtypes")
     volatile Reference next;

     /* When active:   next element in a discovered reference list maintained by GC (or this if last)
      *     pending:   next element in the pending list (or null if last)
      *   otherwise:   NULL
      */
     private transient Reference<T> discovered;  /* used by VM */


     /* High-priority thread to enqueue pending References
      */
     private static class ReferenceHandler extends Thread {

         private static void ensureClassInitialized(Class<?> clazz) {
             try {
                 Class.forName(clazz.getName(), true, clazz.getClassLoader());
             } catch (ClassNotFoundException e) {
                 throw (Error) new NoClassDefFoundError(e.getMessage()).initCause(e);
             }
         }

         static {
             // pre-load and initialize Cleaner class so that we don't
             // get into trouble later in the run loop if there's
             // memory shortage while loading/initializing it lazily.
             ensureClassInitialized(Cleaner.class);
         }

         ReferenceHandler(ThreadGroup g, String name) {
             super(g, null, name, 0, false);
         }

         public void run() {
             while (true) {
                 processPendingReferences();
             }
         }
     }

     /*
      * system property to disable clearing before enqueuing.
      */
     private static final class ClearBeforeEnqueue {
         static final boolean DISABLE =
             Boolean.getBoolean("jdk.lang.ref.disableClearBeforeEnqueue");
     }

     /*
      * Atomically get and clear (set to null) the VM's pending list.
      */
     private static native Reference<Object> getAndClearReferencePendingList();

     /*
      * Test whether the VM's pending list contains any entries.
      */
     private static native boolean hasReferencePendingList();

     /*
      * Wait until the VM's pending list may be non-null.
      */
     private static native void waitForReferencePendingList();

     private static final Object processPendingLock = new Object();
     private static boolean processPendingActive = false;

     private static void processPendingReferences() {
         // Only the singleton reference processing thread calls
         // waitForReferencePendingList() and getAndClearReferencePendingList().
         // These are separate operations to avoid a race with other threads
         // that are calling waitForReferenceProcessing().
         waitForReferencePendingList();
         Reference<Object> pendingList;
         synchronized (processPendingLock) {
             pendingList = getAndClearReferencePendingList();
             processPendingActive = true;
         }
         while (pendingList != null) {
             Reference<Object> ref = pendingList;
             pendingList = ref.discovered;
             ref.discovered = null;

             if (ref instanceof Cleaner) {
                 ((Cleaner)ref).clean();
                 // Notify any waiters that progress has been made.
                 // This improves latency for nio.Bits waiters, which
                 // are the only important ones.
                 synchronized (processPendingLock) {
                     processPendingLock.notifyAll();
                 }
             } else {
                 ReferenceQueue<? super Object> q = ref.queue;
                 if (q != ReferenceQueue.NULL) q.enqueue(ref);
             }
         }
         // Notify any waiters of completion of current round.
         synchronized (processPendingLock) {
             processPendingActive = false;
             processPendingLock.notifyAll();
         }
     }

     // Wait for progress in reference processing.
     //
     // Returns true after waiting (for notification from the reference
     // processing thread) if either (1) the VM has any pending
     // references, or (2) the reference processing thread is
     // processing references. Otherwise, returns false immediately.
     private static boolean waitForReferenceProcessing()
         throws InterruptedException
     {
         synchronized (processPendingLock) {
             if (processPendingActive || hasReferencePendingList()) {
                 // Wait for progress, not necessarily completion.
                 processPendingLock.wait();
                 return true;
             } else {
                 return false;
             }
         }
     }

     static {
         ThreadGroup tg = Thread.currentThread().getThreadGroup();
         for (ThreadGroup tgn = tg;
              tgn != null;
              tg = tgn, tgn = tg.getParent());
         Thread handler = new ReferenceHandler(tg, "Reference Handler");
         /* If there were a special system-only priority greater than
          * MAX_PRIORITY, it would be used here
          */
         handler.setPriority(Thread.MAX_PRIORITY);
         handler.setDaemon(true);
         handler.start();

         // provide access in SharedSecrets
         SharedSecrets.setJavaLangRefAccess(new JavaLangRefAccess() {
             @Override
             public boolean waitForReferenceProcessing()
                 throws InterruptedException
             {
                 return Reference.waitForReferenceProcessing();
             }
         });
     }

     /* -- Referent accessor and setters -- */

     /**
      * Returns this reference object's referent.  If this reference object has
      * been cleared, either by the program or by the garbage collector, then
      * this method returns <code>null</code>.
      *
      * @return   The object to which this reference refers, or
      *           <code>null</code> if this reference object has been cleared
      */
     @HotSpotIntrinsicCandidate
     public T get() {
         return this.referent;
     }

     /**
      * Clears this reference object.  Invoking this method will not cause this
      * object to be enqueued.
      *
      * <p> This method is invoked only by Java code; when the garbage collector
      * clears references it does so directly, without invoking this method.
      */
     public void clear() {
         this.referent = null;
     }

     /* -- Queue operations -- */

     /**
      * Tells whether or not this reference object has been enqueued, either by
      * the program or by the garbage collector.  If this reference object was
      * not registered with a queue when it was created, then this method will
      * always return <code>false</code>.
      *
      * @return   <code>true</code> if and only if this reference object has
      *           been enqueued
      */
     public boolean isEnqueued() {
         return (this.queue == ReferenceQueue.ENQUEUED);
     }

     /**
      * Clears this reference object and adds it to the queue with which
      * it is registered, if any.
      *
      * <p> This method is invoked only by Java code; when the garbage collector
      * enqueues references it does so directly, without invoking this method.
      *
      * @return   <code>true</code> if this reference object was successfully
      *           enqueued; <code>false</code> if it was already enqueued or if
      *           it was not registered with a queue when it was created
      */
     public boolean enqueue() {
         if (!ClearBeforeEnqueue.DISABLE)
             this.referent = null;
         return this.queue.enqueue(this);
     }

     /* -- Constructors -- */

     Reference(T referent) {
         this(referent, null);
     }

     Reference(T referent, ReferenceQueue<? super T> queue) {
         this.referent = referent;
         this.queue = (queue == null) ? ReferenceQueue.NULL : queue;
     }

     /**
      * Ensures that the object referenced by the given reference remains
      * <a href="package-summary.html#reachability"><em>strongly reachable</em></a>,
      * regardless of any prior actions of the program that might otherwise cause
      * the object to become unreachable; thus, the referenced object is not
      * reclaimable by garbage collection at least until after the invocation of
      * this method.  Invocation of this method does not itself initiate garbage
      * collection or finalization.
      *
      * <p> This method establishes an ordering for
      * <a href="package-summary.html#reachability"><em>strong reachability</em></a>
      * with respect to garbage collection.  It controls relations that are
      * otherwise only implicit in a program -- the reachability conditions
      * triggering garbage collection.  This method is designed for use in
      * uncommon situations of premature finalization where using
      * {@code synchronized} blocks or methods, or using other synchronization
      * facilities are not possible or do not provide the desired control.  This
      * method is applicable only when reclamation may have visible effects,
      * which is possible for objects with finalizers (See
      * <a href="https://docs.oracle.com/javase/specs/jls/se8/html/jls-12.html#jls-12.6">
      * Section 12.6 17 of <cite>The Java&trade; Language Specification</cite></a>)
      * that are implemented in ways that rely on ordering control for correctness.
      *
      * @apiNote
      * Finalization may occur whenever the virtual machine detects that no
      * reference to an object will ever be stored in the heap: The garbage
      * collector may reclaim an object even if the fields of that object are
      * still in use, so long as the object has otherwise become unreachable.
      * This may have surprising and undesirable effects in cases such as the
      * following example in which the bookkeeping associated with a class is
      * managed through array indices.  Here, method {@code action} uses a
      * {@code reachabilityFence} to ensure that the {@code Resource} object is
      * not reclaimed before bookkeeping on an associated
      * {@code ExternalResource} has been performed; in particular here, to
      * ensure that the array slot holding the {@code ExternalResource} is not
      * nulled out in method {@link Object#finalize}, which may otherwise run
      * concurrently.
      *
      * <pre> {@code
      * class Resource {
      *   private static ExternalResource[] externalResourceArray = ...
      *
      *   int myIndex;
      *   Resource(...) {
      *     myIndex = ...
      *     externalResourceArray[myIndex] = ...;
      *     ...
      *   }
      *   protected void finalize() {
      *     externalResourceArray[myIndex] = null;
      *     ...
      *   }
      *   public void action() {
      *     try {
      *       // ...
      *       int i = myIndex;
      *       Resource.update(externalResourceArray[i]);
      *     } finally {
      *       Reference.reachabilityFence(this);
      *     }
      *   }
      *   private static void update(ExternalResource ext) {
      *     ext.status = ...;
      *   }
      * }}</pre>
      *
      * Here, the invocation of {@code reachabilityFence} is nonintuitively
      * placed <em>after</em> the call to {@code update}, to ensure that the
      * array slot is not nulled out by {@link Object#finalize} before the
      * update, even if the call to {@code action} was the last use of this
      * object.  This might be the case if, for example a usage in a user program
      * had the form {@code new Resource().action();} which retains no other
      * reference to this {@code Resource}.  While probably overkill here,
      * {@code reachabilityFence} is placed in a {@code finally} block to ensure
      * that it is invoked across all paths in the method.  In a method with more
      * complex control paths, you might need further precautions to ensure that
      * {@code reachabilityFence} is encountered along all of them.
      *
      * <p> It is sometimes possible to better encapsulate use of
      * {@code reachabilityFence}.  Continuing the above example, if it were
      * acceptable for the call to method {@code update} to proceed even if the
      * finalizer had already executed (nulling out slot), then you could
      * localize use of {@code reachabilityFence}:
      *
      * <pre> {@code
      * public void action2() {
      *   // ...
      *   Resource.update(getExternalResource());
      * }
      * private ExternalResource getExternalResource() {
      *   ExternalResource ext = externalResourceArray[myIndex];
      *   Reference.reachabilityFence(this);
      *   return ext;
      * }}</pre>
      *
      * <p> Method {@code reachabilityFence} is not required in constructions
      * that themselves ensure reachability.  For example, because objects that
      * are locked cannot, in general, be reclaimed, it would suffice if all
      * accesses of the object, in all methods of class {@code Resource}
      * (including {@code finalize}) were enclosed in {@code synchronized (this)}
      * blocks.  (Further, such blocks must not include infinite loops, or
      * themselves be unreachable, which fall into the corner case exceptions to
      * the "in general" disclaimer.)  However, method {@code reachabilityFence}
      * remains a better option in cases where this approach is not as efficient,
      * desirable, or possible; for example because it would encounter deadlock.
      *
      * @param ref the reference. If {@code null}, this method has no effect.
      * @since 9
      */
     @DontInline
     public static void reachabilityFence(Object ref) {
         // Does nothing, because this method is annotated with @DontInline
         // HotSpot needs to retain the ref and not GC it before a call to this
         // method
     }
 }
	/*
	* Copyright (c) 1997, 2017, Oracle and/or its affiliates. All rights reserved.
	* DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER.
	*
	* This code is free software; you can redistribute it and/or modify it
	* under the terms of the GNU General Public License version 2 only, as
	* published by the Free Software Foundation. Oracle designates this
	* particular file as subject to the "Classpath" exception as provided
	* by Oracle in the LICENSE file that accompanied this code.
	*
	* This code is distributed in the hope that it will be useful, but WITHOUT
	* ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
	* FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
	* version 2 for more details (a copy is included in the LICENSE file that
	* accompanied this code).
	*
	* You should have received a copy of the GNU General Public License version
	* 2 along with this work; if not, write to the Free Software Foundation,
	* Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA.
	*
	* Please contact Oracle, 500 Oracle Parkway, Redwood Shores, CA 94065 USA
	* or visit www.oracle.com if you need additional information or have any
	* questions.
	*/

	package java.lang.ref;

	import jdk.internal.vm.annotation.DontInline;
	import jdk.internal.HotSpotIntrinsicCandidate;
	import jdk.internal.misc.JavaLangRefAccess;
	import jdk.internal.misc.SharedSecrets;
	import jdk.internal.ref.Cleaner;

	/**
	* Abstract base class for reference objects. This class defines the
	* operations common to all reference objects. Because reference objects are
	* implemented in close cooperation with the garbage collector, this class may
	* not be subclassed directly.
	*
	* @author Mark Reinhold
	* @since 1.2
	*/

	public abstract class Reference<T> {

	/* A Reference instance is in one of four possible internal states:
	*
	* Active: Subject to special treatment by the garbage collector. Some
	* time after the collector detects that the reachability of the
	* referent has changed to the appropriate state, it changes the
	* instance's state to either Pending or Inactive, depending upon
	* whether or not the instance was registered with a queue when it was
	* created. In the former case it also adds the instance to the
	* pending-Reference list. Newly-created instances are Active.
	*
	* Pending: An element of the pending-Reference list, waiting to be
	* enqueued by the Reference-handler thread. Unregistered instances
	* are never in this state.
	*
	* Enqueued: An element of the queue with which the instance was
	* registered when it was created. When an instance is removed from
	* its ReferenceQueue, it is made Inactive. Unregistered instances are
	* never in this state.
	*
	* Inactive: Nothing more to do. Once an instance becomes Inactive its
	* state will never change again.
	*
	* The state is encoded in the queue and next fields as follows:
	*
	* Active: queue = ReferenceQueue with which instance is registered, or
	* ReferenceQueue.NULL if it was not registered with a queue; next =
	* null.
	*
	* Pending: queue = ReferenceQueue with which instance is registered;
	* next = this
	*
	* Enqueued: queue = ReferenceQueue.ENQUEUED; next = Following instance
	* in queue, or this if at end of list.
	*
	* Inactive: queue = ReferenceQueue.NULL; next = this.
	*
	* With this scheme the collector need only examine the next field in order
	* to determine whether a Reference instance requires special treatment: If
	* the next field is null then the instance is active; if it is non-null,
	* then the collector should treat the instance normally.
	*
	* To ensure that a concurrent collector can discover active Reference
	* objects without interfering with application threads that may apply
	* the enqueue() method to those objects, collectors should link
	* discovered objects through the discovered field. The discovered
	* field is also used for linking Reference objects in the pending list.
	*/

	private T referent; /* Treated specially by GC */

	volatile ReferenceQueue<? super T> queue;

	/* When active: NULL
	* pending: this
	* Enqueued: next reference in queue (or this if last)
	* Inactive: this
	*/
	@SuppressWarnings("rawtypes")
	volatile Reference next;

	/* When active: next element in a discovered reference list maintained by GC (or this if last)
	* pending: next element in the pending list (or null if last)
	* otherwise: NULL
	*/
	private transient Reference<T> discovered; /* used by VM */


	/* High-priority thread to enqueue pending References
	*/
	private static class ReferenceHandler extends Thread {

	private static void ensureClassInitialized(Class<?> clazz) {
	try {
	Class.forName(clazz.getName(), true, clazz.getClassLoader());
	} catch (ClassNotFoundException e) {
	throw (Error) new NoClassDefFoundError(e.getMessage()).initCause(e);
	}
	}

	static {
	// pre-load and initialize Cleaner class so that we don't
	// get into trouble later in the run loop if there's
	// memory shortage while loading/initializing it lazily.
	ensureClassInitialized(Cleaner.class);
	}

	ReferenceHandler(ThreadGroup g, String name) {
	super(g, null, name, 0, false);
	}

	public void run() {
	while (true) {
	processPendingReferences();
	}
	}
	}

	/*
	* system property to disable clearing before enqueuing.
	*/
	private static final class ClearBeforeEnqueue {
	static final boolean DISABLE =
	Boolean.getBoolean("jdk.lang.ref.disableClearBeforeEnqueue");
	}

	/*
	* Atomically get and clear (set to null) the VM's pending list.
	*/
	private static native Reference<Object> getAndClearReferencePendingList();

	/*
	* Test whether the VM's pending list contains any entries.
	*/
	private static native boolean hasReferencePendingList();

	/*
	* Wait until the VM's pending list may be non-null.
	*/
	private static native void waitForReferencePendingList();

	private static final Object processPendingLock = new Object();
	private static boolean processPendingActive = false;

	private static void processPendingReferences() {
	// Only the singleton reference processing thread calls
	// waitForReferencePendingList() and getAndClearReferencePendingList().
	// These are separate operations to avoid a race with other threads
	// that are calling waitForReferenceProcessing().
	waitForReferencePendingList();
	Reference<Object> pendingList;
	synchronized (processPendingLock) {
	pendingList = getAndClearReferencePendingList();
	processPendingActive = true;
	}
	while (pendingList != null) {
	Reference<Object> ref = pendingList;
	pendingList = ref.discovered;
	ref.discovered = null;

	if (ref instanceof Cleaner) {
	((Cleaner)ref).clean();
	// Notify any waiters that progress has been made.
	// This improves latency for nio.Bits waiters, which
	// are the only important ones.
	synchronized (processPendingLock) {
	processPendingLock.notifyAll();
	}
	} else {
	ReferenceQueue<? super Object> q = ref.queue;
	if (q != ReferenceQueue.NULL) q.enqueue(ref);
	}
	}
	// Notify any waiters of completion of current round.
	synchronized (processPendingLock) {
	processPendingActive = false;
	processPendingLock.notifyAll();
	}
	}

	// Wait for progress in reference processing.
	//
	// Returns true after waiting (for notification from the reference
	// processing thread) if either (1) the VM has any pending
	// references, or (2) the reference processing thread is
	// processing references. Otherwise, returns false immediately.
	private static boolean waitForReferenceProcessing()
	throws InterruptedException
	{
	synchronized (processPendingLock) {
	if (processPendingActive \|\| hasReferencePendingList()) {
	// Wait for progress, not necessarily completion.
	processPendingLock.wait();
	return true;
	} else {
	return false;
	}
	}
	}

	static {
	ThreadGroup tg = Thread.currentThread().getThreadGroup();
	for (ThreadGroup tgn = tg;
	tgn != null;
	tg = tgn, tgn = tg.getParent());
	Thread handler = new ReferenceHandler(tg, "Reference Handler");
	/* If there were a special system-only priority greater than
	* MAX_PRIORITY, it would be used here
	*/
	handler.setPriority(Thread.MAX_PRIORITY);
	handler.setDaemon(true);
	handler.start();

	// provide access in SharedSecrets
	SharedSecrets.setJavaLangRefAccess(new JavaLangRefAccess() {
	@Override
	public boolean waitForReferenceProcessing()
	throws InterruptedException
	{
	return Reference.waitForReferenceProcessing();
	}
	});
	}

	/* -- Referent accessor and setters -- */

	/**
	* Returns this reference object's referent. If this reference object has
	* been cleared, either by the program or by the garbage collector, then
	* this method returns <code>null</code>.
	*
	* @return The object to which this reference refers, or
	* <code>null</code> if this reference object has been cleared
	*/
	@HotSpotIntrinsicCandidate
	public T get() {
	return this.referent;
	}

	/**
	* Clears this reference object. Invoking this method will not cause this
	* object to be enqueued.
	*
	* <p> This method is invoked only by Java code; when the garbage collector
	* clears references it does so directly, without invoking this method.
	*/
	public void clear() {
	this.referent = null;
	}

	/* -- Queue operations -- */

	/**
	* Tells whether or not this reference object has been enqueued, either by
	* the program or by the garbage collector. If this reference object was
	* not registered with a queue when it was created, then this method will
	* always return <code>false</code>.
	*
	* @return <code>true</code> if and only if this reference object has
	* been enqueued
	*/
	public boolean isEnqueued() {
	return (this.queue == ReferenceQueue.ENQUEUED);
	}

	/**
	* Clears this reference object and adds it to the queue with which
	* it is registered, if any.
	*
	* <p> This method is invoked only by Java code; when the garbage collector
	* enqueues references it does so directly, without invoking this method.
	*
	* @return <code>true</code> if this reference object was successfully
	* enqueued; <code>false</code> if it was already enqueued or if
	* it was not registered with a queue when it was created
	*/
	public boolean enqueue() {
	if (!ClearBeforeEnqueue.DISABLE)
	this.referent = null;
	return this.queue.enqueue(this);
	}

	/* -- Constructors -- */

	Reference(T referent) {
	this(referent, null);
	}

	Reference(T referent, ReferenceQueue<? super T> queue) {
	this.referent = referent;
	this.queue = (queue == null) ? ReferenceQueue.NULL : queue;
	}

	/**
	* Ensures that the object referenced by the given reference remains
	* <a href="package-summary.html#reachability"><em>strongly reachable</em></a>,
	* regardless of any prior actions of the program that might otherwise cause
	* the object to become unreachable; thus, the referenced object is not
	* reclaimable by garbage collection at least until after the invocation of
	* this method. Invocation of this method does not itself initiate garbage
	* collection or finalization.
	*
	* <p> This method establishes an ordering for
	* <a href="package-summary.html#reachability"><em>strong reachability</em></a>
	* with respect to garbage collection. It controls relations that are
	* otherwise only implicit in a program -- the reachability conditions
	* triggering garbage collection. This method is designed for use in
	* uncommon situations of premature finalization where using
	* {@code synchronized} blocks or methods, or using other synchronization
	* facilities are not possible or do not provide the desired control. This
	* method is applicable only when reclamation may have visible effects,
	* which is possible for objects with finalizers (See
	* <a href="https://docs.oracle.com/javase/specs/jls/se8/html/jls-12.html#jls-12.6">
	* Section 12.6 17 of <cite>The Java™ Language Specification</cite></a>)
	* that are implemented in ways that rely on ordering control for correctness.
	*
	* @apiNote
	* Finalization may occur whenever the virtual machine detects that no
	* reference to an object will ever be stored in the heap: The garbage
	* collector may reclaim an object even if the fields of that object are
	* still in use, so long as the object has otherwise become unreachable.
	* This may have surprising and undesirable effects in cases such as the
	* following example in which the bookkeeping associated with a class is
	* managed through array indices. Here, method {@code action} uses a
	* {@code reachabilityFence} to ensure that the {@code Resource} object is
	* not reclaimed before bookkeeping on an associated
	* {@code ExternalResource} has been performed; in particular here, to
	* ensure that the array slot holding the {@code ExternalResource} is not
	* nulled out in method {@link Object#finalize}, which may otherwise run
	* concurrently.
	*
	* <pre> {@code
	* class Resource {
	* private static ExternalResource[] externalResourceArray = ...
	*
	* int myIndex;
	* Resource(...) {
	* myIndex = ...
	* externalResourceArray[myIndex] = ...;
	* ...
	* }
	* protected void finalize() {
	* externalResourceArray[myIndex] = null;
	* ...
	* }
	* public void action() {
	* try {
	* // ...
	* int i = myIndex;
	* Resource.update(externalResourceArray[i]);
	* } finally {
	* Reference.reachabilityFence(this);
	* }
	* }
	* private static void update(ExternalResource ext) {
	* ext.status = ...;
	* }
	* }}</pre>
	*
	* Here, the invocation of {@code reachabilityFence} is nonintuitively
	* placed <em>after</em> the call to {@code update}, to ensure that the
	* array slot is not nulled out by {@link Object#finalize} before the
	* update, even if the call to {@code action} was the last use of this
	* object. This might be the case if, for example a usage in a user program
	* had the form {@code new Resource().action();} which retains no other
	* reference to this {@code Resource}. While probably overkill here,
	* {@code reachabilityFence} is placed in a {@code finally} block to ensure
	* that it is invoked across all paths in the method. In a method with more
	* complex control paths, you might need further precautions to ensure that
	* {@code reachabilityFence} is encountered along all of them.
	*
	* <p> It is sometimes possible to better encapsulate use of
	* {@code reachabilityFence}. Continuing the above example, if it were
	* acceptable for the call to method {@code update} to proceed even if the
	* finalizer had already executed (nulling out slot), then you could
	* localize use of {@code reachabilityFence}:
	*
	* <pre> {@code
	* public void action2() {
	* // ...
	* Resource.update(getExternalResource());
	* }
	* private ExternalResource getExternalResource() {
	* ExternalResource ext = externalResourceArray[myIndex];
	* Reference.reachabilityFence(this);
	* return ext;
	* }}</pre>
	*
	* <p> Method {@code reachabilityFence} is not required in constructions
	* that themselves ensure reachability. For example, because objects that
	* are locked cannot, in general, be reclaimed, it would suffice if all
	* accesses of the object, in all methods of class {@code Resource}
	* (including {@code finalize}) were enclosed in {@code synchronized (this)}
	* blocks. (Further, such blocks must not include infinite loops, or
	* themselves be unreachable, which fall into the corner case exceptions to
	* the "in general" disclaimer.) However, method {@code reachabilityFence}
	* remains a better option in cases where this approach is not as efficient,
	* desirable, or possible; for example because it would encounter deadlock.
	*
	* @param ref the reference. If {@code null}, this method has no effect.
	* @since 9
	*/
	@DontInline
	public static void reachabilityFence(Object ref) {
	// Does nothing, because this method is annotated with @DontInline
	// HotSpot needs to retain the ref and not GC it before a call to this
	// method
	}
	}