/*
* Written by Doug Lea with assistance from members of JCP JSR-166
* Expert Group and released to the public domain, as explained at
* http://creativecommons.org/licenses/publicdomain
*/
package jsr166y;
import java.util.concurrent.*;
import java.util.concurrent.locks.*;
import java.util.concurrent.atomic.*;
import java.util.*;
import java.io.*;
import sun.misc.Unsafe;
import java.lang.reflect.*;
/**
* An unbounded {@linkplain TransferQueue} based on linked nodes.
* This queue orders elements FIFO (first-in-first-out) with respect
* to any given producer. The head of the queue is that
* element that has been on the queue the longest time for some
* producer. The tail of the queue is that element that has
* been on the queue the shortest time for some producer.
*
* Beware that, unlike in most collections, the {@code size}
* method is NOT a constant-time operation. Because of the
* asynchronous nature of these queues, determining the current number
* of elements requires a traversal of the elements.
*
*
This class and its iterator implement all of the
* optional methods of the {@link Collection} and {@link
* Iterator} interfaces.
*
*
Memory consistency effects: As with other concurrent
* collections, actions in a thread prior to placing an object into a
* {@code LinkedTransferQueue}
* happen-before
This class is a member of the
*
* Java Collections Framework .
*
* @since 1.7
* @author Doug Lea
* @param the type of elements held in this collection
*/
public class LinkedTransferQueue extends AbstractQueue
implements TransferQueue, java.io.Serializable {
private static final long serialVersionUID = -3223113410248163686L;
/*
* This class extends the approach used in FIFO-mode
* SynchronousQueues. See the internal documentation, as well as
* the PPoPP 2006 paper "Scalable Synchronous Queues" by Scherer,
* Lea & Scott
* (http://www.cs.rice.edu/~wns1/papers/2006-PPoPP-SQ.pdf)
*
* The main extension is to provide different Wait modes for the
* main "xfer" method that puts or takes items. These don't
* impact the basic dual-queue logic, but instead control whether
* or how threads block upon insertion of request or data nodes
* into the dual queue. It also uses slightly different
* conventions for tracking whether nodes are off-list or
* cancelled.
*/
// Wait modes for xfer method
static final int NOWAIT = 0;
static final int TIMEOUT = 1;
static final int WAIT = 2;
/** The number of CPUs, for spin control */
static final int NCPUS = Runtime.getRuntime().availableProcessors();
/**
* The number of times to spin before blocking in timed waits.
* The value is empirically derived -- it works well across a
* variety of processors and OSes. Empirically, the best value
* seems not to vary with number of CPUs (beyond 2) so is just
* a constant.
*/
static final int maxTimedSpins = (NCPUS < 2) ? 0 : 32;
/**
* The number of times to spin before blocking in untimed waits.
* This is greater than timed value because untimed waits spin
* faster since they don't need to check times on each spin.
*/
static final int maxUntimedSpins = maxTimedSpins * 16;
/**
* The number of nanoseconds for which it is faster to spin
* rather than to use timed park. A rough estimate suffices.
*/
static final long spinForTimeoutThreshold = 1000L;
/**
* Node class for LinkedTransferQueue. Opportunistically
* subclasses from AtomicReference to represent item. Uses Object,
* not E, to allow setting item to "this" after use, to avoid
* garbage retention. Similarly, setting the next field to this is
* used as sentinel that node is off list.
*/
static final class QNode extends AtomicReference {
volatile QNode next;
volatile Thread waiter; // to control park/unpark
final boolean isData;
QNode(Object item, boolean isData) {
super(item);
this.isData = isData;
}
static final AtomicReferenceFieldUpdater
nextUpdater = AtomicReferenceFieldUpdater.newUpdater
(QNode.class, QNode.class, "next");
final boolean casNext(QNode cmp, QNode val) {
return nextUpdater.compareAndSet(this, cmp, val);
}
final void clearNext() {
nextUpdater.lazySet(this, this);
}
}
/**
* Padded version of AtomicReference used for head, tail and
* cleanMe, to alleviate contention across threads CASing one vs
* the other.
*/
static final class PaddedAtomicReference extends AtomicReference {
// enough padding for 64bytes with 4byte refs
Object p0, p1, p2, p3, p4, p5, p6, p7, p8, p9, pa, pb, pc, pd, pe;
PaddedAtomicReference(T r) { super(r); }
}
/** head of the queue */
private transient final PaddedAtomicReference head;
/** tail of the queue */
private transient final PaddedAtomicReference tail;
/**
* Reference to a cancelled node that might not yet have been
* unlinked from queue because it was the last inserted node
* when it cancelled.
*/
private transient final PaddedAtomicReference cleanMe;
/**
* Tries to cas nh as new head; if successful, unlink
* old head's next node to avoid garbage retention.
*/
private boolean advanceHead(QNode h, QNode nh) {
if (h == head.get() && head.compareAndSet(h, nh)) {
h.clearNext(); // forget old next
return true;
}
return false;
}
/**
* Puts or takes an item. Used for most queue operations (except
* poll() and tryTransfer()). See the similar code in
* SynchronousQueue for detailed explanation.
*
* @param e the item or if null, signifies that this is a take
* @param mode the wait mode: NOWAIT, TIMEOUT, WAIT
* @param nanos timeout in nanosecs, used only if mode is TIMEOUT
* @return an item, or null on failure
*/
private Object xfer(Object e, int mode, long nanos) {
boolean isData = (e != null);
QNode s = null;
final PaddedAtomicReference head = this.head;
final PaddedAtomicReference tail = this.tail;
for (;;) {
QNode t = tail.get();
QNode h = head.get();
if (t != null && (t == h || t.isData == isData)) {
if (s == null)
s = new QNode(e, isData);
QNode last = t.next;
if (last != null) {
if (t == tail.get())
tail.compareAndSet(t, last);
}
else if (t.casNext(null, s)) {
tail.compareAndSet(t, s);
return awaitFulfill(t, s, e, mode, nanos);
}
}
else if (h != null) {
QNode first = h.next;
if (t == tail.get() && first != null &&
advanceHead(h, first)) {
Object x = first.get();
if (x != first && first.compareAndSet(x, e)) {
LockSupport.unpark(first.waiter);
return isData ? e : x;
}
}
}
}
}
/**
* Version of xfer for poll() and tryTransfer, which
* simplifies control paths both here and in xfer.
*/
private Object fulfill(Object e) {
boolean isData = (e != null);
final PaddedAtomicReference head = this.head;
final PaddedAtomicReference tail = this.tail;
for (;;) {
QNode t = tail.get();
QNode h = head.get();
if (t != null && (t == h || t.isData == isData)) {
QNode last = t.next;
if (t == tail.get()) {
if (last != null)
tail.compareAndSet(t, last);
else
return null;
}
}
else if (h != null) {
QNode first = h.next;
if (t == tail.get() &&
first != null &&
advanceHead(h, first)) {
Object x = first.get();
if (x != first && first.compareAndSet(x, e)) {
LockSupport.unpark(first.waiter);
return isData ? e : x;
}
}
}
}
}
/**
* Spins/blocks until node s is fulfilled or caller gives up,
* depending on wait mode.
*
* @param pred the predecessor of waiting node
* @param s the waiting node
* @param e the comparison value for checking match
* @param mode mode
* @param nanos timeout value
* @return matched item, or s if cancelled
*/
private Object awaitFulfill(QNode pred, QNode s, Object e,
int mode, long nanos) {
if (mode == NOWAIT)
return null;
long lastTime = (mode == TIMEOUT) ? System.nanoTime() : 0;
Thread w = Thread.currentThread();
int spins = -1; // set to desired spin count below
for (;;) {
if (w.isInterrupted())
s.compareAndSet(e, s);
Object x = s.get();
if (x != e) { // Node was matched or cancelled
advanceHead(pred, s); // unlink if head
if (x == s) { // was cancelled
clean(pred, s);
return null;
}
else if (x != null) {
s.set(s); // avoid garbage retention
return x;
}
else
return e;
}
if (mode == TIMEOUT) {
long now = System.nanoTime();
nanos -= now - lastTime;
lastTime = now;
if (nanos <= 0) {
s.compareAndSet(e, s); // try to cancel
continue;
}
}
if (spins < 0) {
QNode h = head.get(); // only spin if at head
spins = ((h != null && h.next == s) ?
((mode == TIMEOUT) ?
maxTimedSpins : maxUntimedSpins) : 0);
}
if (spins > 0)
--spins;
else if (s.waiter == null)
s.waiter = w;
else if (mode != TIMEOUT) {
LockSupport.park(this);
s.waiter = null;
spins = -1;
}
else if (nanos > spinForTimeoutThreshold) {
LockSupport.parkNanos(this, nanos);
s.waiter = null;
spins = -1;
}
}
}
/**
* Returns validated tail for use in cleaning methods.
*/
private QNode getValidatedTail() {
for (;;) {
QNode h = head.get();
QNode first = h.next;
if (first != null && first.next == first) { // help advance
advanceHead(h, first);
continue;
}
QNode t = tail.get();
QNode last = t.next;
if (t == tail.get()) {
if (last != null)
tail.compareAndSet(t, last); // help advance
else
return t;
}
}
}
/**
* Gets rid of cancelled node s with original predecessor pred.
*
* @param pred predecessor of cancelled node
* @param s the cancelled node
*/
private void clean(QNode pred, QNode s) {
Thread w = s.waiter;
if (w != null) { // Wake up thread
s.waiter = null;
if (w != Thread.currentThread())
LockSupport.unpark(w);
}
if (pred == null)
return;
/*
* At any given time, exactly one node on list cannot be
* deleted -- the last inserted node. To accommodate this, if
* we cannot delete s, we save its predecessor as "cleanMe",
* processing the previously saved version first. At least one
* of node s or the node previously saved can always be
* processed, so this always terminates.
*/
while (pred.next == s) {
QNode oldpred = reclean(); // First, help get rid of cleanMe
QNode t = getValidatedTail();
if (s != t) { // If not tail, try to unsplice
QNode sn = s.next; // s.next == s means s already off list
if (sn == s || pred.casNext(s, sn))
break;
}
else if (oldpred == pred || // Already saved
(oldpred == null && cleanMe.compareAndSet(null, pred)))
break; // Postpone cleaning
}
}
/**
* Tries to unsplice the cancelled node held in cleanMe that was
* previously uncleanable because it was at tail.
*
* @return current cleanMe node (or null)
*/
private QNode reclean() {
/*
* cleanMe is, or at one time was, predecessor of cancelled
* node s that was the tail so could not be unspliced. If s
* is no longer the tail, try to unsplice if necessary and
* make cleanMe slot available. This differs from similar
* code in clean() because we must check that pred still
* points to a cancelled node that must be unspliced -- if
* not, we can (must) clear cleanMe without unsplicing.
* This can loop only due to contention on casNext or
* clearing cleanMe.
*/
QNode pred;
while ((pred = cleanMe.get()) != null) {
QNode t = getValidatedTail();
QNode s = pred.next;
if (s != t) {
QNode sn;
if (s == null || s == pred || s.get() != s ||
(sn = s.next) == s || pred.casNext(s, sn))
cleanMe.compareAndSet(pred, null);
}
else // s is still tail; cannot clean
break;
}
return pred;
}
/**
* Creates an initially empty {@code LinkedTransferQueue}.
*/
public LinkedTransferQueue() {
QNode dummy = new QNode(null, false);
head = new PaddedAtomicReference(dummy);
tail = new PaddedAtomicReference(dummy);
cleanMe = new PaddedAtomicReference(null);
}
/**
* Creates a {@code LinkedTransferQueue}
* initially containing the elements of the given collection,
* added in traversal order of the collection's iterator.
*
* @param c the collection of elements to initially contain
* @throws NullPointerException if the specified collection or any
* of its elements are null
*/
public LinkedTransferQueue(Collection c) {
this();
addAll(c);
}
public void put(E e) throws InterruptedException {
if (e == null) throw new NullPointerException();
if (Thread.interrupted()) throw new InterruptedException();
xfer(e, NOWAIT, 0);
}
public boolean offer(E e, long timeout, TimeUnit unit)
throws InterruptedException {
if (e == null) throw new NullPointerException();
if (Thread.interrupted()) throw new InterruptedException();
xfer(e, NOWAIT, 0);
return true;
}
public boolean offer(E e) {
if (e == null) throw new NullPointerException();
xfer(e, NOWAIT, 0);
return true;
}
public boolean add(E e) {
if (e == null) throw new NullPointerException();
xfer(e, NOWAIT, 0);
return true;
}
public void transfer(E e) throws InterruptedException {
if (e == null) throw new NullPointerException();
if (xfer(e, WAIT, 0) == null) {
Thread.interrupted();
throw new InterruptedException();
}
}
public boolean tryTransfer(E e, long timeout, TimeUnit unit)
throws InterruptedException {
if (e == null) throw new NullPointerException();
if (xfer(e, TIMEOUT, unit.toNanos(timeout)) != null)
return true;
if (!Thread.interrupted())
return false;
throw new InterruptedException();
}
public boolean tryTransfer(E e) {
if (e == null) throw new NullPointerException();
return fulfill(e) != null;
}
public E take() throws InterruptedException {
Object e = xfer(null, WAIT, 0);
if (e != null)
return (E) e;
Thread.interrupted();
throw new InterruptedException();
}
public E poll(long timeout, TimeUnit unit) throws InterruptedException {
Object e = xfer(null, TIMEOUT, unit.toNanos(timeout));
if (e != null || !Thread.interrupted())
return (E) e;
throw new InterruptedException();
}
public E poll() {
return (E) fulfill(null);
}
public int drainTo(Collection c) {
if (c == null)
throw new NullPointerException();
if (c == this)
throw new IllegalArgumentException();
int n = 0;
E e;
while ( (e = poll()) != null) {
c.add(e);
++n;
}
return n;
}
public int drainTo(Collection c, int maxElements) {
if (c == null)
throw new NullPointerException();
if (c == this)
throw new IllegalArgumentException();
int n = 0;
E e;
while (n < maxElements && (e = poll()) != null) {
c.add(e);
++n;
}
return n;
}
// Traversal-based methods
/**
* Returns head after performing any outstanding helping steps.
*/
private QNode traversalHead() {
for (;;) {
QNode t = tail.get();
QNode h = head.get();
if (h != null && t != null) {
QNode last = t.next;
QNode first = h.next;
if (t == tail.get()) {
if (last != null)
tail.compareAndSet(t, last);
else if (first != null) {
Object x = first.get();
if (x == first)
advanceHead(h, first);
else
return h;
}
else
return h;
}
}
reclean();
}
}
public Iterator iterator() {
return new Itr();
}
/**
* Iterators. Basic strategy is to traverse list, treating
* non-data (i.e., request) nodes as terminating list.
* Once a valid data node is found, the item is cached
* so that the next call to next() will return it even
* if subsequently removed.
*/
class Itr implements Iterator {
QNode next; // node to return next
QNode pnext; // predecessor of next
QNode snext; // successor of next
QNode curr; // last returned node, for remove()
QNode pcurr; // predecessor of curr, for remove()
E nextItem; // Cache of next item, once committed to in next
Itr() {
findNext();
}
/**
* Ensures next points to next valid node, or null if none.
*/
void findNext() {
for (;;) {
QNode pred = pnext;
QNode q = next;
if (pred == null || pred == q) {
pred = traversalHead();
q = pred.next;
}
if (q == null || !q.isData) {
next = null;
return;
}
Object x = q.get();
QNode s = q.next;
if (x != null && q != x && q != s) {
nextItem = (E) x;
snext = s;
pnext = pred;
next = q;
return;
}
pnext = q;
next = s;
}
}
public boolean hasNext() {
return next != null;
}
public E next() {
if (next == null) throw new NoSuchElementException();
pcurr = pnext;
curr = next;
pnext = next;
next = snext;
E x = nextItem;
findNext();
return x;
}
public void remove() {
QNode p = curr;
if (p == null)
throw new IllegalStateException();
Object x = p.get();
if (x != null && x != p && p.compareAndSet(x, p))
clean(pcurr, p);
}
}
public E peek() {
for (;;) {
QNode h = traversalHead();
QNode p = h.next;
if (p == null)
return null;
Object x = p.get();
if (p != x) {
if (!p.isData)
return null;
if (x != null)
return (E) x;
}
}
}
public boolean isEmpty() {
for (;;) {
QNode h = traversalHead();
QNode p = h.next;
if (p == null)
return true;
Object x = p.get();
if (p != x) {
if (!p.isData)
return true;
if (x != null)
return false;
}
}
}
public boolean hasWaitingConsumer() {
for (;;) {
QNode h = traversalHead();
QNode p = h.next;
if (p == null)
return false;
Object x = p.get();
if (p != x)
return !p.isData;
}
}
/**
* Returns the number of elements in this queue. If this queue
* contains more than {@code Integer.MAX_VALUE} elements, returns
* {@code Integer.MAX_VALUE}.
*
* Beware that, unlike in most collections, this method is
* NOT a constant-time operation. Because of the
* asynchronous nature of these queues, determining the current
* number of elements requires an O(n) traversal.
*
* @return the number of elements in this queue
*/
public int size() {
int count = 0;
QNode h = traversalHead();
for (QNode p = h.next; p != null && p.isData; p = p.next) {
Object x = p.get();
if (x != null && x != p) {
if (++count == Integer.MAX_VALUE) // saturated
break;
}
}
return count;
}
public int getWaitingConsumerCount() {
int count = 0;
QNode h = traversalHead();
for (QNode p = h.next; p != null && !p.isData; p = p.next) {
if (p.get() == null) {
if (++count == Integer.MAX_VALUE)
break;
}
}
return count;
}
public int remainingCapacity() {
return Integer.MAX_VALUE;
}
public boolean remove(Object o) {
if (o == null)
return false;
for (;;) {
QNode pred = traversalHead();
for (;;) {
QNode q = pred.next;
if (q == null || !q.isData)
return false;
if (q == pred) // restart
break;
Object x = q.get();
if (x != null && x != q && o.equals(x) &&
q.compareAndSet(x, q)) {
clean(pred, q);
return true;
}
pred = q;
}
}
}
/**
* Save the state to a stream (that is, serialize it).
*
* @serialData All of the elements (each an {@code E}) in
* the proper order, followed by a null
* @param s the stream
*/
private void writeObject(java.io.ObjectOutputStream s)
throws java.io.IOException {
s.defaultWriteObject();
for (E e : this)
s.writeObject(e);
// Use trailing null as sentinel
s.writeObject(null);
}
/**
* Reconstitute the Queue instance from a stream (that is,
* deserialize it).
*
* @param s the stream
*/
private void readObject(java.io.ObjectInputStream s)
throws java.io.IOException, ClassNotFoundException {
s.defaultReadObject();
resetHeadAndTail();
for (;;) {
E item = (E) s.readObject();
if (item == null)
break;
else
offer(item);
}
}
// Support for resetting head/tail while deserializing
private void resetHeadAndTail() {
QNode dummy = new QNode(null, false);
UNSAFE.putObjectVolatile(this, headOffset,
new PaddedAtomicReference(dummy));
UNSAFE.putObjectVolatile(this, tailOffset,
new PaddedAtomicReference(dummy));
UNSAFE.putObjectVolatile(this, cleanMeOffset,
new PaddedAtomicReference(null));
}
// Temporary Unsafe mechanics for preliminary release
private static Unsafe getUnsafe() throws Throwable {
try {
return Unsafe.getUnsafe();
} catch (SecurityException se) {
try {
return java.security.AccessController.doPrivileged
(new java.security.PrivilegedExceptionAction() {
public Unsafe run() throws Exception {
return getUnsafePrivileged();
}});
} catch (java.security.PrivilegedActionException e) {
throw e.getCause();
}
}
}
private static Unsafe getUnsafePrivileged()
throws NoSuchFieldException, IllegalAccessException {
Field f = Unsafe.class.getDeclaredField("theUnsafe");
f.setAccessible(true);
return (Unsafe) f.get(null);
}
private static long fieldOffset(String fieldName)
throws NoSuchFieldException {
return UNSAFE.objectFieldOffset
(LinkedTransferQueue.class.getDeclaredField(fieldName));
}
private static final Unsafe UNSAFE;
private static final long headOffset;
private static final long tailOffset;
private static final long cleanMeOffset;
static {
try {
UNSAFE = getUnsafe();
headOffset = fieldOffset("head");
tailOffset = fieldOffset("tail");
cleanMeOffset = fieldOffset("cleanMe");
} catch (Throwable e) {
throw new RuntimeException("Could not initialize intrinsics", e);
}
}
}