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Comparing jsr166/src/jsr166y/LinkedTransferQueue.java (file contents):
Revision 1.19 by jsr166, Tue Jul 21 00:15:14 2009 UTC vs.
Revision 1.49 by jsr166, Thu Oct 22 15:58:44 2009 UTC

#	Line 5 | Line 5
5		*/
6
7		package jsr166y;
8	+
9		import java.util.concurrent.*;
9	–	import java.util.concurrent.locks.*;
10	–	import java.util.concurrent.atomic.*;
11	–	import java.util.*;
12	–	import java.io.*;
13	–	import sun.misc.Unsafe;
14	–	import java.lang.reflect.*;
10
11	+	import java.util.AbstractQueue;
12	+	import java.util.Collection;
13	+	import java.util.ConcurrentModificationException;
14	+	import java.util.Iterator;
15	+	import java.util.NoSuchElementException;
16	+	import java.util.Queue;
17	+	import java.util.concurrent.locks.LockSupport;
18		/**
19	<	* An unbounded {@linkplain TransferQueue} based on linked nodes.
19	>	* An unbounded {@link TransferQueue} based on linked nodes.
20		* This queue orders elements FIFO (first-in-first-out) with respect
21		* to any given producer.  The <em>head</em> of the queue is that
22		* element that has been on the queue the longest time for some
#	Line 44 | Line 46 | import java.lang.reflect.*;
46		* @since 1.7
47		* @author Doug Lea
48		* @param <E> the type of elements held in this collection
47	–	*
49		*/
50		public class LinkedTransferQueue<E> extends AbstractQueue<E>
51		implements TransferQueue<E>, java.io.Serializable {
52		private static final long serialVersionUID = -3223113410248163686L;
53
54		/*
55	<	* This class extends the approach used in FIFO-mode
55	<	* SynchronousQueues. See the internal documentation, as well as
56	<	* the PPoPP 2006 paper "Scalable Synchronous Queues" by Scherer,
57	<	* Lea & Scott
58	<	* (http://www.cs.rice.edu/~wns1/papers/2006-PPoPP-SQ.pdf)
55	>	* *** Overview of Dual Queues with Slack ***
56		*
57	<	* The main extension is to provide different Wait modes for the
58	<	* main "xfer" method that puts or takes items.  These don't
59	<	* impact the basic dual-queue logic, but instead control whether
60	<	* or how threads block upon insertion of request or data nodes
61	<	* into the dual queue. It also uses slightly different
62	<	* conventions for tracking whether nodes are off-list or
63	<	* cancelled.
64	<	*/
65	<
66	<	// Wait modes for xfer method
67	<	static final int NOWAIT  = 0;
68	<	static final int TIMEOUT = 1;
69	<	static final int WAIT    = 2;
70	<
71	<	/** The number of CPUs, for spin control */
72	<	static final int NCPUS = Runtime.getRuntime().availableProcessors();
57	>	* Dual Queues, introduced by Scherer and Scott
58	>	* (http://www.cs.rice.edu/~wns1/papers/2004-DISC-DDS.pdf) are
59	>	* (linked) queues in which nodes may represent either data or
60	>	* requests.  When a thread tries to enqueue a data node, but
61	>	* encounters a request node, it instead "matches" and removes it;
62	>	* and vice versa for enqueuing requests. Blocking Dual Queues
63	>	* arrange that threads enqueuing unmatched requests block until
64	>	* other threads provide the match. Dual Synchronous Queues (see
65	>	* Scherer, Lea, & Scott
66	>	* http://www.cs.rochester.edu/u/scott/papers/2009_Scherer_CACM_SSQ.pdf)
67	>	* additionally arrange that threads enqueuing unmatched data also
68	>	* block.  Dual Transfer Queues support all of these modes, as
69	>	* dictated by callers.
70	>	*
71	>	* A FIFO dual queue may be implemented using a variation of the
72	>	* Michael & Scott (M&S) lock-free queue algorithm
73	>	* (http://www.cs.rochester.edu/u/scott/papers/1996_PODC_queues.pdf).
74	>	* It maintains two pointer fields, "head", pointing to a
75	>	* (matched) node that in turn points to the first actual
76	>	* (unmatched) queue node (or null if empty); and "tail" that
77	>	* points to the last node on the queue (or again null if
78	>	* empty). For example, here is a possible queue with four data
79	>	* elements:
80	>	*
81	>	*  head                tail
82	>	*    |                   |
83	>	*    v                   v
84	>	*    M -> U -> U -> U -> U
85	>	*
86	>	* The M&S queue algorithm is known to be prone to scalability and
87	>	* overhead limitations when maintaining (via CAS) these head and
88	>	* tail pointers. This has led to the development of
89	>	* contention-reducing variants such as elimination arrays (see
90	>	* Moir et al http://portal.acm.org/citation.cfm?id=1074013) and
91	>	* optimistic back pointers (see Ladan-Mozes & Shavit
92	>	* http://people.csail.mit.edu/edya/publications/OptimisticFIFOQueue-journal.pdf).
93	>	* However, the nature of dual queues enables a simpler tactic for
94	>	* improving M&S-style implementations when dual-ness is needed.
95	>	*
96	>	* In a dual queue, each node must atomically maintain its match
97	>	* status. While there are other possible variants, we implement
98	>	* this here as: for a data-mode node, matching entails CASing an
99	>	* "item" field from a non-null data value to null upon match, and
100	>	* vice-versa for request nodes, CASing from null to a data
101	>	* value. (Note that the linearization properties of this style of
102	>	* queue are easy to verify -- elements are made available by
103	>	* linking, and unavailable by matching.) Compared to plain M&S
104	>	* queues, this property of dual queues requires one additional
105	>	* successful atomic operation per enq/deq pair. But it also
106	>	* enables lower cost variants of queue maintenance mechanics. (A
107	>	* variation of this idea applies even for non-dual queues that
108	>	* support deletion of interior elements, such as
109	>	* j.u.c.ConcurrentLinkedQueue.)
110	>	*
111	>	* Once a node is matched, its match status can never again
112	>	* change.  We may thus arrange that the linked list of them
113	>	* contain a prefix of zero or more matched nodes, followed by a
114	>	* suffix of zero or more unmatched nodes. (Note that we allow
115	>	* both the prefix and suffix to be zero length, which in turn
116	>	* means that we do not use a dummy header.)  If we were not
117	>	* concerned with either time or space efficiency, we could
118	>	* correctly perform enqueue and dequeue operations by traversing
119	>	* from a pointer to the initial node; CASing the item of the
120	>	* first unmatched node on match and CASing the next field of the
121	>	* trailing node on appends. (Plus some special-casing when
122	>	* initially empty).  While this would be a terrible idea in
123	>	* itself, it does have the benefit of not requiring ANY atomic
124	>	* updates on head/tail fields.
125	>	*
126	>	* We introduce here an approach that lies between the extremes of
127	>	* never versus always updating queue (head and tail) pointers.
128	>	* This offers a tradeoff between sometimes requiring extra
129	>	* traversal steps to locate the first and/or last unmatched
130	>	* nodes, versus the reduced overhead and contention of fewer
131	>	* updates to queue pointers. For example, a possible snapshot of
132	>	* a queue is:
133	>	*
134	>	*  head           tail
135	>	*    |              |
136	>	*    v              v
137	>	*    M -> M -> U -> U -> U -> U
138	>	*
139	>	* The best value for this "slack" (the targeted maximum distance
140	>	* between the value of "head" and the first unmatched node, and
141	>	* similarly for "tail") is an empirical matter. We have found
142	>	* that using very small constants in the range of 1-3 work best
143	>	* over a range of platforms. Larger values introduce increasing
144	>	* costs of cache misses and risks of long traversal chains, while
145	>	* smaller values increase CAS contention and overhead.
146	>	*
147	>	* Dual queues with slack differ from plain M&S dual queues by
148	>	* virtue of only sometimes updating head or tail pointers when
149	>	* matching, appending, or even traversing nodes; in order to
150	>	* maintain a targeted slack.  The idea of "sometimes" may be
151	>	* operationalized in several ways. The simplest is to use a
152	>	* per-operation counter incremented on each traversal step, and
153	>	* to try (via CAS) to update the associated queue pointer
154	>	* whenever the count exceeds a threshold. Another, that requires
155	>	* more overhead, is to use random number generators to update
156	>	* with a given probability per traversal step.
157	>	*
158	>	* In any strategy along these lines, because CASes updating
159	>	* fields may fail, the actual slack may exceed targeted
160	>	* slack. However, they may be retried at any time to maintain
161	>	* targets.  Even when using very small slack values, this
162	>	* approach works well for dual queues because it allows all
163	>	* operations up to the point of matching or appending an item
164	>	* (hence potentially releasing another thread) to be read-only,
165	>	* thus not introducing any further contention. As described
166	>	* below, we implement this by performing slack maintenance
167	>	* retries only after these points.
168	>	*
169	>	* As an accompaniment to such techniques, traversal overhead can
170	>	* be further reduced without increasing contention of head
171	>	* pointer updates.  During traversals, threads may sometimes
172	>	* shortcut the "next" link path from the current "head" node to
173	>	* be closer to the currently known first unmatched node. Again,
174	>	* this may be triggered with using thresholds or randomization.
175	>	*
176	>	* These ideas must be further extended to avoid unbounded amounts
177	>	* of costly-to-reclaim garbage caused by the sequential "next"
178	>	* links of nodes starting at old forgotten head nodes: As first
179	>	* described in detail by Boehm
180	>	* (http://portal.acm.org/citation.cfm?doid=503272.503282) if a GC
181	>	* delays noticing that any arbitrarily old node has become
182	>	* garbage, all newer dead nodes will also be unreclaimed.
183	>	* (Similar issues arise in non-GC environments.)  To cope with
184	>	* this in our implementation, upon CASing to advance the head
185	>	* pointer, we set the "next" link of the previous head to point
186	>	* only to itself; thus limiting the length of connected dead lists.
187	>	* (We also take similar care to wipe out possibly garbage
188	>	* retaining values held in other Node fields.)  However, doing so
189	>	* adds some further complexity to traversal: If any "next"
190	>	* pointer links to itself, it indicates that the current thread
191	>	* has lagged behind a head-update, and so the traversal must
192	>	* continue from the "head".  Traversals trying to find the
193	>	* current tail starting from "tail" may also encounter
194	>	* self-links, in which case they also continue at "head".
195	>	*
196	>	* It is tempting in slack-based scheme to not even use CAS for
197	>	* updates (similarly to Ladan-Mozes & Shavit). However, this
198	>	* cannot be done for head updates under the above link-forgetting
199	>	* mechanics because an update may leave head at a detached node.
200	>	* And while direct writes are possible for tail updates, they
201	>	* increase the risk of long retraversals, and hence long garbage
202	>	* chains which can be much more costly than is worthwhile
203	>	* considering that the cost difference of performing a CAS vs
204	>	* write is smaller when they are not triggered on each operation
205	>	* (especially considering that writes and CASes equally require
206	>	* additional GC bookkeeping ("write barriers") that are sometimes
207	>	* more costly than the writes themselves because of contention).
208	>	*
209	>	* Removal of interior nodes (due to timed out or interrupted
210	>	* waits, or calls to remove or Iterator.remove) uses a scheme
211	>	* roughly similar to that in Scherer, Lea, and Scott's
212	>	* SynchronousQueue. Given a predecessor, we can unsplice any node
213	>	* except the (actual) tail of the queue. To avoid build-up of
214	>	* cancelled trailing nodes, upon a request to remove a trailing
215	>	* node, it is placed in field "cleanMe" to be unspliced upon the
216	>	* next call to unsplice any other node.  Situations needing such
217	>	* mechanics are not common but do occur in practice; for example
218	>	* when an unbounded series of short timed calls to poll
219	>	* repeatedly time out but never otherwise fall off the list
220	>	* because of an untimed call to take at the front of the
221	>	* queue. (Note that maintaining field cleanMe does not otherwise
222	>	* much impact garbage retention even if never cleared by some
223	>	* other call because the held node will eventually either
224	>	* directly or indirectly lead to a self-link once off the list.)
225	>	*
226	>	* *** Overview of implementation ***
227	>	*
228	>	* We use a threshold-based approach to updates, with a target
229	>	* slack of two.  The slack value is hard-wired: a path greater
230	>	* than one is naturally implemented by checking equality of
231	>	* traversal pointers except when the list has only one element,
232	>	* in which case we keep target slack at one. Avoiding tracking
233	>	* explicit counts across method calls slightly simplifies an
234	>	* already-messy implementation. Using randomization would
235	>	* probably work better if there were a low-quality dirt-cheap
236	>	* per-thread one available, but even ThreadLocalRandom is too
237	>	* heavy for these purposes.
238	>	*
239	>	* With such a small target slack value, it is rarely worthwhile
240	>	* to augment this with path short-circuiting; i.e., unsplicing
241	>	* nodes between head and the first unmatched node, or similarly
242	>	* for tail, rather than advancing head or tail proper. However,
243	>	* it is used (in awaitMatch) immediately before a waiting thread
244	>	* starts to block, as a final bit of helping at a point when
245	>	* contention with others is extremely unlikely (since if other
246	>	* threads that could release it are operating, then the current
247	>	* thread wouldn't be blocking).
248	>	*
249	>	* We allow both the head and tail fields to be null before any
250	>	* nodes are enqueued; initializing upon first append.  This
251	>	* simplifies some other logic, as well as providing more
252	>	* efficient explicit control paths instead of letting JVMs insert
253	>	* implicit NullPointerExceptions when they are null.  While not
254	>	* currently fully implemented, we also leave open the possibility
255	>	* of re-nulling these fields when empty (which is complicated to
256	>	* arrange, for little benefit.)
257	>	*
258	>	* All enqueue/dequeue operations are handled by the single method
259	>	* "xfer" with parameters indicating whether to act as some form
260	>	* of offer, put, poll, take, or transfer (each possibly with
261	>	* timeout). The relative complexity of using one monolithic
262	>	* method outweighs the code bulk and maintenance problems of
263	>	* using nine separate methods.
264	>	*
265	>	* Operation consists of up to three phases. The first is
266	>	* implemented within method xfer, the second in tryAppend, and
267	>	* the third in method awaitMatch.
268	>	*
269	>	* 1. Try to match an existing node
270	>	*
271	>	*    Starting at head, skip already-matched nodes until finding
272	>	*    an unmatched node of opposite mode, if one exists, in which
273	>	*    case matching it and returning, also if necessary updating
274	>	*    head to one past the matched node (or the node itself if the
275	>	*    list has no other unmatched nodes). If the CAS misses, then
276	>	*    a loop retries advancing head by two steps until either
277	>	*    success or the slack is at most two. By requiring that each
278	>	*    attempt advances head by two (if applicable), we ensure that
279	>	*    the slack does not grow without bound. Traversals also check
280	>	*    if the initial head is now off-list, in which case they
281	>	*    start at the new head.
282	>	*
283	>	*    If no candidates are found and the call was untimed
284	>	*    poll/offer, (argument "how" is NOW) return.
285	>	*
286	>	* 2. Try to append a new node (method tryAppend)
287	>	*
288	>	*    Starting at current tail pointer, try to append a new node
289	>	*    to the list (or if head was null, establish the first
290	>	*    node). Nodes can be appended only if their predecessors are
291	>	*    either already matched or are of the same mode. If we detect
292	>	*    otherwise, then a new node with opposite mode must have been
293	>	*    appended during traversal, so must restart at phase 1. The
294	>	*    traversal and update steps are otherwise similar to phase 1:
295	>	*    Retrying upon CAS misses and checking for staleness.  In
296	>	*    particular, if a self-link is encountered, then we can
297	>	*    safely jump to a node on the list by continuing the
298	>	*    traversal at current head.
299	>	*
300	>	*    On successful append, if the call was ASYNC, return.
301	>	*
302	>	* 3. Await match or cancellation (method awaitMatch)
303	>	*
304	>	*    Wait for another thread to match node; instead cancelling if
305	>	*    current thread was interrupted or the wait timed out. On
306	>	*    multiprocessors, we use front-of-queue spinning: If a node
307	>	*    appears to be the first unmatched node in the queue, it
308	>	*    spins a bit before blocking. In either case, before blocking
309	>	*    it tries to unsplice any nodes between the current "head"
310	>	*    and the first unmatched node.
311	>	*
312	>	*    Front-of-queue spinning vastly improves performance of
313	>	*    heavily contended queues. And so long as it is relatively
314	>	*    brief and "quiet", spinning does not much impact performance
315	>	*    of less-contended queues.  During spins threads check their
316	>	*    interrupt status and generate a thread-local random number
317	>	*    to decide to occasionally perform a Thread.yield. While
318	>	*    yield has underdefined specs, we assume that might it help,
319	>	*    and will not hurt in limiting impact of spinning on busy
320	>	*    systems.  We also use much smaller (1/4) spins for nodes
321	>	*    that are not known to be front but whose predecessors have
322	>	*    not blocked -- these "chained" spins avoid artifacts of
323	>	*    front-of-queue rules which otherwise lead to alternating
324	>	*    nodes spinning vs blocking. Further, front threads that
325	>	*    represent phase changes (from data to request node or vice
326	>	*    versa) compared to their predecessors receive additional
327	>	*    spins, reflecting the longer code path lengths necessary to
328	>	*    release them under contention.
329	>	*/
330	>
331	>	/** True if on multiprocessor */
332	>	private static final boolean MP =
333	>	Runtime.getRuntime().availableProcessors() > 1;
334
335		/**
336	<	* The number of times to spin before blocking in timed waits.
337	<	* The value is empirically derived -- it works well across a
338	<	* variety of processors and OSes. Empirically, the best value
339	<	* seems not to vary with number of CPUs (beyond 2) so is just
340	<	* a constant.
336	>	* The number of times to spin (with on average one randomly
337	>	* interspersed call to Thread.yield) on multiprocessor before
338	>	* blocking when a node is apparently the first waiter in the
339	>	* queue.  See above for explanation. Must be a power of two. The
340	>	* value is empirically derived -- it works pretty well across a
341	>	* variety of processors, numbers of CPUs, and OSes.
342		*/
343	<	static final int maxTimedSpins = (NCPUS < 2)? 0 : 32;
343	>	private static final int FRONT_SPINS   = 1 << 7;
344
345		/**
346	<	* The number of times to spin before blocking in untimed waits.
347	<	* This is greater than timed value because untimed waits spin
89	<	* faster since they don't need to check times on each spin.
346	>	* The number of times to spin before blocking when a node is
347	>	* preceded by another node that is apparently spinning.
348		*/
349	<	static final int maxUntimedSpins = maxTimedSpins * 16;
349	>	private static final int CHAINED_SPINS = FRONT_SPINS >>> 2;
350
351		/**
352	<	* The number of nanoseconds for which it is faster to spin
353	<	* rather than to use timed park. A rough estimate suffices.
354	<	*/
355	<	static final long spinForTimeoutThreshold = 1000L;
352	>	* Queue nodes. Uses Object, not E, for items to allow forgetting
353	>	* them after use.  Relies heavily on Unsafe mechanics to minimize
354	>	* unnecessary ordering constraints: Writes that intrinsically
355	>	* precede or follow CASes use simple relaxed forms.  Other
356	>	* cleanups use releasing/lazy writes.
357	>	*/
358	>	static final class Node {
359	>	final boolean isData;   // false if this is a request node
360	>	volatile Object item;   // initially non-null if isData; CASed to match
361	>	volatile Node next;
362	>	volatile Thread waiter; // null until waiting
363	>
364	>	// CAS methods for fields
365	>	final boolean casNext(Node cmp, Node val) {
366	>	return UNSAFE.compareAndSwapObject(this, nextOffset, cmp, val);
367	>	}
368
369	<	/**
370	<	* Node class for LinkedTransferQueue. Opportunistically
371	<	* subclasses from AtomicReference to represent item. Uses Object,
372	<	* not E, to allow setting item to "this" after use, to avoid
373	<	* garbage retention. Similarly, setting the next field to this is
374	<	* used as sentinel that node is off list.
375	<	*/
376	<	static final class QNode extends AtomicReference<Object> {
377	<	volatile QNode next;
378	<	volatile Thread waiter;       // to control park/unpark
109	<	final boolean isData;
110	<	QNode(Object item, boolean isData) {
111	<	super(item);
369	>	final boolean casItem(Object cmp, Object val) {
370	>	return UNSAFE.compareAndSwapObject(this, itemOffset, cmp, val);
371	>	}
372	>
373	>	/**
374	>	* Creates a new node. Uses relaxed write because item can only
375	>	* be seen if followed by CAS.
376	>	*/
377	>	Node(Object item, boolean isData) {
378	>	UNSAFE.putObject(this, itemOffset, item); // relaxed write
379		this.isData = isData;
380		}
381
382	<	static final AtomicReferenceFieldUpdater<QNode, QNode>
383	<	nextUpdater = AtomicReferenceFieldUpdater.newUpdater
384	<	(QNode.class, QNode.class, "next");
382	>	/**
383	>	* Links node to itself to avoid garbage retention.  Called
384	>	* only after CASing head field, so uses relaxed write.
385	>	*/
386	>	final void forgetNext() {
387	>	UNSAFE.putObject(this, nextOffset, this);
388	>	}
389
390	<	final boolean casNext(QNode cmp, QNode val) {
391	<	return nextUpdater.compareAndSet(this, cmp, val);
390	>	/**
391	>	* Sets item to self (using a releasing/lazy write) and waiter
392	>	* to null, to avoid garbage retention after extracting or
393	>	* cancelling.
394	>	*/
395	>	final void forgetContents() {
396	>	UNSAFE.putOrderedObject(this, itemOffset, this);
397	>	UNSAFE.putOrderedObject(this, waiterOffset, null);
398		}
399
400	<	final void clearNext() {
401	<	nextUpdater.lazySet(this, this);
400	>	/**
401	>	* Returns true if this node has been matched, including the
402	>	* case of artificial matches due to cancellation.
403	>	*/
404	>	final boolean isMatched() {
405	>	Object x = item;
406	>	return x == this || (x != null) != isData;
407		}
408
409	<	}
409	>	/**
410	>	* Returns true if a node with the given mode cannot be
411	>	* appended to this node because this node is unmatched and
412	>	* has opposite data mode.
413	>	*/
414	>	final boolean cannotPrecede(boolean haveData) {
415	>	boolean d = isData;
416	>	Object x;
417	>	return d != haveData && (x = item) != this && (x != null) == d;
418	>	}
419
420	<	/**
421	<	* Padded version of AtomicReference used for head, tail and
422	<	* cleanMe, to alleviate contention across threads CASing one vs
423	<	* the other.
424	<	*/
425	<	static final class PaddedAtomicReference<T> extends AtomicReference<T> {
426	<	// enough padding for 64bytes with 4byte refs
427	<	Object p0, p1, p2, p3, p4, p5, p6, p7, p8, p9, pa, pb, pc, pd, pe;
428	<	PaddedAtomicReference(T r) { super(r); }
420	>	/**
421	>	* Tries to artificially match a data node -- used by remove.
422	>	*/
423	>	final boolean tryMatchData() {
424	>	Object x = item;
425	>	if (x != null && x != this && casItem(x, null)) {
426	>	LockSupport.unpark(waiter);
427	>	return true;
428	>	}
429	>	return false;
430	>	}
431	>
432	>	// Unsafe mechanics
433	>	private static final sun.misc.Unsafe UNSAFE = getUnsafe();
434	>	private static final long nextOffset =
435	>	objectFieldOffset(UNSAFE, "next", Node.class);
436	>	private static final long itemOffset =
437	>	objectFieldOffset(UNSAFE, "item", Node.class);
438	>	private static final long waiterOffset =
439	>	objectFieldOffset(UNSAFE, "waiter", Node.class);
440	>
441	>	private static final long serialVersionUID = -3375979862319811754L;
442		}
443
444	+	/** head of the queue; null until first enqueue */
445	+	private transient volatile Node head;
446
447	<	/** head of the queue */
448	<	private transient final PaddedAtomicReference<QNode> head;
143	<	/** tail of the queue */
144	<	private transient final PaddedAtomicReference<QNode> tail;
447	>	/** predecessor of dangling unspliceable node */
448	>	private transient volatile Node cleanMe; // decl here to reduce contention
449
450	<	/**
451	<	* Reference to a cancelled node that might not yet have been
148	<	* unlinked from queue because it was the last inserted node
149	<	* when it cancelled.
150	<	*/
151	<	private transient final PaddedAtomicReference<QNode> cleanMe;
450	>	/** tail of the queue; null until first append */
451	>	private transient volatile Node tail;
452
453	<	/**
454	<	* Tries to cas nh as new head; if successful, unlink
455	<	* old head's next node to avoid garbage retention.
156	<	*/
157	<	private boolean advanceHead(QNode h, QNode nh) {
158	<	if (h == head.get() && head.compareAndSet(h, nh)) {
159	<	h.clearNext(); // forget old next
160	<	return true;
161	<	}
162	<	return false;
453	>	// CAS methods for fields
454	>	private boolean casTail(Node cmp, Node val) {
455	>	return UNSAFE.compareAndSwapObject(this, tailOffset, cmp, val);
456		}
457
458	+	private boolean casHead(Node cmp, Node val) {
459	+	return UNSAFE.compareAndSwapObject(this, headOffset, cmp, val);
460	+	}
461	+
462	+	private boolean casCleanMe(Node cmp, Node val) {
463	+	return UNSAFE.compareAndSwapObject(this, cleanMeOffset, cmp, val);
464	+	}
465	+
466	+	/*
467	+	* Possible values for "how" argument in xfer method. Beware that
468	+	* the order of assigned numerical values matters.
469	+	*/
470	+	private static final int NOW     = 0; // for untimed poll, tryTransfer
471	+	private static final int ASYNC   = 1; // for offer, put, add
472	+	private static final int SYNC    = 2; // for transfer, take
473	+	private static final int TIMEOUT = 3; // for timed poll, tryTransfer
474	+
475		/**
476	<	* Puts or takes an item. Used for most queue operations (except
167	<	* poll() and tryTransfer()). See the similar code in
168	<	* SynchronousQueue for detailed explanation.
476	>	* Implements all queuing methods. See above for explanation.
477		*
478	<	* @param e the item or if null, signifies that this is a take
479	<	* @param mode the wait mode: NOWAIT, TIMEOUT, WAIT
478	>	* @param e the item or null for take
479	>	* @param haveData true if this is a put, else a take
480	>	* @param how NOW, ASYNC, SYNC, or TIMEOUT
481		* @param nanos timeout in nanosecs, used only if mode is TIMEOUT
482	<	* @return an item, or null on failure
482	>	* @return an item if matched, else e
483	>	* @throws NullPointerException if haveData mode but e is null
484		*/
485	<	private Object xfer(Object e, int mode, long nanos) {
486	<	boolean isData = (e != null);
487	<	QNode s = null;
488	<	final PaddedAtomicReference<QNode> head = this.head;
179	<	final PaddedAtomicReference<QNode> tail = this.tail;
485	>	private Object xfer(Object e, boolean haveData, int how, long nanos) {
486	>	if (haveData && (e == null))
487	>	throw new NullPointerException();
488	>	Node s = null;                        // the node to append, if needed
489
490	<	for (;;) {
182	<	QNode t = tail.get();
183	<	QNode h = head.get();
490	>	retry: for (;;) {                     // restart on append race
491
492	<	if (t != null && (t == h || t.isData == isData)) {
493	<	if (s == null)
494	<	s = new QNode(e, isData);
495	<	QNode last = t.next;
496	<	if (last != null) {
497	<	if (t == tail.get())
498	<	tail.compareAndSet(t, last);
499	<	}
500	<	else if (t.casNext(null, s)) {
501	<	tail.compareAndSet(t, s);
502	<	return awaitFulfill(t, s, e, mode, nanos);
492	>	for (Node h = head, p = h; p != null;) { // find & match first node
493	>	boolean isData = p.isData;
494	>	Object item = p.item;
495	>	if (item != p && (item != null) == isData) { // unmatched
496	>	if (isData == haveData)   // can't match
497	>	break;
498	>	if (p.casItem(item, e)) { // match
499	>	Thread w = p.waiter;
500	>	while (p != h) {      // update head
501	>	Node n = p.next;  // by 2 unless singleton
502	>	if (n != null)
503	>	p = n;
504	>	if (head == h && casHead(h, p)) {
505	>	h.forgetNext();
506	>	break;
507	>	}                 // advance and retry
508	>	if ((h = head)   == null ||
509	>	(p = h.next) == null || !p.isMatched())
510	>	break;        // unless slack < 2
511	>	}
512	>	LockSupport.unpark(w);
513	>	return item;
514	>	}
515		}
516	+	Node n = p.next;
517	+	p = (p != n) ? n : (h = head); // Use head if p offlist
518		}
519
520	<	else if (h != null) {
521	<	QNode first = h.next;
522	<	if (t == tail.get() && first != null &&
523	<	advanceHead(h, first)) {
524	<	Object x = first.get();
525	<	if (x != first && first.compareAndSet(x, e)) {
526	<	LockSupport.unpark(first.waiter);
527	<	return isData? e : x;
207	<	}
208	<	}
520	>	if (how >= ASYNC) {               // No matches available
521	>	if (s == null)
522	>	s = new Node(e, haveData);
523	>	Node pred = tryAppend(s, haveData);
524	>	if (pred == null)
525	>	continue retry;           // lost race vs opposite mode
526	>	if (how >= SYNC)
527	>	return awaitMatch(pred, s, e, how, nanos);
528		}
529	+	return e; // not waiting
530		}
531		}
532
213	–
533		/**
534	<	* Version of xfer for poll() and tryTransfer, which
535	<	* simplifies control paths both here and in xfer.
536	<	*/
537	<	private Object fulfill(Object e) {
538	<	boolean isData = (e != null);
539	<	final PaddedAtomicReference<QNode> head = this.head;
540	<	final PaddedAtomicReference<QNode> tail = this.tail;
541	<
542	<	for (;;) {
543	<	QNode t = tail.get();
544	<	QNode h = head.get();
545	<
546	<	if (t != null && (t == h || t.isData == isData)) {
547	<	QNode last = t.next;
548	<	if (t == tail.get()) {
549	<	if (last != null)
550	<	tail.compareAndSet(t, last);
551	<	else
552	<	return null;
553	<	}
554	<	}
555	<	else if (h != null) {
556	<	QNode first = h.next;
557	<	if (t == tail.get() &&
558	<	first != null &&
559	<	advanceHead(h, first)) {
560	<	Object x = first.get();
561	<	if (x != first && first.compareAndSet(x, e)) {
243	<	LockSupport.unpark(first.waiter);
244	<	return isData? e : x;
245	<	}
534	>	* Tries to append node s as tail.
535	>	*
536	>	* @param s the node to append
537	>	* @param haveData true if appending in data mode
538	>	* @return null on failure due to losing race with append in
539	>	* different mode, else s's predecessor, or s itself if no
540	>	* predecessor
541	>	*/
542	>	private Node tryAppend(Node s, boolean haveData) {
543	>	for (Node t = tail, p = t;;) { // move p to last node and append
544	>	Node n, u;                        // temps for reads of next & tail
545	>	if (p == null && (p = head) == null) {
546	>	if (casHead(null, s))
547	>	return s;                 // initialize
548	>	}
549	>	else if (p.cannotPrecede(haveData))
550	>	return null;                  // lost race vs opposite mode
551	>	else if ((n = p.next) != null)    // not last; keep traversing
552	>	p = p != t && t != (u = tail) ? (t = u) : // stale tail
553	>	(p != n) ? n : null;      // restart if off list
554	>	else if (!p.casNext(null, s))
555	>	p = p.next;                   // re-read on CAS failure
556	>	else {
557	>	if (p != t) {                 // update if slack now >= 2
558	>	while ((tail != t || !casTail(t, s)) &&
559	>	(t = tail)   != null &&
560	>	(s = t.next) != null && // advance and retry
561	>	(s = s.next) != null && s != t);
562		}
563	+	return p;
564		}
565		}
566		}
567
568		/**
569	<	* Spins/blocks until node s is fulfilled or caller gives up,
253	<	* depending on wait mode.
569	>	* Spins/yields/blocks until node s is matched or caller gives up.
570		*
571	<	* @param pred the predecessor of waiting node
571	>	* @param pred the predecessor of s, or s or null if none
572		* @param s the waiting node
573		* @param e the comparison value for checking match
574	<	* @param mode mode
574	>	* @param how either SYNC or TIMEOUT
575		* @param nanos timeout value
576	<	* @return matched item, or s if cancelled
576	>	* @return matched item, or e if unmatched on interrupt or timeout
577		*/
578	<	private Object awaitFulfill(QNode pred, QNode s, Object e,
579	<	int mode, long nanos) {
580	<	if (mode == NOWAIT)
265	<	return null;
266	<
267	<	long lastTime = (mode == TIMEOUT)? System.nanoTime() : 0;
578	>	private Object awaitMatch(Node pred, Node s, Object e,
579	>	int how, long nanos) {
580	>	long lastTime = (how == TIMEOUT) ? System.nanoTime() : 0L;
581		Thread w = Thread.currentThread();
582	<	int spins = -1; // set to desired spin count below
582	>	int spins = -1; // initialized after first item and cancel checks
583	>	ThreadLocalRandom randomYields = null; // bound if needed
584	>
585		for (;;) {
586	<	if (w.isInterrupted())
587	<	s.compareAndSet(e, s);
588	<	Object x = s.get();
589	<	if (x != e) {                 // Node was matched or cancelled
590	<	advanceHead(pred, s);     // unlink if head
591	<	if (x == s) {             // was cancelled
592	<	clean(pred, s);
593	<	return null;
594	<	}
595	<	else if (x != null) {
596	<	s.set(s);             // avoid garbage retention
597	<	return x;
598	<	}
599	<	else
600	<	return e;
586	>	Object item = s.item;
587	>	if (item != e) {                  // matched
588	>	s.forgetContents();           // avoid garbage
589	>	return item;
590	>	}
591	>	if ((w.isInterrupted() || (how == TIMEOUT && nanos <= 0)) &&
592	>	s.casItem(e, s)) {       // cancel
593	>	unsplice(pred, s);
594	>	return e;
595	>	}
596	>
597	>	if (spins < 0) {                  // establish spins at/near front
598	>	if ((spins = spinsFor(pred, s.isData)) > 0)
599	>	randomYields = ThreadLocalRandom.current();
600	>	}
601	>	else if (spins > 0) {             // spin, occasionally yield
602	>	if (randomYields.nextInt(FRONT_SPINS) == 0)
603	>	Thread.yield();
604	>	--spins;
605		}
606	<	if (mode == TIMEOUT) {
606	>	else if (s.waiter == null) {
607	>	shortenHeadPath();            // reduce slack before blocking
608	>	s.waiter = w;                 // request unpark
609	>	}
610	>	else if (how == TIMEOUT) {
611		long now = System.nanoTime();
612	<	nanos -= now - lastTime;
612	>	if ((nanos -= now - lastTime) > 0)
613	>	LockSupport.parkNanos(this, nanos);
614		lastTime = now;
291	–	if (nanos <= 0) {
292	–	s.compareAndSet(e, s); // try to cancel
293	–	continue;
294	–	}
615		}
616	<	if (spins < 0) {
297	<	QNode h = head.get(); // only spin if at head
298	<	spins = ((h != null && h.next == s) ?
299	<	(mode == TIMEOUT?
300	<	maxTimedSpins : maxUntimedSpins) : 0);
301	<	}
302	<	if (spins > 0)
303	<	--spins;
304	<	else if (s.waiter == null)
305	<	s.waiter = w;
306	<	else if (mode != TIMEOUT) {
616	>	else {
617		LockSupport.park(this);
618	<	s.waiter = null;
309	<	spins = -1;
310	<	}
311	<	else if (nanos > spinForTimeoutThreshold) {
312	<	LockSupport.parkNanos(this, nanos);
313	<	s.waiter = null;
314	<	spins = -1;
618	>	spins = -1;                   // spin if front upon wakeup
619		}
620		}
621		}
622
623		/**
624	<	* Returns validated tail for use in cleaning methods.
624	>	* Returns spin/yield value for a node with given predecessor and
625	>	* data mode. See above for explanation.
626		*/
627	<	private QNode getValidatedTail() {
628	<	for (;;) {
629	<	QNode h = head.get();
630	<	QNode first = h.next;
631	<	if (first != null && first.next == first) { // help advance
632	<	advanceHead(h, first);
633	<	continue;
634	<	}
635	<	QNode t = tail.get();
636	<	QNode last = t.next;
637	<	if (t == tail.get()) {
638	<	if (last != null)
639	<	tail.compareAndSet(t, last); // help advance
640	<	else
641	<	return t;
627	>	private static int spinsFor(Node pred, boolean haveData) {
628	>	if (MP && pred != null) {
629	>	boolean predData = pred.isData;
630	>	if (predData != haveData)         // front and phase change
631	>	return FRONT_SPINS + (FRONT_SPINS >>> 1);
632	>	if (predData != (pred.item != null)) // probably at front
633	>	return FRONT_SPINS;
634	>	if (pred.waiter == null)          // pred apparently spinning
635	>	return CHAINED_SPINS;
636	>	}
637	>	return 0;
638	>	}
639	>
640	>	/**
641	>	* Tries (once) to unsplice nodes between head and first unmatched
642	>	* or trailing node; failing on contention.
643	>	*/
644	>	private void shortenHeadPath() {
645	>	Node h, hn, p, q;
646	>	if ((p = h = head) != null && h.isMatched() &&
647	>	(q = hn = h.next) != null) {
648	>	Node n;
649	>	while ((n = q.next) != q) {
650	>	if (n == null || !q.isMatched()) {
651	>	if (hn != q && h.next == hn)
652	>	h.casNext(hn, q);
653	>	break;
654	>	}
655	>	p = q;
656	>	q = n;
657		}
658		}
659		}
660
661	+	/* -------------- Traversal methods -------------- */
662	+
663		/**
664	<	* Gets rid of cancelled node s with original predecessor pred.
665	<	*
666	<	* @param pred predecessor of cancelled node
667	<	* @param s the cancelled node
664	>	* Returns the first unmatched node of the given mode, or null if
665	>	* none.  Used by methods isEmpty, hasWaitingConsumer.
666	>	*/
667	>	private Node firstOfMode(boolean data) {
668	>	for (Node p = head; p != null; ) {
669	>	if (!p.isMatched())
670	>	return (p.isData == data) ? p : null;
671	>	Node n = p.next;
672	>	p = (n != p) ? n : head;
673	>	}
674	>	return null;
675	>	}
676	>
677	>	/**
678	>	* Returns the item in the first unmatched node with isData; or
679	>	* null if none. Used by peek.
680		*/
681	<	private void clean(QNode pred, QNode s) {
682	<	Thread w = s.waiter;
683	<	if (w != null) {             // Wake up thread
684	<	s.waiter = null;
685	<	if (w != Thread.currentThread())
686	<	LockSupport.unpark(w);
681	>	private Object firstDataItem() {
682	>	for (Node p = head; p != null; ) {
683	>	boolean isData = p.isData;
684	>	Object item = p.item;
685	>	if (item != p && (item != null) == isData)
686	>	return isData ? item : null;
687	>	Node n = p.next;
688	>	p = (n != p) ? n : head;
689		}
690	+	return null;
691	+	}
692
693	<	if (pred == null)
694	<	return;
693	>	/**
694	>	* Traverses and counts unmatched nodes of the given mode.
695	>	* Used by methods size and getWaitingConsumerCount.
696	>	*/
697	>	private int countOfMode(boolean data) {
698	>	int count = 0;
699	>	for (Node p = head; p != null; ) {
700	>	if (!p.isMatched()) {
701	>	if (p.isData != data)
702	>	return 0;
703	>	if (++count == Integer.MAX_VALUE) // saturated
704	>	break;
705	>	}
706	>	Node n = p.next;
707	>	if (n != p)
708	>	p = n;
709	>	else {
710	>	count = 0;
711	>	p = head;
712	>	}
713	>	}
714	>	return count;
715	>	}
716
717	+	final class Itr implements Iterator<E> {
718	+	private Node nextNode;   // next node to return item for
719	+	private Object nextItem; // the corresponding item
720	+	private Node lastRet;    // last returned node, to support remove
721	+
722	+	/**
723	+	* Moves to next node after prev, or first node if prev null.
724	+	*/
725	+	private void advance(Node prev) {
726	+	lastRet = prev;
727	+	Node p;
728	+	if (prev == null || (p = prev.next) == prev)
729	+	p = head;
730	+	while (p != null) {
731	+	Object item = p.item;
732	+	if (p.isData) {
733	+	if (item != null && item != p) {
734	+	nextItem = item;
735	+	nextNode = p;
736	+	return;
737	+	}
738	+	}
739	+	else if (item == null)
740	+	break;
741	+	Node n = p.next;
742	+	p = (n != p) ? n : head;
743	+	}
744	+	nextNode = null;
745	+	}
746	+
747	+	Itr() {
748	+	advance(null);
749	+	}
750	+
751	+	public final boolean hasNext() {
752	+	return nextNode != null;
753	+	}
754	+
755	+	public final E next() {
756	+	Node p = nextNode;
757	+	if (p == null) throw new NoSuchElementException();
758	+	Object e = nextItem;
759	+	advance(p);
760	+	return (E) e;
761	+	}
762	+
763	+	public final void remove() {
764	+	Node p = lastRet;
765	+	if (p == null) throw new IllegalStateException();
766	+	lastRet = null;
767	+	findAndRemoveNode(p);
768	+	}
769	+	}
770	+
771	+	/* -------------- Removal methods -------------- */
772	+
773	+	/**
774	+	* Unsplices (now or later) the given deleted/cancelled node with
775	+	* the given predecessor.
776	+	*
777	+	* @param pred predecessor of node to be unspliced
778	+	* @param s the node to be unspliced
779	+	*/
780	+	private void unsplice(Node pred, Node s) {
781	+	s.forgetContents(); // clear unneeded fields
782		/*
783		* At any given time, exactly one node on list cannot be
784	<	* deleted -- the last inserted node. To accommodate this, if
785	<	* we cannot delete s, we save its predecessor as "cleanMe",
786	<	* processing the previously saved version first. At least one
787	<	* of node s or the node previously saved can always be
784	>	* unlinked -- the last inserted node. To accommodate this, if
785	>	* we cannot unlink s, we save its predecessor as "cleanMe",
786	>	* processing the previously saved version first. Because only
787	>	* one node in the list can have a null next, at least one of
788	>	* node s or the node previously saved can always be
789		* processed, so this always terminates.
790		*/
791	<	while (pred.next == s) {
792	<	QNode oldpred = reclean();  // First, help get rid of cleanMe
793	<	QNode t = getValidatedTail();
794	<	if (s != t) {               // If not tail, try to unsplice
795	<	QNode sn = s.next;      // s.next == s means s already off list
796	<	if (sn == s || pred.casNext(s, sn))
791	>	if (pred != null && pred != s) {
792	>	while (pred.next == s) {
793	>	Node oldpred = (cleanMe == null) ? null : reclean();
794	>	Node n = s.next;
795	>	if (n != null) {
796	>	if (n != s)
797	>	pred.casNext(s, n);
798		break;
799	+	}
800	+	if (oldpred == pred ||      // Already saved
801	+	(oldpred == null && casCleanMe(null, pred)))
802	+	break;                  // Postpone cleaning
803		}
374	–	else if (oldpred == pred || // Already saved
375	–	(oldpred == null && cleanMe.compareAndSet(null, pred)))
376	–	break;                  // Postpone cleaning
804		}
805		}
806
807		/**
808	<	* Tries to unsplice the cancelled node held in cleanMe that was
809	<	* previously uncleanable because it was at tail.
808	>	* Tries to unsplice the deleted/cancelled node held in cleanMe
809	>	* that was previously uncleanable because it was at tail.
810		*
811		* @return current cleanMe node (or null)
812		*/
813	<	private QNode reclean() {
813	>	private Node reclean() {
814		/*
815	<	* cleanMe is, or at one time was, predecessor of cancelled
816	<	* node s that was the tail so could not be unspliced.  If s
815	>	* cleanMe is, or at one time was, predecessor of a cancelled
816	>	* node s that was the tail so could not be unspliced.  If it
817		* is no longer the tail, try to unsplice if necessary and
818		* make cleanMe slot available.  This differs from similar
819	<	* code in clean() because we must check that pred still
820	<	* points to a cancelled node that must be unspliced -- if
821	<	* not, we can (must) clear cleanMe without unsplicing.
822	<	* This can loop only due to contention on casNext or
396	<	* clearing cleanMe.
819	>	* code in unsplice() because we must check that pred still
820	>	* points to a matched node that can be unspliced -- if not,
821	>	* we can (must) clear cleanMe without unsplicing.  This can
822	>	* loop only due to contention.
823		*/
824	<	QNode pred;
825	<	while ((pred = cleanMe.get()) != null) {
826	<	QNode t = getValidatedTail();
827	<	QNode s = pred.next;
828	<	if (s != t) {
829	<	QNode sn;
830	<	if (s == null || s == pred || s.get() != s ||
831	<	(sn = s.next) == s || pred.casNext(s, sn))
832	<	cleanMe.compareAndSet(pred, null);
824	>	Node pred;
825	>	while ((pred = cleanMe) != null) {
826	>	Node s = pred.next;
827	>	Node n;
828	>	if (s == null || s == pred || !s.isMatched())
829	>	casCleanMe(pred, null); // already gone
830	>	else if ((n = s.next) != null) {
831	>	if (n != s)
832	>	pred.casNext(s, n);
833	>	casCleanMe(pred, null);
834		}
835	<	else // s is still tail; cannot clean
835	>	else
836		break;
837		}
838		return pred;
839		}
840
841		/**
842	+	* Main implementation of Iterator.remove(). Find
843	+	* and unsplice the given node.
844	+	*/
845	+	final void findAndRemoveNode(Node s) {
846	+	if (s.tryMatchData()) {
847	+	Node pred = null;
848	+	Node p = head;
849	+	while (p != null) {
850	+	if (p == s) {
851	+	unsplice(pred, p);
852	+	break;
853	+	}
854	+	if (!p.isData && !p.isMatched())
855	+	break;
856	+	pred = p;
857	+	if ((p = p.next) == pred) { // stale
858	+	pred = null;
859	+	p = head;
860	+	}
861	+	}
862	+	}
863	+	}
864	+
865	+	/**
866	+	* Main implementation of remove(Object)
867	+	*/
868	+	private boolean findAndRemove(Object e) {
869	+	if (e != null) {
870	+	Node pred = null;
871	+	Node p = head;
872	+	while (p != null) {
873	+	Object item = p.item;
874	+	if (p.isData) {
875	+	if (item != null && item != p && e.equals(item) &&
876	+	p.tryMatchData()) {
877	+	unsplice(pred, p);
878	+	return true;
879	+	}
880	+	}
881	+	else if (item == null)
882	+	break;
883	+	pred = p;
884	+	if ((p = p.next) == pred) {
885	+	pred = null;
886	+	p = head;
887	+	}
888	+	}
889	+	}
890	+	return false;
891	+	}
892	+
893	+
894	+	/**
895		* Creates an initially empty {@code LinkedTransferQueue}.
896		*/
897		public LinkedTransferQueue() {
418	–	QNode dummy = new QNode(null, false);
419	–	head = new PaddedAtomicReference<QNode>(dummy);
420	–	tail = new PaddedAtomicReference<QNode>(dummy);
421	–	cleanMe = new PaddedAtomicReference<QNode>(null);
898		}
899
900		/**
#	Line 435 | Line 911 | public class LinkedTransferQueue<E> exte
911		addAll(c);
912		}
913
914	<	public void put(E e) throws InterruptedException {
915	<	if (e == null) throw new NullPointerException();
916	<	if (Thread.interrupted()) throw new InterruptedException();
917	<	xfer(e, NOWAIT, 0);
914	>	/**
915	>	* Inserts the specified element at the tail of this queue.
916	>	* As the queue is unbounded, this method will never block.
917	>	*
918	>	* @throws NullPointerException if the specified element is null
919	>	*/
920	>	public void put(E e) {
921	>	xfer(e, true, ASYNC, 0);
922		}
923
924	<	public boolean offer(E e, long timeout, TimeUnit unit)
925	<	throws InterruptedException {
926	<	if (e == null) throw new NullPointerException();
927	<	if (Thread.interrupted()) throw new InterruptedException();
928	<	xfer(e, NOWAIT, 0);
924	>	/**
925	>	* Inserts the specified element at the tail of this queue.
926	>	* As the queue is unbounded, this method will never block or
927	>	* return {@code false}.
928	>	*
929	>	* @return {@code true} (as specified by
930	>	*  {@link BlockingQueue#offer(Object,long,TimeUnit) BlockingQueue.offer})
931	>	* @throws NullPointerException if the specified element is null
932	>	*/
933	>	public boolean offer(E e, long timeout, TimeUnit unit) {
934	>	xfer(e, true, ASYNC, 0);
935		return true;
936		}
937
938	+	/**
939	+	* Inserts the specified element at the tail of this queue.
940	+	* As the queue is unbounded, this method will never return {@code false}.
941	+	*
942	+	* @return {@code true} (as specified by
943	+	*         {@link BlockingQueue#offer(Object) BlockingQueue.offer})
944	+	* @throws NullPointerException if the specified element is null
945	+	*/
946		public boolean offer(E e) {
947	<	if (e == null) throw new NullPointerException();
454	<	xfer(e, NOWAIT, 0);
947	>	xfer(e, true, ASYNC, 0);
948		return true;
949		}
950
951	+	/**
952	+	* Inserts the specified element at the tail of this queue.
953	+	* As the queue is unbounded, this method will never throw
954	+	* {@link IllegalStateException} or return {@code false}.
955	+	*
956	+	* @return {@code true} (as specified by {@link Collection#add})
957	+	* @throws NullPointerException if the specified element is null
958	+	*/
959		public boolean add(E e) {
960	<	if (e == null) throw new NullPointerException();
460	<	xfer(e, NOWAIT, 0);
960	>	xfer(e, true, ASYNC, 0);
961		return true;
962		}
963
964	+	/**
965	+	* Transfers the element to a waiting consumer immediately, if possible.
966	+	*
967	+	* <p>More precisely, transfers the specified element immediately
968	+	* if there exists a consumer already waiting to receive it (in
969	+	* {@link #take} or timed {@link #poll(long,TimeUnit) poll}),
970	+	* otherwise returning {@code false} without enqueuing the element.
971	+	*
972	+	* @throws NullPointerException if the specified element is null
973	+	*/
974	+	public boolean tryTransfer(E e) {
975	+	return xfer(e, true, NOW, 0) == null;
976	+	}
977	+
978	+	/**
979	+	* Transfers the element to a consumer, waiting if necessary to do so.
980	+	*
981	+	* <p>More precisely, transfers the specified element immediately
982	+	* if there exists a consumer already waiting to receive it (in
983	+	* {@link #take} or timed {@link #poll(long,TimeUnit) poll}),
984	+	* else inserts the specified element at the tail of this queue
985	+	* and waits until the element is received by a consumer.
986	+	*
987	+	* @throws NullPointerException if the specified element is null
988	+	*/
989		public void transfer(E e) throws InterruptedException {
990	<	if (e == null) throw new NullPointerException();
991	<	if (xfer(e, WAIT, 0) == null) {
467	<	Thread.interrupted();
990	>	if (xfer(e, true, SYNC, 0) != null) {
991	>	Thread.interrupted(); // failure possible only due to interrupt
992		throw new InterruptedException();
993		}
994		}
995
996	+	/**
997	+	* Transfers the element to a consumer if it is possible to do so
998	+	* before the timeout elapses.
999	+	*
1000	+	* <p>More precisely, transfers the specified element immediately
1001	+	* if there exists a consumer already waiting to receive it (in
1002	+	* {@link #take} or timed {@link #poll(long,TimeUnit) poll}),
1003	+	* else inserts the specified element at the tail of this queue
1004	+	* and waits until the element is received by a consumer,
1005	+	* returning {@code false} if the specified wait time elapses
1006	+	* before the element can be transferred.
1007	+	*
1008	+	* @throws NullPointerException if the specified element is null
1009	+	*/
1010		public boolean tryTransfer(E e, long timeout, TimeUnit unit)
1011		throws InterruptedException {
1012	<	if (e == null) throw new NullPointerException();
475	<	if (xfer(e, TIMEOUT, unit.toNanos(timeout)) != null)
1012	>	if (xfer(e, true, TIMEOUT, unit.toNanos(timeout)) == null)
1013		return true;
1014		if (!Thread.interrupted())
1015		return false;
1016		throw new InterruptedException();
1017		}
1018
482	–	public boolean tryTransfer(E e) {
483	–	if (e == null) throw new NullPointerException();
484	–	return fulfill(e) != null;
485	–	}
486	–
1019		public E take() throws InterruptedException {
1020	<	Object e = xfer(null, WAIT, 0);
1020	>	Object e = xfer(null, false, SYNC, 0);
1021		if (e != null)
1022		return (E)e;
1023		Thread.interrupted();
#	Line 493 | Line 1025 | public class LinkedTransferQueue<E> exte
1025		}
1026
1027		public E poll(long timeout, TimeUnit unit) throws InterruptedException {
1028	<	Object e = xfer(null, TIMEOUT, unit.toNanos(timeout));
1028	>	Object e = xfer(null, false, TIMEOUT, unit.toNanos(timeout));
1029		if (e != null || !Thread.interrupted())
1030		return (E)e;
1031		throw new InterruptedException();
1032		}
1033
1034		public E poll() {
1035	<	return (E)fulfill(null);
1035	>	return (E)xfer(null, false, NOW, 0);
1036		}
1037
1038	+	/**
1039	+	* @throws NullPointerException     {@inheritDoc}
1040	+	* @throws IllegalArgumentException {@inheritDoc}
1041	+	*/
1042		public int drainTo(Collection<? super E> c) {
1043		if (c == null)
1044		throw new NullPointerException();
#	Line 517 | Line 1053 | public class LinkedTransferQueue<E> exte
1053		return n;
1054		}
1055
1056	+	/**
1057	+	* @throws NullPointerException     {@inheritDoc}
1058	+	* @throws IllegalArgumentException {@inheritDoc}
1059	+	*/
1060		public int drainTo(Collection<? super E> c, int maxElements) {
1061		if (c == null)
1062		throw new NullPointerException();
#	Line 531 | Line 1071 | public class LinkedTransferQueue<E> exte
1071		return n;
1072		}
1073
534	–	// Traversal-based methods
535	–
1074		/**
1075	<	* Returns head after performing any outstanding helping steps.
1075	>	* Returns an iterator over the elements in this queue in proper
1076	>	* sequence, from head to tail.
1077	>	*
1078	>	* <p>The returned iterator is a "weakly consistent" iterator that
1079	>	* will never throw
1080	>	* {@link ConcurrentModificationException ConcurrentModificationException},
1081	>	* and guarantees to traverse elements as they existed upon
1082	>	* construction of the iterator, and may (but is not guaranteed
1083	>	* to) reflect any modifications subsequent to construction.
1084	>	*
1085	>	* @return an iterator over the elements in this queue in proper sequence
1086		*/
539	–	private QNode traversalHead() {
540	–	for (;;) {
541	–	QNode t = tail.get();
542	–	QNode h = head.get();
543	–	if (h != null && t != null) {
544	–	QNode last = t.next;
545	–	QNode first = h.next;
546	–	if (t == tail.get()) {
547	–	if (last != null)
548	–	tail.compareAndSet(t, last);
549	–	else if (first != null) {
550	–	Object x = first.get();
551	–	if (x == first)
552	–	advanceHead(h, first);
553	–	else
554	–	return h;
555	–	}
556	–	else
557	–	return h;
558	–	}
559	–	}
560	–	reclean();
561	–	}
562	–	}
563	–
564	–
1087		public Iterator<E> iterator() {
1088		return new Itr();
1089		}
1090
569	–	/**
570	–	* Iterators. Basic strategy is to traverse list, treating
571	–	* non-data (i.e., request) nodes as terminating list.
572	–	* Once a valid data node is found, the item is cached
573	–	* so that the next call to next() will return it even
574	–	* if subsequently removed.
575	–	*/
576	–	class Itr implements Iterator<E> {
577	–	QNode next;        // node to return next
578	–	QNode pnext;       // predecessor of next
579	–	QNode snext;       // successor of next
580	–	QNode curr;        // last returned node, for remove()
581	–	QNode pcurr;       // predecessor of curr, for remove()
582	–	E nextItem;        // Cache of next item, once committed to in next
583	–
584	–	Itr() {
585	–	findNext();
586	–	}
587	–
588	–	/**
589	–	* Ensures next points to next valid node, or null if none.
590	–	*/
591	–	void findNext() {
592	–	for (;;) {
593	–	QNode pred = pnext;
594	–	QNode q = next;
595	–	if (pred == null || pred == q) {
596	–	pred = traversalHead();
597	–	q = pred.next;
598	–	}
599	–	if (q == null || !q.isData) {
600	–	next = null;
601	–	return;
602	–	}
603	–	Object x = q.get();
604	–	QNode s = q.next;
605	–	if (x != null && q != x && q != s) {
606	–	nextItem = (E)x;
607	–	snext = s;
608	–	pnext = pred;
609	–	next = q;
610	–	return;
611	–	}
612	–	pnext = q;
613	–	next = s;
614	–	}
615	–	}
616	–
617	–	public boolean hasNext() {
618	–	return next != null;
619	–	}
620	–
621	–	public E next() {
622	–	if (next == null) throw new NoSuchElementException();
623	–	pcurr = pnext;
624	–	curr = next;
625	–	pnext = next;
626	–	next = snext;
627	–	E x = nextItem;
628	–	findNext();
629	–	return x;
630	–	}
631	–
632	–	public void remove() {
633	–	QNode p = curr;
634	–	if (p == null)
635	–	throw new IllegalStateException();
636	–	Object x = p.get();
637	–	if (x != null && x != p && p.compareAndSet(x, p))
638	–	clean(pcurr, p);
639	–	}
640	–	}
641	–
1091		public E peek() {
1092	<	for (;;) {
644	<	QNode h = traversalHead();
645	<	QNode p = h.next;
646	<	if (p == null)
647	<	return null;
648	<	Object x = p.get();
649	<	if (p != x) {
650	<	if (!p.isData)
651	<	return null;
652	<	if (x != null)
653	<	return (E)x;
654	<	}
655	<	}
1092	>	return (E) firstDataItem();
1093		}
1094
1095	+	/**
1096	+	* Returns {@code true} if this queue contains no elements.
1097	+	*
1098	+	* @return {@code true} if this queue contains no elements
1099	+	*/
1100		public boolean isEmpty() {
1101	<	for (;;) {
660	<	QNode h = traversalHead();
661	<	QNode p = h.next;
662	<	if (p == null)
663	<	return true;
664	<	Object x = p.get();
665	<	if (p != x) {
666	<	if (!p.isData)
667	<	return true;
668	<	if (x != null)
669	<	return false;
670	<	}
671	<	}
1101	>	return firstOfMode(true) == null;
1102		}
1103
1104		public boolean hasWaitingConsumer() {
1105	<	for (;;) {
676	<	QNode h = traversalHead();
677	<	QNode p = h.next;
678	<	if (p == null)
679	<	return false;
680	<	Object x = p.get();
681	<	if (p != x)
682	<	return !p.isData;
683	<	}
1105	>	return firstOfMode(false) != null;
1106		}
1107
1108		/**
#	Line 696 | Line 1118 | public class LinkedTransferQueue<E> exte
1118		* @return the number of elements in this queue
1119		*/
1120		public int size() {
1121	<	int count = 0;
700	<	QNode h = traversalHead();
701	<	for (QNode p = h.next; p != null && p.isData; p = p.next) {
702	<	Object x = p.get();
703	<	if (x != null && x != p) {
704	<	if (++count == Integer.MAX_VALUE) // saturated
705	<	break;
706	<	}
707	<	}
708	<	return count;
1121	>	return countOfMode(true);
1122		}
1123
1124		public int getWaitingConsumerCount() {
1125	<	int count = 0;
713	<	QNode h = traversalHead();
714	<	for (QNode p = h.next; p != null && !p.isData; p = p.next) {
715	<	if (p.get() == null) {
716	<	if (++count == Integer.MAX_VALUE)
717	<	break;
718	<	}
719	<	}
720	<	return count;
1125	>	return countOfMode(false);
1126		}
1127
1128	<	public int remainingCapacity() {
1129	<	return Integer.MAX_VALUE;
1128	>	/**
1129	>	* Removes a single instance of the specified element from this queue,
1130	>	* if it is present.  More formally, removes an element {@code e} such
1131	>	* that {@code o.equals(e)}, if this queue contains one or more such
1132	>	* elements.
1133	>	* Returns {@code true} if this queue contained the specified element
1134	>	* (or equivalently, if this queue changed as a result of the call).
1135	>	*
1136	>	* @param o element to be removed from this queue, if present
1137	>	* @return {@code true} if this queue changed as a result of the call
1138	>	*/
1139	>	public boolean remove(Object o) {
1140	>	return findAndRemove(o);
1141		}
1142
1143	<	public boolean remove(Object o) {
1144	<	if (o == null)
1145	<	return false;
1146	<	for (;;) {
1147	<	QNode pred = traversalHead();
1148	<	for (;;) {
1149	<	QNode q = pred.next;
1150	<	if (q == null || !q.isData)
1151	<	return false;
736	<	if (q == pred) // restart
737	<	break;
738	<	Object x = q.get();
739	<	if (x != null && x != q && o.equals(x) &&
740	<	q.compareAndSet(x, q)) {
741	<	clean(pred, q);
742	<	return true;
743	<	}
744	<	pred = q;
745	<	}
746	<	}
1143	>	/**
1144	>	* Always returns {@code Integer.MAX_VALUE} because a
1145	>	* {@code LinkedTransferQueue} is not capacity constrained.
1146	>	*
1147	>	* @return {@code Integer.MAX_VALUE} (as specified by
1148	>	*         {@link BlockingQueue#remainingCapacity()})
1149	>	*/
1150	>	public int remainingCapacity() {
1151	>	return Integer.MAX_VALUE;
1152		}
1153
1154		/**
1155	<	* Save the state to a stream (that is, serialize it).
1155	>	* Saves the state to a stream (that is, serializes it).
1156		*
1157		* @serialData All of the elements (each an {@code E}) in
1158		* the proper order, followed by a null
#	Line 763 | Line 1168 | public class LinkedTransferQueue<E> exte
1168		}
1169
1170		/**
1171	<	* Reconstitute the Queue instance from a stream (that is,
1172	<	* deserialize it).
1171	>	* Reconstitutes the Queue instance from a stream (that is,
1172	>	* deserializes it).
1173		*
1174		* @param s the stream
1175		*/
1176		private void readObject(java.io.ObjectInputStream s)
1177		throws java.io.IOException, ClassNotFoundException {
1178		s.defaultReadObject();
774	–	resetHeadAndTail();
1179		for (;;) {
1180	<	E item = (E)s.readObject();
1180	>	@SuppressWarnings("unchecked") E item = (E) s.readObject();
1181		if (item == null)
1182		break;
1183		else
#	Line 782 | Line 1186 | public class LinkedTransferQueue<E> exte
1186		}
1187
1188
1189	<	// Support for resetting head/tail while deserializing
1190	<	private void resetHeadAndTail() {
1191	<	QNode dummy = new QNode(null, false);
1192	<	_unsafe.putObjectVolatile(this, headOffset,
1193	<	new PaddedAtomicReference<QNode>(dummy));
1194	<	_unsafe.putObjectVolatile(this, tailOffset,
1195	<	new PaddedAtomicReference<QNode>(dummy));
1196	<	_unsafe.putObjectVolatile(this, cleanMeOffset,
1197	<	new PaddedAtomicReference<QNode>(null));
1189	>	// Unsafe mechanics
1190	>
1191	>	private static final sun.misc.Unsafe UNSAFE = getUnsafe();
1192	>	private static final long headOffset =
1193	>	objectFieldOffset(UNSAFE, "head", LinkedTransferQueue.class);
1194	>	private static final long tailOffset =
1195	>	objectFieldOffset(UNSAFE, "tail", LinkedTransferQueue.class);
1196	>	private static final long cleanMeOffset =
1197	>	objectFieldOffset(UNSAFE, "cleanMe", LinkedTransferQueue.class);
1198	>
1199	>	static long objectFieldOffset(sun.misc.Unsafe UNSAFE,
1200	>	String field, Class<?> klazz) {
1201	>	try {
1202	>	return UNSAFE.objectFieldOffset(klazz.getDeclaredField(field));
1203	>	} catch (NoSuchFieldException e) {
1204	>	// Convert Exception to corresponding Error
1205	>	NoSuchFieldError error = new NoSuchFieldError(field);
1206	>	error.initCause(e);
1207	>	throw error;
1208	>	}
1209		}
1210
1211	<	// Temporary Unsafe mechanics for preliminary release
797	<	private static Unsafe getUnsafe() throws Throwable {
1211	>	private static sun.misc.Unsafe getUnsafe() {
1212		try {
1213	<	return Unsafe.getUnsafe();
1213	>	return sun.misc.Unsafe.getUnsafe();
1214		} catch (SecurityException se) {
1215		try {
1216		return java.security.AccessController.doPrivileged
1217	<	(new java.security.PrivilegedExceptionAction<Unsafe>() {
1218	<	public Unsafe run() throws Exception {
1219	<	return getUnsafePrivileged();
1217	>	(new java.security
1218	>	.PrivilegedExceptionAction<sun.misc.Unsafe>() {
1219	>	public sun.misc.Unsafe run() throws Exception {
1220	>	java.lang.reflect.Field f = sun.misc
1221	>	.Unsafe.class.getDeclaredField("theUnsafe");
1222	>	f.setAccessible(true);
1223	>	return (sun.misc.Unsafe) f.get(null);
1224		}});
1225		} catch (java.security.PrivilegedActionException e) {
1226	<	throw e.getCause();
1226	>	throw new RuntimeException("Could not initialize intrinsics",
1227	>	e.getCause());
1228		}
1229		}
1230		}
1231
813	–	private static Unsafe getUnsafePrivileged()
814	–	throws NoSuchFieldException, IllegalAccessException {
815	–	Field f = Unsafe.class.getDeclaredField("theUnsafe");
816	–	f.setAccessible(true);
817	–	return (Unsafe) f.get(null);
818	–	}
819	–
820	–	private static long fieldOffset(String fieldName)
821	–	throws NoSuchFieldException {
822	–	return _unsafe.objectFieldOffset
823	–	(LinkedTransferQueue.class.getDeclaredField(fieldName));
824	–	}
825	–
826	–	private static final Unsafe _unsafe;
827	–	private static final long headOffset;
828	–	private static final long tailOffset;
829	–	private static final long cleanMeOffset;
830	–	static {
831	–	try {
832	–	_unsafe = getUnsafe();
833	–	headOffset = fieldOffset("head");
834	–	tailOffset = fieldOffset("tail");
835	–	cleanMeOffset = fieldOffset("cleanMe");
836	–	} catch (Throwable e) {
837	–	throw new RuntimeException("Could not initialize intrinsics", e);
838	–	}
839	–	}
840	–
1232		}

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