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root/jsr166/jsr166/src/jsr166y/ForkJoinPool.java

Comparing jsr166/src/jsr166y/ForkJoinPool.java (file contents):
Revision 1.45 by dl, Tue Aug 4 12:41:27 2009 UTC vs.
Revision 1.65 by dl, Wed Aug 18 14:05:27 2010 UTC

#	Line 13 | Line 13 | import java.util.Arrays;
13		import java.util.Collection;
14		import java.util.Collections;
15		import java.util.List;
16	–	import java.util.concurrent.locks.Condition;
16		import java.util.concurrent.locks.LockSupport;
17		import java.util.concurrent.locks.ReentrantLock;
18		import java.util.concurrent.atomic.AtomicInteger;
19	<	import java.util.concurrent.atomic.AtomicLong;
19	>	import java.util.concurrent.CountDownLatch;
20
21		/**
22		* An {@link ExecutorService} for running {@link ForkJoinTask}s.
23		* A {@code ForkJoinPool} provides the entry point for submissions
24	<	* from non-{@code ForkJoinTask}s, as well as management and
25	<	* monitoring operations.
24	>	* from non-{@code ForkJoinTask} clients, as well as management and
25	>	* monitoring operations.
26		*
27		* <p>A {@code ForkJoinPool} differs from other kinds of {@link
28		* ExecutorService} mainly by virtue of employing
#	Line 31 | Line 30 | import java.util.concurrent.atomic.Atomi
30		* execute subtasks created by other active tasks (eventually blocking
31		* waiting for work if none exist). This enables efficient processing
32		* when most tasks spawn other subtasks (as do most {@code
33	<	* ForkJoinTask}s). A {@code ForkJoinPool} may also be used for mixed
34	<	* execution of some plain {@code Runnable}- or {@code Callable}-
35	<	* based activities along with {@code ForkJoinTask}s. When setting
37	<	* {@linkplain #setAsyncMode async mode}, a {@code ForkJoinPool} may
38	<	* also be appropriate for use with fine-grained tasks of any form
39	<	* that are never joined. Otherwise, other {@code ExecutorService}
40	<	* implementations are typically more appropriate choices.
33	>	* ForkJoinTask}s). When setting <em>asyncMode</em> to true in
34	>	* constructors, {@code ForkJoinPool}s may also be appropriate for use
35	>	* with event-style tasks that are never joined.
36		*
37		* <p>A {@code ForkJoinPool} is constructed with a given target
38		* parallelism level; by default, equal to the number of available
39	<	* processors. Unless configured otherwise via {@link
40	<	* #setMaintainsParallelism}, the pool attempts to maintain this
41	<	* number of active (or available) threads by dynamically adding,
42	<	* suspending, or resuming internal worker threads, even if some tasks
43	<	* are stalled waiting to join others. However, no such adjustments
44	<	* are performed in the face of blocked IO or other unmanaged
45	<	* synchronization. The nested {@link ManagedBlocker} interface
51	<	* enables extension of the kinds of synchronization accommodated.
52	<	* The target parallelism level may also be changed dynamically
53	<	* ({@link #setParallelism}). The total number of threads may be
54	<	* limited using method {@link #setMaximumPoolSize}, in which case it
55	<	* may become possible for the activities of a pool to stall due to
56	<	* the lack of available threads to process new tasks.
39	>	* processors. The pool attempts to maintain enough active (or
40	>	* available) threads by dynamically adding, suspending, or resuming
41	>	* internal worker threads, even if some tasks are stalled waiting to
42	>	* join others. However, no such adjustments are guaranteed in the
43	>	* face of blocked IO or other unmanaged synchronization. The nested
44	>	* {@link ManagedBlocker} interface enables extension of the kinds of
45	>	* synchronization accommodated.
46		*
47		* <p>In addition to execution and lifecycle control methods, this
48		* class provides status check methods (for example
#	Line 62 | Line 51 | import java.util.concurrent.atomic.Atomi
51		* {@link #toString} returns indications of pool state in a
52		* convenient form for informal monitoring.
53		*
54	+	* <p> As is the case with other ExecutorServices, there are three
55	+	* main task execution methods summarized in the following
56	+	* table. These are designed to be used by clients not already engaged
57	+	* in fork/join computations in the current pool.  The main forms of
58	+	* these methods accept instances of {@code ForkJoinTask}, but
59	+	* overloaded forms also allow mixed execution of plain {@code
60	+	* Runnable}- or {@code Callable}- based activities as well.  However,
61	+	* tasks that are already executing in a pool should normally
62	+	* <em>NOT</em> use these pool execution methods, but instead use the
63	+	* within-computation forms listed in the table.
64	+	*
65	+	* <table BORDER CELLPADDING=3 CELLSPACING=1>
66	+	*  <tr>
67	+	*    <td></td>
68	+	*    <td ALIGN=CENTER> <b>Call from non-fork/join clients</b></td>
69	+	*    <td ALIGN=CENTER> <b>Call from within fork/join computations</b></td>
70	+	*  </tr>
71	+	*  <tr>
72	+	*    <td> <b>Arange async execution</td>
73	+	*    <td> {@link #execute(ForkJoinTask)}</td>
74	+	*    <td> {@link ForkJoinTask#fork}</td>
75	+	*  </tr>
76	+	*  <tr>
77	+	*    <td> <b>Await and obtain result</td>
78	+	*    <td> {@link #invoke(ForkJoinTask)}</td>
79	+	*    <td> {@link ForkJoinTask#invoke}</td>
80	+	*  </tr>
81	+	*  <tr>
82	+	*    <td> <b>Arrange exec and obtain Future</td>
83	+	*    <td> {@link #submit(ForkJoinTask)}</td>
84	+	*    <td> {@link ForkJoinTask#fork} (ForkJoinTasks <em>are</em> Futures)</td>
85	+	*  </tr>
86	+	* </table>
87	+	*
88		* <p><b>Sample Usage.</b> Normally a single {@code ForkJoinPool} is
89		* used for all parallel task execution in a program or subsystem.
90		* Otherwise, use would not usually outweigh the construction and
#	Line 82 | Line 105 | import java.util.concurrent.atomic.Atomi
105		*
106		* <p><b>Implementation notes</b>: This implementation restricts the
107		* maximum number of running threads to 32767. Attempts to create
108	<	* pools with greater than the maximum result in
108	>	* pools with greater than the maximum number result in
109		* {@code IllegalArgumentException}.
110		*
111	+	* <p>This implementation rejects submitted tasks (that is, by throwing
112	+	* {@link RejectedExecutionException}) only when the pool is shut down
113	+	* or internal resources have been exhausted.
114	+	*
115		* @since 1.7
116		* @author Doug Lea
117		*/
118		public class ForkJoinPool extends AbstractExecutorService {
119
120		/*
121	<	* See the extended comments interspersed below for design,
122	<	* rationale, and walkthroughs.
121	>	* Implementation Overview
122	>	*
123	>	* This class provides the central bookkeeping and control for a
124	>	* set of worker threads: Submissions from non-FJ threads enter
125	>	* into a submission queue. Workers take these tasks and typically
126	>	* split them into subtasks that may be stolen by other workers.
127	>	* The main work-stealing mechanics implemented in class
128	>	* ForkJoinWorkerThread give first priority to processing tasks
129	>	* from their own queues (LIFO or FIFO, depending on mode), then
130	>	* to randomized FIFO steals of tasks in other worker queues, and
131	>	* lastly to new submissions. These mechanics do not consider
132	>	* affinities, loads, cache localities, etc, so rarely provide the
133	>	* best possible performance on a given machine, but portably
134	>	* provide good throughput by averaging over these factors.
135	>	* (Further, even if we did try to use such information, we do not
136	>	* usually have a basis for exploiting it. For example, some sets
137	>	* of tasks profit from cache affinities, but others are harmed by
138	>	* cache pollution effects.)
139	>	*
140	>	* Beyond work-stealing support and essential bookkeeping, the
141	>	* main responsibility of this framework is to take actions when
142	>	* one worker is waiting to join a task stolen (or always held by)
143	>	* another.  Becauae we are multiplexing many tasks on to a pool
144	>	* of workers, we can't just let them block (as in Thread.join).
145	>	* We also cannot just reassign the joiner's run-time stack with
146	>	* another and replace it later, which would be a form of
147	>	* "continuation", that even if possible is not necessarily a good
148	>	* idea. Given that the creation costs of most threads on most
149	>	* systems mainly surrounds setting up runtime stacks, thread
150	>	* creation and switching is usually not much more expensive than
151	>	* stack creation and switching, and is more flexible). Instead we
152	>	* combine two tactics:
153	>	*
154	>	*   Helping: Arranging for the joiner to execute some task that it
155	>	*      would be running if the steal had not occurred.  Method
156	>	*      ForkJoinWorkerThread.helpJoinTask tracks joining->stealing
157	>	*      links to try to find such a task.
158	>	*
159	>	*   Compensating: Unless there are already enough live threads,
160	>	*      method helpMaintainParallelism() may create or or
161	>	*      re-activate a spare thread to compensate for blocked
162	>	*      joiners until they unblock.
163	>	*
164	>	* Because the determining existence of conservatively safe
165	>	* helping targets, the availability of already-created spares,
166	>	* and the apparent need to create new spares are all racy and
167	>	* require heuristic guidance, we rely on multiple retries of
168	>	* each. Further, because it is impossible to keep exactly the
169	>	* target (parallelism) number of threads running at any given
170	>	* time, we allow compensation during joins to fail, and enlist
171	>	* all other threads to help out whenever they are not otherwise
172	>	* occupied (i.e., mainly in method preStep).
173	>	*
174	>	* The ManagedBlocker extension API can't use helping so relies
175	>	* only on compensation in method awaitBlocker.
176	>	*
177	>	* The main throughput advantages of work-stealing stem from
178	>	* decentralized control -- workers mostly steal tasks from each
179	>	* other. We do not want to negate this by creating bottlenecks
180	>	* implementing other management responsibilities. So we use a
181	>	* collection of techniques that avoid, reduce, or cope well with
182	>	* contention. These entail several instances of bit-packing into
183	>	* CASable fields to maintain only the minimally required
184	>	* atomicity. To enable such packing, we restrict maximum
185	>	* parallelism to (1<<15)-1 (enabling twice this (to accommodate
186	>	* unbalanced increments and decrements) to fit into a 16 bit
187	>	* field, which is far in excess of normal operating range.  Even
188	>	* though updates to some of these bookkeeping fields do sometimes
189	>	* contend with each other, they don't normally cache-contend with
190	>	* updates to others enough to warrant memory padding or
191	>	* isolation. So they are all held as fields of ForkJoinPool
192	>	* objects.  The main capabilities are as follows:
193	>	*
194	>	* 1. Creating and removing workers. Workers are recorded in the
195	>	* "workers" array. This is an array as opposed to some other data
196	>	* structure to support index-based random steals by workers.
197	>	* Updates to the array recording new workers and unrecording
198	>	* terminated ones are protected from each other by a lock
199	>	* (workerLock) but the array is otherwise concurrently readable,
200	>	* and accessed directly by workers. To simplify index-based
201	>	* operations, the array size is always a power of two, and all
202	>	* readers must tolerate null slots. Currently, all worker thread
203	>	* creation is on-demand, triggered by task submissions,
204	>	* replacement of terminated workers, and/or compensation for
205	>	* blocked workers. However, all other support code is set up to
206	>	* work with other policies.
207	>	*
208	>	* To ensure that we do not hold on to worker references that
209	>	* would prevent GC, ALL accesses to workers are via indices into
210	>	* the workers array (which is one source of some of the unusual
211	>	* code constructions here). In essence, the workers array serves
212	>	* as a WeakReference mechanism. Thus for example the event queue
213	>	* stores worker indices, not worker references. Access to the
214	>	* workers in associated methods (for example releaseEventWaiters)
215	>	* must both index-check and null-check the IDs. All such accesses
216	>	* ignore bad IDs by returning out early from what they are doing,
217	>	* since this can only be associated with shutdown, in which case
218	>	* it is OK to give up. On termination, we just clobber these
219	>	* data structures without trying to use them.
220	>	*
221	>	* 2. Bookkeeping for dynamically adding and removing workers. We
222	>	* aim to approximately maintain the given level of parallelism.
223	>	* When some workers are known to be blocked (on joins or via
224	>	* ManagedBlocker), we may create or resume others to take their
225	>	* place until they unblock (see below). Implementing this
226	>	* requires counts of the number of "running" threads (i.e., those
227	>	* that are neither blocked nor artifically suspended) as well as
228	>	* the total number.  These two values are packed into one field,
229	>	* "workerCounts" because we need accurate snapshots when deciding
230	>	* to create, resume or suspend.  Note however that the
231	>	* correspondance of these counts to reality is not guaranteed. In
232	>	* particular updates for unblocked threads may lag until they
233	>	* actually wake up.
234	>	*
235	>	* 3. Maintaining global run state. The run state of the pool
236	>	* consists of a runLevel (SHUTDOWN, TERMINATING, etc) similar to
237	>	* those in other Executor implementations, as well as a count of
238	>	* "active" workers -- those that are, or soon will be, or
239	>	* recently were executing tasks. The runLevel and active count
240	>	* are packed together in order to correctly trigger shutdown and
241	>	* termination. Without care, active counts can be subject to very
242	>	* high contention.  We substantially reduce this contention by
243	>	* relaxing update rules.  A worker must claim active status
244	>	* prospectively, by activating if it sees that a submitted or
245	>	* stealable task exists (it may find after activating that the
246	>	* task no longer exists). It stays active while processing this
247	>	* task (if it exists) and any other local subtasks it produces,
248	>	* until it cannot find any other tasks. It then tries
249	>	* inactivating (see method preStep), but upon update contention
250	>	* instead scans for more tasks, later retrying inactivation if it
251	>	* doesn't find any.
252	>	*
253	>	* 4. Managing idle workers waiting for tasks. We cannot let
254	>	* workers spin indefinitely scanning for tasks when none are
255	>	* available. On the other hand, we must quickly prod them into
256	>	* action when new tasks are submitted or generated.  We
257	>	* park/unpark these idle workers using an event-count scheme.
258	>	* Field eventCount is incremented upon events that may enable
259	>	* workers that previously could not find a task to now find one:
260	>	* Submission of a new task to the pool, or another worker pushing
261	>	* a task onto a previously empty queue.  (We also use this
262	>	* mechanism for configuration and termination actions that
263	>	* require wakeups of idle workers).  Each worker maintains its
264	>	* last known event count, and blocks when a scan for work did not
265	>	* find a task AND its lastEventCount matches the current
266	>	* eventCount. Waiting idle workers are recorded in a variant of
267	>	* Treiber stack headed by field eventWaiters which, when nonzero,
268	>	* encodes the thread index and count awaited for by the worker
269	>	* thread most recently calling eventSync. This thread in turn has
270	>	* a record (field nextEventWaiter) for the next waiting worker.
271	>	* In addition to allowing simpler decisions about need for
272	>	* wakeup, the event count bits in eventWaiters serve the role of
273	>	* tags to avoid ABA errors in Treiber stacks. Upon any wakeup,
274	>	* released threads also try to release others (but give up upon
275	>	* contention to reduce useless flailing).  The net effect is a
276	>	* tree-like diffusion of signals, where released threads (and
277	>	* possibly others) help with unparks.  To further reduce
278	>	* contention effects a bit, failed CASes to increment field
279	>	* eventCount are tolerated without retries in signalWork.
280	>	* Conceptually they are merged into the same event, which is OK
281	>	* when their only purpose is to enable workers to scan for work.
282	>	*
283	>	* 5. Managing suspension of extra workers. When a worker is about
284	>	* to block waiting for a join (or via ManagedBlockers), we may
285	>	* create a new thread to maintain parallelism level, or at least
286	>	* avoid starvation. Usually, extra threads are needed for only
287	>	* very short periods, yet join dependencies are such that we
288	>	* sometimes need them in bursts. Rather than create new threads
289	>	* each time this happens, we suspend no-longer-needed extra ones
290	>	* as "spares". For most purposes, we don't distinguish "extra"
291	>	* spare threads from normal "core" threads: On each call to
292	>	* preStep (the only point at which we can do this) a worker
293	>	* checks to see if there are now too many running workers, and if
294	>	* so, suspends itself.  Method helpMaintainParallelism looks for
295	>	* suspended threads to resume before considering creating a new
296	>	* replacement. The spares themselves are encoded on another
297	>	* variant of a Treiber Stack, headed at field "spareWaiters".
298	>	* Note that the use of spares is intrinsically racy.  One thread
299	>	* may become a spare at about the same time as another is
300	>	* needlessly being created. We counteract this and related slop
301	>	* in part by requiring resumed spares to immediately recheck (in
302	>	* preStep) to see whether they they should re-suspend.
303	>	*
304	>	* 6. Killing off unneeded workers. The Spare and Event queues use
305	>	* similar mechanisms to shed unused workers: The oldest (first)
306	>	* waiter uses a timed rather than hard wait. When this wait times
307	>	* out without a normal wakeup, it tries to shutdown any one (for
308	>	* convenience the newest) other waiter via tryShutdownSpare or
309	>	* tryShutdownWaiter, respectively. The wakeup rates for spares
310	>	* are much shorter than for waiters. Together, they will
311	>	* eventually reduce the number of worker threads to a minimum of
312	>	* one after a long enough period without use.
313	>	*
314	>	* 7. Deciding when to create new workers. The main dynamic
315	>	* control in this class is deciding when to create extra threads
316	>	* in method helpMaintainParallelism. We would like to keep
317	>	* exactly #parallelism threads running, which is an impossble
318	>	* task. We always need to create one when the number of running
319	>	* threads would become zero and all workers are busy. Beyond
320	>	* this, we must rely on heuristics that work well in the the
321	>	* presence of transients phenomena such as GC stalls, dynamic
322	>	* compilation, and wake-up lags. These transients are extremely
323	>	* common -- we are normally trying to fully saturate the CPUs on
324	>	* a machine, so almost any activity other than running tasks
325	>	* impedes accuracy. Our main defense is to allow some slack in
326	>	* creation thresholds, using rules that reflect the fact that the
327	>	* more threads we have running, the more likely that we are
328	>	* underestimating the number running threads. (We also include
329	>	* some heuristic use of Thread.yield when all workers appear to
330	>	* be busy, to improve likelihood of counts settling.) The rules
331	>	* also better cope with the fact that some of the methods in this
332	>	* class tend to never become compiled (but are interpreted), so
333	>	* some components of the entire set of controls might execute 100
334	>	* times faster than others. And similarly for cases where the
335	>	* apparent lack of work is just due to GC stalls and other
336	>	* transient system activity.
337	>	*
338	>	* Beware that there is a lot of representation-level coupling
339	>	* among classes ForkJoinPool, ForkJoinWorkerThread, and
340	>	* ForkJoinTask.  For example, direct access to "workers" array by
341	>	* workers, and direct access to ForkJoinTask.status by both
342	>	* ForkJoinPool and ForkJoinWorkerThread.  There is little point
343	>	* trying to reduce this, since any associated future changes in
344	>	* representations will need to be accompanied by algorithmic
345	>	* changes anyway.
346	>	*
347	>	* Style notes: There are lots of inline assignments (of form
348	>	* "while ((local = field) != 0)") which are usually the simplest
349	>	* way to ensure the required read orderings (which are sometimes
350	>	* critical). Also several occurrences of the unusual "do {}
351	>	* while(!cas...)" which is the simplest way to force an update of
352	>	* a CAS'ed variable. There are also other coding oddities that
353	>	* help some methods perform reasonably even when interpreted (not
354	>	* compiled), at the expense of some messy constructions that
355	>	* reduce byte code counts.
356	>	*
357	>	* The order of declarations in this file is: (1) statics (2)
358	>	* fields (along with constants used when unpacking some of them)
359	>	* (3) internal control methods (4) callbacks and other support
360	>	* for ForkJoinTask and ForkJoinWorkerThread classes, (5) exported
361	>	* methods (plus a few little helpers).
362		*/
363
98	–	/** Mask for packing and unpacking shorts */
99	–	private static final int  shortMask = 0xffff;
100	–
101	–	/** Max pool size -- must be a power of two minus 1 */
102	–	private static final int MAX_THREADS =  0x7FFF;
103	–
364		/**
365		* Factory for creating new {@link ForkJoinWorkerThread}s.
366		* A {@code ForkJoinWorkerThreadFactory} must be defined and used
#	Line 112 | Line 372 | public class ForkJoinPool extends Abstra
372		* Returns a new worker thread operating in the given pool.
373		*
374		* @param pool the pool this thread works in
375	<	* @throws NullPointerException if pool is null
375	>	* @throws NullPointerException if the pool is null
376		*/
377		public ForkJoinWorkerThread newThread(ForkJoinPool pool);
378		}
#	Line 121 | Line 381 | public class ForkJoinPool extends Abstra
381		* Default ForkJoinWorkerThreadFactory implementation; creates a
382		* new ForkJoinWorkerThread.
383		*/
384	<	static class  DefaultForkJoinWorkerThreadFactory
384	>	static class DefaultForkJoinWorkerThreadFactory
385		implements ForkJoinWorkerThreadFactory {
386		public ForkJoinWorkerThread newThread(ForkJoinPool pool) {
387	<	try {
128	<	return new ForkJoinWorkerThread(pool);
129	<	} catch (OutOfMemoryError oom)  {
130	<	return null;
131	<	}
387	>	return new ForkJoinWorkerThread(pool);
388		}
389		}
390
#	Line 164 | Line 420 | public class ForkJoinPool extends Abstra
420		new AtomicInteger();
421
422		/**
423	<	* Array holding all worker threads in the pool. Initialized upon
424	<	* first use. Array size must be a power of two.  Updates and
425	<	* replacements are protected by workerLock, but it is always kept
426	<	* in a consistent enough state to be randomly accessed without
427	<	* locking by workers performing work-stealing.
423	>	* The wakeup interval (in nanoseconds) for the oldest worker
424	>	* worker waiting for an event invokes tryShutdownWaiter to shrink
425	>	* the number of workers.  The exact value does not matter too
426	>	* much, but should be long enough to slowly release resources
427	>	* during long periods without use without disrupting normal use.
428	>	*/
429	>	private static final long SHRINK_RATE_NANOS =
430	>	60L * 1000L * 1000L * 1000L; // one minute
431	>
432	>	/**
433	>	* Absolute bound for parallelism level. Twice this number plus
434	>	* one (i.e., 0xfff) must fit into a 16bit field to enable
435	>	* word-packing for some counts and indices.
436	>	*/
437	>	private static final int MAX_WORKERS   = 0x7fff;
438	>
439	>	/**
440	>	* Array holding all worker threads in the pool.  Array size must
441	>	* be a power of two.  Updates and replacements are protected by
442	>	* workerLock, but the array is always kept in a consistent enough
443	>	* state to be randomly accessed without locking by workers
444	>	* performing work-stealing, as well as other traversal-based
445	>	* methods in this class. All readers must tolerate that some
446	>	* array slots may be null.
447		*/
448		volatile ForkJoinWorkerThread[] workers;
449
450		/**
451	<	* Lock protecting access to workers.
451	>	* Queue for external submissions.
452		*/
453	<	private final ReentrantLock workerLock;
453	>	private final LinkedTransferQueue<ForkJoinTask<?>> submissionQueue;
454
455		/**
456	<	* Condition for awaitTermination.
456	>	* Lock protecting updates to workers array.
457		*/
458	<	private final Condition termination;
458	>	private final ReentrantLock workerLock;
459
460		/**
461	<	* The uncaught exception handler used when any worker
187	<	* abruptly terminates
461	>	* Latch released upon termination.
462		*/
463	<	private Thread.UncaughtExceptionHandler ueh;
463	>	private final Phaser termination;
464
465		/**
466		* Creation factory for worker threads.
#	Line 194 | Line 468 | public class ForkJoinPool extends Abstra
468		private final ForkJoinWorkerThreadFactory factory;
469
470		/**
197	–	* Head of stack of threads that were created to maintain
198	–	* parallelism when other threads blocked, but have since
199	–	* suspended when the parallelism level rose.
200	–	*/
201	–	private volatile WaitQueueNode spareStack;
202	–
203	–	/**
471		* Sum of per-thread steal counts, updated only when threads are
472		* idle or terminating.
473		*/
474	<	private final AtomicLong stealCount;
474	>	private volatile long stealCount;
475
476		/**
477	<	* Queue for external submissions.
477	>	* Encoded record of top of treiber stack of threads waiting for
478	>	* events. The top 32 bits contain the count being waited for. The
479	>	* bottom 16 bits contains one plus the pool index of waiting
480	>	* worker thread. (Bits 16-31 are unused.)
481		*/
482	<	private final LinkedTransferQueue<ForkJoinTask<?>> submissionQueue;
482	>	private volatile long eventWaiters;
483	>
484	>	private static final int  EVENT_COUNT_SHIFT = 32;
485	>	private static final long WAITER_ID_MASK    = (1L << 16) - 1L;
486
487		/**
488	<	* Head of Treiber stack for barrier sync. See below for explanation.
488	>	* A counter for events that may wake up worker threads:
489	>	*   - Submission of a new task to the pool
490	>	*   - A worker pushing a task on an empty queue
491	>	*   - termination
492		*/
493	<	private volatile WaitQueueNode syncStack;
493	>	private volatile int eventCount;
494
495		/**
496	<	* The count for event barrier
496	>	* Encoded record of top of treiber stack of spare threads waiting
497	>	* for resumption. The top 16 bits contain an arbitrary count to
498	>	* avoid ABA effects. The bottom 16bits contains one plus the pool
499	>	* index of waiting worker thread.
500		*/
501	<	private volatile long eventCount;
501	>	private volatile int spareWaiters;
502	>
503	>	private static final int SPARE_COUNT_SHIFT = 16;
504	>	private static final int SPARE_ID_MASK     = (1 << 16) - 1;
505
506		/**
507	<	* Pool number, just for assigning useful names to worker threads
507	>	* Lifecycle control. The low word contains the number of workers
508	>	* that are (probably) executing tasks. This value is atomically
509	>	* incremented before a worker gets a task to run, and decremented
510	>	* when worker has no tasks and cannot find any.  Bits 16-18
511	>	* contain runLevel value. When all are zero, the pool is
512	>	* running. Level transitions are monotonic (running -> shutdown
513	>	* -> terminating -> terminated) so each transition adds a bit.
514	>	* These are bundled together to ensure consistent read for
515	>	* termination checks (i.e., that runLevel is at least SHUTDOWN
516	>	* and active threads is zero).
517	>	*
518	>	* Notes: Most direct CASes are dependent on these bitfield
519	>	* positions.  Also, this field is non-private to enable direct
520	>	* performance-sensitive CASes in ForkJoinWorkerThread.
521		*/
522	<	private final int poolNumber;
522	>	volatile int runState;
523	>
524	>	// Note: The order among run level values matters.
525	>	private static final int RUNLEVEL_SHIFT     = 16;
526	>	private static final int SHUTDOWN           = 1 << RUNLEVEL_SHIFT;
527	>	private static final int TERMINATING        = 1 << (RUNLEVEL_SHIFT + 1);
528	>	private static final int TERMINATED         = 1 << (RUNLEVEL_SHIFT + 2);
529	>	private static final int ACTIVE_COUNT_MASK  = (1 << RUNLEVEL_SHIFT) - 1;
530
531		/**
532	<	* The maximum allowed pool size
532	>	* Holds number of total (i.e., created and not yet terminated)
533	>	* and running (i.e., not blocked on joins or other managed sync)
534	>	* threads, packed together to ensure consistent snapshot when
535	>	* making decisions about creating and suspending spare
536	>	* threads. Updated only by CAS. Note that adding a new worker
537	>	* requires incrementing both counts, since workers start off in
538	>	* running state.
539		*/
540	<	private volatile int maxPoolSize;
540	>	private volatile int workerCounts;
541	>
542	>	private static final int TOTAL_COUNT_SHIFT  = 16;
543	>	private static final int RUNNING_COUNT_MASK = (1 << TOTAL_COUNT_SHIFT) - 1;
544	>	private static final int ONE_RUNNING        = 1;
545	>	private static final int ONE_TOTAL          = 1 << TOTAL_COUNT_SHIFT;
546
547		/**
548	<	* The desired parallelism level, updated only under workerLock.
548	>	* The target parallelism level.
549	>	* Accessed directly by ForkJoinWorkerThreads.
550		*/
551	<	private volatile int parallelism;
551	>	final int parallelism;
552
553		/**
554		* True if use local fifo, not default lifo, for local polling
555	+	* Read by, and replicated by ForkJoinWorkerThreads
556		*/
557	<	private volatile boolean locallyFifo;
557	>	final boolean locallyFifo;
558
559		/**
560	<	* Holds number of total (i.e., created and not yet terminated)
561	<	* and running (i.e., not blocked on joins or other managed sync)
247	<	* threads, packed into one int to ensure consistent snapshot when
248	<	* making decisions about creating and suspending spare
249	<	* threads. Updated only by CAS.  Note: CASes in
250	<	* updateRunningCount and preJoin assume that running active count
251	<	* is in low word, so need to be modified if this changes.
560	>	* The uncaught exception handler used when any worker abruptly
561	>	* terminates.
562		*/
563	<	private volatile int workerCounts;
563	>	private final Thread.UncaughtExceptionHandler ueh;
564
565	<	private static int totalCountOf(int s)           { return s >>> 16;  }
566	<	private static int runningCountOf(int s)         { return s & shortMask; }
567	<	private static int workerCountsFor(int t, int r) { return (t << 16) + r; }
565	>	/**
566	>	* Pool number, just for assigning useful names to worker threads
567	>	*/
568	>	private final int poolNumber;
569	>
570	>
571	>	// Utilities for CASing fields. Note that most of these
572	>	// are usually manually inlined by callers
573
574		/**
575	<	* Adds delta (which may be negative) to running count.  This must
261	<	* be called before (with negative arg) and after (with positive)
262	<	* any managed synchronization (i.e., mainly, joins).
263	<	*
264	<	* @param delta the number to add
575	>	* Increments running count part of workerCounts
576		*/
577	<	final void updateRunningCount(int delta) {
578	<	int s;
579	<	do {} while (!casWorkerCounts(s = workerCounts, s + delta));
577	>	final void incrementRunningCount() {
578	>	int c;
579	>	do {} while (!UNSAFE.compareAndSwapInt(this, workerCountsOffset,
580	>	c = workerCounts,
581	>	c + ONE_RUNNING));
582		}
583
584		/**
585	<	* Adds delta (which may be negative) to both total and running
273	<	* count.  This must be called upon creation and termination of
274	<	* worker threads.
275	<	*
276	<	* @param delta the number to add
585	>	* Tries to decrement running count unless already zero
586		*/
587	<	private void updateWorkerCount(int delta) {
588	<	int d = delta + (delta << 16); // add to both lo and hi parts
589	<	int s;
590	<	do {} while (!casWorkerCounts(s = workerCounts, s + d));
587	>	final boolean tryDecrementRunningCount() {
588	>	int wc = workerCounts;
589	>	if ((wc & RUNNING_COUNT_MASK) == 0)
590	>	return false;
591	>	return UNSAFE.compareAndSwapInt(this, workerCountsOffset,
592	>	wc, wc - ONE_RUNNING);
593		}
594
595		/**
596	<	* Lifecycle control. High word contains runState, low word
597	<	* contains the number of workers that are (probably) executing
598	<	* tasks. This value is atomically incremented before a worker
599	<	* gets a task to run, and decremented when worker has no tasks
600	<	* and cannot find any. These two fields are bundled together to
290	<	* support correct termination triggering.  Note: activeCount
291	<	* CAS'es cheat by assuming active count is in low word, so need
292	<	* to be modified if this changes
596	>	* Forces decrement of encoded workerCounts, awaiting nonzero if
597	>	* (rarely) necessary when other count updates lag.
598	>	*
599	>	* @param dr -- either zero or ONE_RUNNING
600	>	* @param dt == either zero or ONE_TOTAL
601		*/
602	<	private volatile int runControl;
603	<
604	<	// RunState values. Order among values matters
605	<	private static final int RUNNING     = 0;
606	<	private static final int SHUTDOWN    = 1;
607	<	private static final int TERMINATING = 2;
608	<	private static final int TERMINATED  = 3;
602	>	private void decrementWorkerCounts(int dr, int dt) {
603	>	for (;;) {
604	>	int wc = workerCounts;
605	>	if ((wc & RUNNING_COUNT_MASK)  - dr < 0 ||
606	>	(wc >>> TOTAL_COUNT_SHIFT) - dt < 0) {
607	>	if ((runState & TERMINATED) != 0)
608	>	return; // lagging termination on a backout
609	>	Thread.yield();
610	>	}
611	>	if (UNSAFE.compareAndSwapInt(this, workerCountsOffset,
612	>	wc, wc - (dr + dt)))
613	>	return;
614	>	}
615	>	}
616
617	<	private static int runStateOf(int c)             { return c >>> 16; }
618	<	private static int activeCountOf(int c)          { return c & shortMask; }
619	<	private static int runControlFor(int r, int a)   { return (r << 16) + a; }
617	>	/**
618	>	* Increments event count
619	>	*/
620	>	private void advanceEventCount() {
621	>	int c;
622	>	do {} while(!UNSAFE.compareAndSwapInt(this, eventCountOffset,
623	>	c = eventCount, c+1));
624	>	}
625
626		/**
627		* Tries incrementing active count; fails on contention.
628	<	* Called by workers before/during executing tasks.
628	>	* Called by workers before executing tasks.
629		*
630		* @return true on success
631		*/
632		final boolean tryIncrementActiveCount() {
633	<	int c = runControl;
634	<	return casRunControl(c, c+1);
633	>	int c;
634	>	return UNSAFE.compareAndSwapInt(this, runStateOffset,
635	>	c = runState, c + 1);
636		}
637
638		/**
639		* Tries decrementing active count; fails on contention.
640	<	* Possibly triggers termination on success.
320	<	* Called by workers when they can't find tasks.
321	<	*
322	<	* @return true on success
640	>	* Called when workers cannot find tasks to run.
641		*/
642		final boolean tryDecrementActiveCount() {
643	<	int c = runControl;
644	<	int nextc = c - 1;
645	<	if (!casRunControl(c, nextc))
328	<	return false;
329	<	if (canTerminateOnShutdown(nextc))
330	<	terminateOnShutdown();
331	<	return true;
643	>	int c;
644	>	return UNSAFE.compareAndSwapInt(this, runStateOffset,
645	>	c = runState, c - 1);
646		}
647
648		/**
649	<	* Returns {@code true} if argument represents zero active count
650	<	* and nonzero runstate, which is the triggering condition for
337	<	* terminating on shutdown.
649	>	* Advances to at least the given level. Returns true if not
650	>	* already in at least the given level.
651		*/
652	<	private static boolean canTerminateOnShutdown(int c) {
653	<	// i.e. least bit is nonzero runState bit
654	<	return ((c & -c) >>> 16) != 0;
652	>	private boolean advanceRunLevel(int level) {
653	>	for (;;) {
654	>	int s = runState;
655	>	if ((s & level) != 0)
656	>	return false;
657	>	if (UNSAFE.compareAndSwapInt(this, runStateOffset, s, s | level))
658	>	return true;
659	>	}
660		}
661
662	+	// workers array maintenance
663	+
664		/**
665	<	* Transition run state to at least the given state. Return true
346	<	* if not already at least given state.
665	>	* Records and returns a workers array index for new worker.
666		*/
667	<	private boolean transitionRunStateTo(int state) {
668	<	for (;;) {
669	<	int c = runControl;
670	<	if (runStateOf(c) >= state)
671	<	return false;
672	<	if (casRunControl(c, runControlFor(state, activeCountOf(c))))
673	<	return true;
667	>	private int recordWorker(ForkJoinWorkerThread w) {
668	>	// Try using slot totalCount-1. If not available, scan and/or resize
669	>	int k = (workerCounts >>> TOTAL_COUNT_SHIFT) - 1;
670	>	final ReentrantLock lock = this.workerLock;
671	>	lock.lock();
672	>	try {
673	>	ForkJoinWorkerThread[] ws = workers;
674	>	int n = ws.length;
675	>	if (k < 0 || k >= n || ws[k] != null) {
676	>	for (k = 0; k < n && ws[k] != null; ++k)
677	>	;
678	>	if (k == n)
679	>	ws = Arrays.copyOf(ws, n << 1);
680	>	}
681	>	ws[k] = w;
682	>	workers = ws; // volatile array write ensures slot visibility
683	>	} finally {
684	>	lock.unlock();
685		}
686	+	return k;
687		}
688
689		/**
690	<	* Controls whether to add spares to maintain parallelism
690	>	* Nulls out record of worker in workers array
691		*/
692	<	private volatile boolean maintainsParallelism;
692	>	private void forgetWorker(ForkJoinWorkerThread w) {
693	>	int idx = w.poolIndex;
694	>	// Locking helps method recordWorker avoid unecessary expansion
695	>	final ReentrantLock lock = this.workerLock;
696	>	lock.lock();
697	>	try {
698	>	ForkJoinWorkerThread[] ws = workers;
699	>	if (idx >= 0 && idx < ws.length && ws[idx] == w) // verify
700	>	ws[idx] = null;
701	>	} finally {
702	>	lock.unlock();
703	>	}
704	>	}
705
706	<	// Constructors
706	>	// adding and removing workers
707
708		/**
709	<	* Creates a {@code ForkJoinPool} with parallelism equal to {@link
710	<	* java.lang.Runtime#availableProcessors}, and using the {@linkplain
711	<	* #defaultForkJoinWorkerThreadFactory default thread factory}.
709	>	* Tries to create and add new worker. Assumes that worker counts
710	>	* are already updated to accommodate the worker, so adjusts on
711	>	* failure.
712		*
713	<	* @throws SecurityException if a security manager exists and
371	<	*         the caller is not permitted to modify threads
372	<	*         because it does not hold {@link
373	<	*         java.lang.RuntimePermission}{@code ("modifyThread")}
713	>	* @return the worker, or null on failure
714		*/
715	<	public ForkJoinPool() {
716	<	this(Runtime.getRuntime().availableProcessors(),
717	<	defaultForkJoinWorkerThreadFactory);
715	>	private ForkJoinWorkerThread addWorker() {
716	>	ForkJoinWorkerThread w = null;
717	>	try {
718	>	w = factory.newThread(this);
719	>	} finally { // Adjust on either null or exceptional factory return
720	>	if (w == null) {
721	>	decrementWorkerCounts(ONE_RUNNING, ONE_TOTAL);
722	>	tryTerminate(false); // in case of failure during shutdown
723	>	}
724	>	}
725	>	if (w != null) {
726	>	w.start(recordWorker(w), ueh);
727	>	advanceEventCount();
728	>	}
729	>	return w;
730		}
731
732		/**
733	<	* Creates a {@code ForkJoinPool} with the indicated parallelism
734	<	* level and using the {@linkplain
735	<	* #defaultForkJoinWorkerThreadFactory default thread factory}.
733	>	* Final callback from terminating worker.  Removes record of
734	>	* worker from array, and adjusts counts. If pool is shutting
735	>	* down, tries to complete terminatation.
736		*
737	<	* @param parallelism the parallelism level
386	<	* @throws IllegalArgumentException if parallelism less than or
387	<	* equal to zero
388	<	* @throws SecurityException if a security manager exists and
389	<	*         the caller is not permitted to modify threads
390	<	*         because it does not hold {@link
391	<	*         java.lang.RuntimePermission}{@code ("modifyThread")}
737	>	* @param w the worker
738		*/
739	<	public ForkJoinPool(int parallelism) {
740	<	this(parallelism, defaultForkJoinWorkerThreadFactory);
739	>	final void workerTerminated(ForkJoinWorkerThread w) {
740	>	forgetWorker(w);
741	>	decrementWorkerCounts(w.isTrimmed()? 0 : ONE_RUNNING, ONE_TOTAL);
742	>	while (w.stealCount != 0) // collect final count
743	>	tryAccumulateStealCount(w);
744	>	tryTerminate(false);
745		}
746
747	+	// Waiting for and signalling events
748	+
749		/**
750	<	* Creates a {@code ForkJoinPool} with parallelism equal to {@link
751	<	* java.lang.Runtime#availableProcessors}, and using the given
752	<	* thread factory.
753	<	*
402	<	* @param factory the factory for creating new threads
403	<	* @throws NullPointerException if factory is null
404	<	* @throws SecurityException if a security manager exists and
405	<	*         the caller is not permitted to modify threads
406	<	*         because it does not hold {@link
407	<	*         java.lang.RuntimePermission}{@code ("modifyThread")}
750	>	* Releases workers blocked on a count not equal to current count.
751	>	* Normally called after precheck that eventWaiters isn't zero to
752	>	* avoid wasted array checks. Gives up upon a change in count or
753	>	* contention, letting other workers take over.
754		*/
755	<	public ForkJoinPool(ForkJoinWorkerThreadFactory factory) {
756	<	this(Runtime.getRuntime().availableProcessors(), factory);
755	>	private void releaseEventWaiters() {
756	>	ForkJoinWorkerThread[] ws = workers;
757	>	int n = ws.length;
758	>	long h = eventWaiters;
759	>	int ec = eventCount;
760	>	ForkJoinWorkerThread w; int id;
761	>	while ((int)(h >>> EVENT_COUNT_SHIFT) != ec &&
762	>	(id = ((int)(h & WAITER_ID_MASK)) - 1) >= 0 &&
763	>	id < n && (w = ws[id]) != null &&
764	>	UNSAFE.compareAndSwapLong(this, eventWaitersOffset,
765	>	h,  h = w.nextWaiter)) {
766	>	LockSupport.unpark(w);
767	>	if (eventWaiters != h || eventCount != ec)
768	>	break;
769	>	}
770		}
771
772		/**
773	<	* Creates a {@code ForkJoinPool} with the given parallelism and
774	<	* thread factory.
773	>	* Tries to advance eventCount and releases waiters. Called only
774	>	* from workers.
775	>	*/
776	>	final void signalWork() {
777	>	int c; // try to increment event count -- CAS failure OK
778	>	UNSAFE.compareAndSwapInt(this, eventCountOffset, c = eventCount, c+1);
779	>	if (eventWaiters != 0L)
780	>	releaseEventWaiters();
781	>	}
782	>
783	>	/**
784	>	* Adds the given worker to event queue and blocks until
785	>	* terminating or event count advances from the workers
786	>	* lastEventCount value
787		*
788	<	* @param parallelism the parallelism level
418	<	* @param factory the factory for creating new threads
419	<	* @throws IllegalArgumentException if parallelism less than or
420	<	* equal to zero, or greater than implementation limit
421	<	* @throws NullPointerException if factory is null
422	<	* @throws SecurityException if a security manager exists and
423	<	*         the caller is not permitted to modify threads
424	<	*         because it does not hold {@link
425	<	*         java.lang.RuntimePermission}{@code ("modifyThread")}
788	>	* @param w the calling worker thread
789		*/
790	<	public ForkJoinPool(int parallelism, ForkJoinWorkerThreadFactory factory) {
791	<	if (parallelism <= 0 || parallelism > MAX_THREADS)
792	<	throw new IllegalArgumentException();
793	<	if (factory == null)
794	<	throw new NullPointerException();
795	<	checkPermission();
796	<	this.factory = factory;
797	<	this.parallelism = parallelism;
798	<	this.maxPoolSize = MAX_THREADS;
799	<	this.maintainsParallelism = true;
800	<	this.poolNumber = poolNumberGenerator.incrementAndGet();
801	<	this.workerLock = new ReentrantLock();
802	<	this.termination = workerLock.newCondition();
803	<	this.stealCount = new AtomicLong();
441	<	this.submissionQueue = new LinkedTransferQueue<ForkJoinTask<?>>();
442	<	// worker array and workers are lazily constructed
790	>	private void eventSync(ForkJoinWorkerThread w) {
791	>	int ec = w.lastEventCount;
792	>	long nh = (((long)ec) << EVENT_COUNT_SHIFT) | ((long)(w.poolIndex+1));
793	>	long h;
794	>	while ((runState < SHUTDOWN || !tryTerminate(false)) &&
795	>	(((int)((h = eventWaiters) & WAITER_ID_MASK)) == 0 ||
796	>	(int)(h >>> EVENT_COUNT_SHIFT) == ec) &&
797	>	eventCount == ec) {
798	>	if (UNSAFE.compareAndSwapLong(this, eventWaitersOffset,
799	>	w.nextWaiter = h, nh)) {
800	>	awaitEvent(w, ec);
801	>	break;
802	>	}
803	>	}
804		}
805
806		/**
807	<	* Creates a new worker thread using factory.
807	>	* Blocks the given worker (that has already been entered as an
808	>	* event waiter) until terminating or event count advances from
809	>	* the given value. The oldest (first) waiter uses a timed wait to
810	>	* occasionally one-by-one shrink the number of workers (to a
811	>	* minumum of one) if the pool has not been used for extended
812	>	* periods.
813		*
814	<	* @param index the index to assign worker
815	<	* @return new worker, or null if factory failed
814	>	* @param w the calling worker thread
815	>	* @param ec the count
816		*/
817	<	private ForkJoinWorkerThread createWorker(int index) {
818	<	Thread.UncaughtExceptionHandler h = ueh;
819	<	ForkJoinWorkerThread w = factory.newThread(this);
820	<	if (w != null) {
821	<	w.poolIndex = index;
822	<	w.setDaemon(true);
823	<	w.setAsyncMode(locallyFifo);
824	<	w.setName("ForkJoinPool-" + poolNumber + "-worker-" + index);
825	<	if (h != null)
826	<	w.setUncaughtExceptionHandler(h);
817	>	private void awaitEvent(ForkJoinWorkerThread w, int ec) {
818	>	while (eventCount == ec) {
819	>	if (tryAccumulateStealCount(w)) { // transfer while idle
820	>	boolean untimed = (w.nextWaiter != 0L ||
821	>	(workerCounts & RUNNING_COUNT_MASK) <= 1);
822	>	long startTime = untimed? 0 : System.nanoTime();
823	>	Thread.interrupted();         // clear/ignore interrupt
824	>	if (eventCount != ec || !w.isRunning() ||
825	>	runState >= TERMINATING)  // recheck after clear
826	>	break;
827	>	if (untimed)
828	>	LockSupport.park(w);
829	>	else {
830	>	LockSupport.parkNanos(w, SHRINK_RATE_NANOS);
831	>	if (eventCount != ec || !w.isRunning() ||
832	>	runState >= TERMINATING)
833	>	break;
834	>	if (System.nanoTime() - startTime >= SHRINK_RATE_NANOS)
835	>	tryShutdownWaiter(ec);
836	>	}
837	>	}
838		}
462	–	return w;
839		}
840
841		/**
842	<	* Returns a good size for worker array given pool size.
843	<	* Currently requires size to be a power of two.
842	>	* Callback from the oldest waiter in awaitEvent waking up after a
843	>	* period of non-use. Tries (once) to shutdown an event waiter (or
844	>	* a spare, if one exists). Note that we don't need CAS or locks
845	>	* here because the method is called only from one thread
846	>	* occasionally waking (and even misfires are OK). Note that
847	>	* until the shutdown worker fully terminates, workerCounts
848	>	* will overestimate total count, which is tolerable.
849	>	*
850	>	* @param ec the event count waited on by caller (to abort
851	>	* attempt if count has since changed).
852	>	*/
853	>	private void tryShutdownWaiter(int ec) {
854	>	if (spareWaiters != 0) { // prefer killing spares
855	>	tryShutdownSpare();
856	>	return;
857	>	}
858	>	ForkJoinWorkerThread[] ws = workers;
859	>	int n = ws.length;
860	>	long h = eventWaiters;
861	>	ForkJoinWorkerThread w; int id; long nh;
862	>	if (runState == 0 &&
863	>	submissionQueue.isEmpty() &&
864	>	eventCount == ec &&
865	>	(id = ((int)(h & WAITER_ID_MASK)) - 1) >= 0 &&
866	>	id < n && (w = ws[id]) != null &&
867	>	(nh = w.nextWaiter) != 0L && // keep at least one worker
868	>	UNSAFE.compareAndSwapLong(this, eventWaitersOffset, h, nh)) {
869	>	w.shutdown();
870	>	LockSupport.unpark(w);
871	>	}
872	>	releaseEventWaiters();
873	>	}
874	>
875	>	// Maintaining spares
876	>
877	>	/**
878	>	* Pushes worker onto the spare stack
879	>	*/
880	>	final void pushSpare(ForkJoinWorkerThread w) {
881	>	int ns = (++w.spareCount << SPARE_COUNT_SHIFT) | (w.poolIndex + 1);
882	>	do {} while (!UNSAFE.compareAndSwapInt(this, spareWaitersOffset,
883	>	w.nextSpare = spareWaiters,ns));
884	>	}
885	>
886	>	/**
887	>	* Callback from oldest spare occasionally waking up.  Tries
888	>	* (once) to shutdown a spare. Same idea as tryShutdownWaiter.
889		*/
890	<	private static int arraySizeFor(int poolSize) {
891	<	if (poolSize <= 1)
892	<	return 1;
893	<	// See Hackers Delight, sec 3.2
894	<	int c = poolSize >= MAX_THREADS ? MAX_THREADS : (poolSize - 1);
895	<	c |= c >>>  1;
896	<	c |= c >>>  2;
897	<	c |= c >>>  4;
898	<	c |= c >>>  8;
899	<	c |= c >>> 16;
900	<	return c + 1;
890	>	final void tryShutdownSpare() {
891	>	int sw, id;
892	>	ForkJoinWorkerThread w;
893	>	ForkJoinWorkerThread[] ws;
894	>	if ((id = ((sw = spareWaiters) & SPARE_ID_MASK) - 1) >= 0 &&
895	>	id < (ws = workers).length && (w = ws[id]) != null &&
896	>	(workerCounts & RUNNING_COUNT_MASK) >= parallelism &&
897	>	UNSAFE.compareAndSwapInt(this, spareWaitersOffset,
898	>	sw, w.nextSpare)) {
899	>	w.shutdown();
900	>	LockSupport.unpark(w);
901	>	advanceEventCount();
902	>	}
903		}
904
905		/**
906	<	* Creates or resizes array if necessary to hold newLength.
907	<	* Call only under exclusion.
906	>	* Tries (once) to resume a spare if worker counts match
907	>	* the given count.
908		*
909	<	* @return the array
909	>	* @param wc workerCounts value on invocation of this method
910		*/
911	<	private ForkJoinWorkerThread[] ensureWorkerArrayCapacity(int newLength) {
911	>	private void tryResumeSpare(int wc) {
912		ForkJoinWorkerThread[] ws = workers;
913	<	if (ws == null)
914	<	return workers = new ForkJoinWorkerThread[arraySizeFor(newLength)];
915	<	else if (newLength > ws.length)
916	<	return workers = Arrays.copyOf(ws, arraySizeFor(newLength));
917	<	else
918	<	return ws;
913	>	int n = ws.length;
914	>	int sw, id, rs;  ForkJoinWorkerThread w;
915	>	if ((id = ((sw = spareWaiters) & SPARE_ID_MASK) - 1) >= 0 &&
916	>	id < n && (w = ws[id]) != null &&
917	>	(rs = runState) < TERMINATING &&
918	>	eventWaiters == 0L && workerCounts == wc) {
919	>	// In case all workers busy, heuristically back off to let settle
920	>	Thread.yield();
921	>	if (eventWaiters == 0L && runState == rs && // recheck
922	>	workerCounts == wc && spareWaiters == sw &&
923	>	UNSAFE.compareAndSwapInt(this, spareWaitersOffset,
924	>	sw, w.nextSpare)) {
925	>	int c;              // increment running count before resume
926	>	do {} while(!UNSAFE.compareAndSwapInt
927	>	(this, workerCountsOffset,
928	>	c = workerCounts, c + ONE_RUNNING));
929	>	if (w.tryUnsuspend())
930	>	LockSupport.unpark(w);
931	>	else               // back out if w was shutdown
932	>	decrementWorkerCounts(ONE_RUNNING, 0);
933	>	}
934	>	}
935	>	}
936	>
937	>	// adding workers on demand
938	>
939	>	/**
940	>	* Adds one or more workers if needed to establish target parallelism.
941	>	* Retries upon contention.
942	>	*/
943	>	private void addWorkerIfBelowTarget() {
944	>	int pc = parallelism;
945	>	int wc;
946	>	while (((wc = workerCounts) >>> TOTAL_COUNT_SHIFT) < pc &&
947	>	runState < TERMINATING) {
948	>	if (UNSAFE.compareAndSwapInt(this, workerCountsOffset, wc,
949	>	wc + (ONE_RUNNING|ONE_TOTAL))) {
950	>	if (addWorker() == null)
951	>	break;
952	>	}
953	>	}
954		}
955
956		/**
957	<	* Tries to shrink workers into smaller array after one or more terminate.
957	>	* Tries (once) to add a new worker if all existing workers are
958	>	* busy, and there are either no running workers or the deficit is
959	>	* at least twice the surplus.
960	>	*
961	>	* @param wc workerCounts value on invocation of this method
962		*/
963	<	private void tryShrinkWorkerArray() {
964	<	ForkJoinWorkerThread[] ws = workers;
965	<	if (ws != null) {
966	<	int len = ws.length;
967	<	int last = len - 1;
968	<	while (last >= 0 && ws[last] == null)
969	<	--last;
970	<	int newLength = arraySizeFor(last+1);
971	<	if (newLength < len)
972	<	workers = Arrays.copyOf(ws, newLength);
963	>	private void tryAddWorkerIfBusy(int wc) {
964	>	int tc, rc, rs;
965	>	int pc = parallelism;
966	>	if ((tc = wc >>> TOTAL_COUNT_SHIFT) < MAX_WORKERS &&
967	>	((rc = wc & RUNNING_COUNT_MASK) == 0 ||
968	>	rc < pc - ((tc - pc) << 1)) &&
969	>	(rs = runState) < TERMINATING &&
970	>	(rs & ACTIVE_COUNT_MASK) == tc) {
971	>	// Since all workers busy, heuristically back off to let settle
972	>	Thread.yield();
973	>	if (eventWaiters == 0L && spareWaiters == 0 && // recheck
974	>	runState == rs && workerCounts == wc &&
975	>	UNSAFE.compareAndSwapInt(this, workerCountsOffset, wc,
976	>	wc + (ONE_RUNNING|ONE_TOTAL)))
977	>	addWorker();
978		}
979		}
980
981		/**
982	<	* Initializes workers if necessary.
982	>	* Does at most one of:
983	>	*
984	>	* 1. Help wake up existing workers waiting for work via
985	>	*    releaseEventWaiters. (If any exist, then it doesn't
986	>	*    matter right now if under target parallelism level.)
987	>	*
988	>	* 2. If a spare exists, try (once) to resume it via tryResumeSpare.
989	>	*
990	>	* 3. If there are not enough total workers, add some
991	>	*    via addWorkerIfBelowTarget;
992	>	*
993	>	* 4. Try (once) to add a new worker if all existing workers
994	>	*     are busy, via tryAddWorkerIfBusy
995		*/
996	<	final void ensureWorkerInitialization() {
997	<	ForkJoinWorkerThread[] ws = workers;
998	<	if (ws == null) {
999	<	final ReentrantLock lock = this.workerLock;
1000	<	lock.lock();
1001	<	try {
1002	<	ws = workers;
1003	<	if (ws == null) {
1004	<	int ps = parallelism;
1005	<	ws = ensureWorkerArrayCapacity(ps);
1006	<	for (int i = 0; i < ps; ++i) {
1007	<	ForkJoinWorkerThread w = createWorker(i);
1008	<	if (w != null) {
1009	<	ws[i] = w;
1010	<	w.start();
1011	<	updateWorkerCount(1);
1012	<	}
996	>	private void helpMaintainParallelism() {
997	>	long h; int pc, wc;
998	>	if (((int)((h = eventWaiters) & WAITER_ID_MASK)) != 0) {
999	>	if ((int)(h >>> EVENT_COUNT_SHIFT) != eventCount)
1000	>	releaseEventWaiters(); // avoid useless call
1001	>	}
1002	>	else if ((pc = parallelism) >
1003	>	((wc = workerCounts) & RUNNING_COUNT_MASK)) {
1004	>	if (spareWaiters != 0)
1005	>	tryResumeSpare(wc);
1006	>	else if ((wc >>> TOTAL_COUNT_SHIFT) < pc)
1007	>	addWorkerIfBelowTarget();
1008	>	else
1009	>	tryAddWorkerIfBusy(wc);
1010	>	}
1011	>	}
1012	>
1013	>	/**
1014	>	* Callback from workers invoked upon each top-level action (i.e.,
1015	>	* stealing a task or taking a submission and running it).
1016	>	* Performs one or more of the following:
1017	>	*
1018	>	* 1. If the worker is active, try to set its active status to
1019	>	*    inactive and update activeCount. On contention, we may try
1020	>	*    again on this or subsequent call.
1021	>	*
1022	>	* 2. Release any existing event waiters that are now relesable
1023	>	*
1024	>	* 3. If there are too many running threads, suspend this worker
1025	>	*    (first forcing inactive if necessary).  If it is not
1026	>	*    needed, it may be killed while suspended via
1027	>	*    tryShutdownSpare. Otherwise, upon resume it rechecks to make
1028	>	*    sure that it is still needed.
1029	>	*
1030	>	* 4. If more than 1 miss, await the next task event via
1031	>	*    eventSync (first forcing inactivation if necessary), upon
1032	>	*    which worker may also be killed, via tryShutdownWaiter.
1033	>	*
1034	>	* 5. Help reactivate other workers via helpMaintainParallelism
1035	>	*
1036	>	* @param w the worker
1037	>	* @param misses the number of scans by caller failing to find work
1038	>	* (saturating at 2 to avoid wraparound)
1039	>	*/
1040	>	final void preStep(ForkJoinWorkerThread w, int misses) {
1041	>	boolean active = w.active;
1042	>	int pc = parallelism;
1043	>	for (;;) {
1044	>	int rs, wc, rc, ec; long h;
1045	>	if (active && UNSAFE.compareAndSwapInt(this, runStateOffset,
1046	>	rs = runState, rs - 1))
1047	>	active = w.active = false;
1048	>	if (((int)((h = eventWaiters) & WAITER_ID_MASK)) != 0 &&
1049	>	(int)(h >>> EVENT_COUNT_SHIFT) != eventCount) {
1050	>	releaseEventWaiters();
1051	>	if (misses > 1)
1052	>	continue;                  // clear before sync below
1053	>	}
1054	>	if ((rc = ((wc = workerCounts) & RUNNING_COUNT_MASK)) > pc) {
1055	>	if (!active &&                 // must inactivate to suspend
1056	>	workerCounts == wc &&      // try to suspend as spare
1057	>	UNSAFE.compareAndSwapInt(this, workerCountsOffset,
1058	>	wc, wc - ONE_RUNNING)) {
1059	>	w.suspendAsSpare();
1060	>	if (!w.isRunning())
1061	>	break;                 // was killed while spare
1062	>	}
1063	>	continue;
1064	>	}
1065	>	if (misses > 0) {
1066	>	if ((ec = eventCount) == w.lastEventCount && misses > 1) {
1067	>	if (!active) {             // must inactivate to sync
1068	>	eventSync(w);
1069	>	if (w.isRunning())
1070	>	misses = 1;        // don't re-sync
1071	>	else
1072	>	break;             // was killed while waiting
1073		}
1074	+	continue;
1075		}
1076	<	} finally {
537	<	lock.unlock();
1076	>	w.lastEventCount = ec;
1077		}
1078	+	if (rc < pc)
1079	+	helpMaintainParallelism();
1080	+	break;
1081		}
1082		}
1083
1084		/**
1085	<	* Worker creation and startup for threads added via setParallelism.
1085	>	* Helps and/or blocks awaiting join of the given task.
1086	>	* Alternates between helpJoinTask() and helpMaintainParallelism()
1087	>	* as many times as there is a deficit in running count (or longer
1088	>	* if running count would become zero), then blocks if task still
1089	>	* not done.
1090	>	*
1091	>	* @param joinMe the task to join
1092		*/
1093	<	private void createAndStartAddedWorkers() {
1094	<	resumeAllSpares();  // Allow spares to convert to nonspare
1095	<	int ps = parallelism;
1096	<	ForkJoinWorkerThread[] ws = ensureWorkerArrayCapacity(ps);
1097	<	int len = ws.length;
1098	<	// Sweep through slots, to keep lowest indices most populated
1099	<	int k = 0;
1100	<	while (k < len) {
1101	<	if (ws[k] != null) {
1102	<	++k;
1103	<	continue;
1093	>	final void awaitJoin(ForkJoinTask<?> joinMe, ForkJoinWorkerThread worker) {
1094	>	int threshold = parallelism;         // descend blocking thresholds
1095	>	while (joinMe.status >= 0) {
1096	>	boolean block; int wc;
1097	>	worker.helpJoinTask(joinMe);
1098	>	if (joinMe.status < 0)
1099	>	break;
1100	>	if (((wc = workerCounts) & RUNNING_COUNT_MASK) <= threshold) {
1101	>	if (threshold > 0)
1102	>	--threshold;
1103	>	else
1104	>	advanceEventCount(); // force release
1105	>	block = false;
1106		}
1107	<	int s = workerCounts;
1108	<	int tc = totalCountOf(s);
1109	<	int rc = runningCountOf(s);
1110	<	if (rc >= ps || tc >= ps)
1107	>	else
1108	>	block = UNSAFE.compareAndSwapInt(this, workerCountsOffset,
1109	>	wc, wc - ONE_RUNNING);
1110	>	helpMaintainParallelism();
1111	>	if (block) {
1112	>	int c;
1113	>	joinMe.internalAwaitDone();
1114	>	do {} while (!UNSAFE.compareAndSwapInt
1115	>	(this, workerCountsOffset,
1116	>	c = workerCounts, c + ONE_RUNNING));
1117		break;
1118	<	if (casWorkerCounts (s, workerCountsFor(tc+1, rc+1))) {
1119	<	ForkJoinWorkerThread w = createWorker(k);
1120	<	if (w != null) {
1121	<	ws[k++] = w;
1122	<	w.start();
1118	>	}
1119	>	}
1120	>	}
1121	>
1122	>	/**
1123	>	* Same idea as awaitJoin, but no helping
1124	>	*/
1125	>	final void awaitBlocker(ManagedBlocker blocker)
1126	>	throws InterruptedException {
1127	>	int threshold = parallelism;
1128	>	while (!blocker.isReleasable()) {
1129	>	boolean block; int wc;
1130	>	if (((wc = workerCounts) & RUNNING_COUNT_MASK) <= threshold) {
1131	>	if (threshold > 0)
1132	>	--threshold;
1133	>	else
1134	>	advanceEventCount();
1135	>	block = false;
1136	>	}
1137	>	else
1138	>	block = UNSAFE.compareAndSwapInt(this, workerCountsOffset,
1139	>	wc, wc - ONE_RUNNING);
1140	>	helpMaintainParallelism();
1141	>	if (block) {
1142	>	try {
1143	>	do {} while (!blocker.isReleasable() && !blocker.block());
1144	>	} finally {
1145	>	int c;
1146	>	do {} while (!UNSAFE.compareAndSwapInt
1147	>	(this, workerCountsOffset,
1148	>	c = workerCounts, c + ONE_RUNNING));
1149		}
1150	<	else {
1151	<	updateWorkerCount(-1); // back out on failed creation
1152	<	break;
1150	>	break;
1151	>	}
1152	>	}
1153	>	}
1154	>
1155	>	/**
1156	>	* Possibly initiates and/or completes termination.
1157	>	*
1158	>	* @param now if true, unconditionally terminate, else only
1159	>	* if shutdown and empty queue and no active workers
1160	>	* @return true if now terminating or terminated
1161	>	*/
1162	>	private boolean tryTerminate(boolean now) {
1163	>	if (now)
1164	>	advanceRunLevel(SHUTDOWN); // ensure at least SHUTDOWN
1165	>	else if (runState < SHUTDOWN ||
1166	>	!submissionQueue.isEmpty() ||
1167	>	(runState & ACTIVE_COUNT_MASK) != 0)
1168	>	return false;
1169	>
1170	>	if (advanceRunLevel(TERMINATING))
1171	>	startTerminating();
1172	>
1173	>	// Finish now if all threads terminated; else in some subsequent call
1174	>	if ((workerCounts >>> TOTAL_COUNT_SHIFT) == 0) {
1175	>	advanceRunLevel(TERMINATED);
1176	>	termination.arrive();
1177	>	}
1178	>	return true;
1179	>	}
1180	>
1181	>	/**
1182	>	* Actions on transition to TERMINATING
1183	>	*
1184	>	* Runs up to four passes through workers: (0) shutting down each
1185	>	* (without waking up if parked) to quickly spread notifications
1186	>	* without unnecessary bouncing around event queues etc (1) wake
1187	>	* up and help cancel tasks (2) interrupt (3) mop up races with
1188	>	* interrupted workers
1189	>	*/
1190	>	private void startTerminating() {
1191	>	cancelSubmissions();
1192	>	for (int passes = 0; passes < 4 && workerCounts != 0; ++passes) {
1193	>	advanceEventCount();
1194	>	eventWaiters = 0L; // clobber lists
1195	>	spareWaiters = 0;
1196	>	ForkJoinWorkerThread[] ws = workers;
1197	>	int n = ws.length;
1198	>	for (int i = 0; i < n; ++i) {
1199	>	ForkJoinWorkerThread w = ws[i];
1200	>	if (w != null) {
1201	>	w.shutdown();
1202	>	if (passes > 0 && !w.isTerminated()) {
1203	>	w.cancelTasks();
1204	>	LockSupport.unpark(w);
1205	>	if (passes > 1) {
1206	>	try {
1207	>	w.interrupt();
1208	>	} catch (SecurityException ignore) {
1209	>	}
1210	>	}
1211	>	}
1212		}
1213		}
1214		}
1215		}
1216
1217	+	/**
1218	+	* Clear out and cancel submissions, ignoring exceptions
1219	+	*/
1220	+	private void cancelSubmissions() {
1221	+	ForkJoinTask<?> task;
1222	+	while ((task = submissionQueue.poll()) != null) {
1223	+	try {
1224	+	task.cancel(false);
1225	+	} catch (Throwable ignore) {
1226	+	}
1227	+	}
1228	+	}
1229	+
1230	+	// misc support for ForkJoinWorkerThread
1231	+
1232	+	/**
1233	+	* Returns pool number
1234	+	*/
1235	+	final int getPoolNumber() {
1236	+	return poolNumber;
1237	+	}
1238	+
1239	+	/**
1240	+	* Tries to accumulates steal count from a worker, clearing
1241	+	* the worker's value.
1242	+	*
1243	+	* @return true if worker steal count now zero
1244	+	*/
1245	+	final boolean tryAccumulateStealCount(ForkJoinWorkerThread w) {
1246	+	int sc = w.stealCount;
1247	+	long c = stealCount;
1248	+	// CAS even if zero, for fence effects
1249	+	if (UNSAFE.compareAndSwapLong(this, stealCountOffset, c, c + sc)) {
1250	+	if (sc != 0)
1251	+	w.stealCount = 0;
1252	+	return true;
1253	+	}
1254	+	return sc == 0;
1255	+	}
1256	+
1257	+	/**
1258	+	* Returns the approximate (non-atomic) number of idle threads per
1259	+	* active thread.
1260	+	*/
1261	+	final int idlePerActive() {
1262	+	int pc = parallelism; // use parallelism, not rc
1263	+	int ac = runState;    // no mask -- artifically boosts during shutdown
1264	+	// Use exact results for small values, saturate past 4
1265	+	return pc <= ac? 0 : pc >>> 1 <= ac? 1 : pc >>> 2 <= ac? 3 : pc >>> 3;
1266	+	}
1267	+
1268	+	// Public and protected methods
1269	+
1270	+	// Constructors
1271	+
1272	+	/**
1273	+	* Creates a {@code ForkJoinPool} with parallelism equal to {@link
1274	+	* java.lang.Runtime#availableProcessors}, using the {@linkplain
1275	+	* #defaultForkJoinWorkerThreadFactory default thread factory},
1276	+	* no UncaughtExceptionHandler, and non-async LIFO processing mode.
1277	+	*
1278	+	* @throws SecurityException if a security manager exists and
1279	+	*         the caller is not permitted to modify threads
1280	+	*         because it does not hold {@link
1281	+	*         java.lang.RuntimePermission}{@code ("modifyThread")}
1282	+	*/
1283	+	public ForkJoinPool() {
1284	+	this(Runtime.getRuntime().availableProcessors(),
1285	+	defaultForkJoinWorkerThreadFactory, null, false);
1286	+	}
1287	+
1288	+	/**
1289	+	* Creates a {@code ForkJoinPool} with the indicated parallelism
1290	+	* level, the {@linkplain
1291	+	* #defaultForkJoinWorkerThreadFactory default thread factory},
1292	+	* no UncaughtExceptionHandler, and non-async LIFO processing mode.
1293	+	*
1294	+	* @param parallelism the parallelism level
1295	+	* @throws IllegalArgumentException if parallelism less than or
1296	+	*         equal to zero, or greater than implementation limit
1297	+	* @throws SecurityException if a security manager exists and
1298	+	*         the caller is not permitted to modify threads
1299	+	*         because it does not hold {@link
1300	+	*         java.lang.RuntimePermission}{@code ("modifyThread")}
1301	+	*/
1302	+	public ForkJoinPool(int parallelism) {
1303	+	this(parallelism, defaultForkJoinWorkerThreadFactory, null, false);
1304	+	}
1305	+
1306	+	/**
1307	+	* Creates a {@code ForkJoinPool} with the given parameters.
1308	+	*
1309	+	* @param parallelism the parallelism level. For default value,
1310	+	* use {@link java.lang.Runtime#availableProcessors}.
1311	+	* @param factory the factory for creating new threads. For default value,
1312	+	* use {@link #defaultForkJoinWorkerThreadFactory}.
1313	+	* @param handler the handler for internal worker threads that
1314	+	* terminate due to unrecoverable errors encountered while executing
1315	+	* tasks. For default value, use <code>null</code>.
1316	+	* @param asyncMode if true,
1317	+	* establishes local first-in-first-out scheduling mode for forked
1318	+	* tasks that are never joined. This mode may be more appropriate
1319	+	* than default locally stack-based mode in applications in which
1320	+	* worker threads only process event-style asynchronous tasks.
1321	+	* For default value, use <code>false</code>.
1322	+	* @throws IllegalArgumentException if parallelism less than or
1323	+	*         equal to zero, or greater than implementation limit
1324	+	* @throws NullPointerException if the factory is null
1325	+	* @throws SecurityException if a security manager exists and
1326	+	*         the caller is not permitted to modify threads
1327	+	*         because it does not hold {@link
1328	+	*         java.lang.RuntimePermission}{@code ("modifyThread")}
1329	+	*/
1330	+	public ForkJoinPool(int parallelism,
1331	+	ForkJoinWorkerThreadFactory factory,
1332	+	Thread.UncaughtExceptionHandler handler,
1333	+	boolean asyncMode) {
1334	+	checkPermission();
1335	+	if (factory == null)
1336	+	throw new NullPointerException();
1337	+	if (parallelism <= 0 || parallelism > MAX_WORKERS)
1338	+	throw new IllegalArgumentException();
1339	+	this.parallelism = parallelism;
1340	+	this.factory = factory;
1341	+	this.ueh = handler;
1342	+	this.locallyFifo = asyncMode;
1343	+	int arraySize = initialArraySizeFor(parallelism);
1344	+	this.workers = new ForkJoinWorkerThread[arraySize];
1345	+	this.submissionQueue = new LinkedTransferQueue<ForkJoinTask<?>>();
1346	+	this.workerLock = new ReentrantLock();
1347	+	this.termination = new Phaser(1);
1348	+	this.poolNumber = poolNumberGenerator.incrementAndGet();
1349	+	}
1350	+
1351	+	/**
1352	+	* Returns initial power of two size for workers array.
1353	+	* @param pc the initial parallelism level
1354	+	*/
1355	+	private static int initialArraySizeFor(int pc) {
1356	+	// See Hackers Delight, sec 3.2. We know MAX_WORKERS < (1 >>> 16)
1357	+	int size = pc < MAX_WORKERS ? pc + 1 : MAX_WORKERS;
1358	+	size |= size >>> 1;
1359	+	size |= size >>> 2;
1360	+	size |= size >>> 4;
1361	+	size |= size >>> 8;
1362	+	return size + 1;
1363	+	}
1364	+
1365		// Execution methods
1366
1367		/**
#	Line 581 | Line 1370 | public class ForkJoinPool extends Abstra
1370		private <T> void doSubmit(ForkJoinTask<T> task) {
1371		if (task == null)
1372		throw new NullPointerException();
1373	<	if (isShutdown())
1373	>	if (runState >= SHUTDOWN)
1374		throw new RejectedExecutionException();
586	–	if (workers == null)
587	–	ensureWorkerInitialization();
1375		submissionQueue.offer(task);
1376	<	signalIdleWorkers();
1376	>	advanceEventCount();
1377	>	if (eventWaiters != 0L)
1378	>	releaseEventWaiters();
1379	>	if ((workerCounts >>> TOTAL_COUNT_SHIFT) < parallelism)
1380	>	addWorkerIfBelowTarget();
1381		}
1382
1383		/**
#	Line 594 | Line 1385 | public class ForkJoinPool extends Abstra
1385		*
1386		* @param task the task
1387		* @return the task's result
1388	<	* @throws NullPointerException if task is null
1389	<	* @throws RejectedExecutionException if pool is shut down
1388	>	* @throws NullPointerException if the task is null
1389	>	* @throws RejectedExecutionException if the task cannot be
1390	>	*         scheduled for execution
1391		*/
1392		public <T> T invoke(ForkJoinTask<T> task) {
1393		doSubmit(task);
#	Line 606 | Line 1398 | public class ForkJoinPool extends Abstra
1398		* Arranges for (asynchronous) execution of the given task.
1399		*
1400		* @param task the task
1401	<	* @throws NullPointerException if task is null
1402	<	* @throws RejectedExecutionException if pool is shut down
1401	>	* @throws NullPointerException if the task is null
1402	>	* @throws RejectedExecutionException if the task cannot be
1403	>	*         scheduled for execution
1404		*/
1405		public void execute(ForkJoinTask<?> task) {
1406		doSubmit(task);
#	Line 615 | Line 1408 | public class ForkJoinPool extends Abstra
1408
1409		// AbstractExecutorService methods
1410
1411	+	/**
1412	+	* @throws NullPointerException if the task is null
1413	+	* @throws RejectedExecutionException if the task cannot be
1414	+	*         scheduled for execution
1415	+	*/
1416		public void execute(Runnable task) {
1417		ForkJoinTask<?> job;
1418		if (task instanceof ForkJoinTask<?>) // avoid re-wrap
#	Line 624 | Line 1422 | public class ForkJoinPool extends Abstra
1422		doSubmit(job);
1423		}
1424
1425	+	/**
1426	+	* Submits a ForkJoinTask for execution.
1427	+	*
1428	+	* @param task the task to submit
1429	+	* @return the task
1430	+	* @throws NullPointerException if the task is null
1431	+	* @throws RejectedExecutionException if the task cannot be
1432	+	*         scheduled for execution
1433	+	*/
1434	+	public <T> ForkJoinTask<T> submit(ForkJoinTask<T> task) {
1435	+	doSubmit(task);
1436	+	return task;
1437	+	}
1438	+
1439	+	/**
1440	+	* @throws NullPointerException if the task is null
1441	+	* @throws RejectedExecutionException if the task cannot be
1442	+	*         scheduled for execution
1443	+	*/
1444		public <T> ForkJoinTask<T> submit(Callable<T> task) {
1445		ForkJoinTask<T> job = ForkJoinTask.adapt(task);
1446		doSubmit(job);
1447		return job;
1448		}
1449
1450	+	/**
1451	+	* @throws NullPointerException if the task is null
1452	+	* @throws RejectedExecutionException if the task cannot be
1453	+	*         scheduled for execution
1454	+	*/
1455		public <T> ForkJoinTask<T> submit(Runnable task, T result) {
1456		ForkJoinTask<T> job = ForkJoinTask.adapt(task, result);
1457		doSubmit(job);
1458		return job;
1459		}
1460
1461	+	/**
1462	+	* @throws NullPointerException if the task is null
1463	+	* @throws RejectedExecutionException if the task cannot be
1464	+	*         scheduled for execution
1465	+	*/
1466		public ForkJoinTask<?> submit(Runnable task) {
1467		ForkJoinTask<?> job;
1468		if (task instanceof ForkJoinTask<?>) // avoid re-wrap
#	Line 647 | Line 1474 | public class ForkJoinPool extends Abstra
1474		}
1475
1476		/**
1477	<	* Submits a ForkJoinTask for execution.
1478	<	*
652	<	* @param task the task to submit
653	<	* @return the task
654	<	* @throws RejectedExecutionException if the task cannot be
655	<	*         scheduled for execution
656	<	* @throws NullPointerException if the task is null
1477	>	* @throws NullPointerException       {@inheritDoc}
1478	>	* @throws RejectedExecutionException {@inheritDoc}
1479		*/
658	–	public <T> ForkJoinTask<T> submit(ForkJoinTask<T> task) {
659	–	doSubmit(task);
660	–	return task;
661	–	}
662	–
663	–
1480		public <T> List<Future<T>> invokeAll(Collection<? extends Callable<T>> tasks) {
1481		ArrayList<ForkJoinTask<T>> forkJoinTasks =
1482		new ArrayList<ForkJoinTask<T>>(tasks.size());
#	Line 669 | Line 1485 | public class ForkJoinPool extends Abstra
1485		invoke(new InvokeAll<T>(forkJoinTasks));
1486
1487		@SuppressWarnings({"unchecked", "rawtypes"})
1488	<	List<Future<T>> futures = (List<Future<T>>) (List) forkJoinTasks;
1488	>	List<Future<T>> futures = (List<Future<T>>) (List) forkJoinTasks;
1489		return futures;
1490		}
1491
#	Line 683 | Line 1499 | public class ForkJoinPool extends Abstra
1499		private static final long serialVersionUID = -7914297376763021607L;
1500		}
1501
686	–	// Configuration and status settings and queries
687	–
1502		/**
1503		* Returns the factory used for constructing new workers.
1504		*
#	Line 701 | Line 1515 | public class ForkJoinPool extends Abstra
1515		* @return the handler, or {@code null} if none
1516		*/
1517		public Thread.UncaughtExceptionHandler getUncaughtExceptionHandler() {
1518	<	Thread.UncaughtExceptionHandler h;
705	<	final ReentrantLock lock = this.workerLock;
706	<	lock.lock();
707	<	try {
708	<	h = ueh;
709	<	} finally {
710	<	lock.unlock();
711	<	}
712	<	return h;
713	<	}
714	<
715	<	/**
716	<	* Sets the handler for internal worker threads that terminate due
717	<	* to unrecoverable errors encountered while executing tasks.
718	<	* Unless set, the current default or ThreadGroup handler is used
719	<	* as handler.
720	<	*
721	<	* @param h the new handler
722	<	* @return the old handler, or {@code null} if none
723	<	* @throws SecurityException if a security manager exists and
724	<	*         the caller is not permitted to modify threads
725	<	*         because it does not hold {@link
726	<	*         java.lang.RuntimePermission}{@code ("modifyThread")}
727	<	*/
728	<	public Thread.UncaughtExceptionHandler
729	<	setUncaughtExceptionHandler(Thread.UncaughtExceptionHandler h) {
730	<	checkPermission();
731	<	Thread.UncaughtExceptionHandler old = null;
732	<	final ReentrantLock lock = this.workerLock;
733	<	lock.lock();
734	<	try {
735	<	old = ueh;
736	<	ueh = h;
737	<	ForkJoinWorkerThread[] ws = workers;
738	<	if (ws != null) {
739	<	for (int i = 0; i < ws.length; ++i) {
740	<	ForkJoinWorkerThread w = ws[i];
741	<	if (w != null)
742	<	w.setUncaughtExceptionHandler(h);
743	<	}
744	<	}
745	<	} finally {
746	<	lock.unlock();
747	<	}
748	<	return old;
749	<	}
750	<
751	<
752	<	/**
753	<	* Sets the target parallelism level of this pool.
754	<	*
755	<	* @param parallelism the target parallelism
756	<	* @throws IllegalArgumentException if parallelism less than or
757	<	* equal to zero or greater than maximum size bounds
758	<	* @throws SecurityException if a security manager exists and
759	<	*         the caller is not permitted to modify threads
760	<	*         because it does not hold {@link
761	<	*         java.lang.RuntimePermission}{@code ("modifyThread")}
762	<	*/
763	<	public void setParallelism(int parallelism) {
764	<	checkPermission();
765	<	if (parallelism <= 0 || parallelism > maxPoolSize)
766	<	throw new IllegalArgumentException();
767	<	final ReentrantLock lock = this.workerLock;
768	<	lock.lock();
769	<	try {
770	<	if (isProcessingTasks()) {
771	<	int p = this.parallelism;
772	<	this.parallelism = parallelism;
773	<	if (parallelism > p)
774	<	createAndStartAddedWorkers();
775	<	else
776	<	trimSpares();
777	<	}
778	<	} finally {
779	<	lock.unlock();
780	<	}
781	<	signalIdleWorkers();
1518	>	return ueh;
1519		}
1520
1521		/**
#	Line 799 | Line 1536 | public class ForkJoinPool extends Abstra
1536		* @return the number of worker threads
1537		*/
1538		public int getPoolSize() {
1539	<	return totalCountOf(workerCounts);
803	<	}
804	<
805	<	/**
806	<	* Returns the maximum number of threads allowed to exist in the
807	<	* pool. Unless set using {@link #setMaximumPoolSize}, the
808	<	* maximum is an implementation-defined value designed only to
809	<	* prevent runaway growth.
810	<	*
811	<	* @return the maximum
812	<	*/
813	<	public int getMaximumPoolSize() {
814	<	return maxPoolSize;
815	<	}
816	<
817	<	/**
818	<	* Sets the maximum number of threads allowed to exist in the
819	<	* pool. The given value should normally be greater than or equal
820	<	* to the {@link #getParallelism parallelism} level. Setting this
821	<	* value has no effect on current pool size. It controls
822	<	* construction of new threads.
823	<	*
824	<	* @throws IllegalArgumentException if negative or greater than
825	<	* internal implementation limit
826	<	*/
827	<	public void setMaximumPoolSize(int newMax) {
828	<	if (newMax < 0 || newMax > MAX_THREADS)
829	<	throw new IllegalArgumentException();
830	<	maxPoolSize = newMax;
831	<	}
832	<
833	<
834	<	/**
835	<	* Returns {@code true} if this pool dynamically maintains its
836	<	* target parallelism level. If false, new threads are added only
837	<	* to avoid possible starvation.  This setting is by default true.
838	<	*
839	<	* @return {@code true} if maintains parallelism
840	<	*/
841	<	public boolean getMaintainsParallelism() {
842	<	return maintainsParallelism;
843	<	}
844	<
845	<	/**
846	<	* Sets whether this pool dynamically maintains its target
847	<	* parallelism level. If false, new threads are added only to
848	<	* avoid possible starvation.
849	<	*
850	<	* @param enable {@code true} to maintain parallelism
851	<	*/
852	<	public void setMaintainsParallelism(boolean enable) {
853	<	maintainsParallelism = enable;
854	<	}
855	<
856	<	/**
857	<	* Establishes local first-in-first-out scheduling mode for forked
858	<	* tasks that are never joined. This mode may be more appropriate
859	<	* than default locally stack-based mode in applications in which
860	<	* worker threads only process asynchronous tasks.  This method is
861	<	* designed to be invoked only when the pool is quiescent, and
862	<	* typically only before any tasks are submitted. The effects of
863	<	* invocations at other times may be unpredictable.
864	<	*
865	<	* @param async if {@code true}, use locally FIFO scheduling
866	<	* @return the previous mode
867	<	* @see #getAsyncMode
868	<	*/
869	<	public boolean setAsyncMode(boolean async) {
870	<	boolean oldMode = locallyFifo;
871	<	locallyFifo = async;
872	<	ForkJoinWorkerThread[] ws = workers;
873	<	if (ws != null) {
874	<	for (int i = 0; i < ws.length; ++i) {
875	<	ForkJoinWorkerThread t = ws[i];
876	<	if (t != null)
877	<	t.setAsyncMode(async);
878	<	}
879	<	}
880	<	return oldMode;
1539	>	return workerCounts >>> TOTAL_COUNT_SHIFT;
1540		}
1541
1542		/**
#	Line 885 | Line 1544 | public class ForkJoinPool extends Abstra
1544		* scheduling mode for forked tasks that are never joined.
1545		*
1546		* @return {@code true} if this pool uses async mode
888	–	* @see #setAsyncMode
1547		*/
1548		public boolean getAsyncMode() {
1549		return locallyFifo;
#	Line 894 | Line 1552 | public class ForkJoinPool extends Abstra
1552		/**
1553		* Returns an estimate of the number of worker threads that are
1554		* not blocked waiting to join tasks or for other managed
1555	<	* synchronization.
1555	>	* synchronization. This method may overestimate the
1556	>	* number of running threads.
1557		*
1558		* @return the number of worker threads
1559		*/
1560		public int getRunningThreadCount() {
1561	<	return runningCountOf(workerCounts);
1561	>	return workerCounts & RUNNING_COUNT_MASK;
1562		}
1563
1564		/**
#	Line 910 | Line 1569 | public class ForkJoinPool extends Abstra
1569		* @return the number of active threads
1570		*/
1571		public int getActiveThreadCount() {
1572	<	return activeCountOf(runControl);
914	<	}
915	<
916	<	/**
917	<	* Returns an estimate of the number of threads that are currently
918	<	* idle waiting for tasks. This method may underestimate the
919	<	* number of idle threads.
920	<	*
921	<	* @return the number of idle threads
922	<	*/
923	<	final int getIdleThreadCount() {
924	<	int c = runningCountOf(workerCounts) - activeCountOf(runControl);
925	<	return (c <= 0) ? 0 : c;
1572	>	return runState & ACTIVE_COUNT_MASK;
1573		}
1574
1575		/**
#	Line 937 | Line 1584 | public class ForkJoinPool extends Abstra
1584		* @return {@code true} if all threads are currently idle
1585		*/
1586		public boolean isQuiescent() {
1587	<	return activeCountOf(runControl) == 0;
1587	>	return (runState & ACTIVE_COUNT_MASK) == 0;
1588		}
1589
1590		/**
#	Line 952 | Line 1599 | public class ForkJoinPool extends Abstra
1599		* @return the number of steals
1600		*/
1601		public long getStealCount() {
1602	<	return stealCount.get();
956	<	}
957	<
958	<	/**
959	<	* Accumulates steal count from a worker.
960	<	* Call only when worker known to be idle.
961	<	*/
962	<	private void updateStealCount(ForkJoinWorkerThread w) {
963	<	int sc = w.getAndClearStealCount();
964	<	if (sc != 0)
965	<	stealCount.addAndGet(sc);
1602	>	return stealCount;
1603		}
1604
1605		/**
#	Line 978 | Line 1615 | public class ForkJoinPool extends Abstra
1615		public long getQueuedTaskCount() {
1616		long count = 0;
1617		ForkJoinWorkerThread[] ws = workers;
1618	<	if (ws != null) {
1619	<	for (int i = 0; i < ws.length; ++i) {
1620	<	ForkJoinWorkerThread t = ws[i];
1621	<	if (t != null)
1622	<	count += t.getQueueSize();
986	<	}
1618	>	int n = ws.length;
1619	>	for (int i = 0; i < n; ++i) {
1620	>	ForkJoinWorkerThread w = ws[i];
1621	>	if (w != null)
1622	>	count += w.getQueueSize();
1623		}
1624		return count;
1625		}
#	Line 1038 | Line 1674 | public class ForkJoinPool extends Abstra
1674		* @return the number of elements transferred
1675		*/
1676		protected int drainTasksTo(Collection<? super ForkJoinTask<?>> c) {
1677	<	int n = submissionQueue.drainTo(c);
1677	>	int count = submissionQueue.drainTo(c);
1678		ForkJoinWorkerThread[] ws = workers;
1679	<	if (ws != null) {
1680	<	for (int i = 0; i < ws.length; ++i) {
1681	<	ForkJoinWorkerThread w = ws[i];
1682	<	if (w != null)
1683	<	n += w.drainTasksTo(c);
1048	<	}
1679	>	int n = ws.length;
1680	>	for (int i = 0; i < n; ++i) {
1681	>	ForkJoinWorkerThread w = ws[i];
1682	>	if (w != null)
1683	>	count += w.drainTasksTo(c);
1684		}
1685	<	return n;
1685	>	return count;
1686		}
1687
1688		/**
#	Line 1058 | Line 1693 | public class ForkJoinPool extends Abstra
1693		* @return a string identifying this pool, as well as its state
1694		*/
1695		public String toString() {
1061	–	int ps = parallelism;
1062	–	int wc = workerCounts;
1063	–	int rc = runControl;
1696		long st = getStealCount();
1697		long qt = getQueuedTaskCount();
1698		long qs = getQueuedSubmissionCount();
1699	+	int wc = workerCounts;
1700	+	int tc = wc >>> TOTAL_COUNT_SHIFT;
1701	+	int rc = wc & RUNNING_COUNT_MASK;
1702	+	int pc = parallelism;
1703	+	int rs = runState;
1704	+	int ac = rs & ACTIVE_COUNT_MASK;
1705		return super.toString() +
1706	<	"[" + runStateToString(runStateOf(rc)) +
1707	<	", parallelism = " + ps +
1708	<	", size = " + totalCountOf(wc) +
1709	<	", active = " + activeCountOf(rc) +
1710	<	", running = " + runningCountOf(wc) +
1706	>	"[" + runLevelToString(rs) +
1707	>	", parallelism = " + pc +
1708	>	", size = " + tc +
1709	>	", active = " + ac +
1710	>	", running = " + rc +
1711		", steals = " + st +
1712		", tasks = " + qt +
1713		", submissions = " + qs +
1714		"]";
1715		}
1716
1717	<	private static String runStateToString(int rs) {
1718	<	switch(rs) {
1719	<	case RUNNING: return "Running";
1720	<	case SHUTDOWN: return "Shutting down";
1721	<	case TERMINATING: return "Terminating";
1084	<	case TERMINATED: return "Terminated";
1085	<	default: throw new Error("Unknown run state");
1086	<	}
1717	>	private static String runLevelToString(int s) {
1718	>	return ((s & TERMINATED) != 0 ? "Terminated" :
1719	>	((s & TERMINATING) != 0 ? "Terminating" :
1720	>	((s & SHUTDOWN) != 0 ? "Shutting down" :
1721	>	"Running")));
1722		}
1723
1089	–	// lifecycle control
1090	–
1724		/**
1725		* Initiates an orderly shutdown in which previously submitted
1726		* tasks are executed, but no new tasks will be accepted.
#	Line 1102 | Line 1735 | public class ForkJoinPool extends Abstra
1735		*/
1736		public void shutdown() {
1737		checkPermission();
1738	<	transitionRunStateTo(SHUTDOWN);
1739	<	if (canTerminateOnShutdown(runControl)) {
1107	<	if (workers == null) { // shutting down before workers created
1108	<	final ReentrantLock lock = this.workerLock;
1109	<	lock.lock();
1110	<	try {
1111	<	if (workers == null) {
1112	<	terminate();
1113	<	transitionRunStateTo(TERMINATED);
1114	<	termination.signalAll();
1115	<	}
1116	<	} finally {
1117	<	lock.unlock();
1118	<	}
1119	<	}
1120	<	terminateOnShutdown();
1121	<	}
1738	>	advanceRunLevel(SHUTDOWN);
1739	>	tryTerminate(false);
1740		}
1741
1742		/**
#	Line 1139 | Line 1757 | public class ForkJoinPool extends Abstra
1757		*/
1758		public List<Runnable> shutdownNow() {
1759		checkPermission();
1760	<	terminate();
1760	>	tryTerminate(true);
1761		return Collections.emptyList();
1762		}
1763
#	Line 1149 | Line 1767 | public class ForkJoinPool extends Abstra
1767		* @return {@code true} if all tasks have completed following shut down
1768		*/
1769		public boolean isTerminated() {
1770	<	return runStateOf(runControl) == TERMINATED;
1770	>	return runState >= TERMINATED;
1771		}
1772
1773		/**
#	Line 1163 | Line 1781 | public class ForkJoinPool extends Abstra
1781		* @return {@code true} if terminating but not yet terminated
1782		*/
1783		public boolean isTerminating() {
1784	<	return runStateOf(runControl) == TERMINATING;
1784	>	return (runState & (TERMINATING|TERMINATED)) == TERMINATING;
1785		}
1786
1787		/**
#	Line 1172 | Line 1790 | public class ForkJoinPool extends Abstra
1790		* @return {@code true} if this pool has been shut down
1791		*/
1792		public boolean isShutdown() {
1793	<	return runStateOf(runControl) >= SHUTDOWN;
1176	<	}
1177	<
1178	<	/**
1179	<	* Returns true if pool is not terminating or terminated.
1180	<	* Used internally to suppress execution when terminating.
1181	<	*/
1182	<	final boolean isProcessingTasks() {
1183	<	return runStateOf(runControl) < TERMINATING;
1793	>	return runState >= SHUTDOWN;
1794		}
1795
1796		/**
#	Line 1196 | Line 1806 | public class ForkJoinPool extends Abstra
1806		*/
1807		public boolean awaitTermination(long timeout, TimeUnit unit)
1808		throws InterruptedException {
1199	–	long nanos = unit.toNanos(timeout);
1200	–	final ReentrantLock lock = this.workerLock;
1201	–	lock.lock();
1202	–	try {
1203	–	for (;;) {
1204	–	if (isTerminated())
1205	–	return true;
1206	–	if (nanos <= 0)
1207	–	return false;
1208	–	nanos = termination.awaitNanos(nanos);
1209	–	}
1210	–	} finally {
1211	–	lock.unlock();
1212	–	}
1213	–	}
1214	–
1215	–	// Shutdown and termination support
1216	–
1217	–	/**
1218	–	* Callback from terminating worker. Nulls out the corresponding
1219	–	* workers slot, and if terminating, tries to terminate; else
1220	–	* tries to shrink workers array.
1221	–	*
1222	–	* @param w the worker
1223	–	*/
1224	–	final void workerTerminated(ForkJoinWorkerThread w) {
1225	–	updateStealCount(w);
1226	–	updateWorkerCount(-1);
1227	–	final ReentrantLock lock = this.workerLock;
1228	–	lock.lock();
1229	–	try {
1230	–	ForkJoinWorkerThread[] ws = workers;
1231	–	if (ws != null) {
1232	–	int idx = w.poolIndex;
1233	–	if (idx >= 0 && idx < ws.length && ws[idx] == w)
1234	–	ws[idx] = null;
1235	–	if (totalCountOf(workerCounts) == 0) {
1236	–	terminate(); // no-op if already terminating
1237	–	transitionRunStateTo(TERMINATED);
1238	–	termination.signalAll();
1239	–	}
1240	–	else if (isProcessingTasks()) {
1241	–	tryShrinkWorkerArray();
1242	–	tryResumeSpare(true); // allow replacement
1243	–	}
1244	–	}
1245	–	} finally {
1246	–	lock.unlock();
1247	–	}
1248	–	signalIdleWorkers();
1249	–	}
1250	–
1251	–	/**
1252	–	* Initiates termination.
1253	–	*/
1254	–	private void terminate() {
1255	–	if (transitionRunStateTo(TERMINATING)) {
1256	–	stopAllWorkers();
1257	–	resumeAllSpares();
1258	–	signalIdleWorkers();
1259	–	cancelQueuedSubmissions();
1260	–	cancelQueuedWorkerTasks();
1261	–	interruptUnterminatedWorkers();
1262	–	signalIdleWorkers(); // resignal after interrupt
1263	–	}
1264	–	}
1265	–
1266	–	/**
1267	–	* Possibly terminates when on shutdown state.
1268	–	*/
1269	–	private void terminateOnShutdown() {
1270	–	if (!hasQueuedSubmissions() && canTerminateOnShutdown(runControl))
1271	–	terminate();
1272	–	}
1273	–
1274	–	/**
1275	–	* Clears out and cancels submissions.
1276	–	*/
1277	–	private void cancelQueuedSubmissions() {
1278	–	ForkJoinTask<?> task;
1279	–	while ((task = pollSubmission()) != null)
1280	–	task.cancel(false);
1281	–	}
1282	–
1283	–	/**
1284	–	* Cleans out worker queues.
1285	–	*/
1286	–	private void cancelQueuedWorkerTasks() {
1287	–	final ReentrantLock lock = this.workerLock;
1288	–	lock.lock();
1289	–	try {
1290	–	ForkJoinWorkerThread[] ws = workers;
1291	–	if (ws != null) {
1292	–	for (int i = 0; i < ws.length; ++i) {
1293	–	ForkJoinWorkerThread t = ws[i];
1294	–	if (t != null)
1295	–	t.cancelTasks();
1296	–	}
1297	–	}
1298	–	} finally {
1299	–	lock.unlock();
1300	–	}
1301	–	}
1302	–
1303	–	/**
1304	–	* Sets each worker's status to terminating. Requires lock to avoid
1305	–	* conflicts with add/remove.
1306	–	*/
1307	–	private void stopAllWorkers() {
1308	–	final ReentrantLock lock = this.workerLock;
1309	–	lock.lock();
1809		try {
1810	<	ForkJoinWorkerThread[] ws = workers;
1811	<	if (ws != null) {
1313	<	for (int i = 0; i < ws.length; ++i) {
1314	<	ForkJoinWorkerThread t = ws[i];
1315	<	if (t != null)
1316	<	t.shutdownNow();
1317	<	}
1318	<	}
1319	<	} finally {
1320	<	lock.unlock();
1321	<	}
1322	<	}
1323	<
1324	<	/**
1325	<	* Interrupts all unterminated workers.  This is not required for
1326	<	* sake of internal control, but may help unstick user code during
1327	<	* shutdown.
1328	<	*/
1329	<	private void interruptUnterminatedWorkers() {
1330	<	final ReentrantLock lock = this.workerLock;
1331	<	lock.lock();
1332	<	try {
1333	<	ForkJoinWorkerThread[] ws = workers;
1334	<	if (ws != null) {
1335	<	for (int i = 0; i < ws.length; ++i) {
1336	<	ForkJoinWorkerThread t = ws[i];
1337	<	if (t != null && !t.isTerminated()) {
1338	<	try {
1339	<	t.interrupt();
1340	<	} catch (SecurityException ignore) {
1341	<	}
1342	<	}
1343	<	}
1344	<	}
1345	<	} finally {
1346	<	lock.unlock();
1347	<	}
1348	<	}
1349	<
1350	<
1351	<	/*
1352	<	* Nodes for event barrier to manage idle threads.  Queue nodes
1353	<	* are basic Treiber stack nodes, also used for spare stack.
1354	<	*
1355	<	* The event barrier has an event count and a wait queue (actually
1356	<	* a Treiber stack).  Workers are enabled to look for work when
1357	<	* the eventCount is incremented. If they fail to find work, they
1358	<	* may wait for next count. Upon release, threads help others wake
1359	<	* up.
1360	<	*
1361	<	* Synchronization events occur only in enough contexts to
1362	<	* maintain overall liveness:
1363	<	*
1364	<	*   - Submission of a new task to the pool
1365	<	*   - Resizes or other changes to the workers array
1366	<	*   - pool termination
1367	<	*   - A worker pushing a task on an empty queue
1368	<	*
1369	<	* The case of pushing a task occurs often enough, and is heavy
1370	<	* enough compared to simple stack pushes, to require special
1371	<	* handling: Method signalWork returns without advancing count if
1372	<	* the queue appears to be empty.  This would ordinarily result in
1373	<	* races causing some queued waiters not to be woken up. To avoid
1374	<	* this, the first worker enqueued in method sync (see
1375	<	* syncIsReleasable) rescans for tasks after being enqueued, and
1376	<	* helps signal if any are found. This works well because the
1377	<	* worker has nothing better to do, and so might as well help
1378	<	* alleviate the overhead and contention on the threads actually
1379	<	* doing work.  Also, since event counts increments on task
1380	<	* availability exist to maintain liveness (rather than to force
1381	<	* refreshes etc), it is OK for callers to exit early if
1382	<	* contending with another signaller.
1383	<	*/
1384	<	static final class WaitQueueNode {
1385	<	WaitQueueNode next; // only written before enqueued
1386	<	volatile ForkJoinWorkerThread thread; // nulled to cancel wait
1387	<	final long count; // unused for spare stack
1388	<
1389	<	WaitQueueNode(long c, ForkJoinWorkerThread w) {
1390	<	count = c;
1391	<	thread = w;
1392	<	}
1393	<
1394	<	/**
1395	<	* Wakes up waiter, returning false if known to already
1396	<	*/
1397	<	boolean signal() {
1398	<	ForkJoinWorkerThread t = thread;
1399	<	if (t == null)
1400	<	return false;
1401	<	thread = null;
1402	<	LockSupport.unpark(t);
1403	<	return true;
1404	<	}
1405	<
1406	<	/**
1407	<	* Awaits release on sync.
1408	<	*/
1409	<	void awaitSyncRelease(ForkJoinPool p) {
1410	<	while (thread != null && !p.syncIsReleasable(this))
1411	<	LockSupport.park(this);
1412	<	}
1413	<
1414	<	/**
1415	<	* Awaits resumption as spare.
1416	<	*/
1417	<	void awaitSpareRelease() {
1418	<	while (thread != null) {
1419	<	if (!Thread.interrupted())
1420	<	LockSupport.park(this);
1421	<	}
1422	<	}
1423	<	}
1424	<
1425	<	/**
1426	<	* Ensures that no thread is waiting for count to advance from the
1427	<	* current value of eventCount read on entry to this method, by
1428	<	* releasing waiting threads if necessary.
1429	<	*
1430	<	* @return the count
1431	<	*/
1432	<	final long ensureSync() {
1433	<	long c = eventCount;
1434	<	WaitQueueNode q;
1435	<	while ((q = syncStack) != null && q.count < c) {
1436	<	if (casBarrierStack(q, null)) {
1437	<	do {
1438	<	q.signal();
1439	<	} while ((q = q.next) != null);
1440	<	break;
1441	<	}
1442	<	}
1443	<	return c;
1444	<	}
1445	<
1446	<	/**
1447	<	* Increments event count and releases waiting threads.
1448	<	*/
1449	<	private void signalIdleWorkers() {
1450	<	long c;
1451	<	do {} while (!casEventCount(c = eventCount, c+1));
1452	<	ensureSync();
1453	<	}
1454	<
1455	<	/**
1456	<	* Signals threads waiting to poll a task. Because method sync
1457	<	* rechecks availability, it is OK to only proceed if queue
1458	<	* appears to be non-empty, and OK to skip under contention to
1459	<	* increment count (since some other thread succeeded).
1460	<	*/
1461	<	final void signalWork() {
1462	<	long c;
1463	<	WaitQueueNode q;
1464	<	if (syncStack != null &&
1465	<	casEventCount(c = eventCount, c+1) &&
1466	<	(((q = syncStack) != null && q.count <= c) &&
1467	<	(!casBarrierStack(q, q.next) || !q.signal())))
1468	<	ensureSync();
1469	<	}
1470	<
1471	<	/**
1472	<	* Waits until event count advances from last value held by
1473	<	* caller, or if excess threads, caller is resumed as spare, or
1474	<	* caller or pool is terminating. Updates caller's event on exit.
1475	<	*
1476	<	* @param w the calling worker thread
1477	<	*/
1478	<	final void sync(ForkJoinWorkerThread w) {
1479	<	updateStealCount(w); // Transfer w's count while it is idle
1480	<
1481	<	while (!w.isShutdown() && isProcessingTasks() && !suspendIfSpare(w)) {
1482	<	long prev = w.lastEventCount;
1483	<	WaitQueueNode node = null;
1484	<	WaitQueueNode h;
1485	<	while (eventCount == prev &&
1486	<	((h = syncStack) == null || h.count == prev)) {
1487	<	if (node == null)
1488	<	node = new WaitQueueNode(prev, w);
1489	<	if (casBarrierStack(node.next = h, node)) {
1490	<	node.awaitSyncRelease(this);
1491	<	break;
1492	<	}
1493	<	}
1494	<	long ec = ensureSync();
1495	<	if (ec != prev) {
1496	<	w.lastEventCount = ec;
1497	<	break;
1498	<	}
1499	<	}
1500	<	}
1501	<
1502	<	/**
1503	<	* Returns {@code true} if worker waiting on sync can proceed:
1504	<	*  - on signal (thread == null)
1505	<	*  - on event count advance (winning race to notify vs signaller)
1506	<	*  - on interrupt
1507	<	*  - if the first queued node, we find work available
1508	<	* If node was not signalled and event count not advanced on exit,
1509	<	* then we also help advance event count.
1510	<	*
1511	<	* @return {@code true} if node can be released
1512	<	*/
1513	<	final boolean syncIsReleasable(WaitQueueNode node) {
1514	<	long prev = node.count;
1515	<	if (!Thread.interrupted() && node.thread != null &&
1516	<	(node.next != null ||
1517	<	!ForkJoinWorkerThread.hasQueuedTasks(workers)) &&
1518	<	eventCount == prev)
1519	<	return false;
1520	<	if (node.thread != null) {
1521	<	node.thread = null;
1522	<	long ec = eventCount;
1523	<	if (prev <= ec) // help signal
1524	<	casEventCount(ec, ec+1);
1525	<	}
1526	<	return true;
1527	<	}
1528	<
1529	<	/**
1530	<	* Returns {@code true} if a new sync event occurred since last
1531	<	* call to sync or this method, if so, updating caller's count.
1532	<	*/
1533	<	final boolean hasNewSyncEvent(ForkJoinWorkerThread w) {
1534	<	long lc = w.lastEventCount;
1535	<	long ec = ensureSync();
1536	<	if (ec == lc)
1810	>	return termination.awaitAdvanceInterruptibly(0, timeout, unit) > 0;
1811	>	} catch(TimeoutException ex) {
1812		return false;
1538	–	w.lastEventCount = ec;
1539	–	return true;
1540	–	}
1541	–
1542	–	//  Parallelism maintenance
1543	–
1544	–	/**
1545	–	* Decrements running count; if too low, adds spare.
1546	–	*
1547	–	* Conceptually, all we need to do here is add or resume a
1548	–	* spare thread when one is about to block (and remove or
1549	–	* suspend it later when unblocked -- see suspendIfSpare).
1550	–	* However, implementing this idea requires coping with
1551	–	* several problems: we have imperfect information about the
1552	–	* states of threads. Some count updates can and usually do
1553	–	* lag run state changes, despite arrangements to keep them
1554	–	* accurate (for example, when possible, updating counts
1555	–	* before signalling or resuming), especially when running on
1556	–	* dynamic JVMs that don't optimize the infrequent paths that
1557	–	* update counts. Generating too many threads can make these
1558	–	* problems become worse, because excess threads are more
1559	–	* likely to be context-switched with others, slowing them all
1560	–	* down, especially if there is no work available, so all are
1561	–	* busy scanning or idling.  Also, excess spare threads can
1562	–	* only be suspended or removed when they are idle, not
1563	–	* immediately when they aren't needed. So adding threads will
1564	–	* raise parallelism level for longer than necessary.  Also,
1565	–	* FJ applications often encounter highly transient peaks when
1566	–	* many threads are blocked joining, but for less time than it
1567	–	* takes to create or resume spares.
1568	–	*
1569	–	* @param joinMe if non-null, return early if done
1570	–	* @param maintainParallelism if true, try to stay within
1571	–	* target counts, else create only to avoid starvation
1572	–	* @return true if joinMe known to be done
1573	–	*/
1574	–	final boolean preJoin(ForkJoinTask<?> joinMe,
1575	–	boolean maintainParallelism) {
1576	–	maintainParallelism &= maintainsParallelism; // overrride
1577	–	boolean dec = false;  // true when running count decremented
1578	–	while (spareStack == null || !tryResumeSpare(dec)) {
1579	–	int counts = workerCounts;
1580	–	if (dec || (dec = casWorkerCounts(counts, --counts))) {
1581	–	// CAS cheat
1582	–	if (!needSpare(counts, maintainParallelism))
1583	–	break;
1584	–	if (joinMe.status < 0)
1585	–	return true;
1586	–	if (tryAddSpare(counts))
1587	–	break;
1588	–	}
1589	–	}
1590	–	return false;
1591	–	}
1592	–
1593	–	/**
1594	–	* Same idea as preJoin
1595	–	*/
1596	–	final boolean preBlock(ManagedBlocker blocker,
1597	–	boolean maintainParallelism) {
1598	–	maintainParallelism &= maintainsParallelism;
1599	–	boolean dec = false;
1600	–	while (spareStack == null || !tryResumeSpare(dec)) {
1601	–	int counts = workerCounts;
1602	–	if (dec || (dec = casWorkerCounts(counts, --counts))) {
1603	–	if (!needSpare(counts, maintainParallelism))
1604	–	break;
1605	–	if (blocker.isReleasable())
1606	–	return true;
1607	–	if (tryAddSpare(counts))
1608	–	break;
1609	–	}
1610	–	}
1611	–	return false;
1612	–	}
1613	–
1614	–	/**
1615	–	* Returns {@code true} if a spare thread appears to be needed.
1616	–	* If maintaining parallelism, returns true when the deficit in
1617	–	* running threads is more than the surplus of total threads, and
1618	–	* there is apparently some work to do.  This self-limiting rule
1619	–	* means that the more threads that have already been added, the
1620	–	* less parallelism we will tolerate before adding another.
1621	–	*
1622	–	* @param counts current worker counts
1623	–	* @param maintainParallelism try to maintain parallelism
1624	–	*/
1625	–	private boolean needSpare(int counts, boolean maintainParallelism) {
1626	–	int ps = parallelism;
1627	–	int rc = runningCountOf(counts);
1628	–	int tc = totalCountOf(counts);
1629	–	int runningDeficit = ps - rc;
1630	–	int totalSurplus = tc - ps;
1631	–	return (tc < maxPoolSize &&
1632	–	(rc == 0 || totalSurplus < 0 ||
1633	–	(maintainParallelism &&
1634	–	runningDeficit > totalSurplus &&
1635	–	ForkJoinWorkerThread.hasQueuedTasks(workers))));
1636	–	}
1637	–
1638	–	/**
1639	–	* Adds a spare worker if lock available and no more than the
1640	–	* expected numbers of threads exist.
1641	–	*
1642	–	* @return true if successful
1643	–	*/
1644	–	private boolean tryAddSpare(int expectedCounts) {
1645	–	final ReentrantLock lock = this.workerLock;
1646	–	int expectedRunning = runningCountOf(expectedCounts);
1647	–	int expectedTotal = totalCountOf(expectedCounts);
1648	–	boolean success = false;
1649	–	boolean locked = false;
1650	–	// confirm counts while locking; CAS after obtaining lock
1651	–	try {
1652	–	for (;;) {
1653	–	int s = workerCounts;
1654	–	int tc = totalCountOf(s);
1655	–	int rc = runningCountOf(s);
1656	–	if (rc > expectedRunning || tc > expectedTotal)
1657	–	break;
1658	–	if (!locked && !(locked = lock.tryLock()))
1659	–	break;
1660	–	if (casWorkerCounts(s, workerCountsFor(tc+1, rc+1))) {
1661	–	createAndStartSpare(tc);
1662	–	success = true;
1663	–	break;
1664	–	}
1665	–	}
1666	–	} finally {
1667	–	if (locked)
1668	–	lock.unlock();
1669	–	}
1670	–	return success;
1671	–	}
1672	–
1673	–	/**
1674	–	* Adds the kth spare worker. On entry, pool counts are already
1675	–	* adjusted to reflect addition.
1676	–	*/
1677	–	private void createAndStartSpare(int k) {
1678	–	ForkJoinWorkerThread w = null;
1679	–	ForkJoinWorkerThread[] ws = ensureWorkerArrayCapacity(k + 1);
1680	–	int len = ws.length;
1681	–	// Probably, we can place at slot k. If not, find empty slot
1682	–	if (k < len && ws[k] != null) {
1683	–	for (k = 0; k < len && ws[k] != null; ++k)
1684	–	;
1685	–	}
1686	–	if (k < len && isProcessingTasks() && (w = createWorker(k)) != null) {
1687	–	ws[k] = w;
1688	–	w.start();
1689	–	}
1690	–	else
1691	–	updateWorkerCount(-1); // adjust on failure
1692	–	signalIdleWorkers();
1693	–	}
1694	–
1695	–	/**
1696	–	* Suspends calling thread w if there are excess threads.  Called
1697	–	* only from sync.  Spares are enqueued in a Treiber stack using
1698	–	* the same WaitQueueNodes as barriers.  They are resumed mainly
1699	–	* in preJoin, but are also woken on pool events that require all
1700	–	* threads to check run state.
1701	–	*
1702	–	* @param w the caller
1703	–	*/
1704	–	private boolean suspendIfSpare(ForkJoinWorkerThread w) {
1705	–	WaitQueueNode node = null;
1706	–	int s;
1707	–	while (parallelism < runningCountOf(s = workerCounts)) {
1708	–	if (node == null)
1709	–	node = new WaitQueueNode(0, w);
1710	–	if (casWorkerCounts(s, s-1)) { // representation-dependent
1711	–	// push onto stack
1712	–	do {} while (!casSpareStack(node.next = spareStack, node));
1713	–	// block until released by resumeSpare
1714	–	node.awaitSpareRelease();
1715	–	return true;
1716	–	}
1717	–	}
1718	–	return false;
1719	–	}
1720	–
1721	–	/**
1722	–	* Tries to pop and resume a spare thread.
1723	–	*
1724	–	* @param updateCount if true, increment running count on success
1725	–	* @return true if successful
1726	–	*/
1727	–	private boolean tryResumeSpare(boolean updateCount) {
1728	–	WaitQueueNode q;
1729	–	while ((q = spareStack) != null) {
1730	–	if (casSpareStack(q, q.next)) {
1731	–	if (updateCount)
1732	–	updateRunningCount(1);
1733	–	q.signal();
1734	–	return true;
1735	–	}
1736	–	}
1737	–	return false;
1738	–	}
1739	–
1740	–	/**
1741	–	* Pops and resumes all spare threads. Same idea as ensureSync.
1742	–	*
1743	–	* @return true if any spares released
1744	–	*/
1745	–	private boolean resumeAllSpares() {
1746	–	WaitQueueNode q;
1747	–	while ( (q = spareStack) != null) {
1748	–	if (casSpareStack(q, null)) {
1749	–	do {
1750	–	updateRunningCount(1);
1751	–	q.signal();
1752	–	} while ((q = q.next) != null);
1753	–	return true;
1754	–	}
1755	–	}
1756	–	return false;
1757	–	}
1758	–
1759	–	/**
1760	–	* Pops and shuts down excessive spare threads. Call only while
1761	–	* holding lock. This is not guaranteed to eliminate all excess
1762	–	* threads, only those suspended as spares, which are the ones
1763	–	* unlikely to be needed in the future.
1764	–	*/
1765	–	private void trimSpares() {
1766	–	int surplus = totalCountOf(workerCounts) - parallelism;
1767	–	WaitQueueNode q;
1768	–	while (surplus > 0 && (q = spareStack) != null) {
1769	–	if (casSpareStack(q, null)) {
1770	–	do {
1771	–	updateRunningCount(1);
1772	–	ForkJoinWorkerThread w = q.thread;
1773	–	if (w != null && surplus > 0 &&
1774	–	runningCountOf(workerCounts) > 0 && w.shutdown())
1775	–	--surplus;
1776	–	q.signal();
1777	–	} while ((q = q.next) != null);
1778	–	}
1813		}
1814		}
1815
#	Line 1783 | Line 1817 | public class ForkJoinPool extends Abstra
1817		* Interface for extending managed parallelism for tasks running
1818		* in {@link ForkJoinPool}s.
1819		*
1820	<	* <p>A {@code ManagedBlocker} provides two methods.
1821	<	* Method {@code isReleasable} must return {@code true} if
1822	<	* blocking is not necessary. Method {@code block} blocks the
1823	<	* current thread if necessary (perhaps internally invoking
1824	<	* {@code isReleasable} before actually blocking).
1820	>	* <p>A {@code ManagedBlocker} provides two methods.  Method
1821	>	* {@code isReleasable} must return {@code true} if blocking is
1822	>	* not necessary. Method {@code block} blocks the current thread
1823	>	* if necessary (perhaps internally invoking {@code isReleasable}
1824	>	* before actually blocking). The unusual methods in this API
1825	>	* accommodate synchronizers that may, but don't usually, block
1826	>	* for long periods. Similarly, they allow more efficient internal
1827	>	* handling of cases in which additional workers may be, but
1828	>	* usually are not, needed to ensure sufficient parallelism.
1829	>	* Toward this end, implementations of method {@code isReleasable}
1830	>	* must be amenable to repeated invocation.
1831		*
1832		* <p>For example, here is a ManagedBlocker based on a
1833		* ReentrantLock:
#	Line 1805 | Line 1845 | public class ForkJoinPool extends Abstra
1845		*     return hasLock || (hasLock = lock.tryLock());
1846		*   }
1847		* }}</pre>
1848	+	*
1849	+	* <p>Here is a class that possibly blocks waiting for an
1850	+	* item on a given queue:
1851	+	*  <pre> {@code
1852	+	* class QueueTaker<E> implements ManagedBlocker {
1853	+	*   final BlockingQueue<E> queue;
1854	+	*   volatile E item = null;
1855	+	*   QueueTaker(BlockingQueue<E> q) { this.queue = q; }
1856	+	*   public boolean block() throws InterruptedException {
1857	+	*     if (item == null)
1858	+	*       item = queue.take();
1859	+	*     return true;
1860	+	*   }
1861	+	*   public boolean isReleasable() {
1862	+	*     return item != null || (item = queue.poll()) != null;
1863	+	*   }
1864	+	*   public E getItem() { // call after pool.managedBlock completes
1865	+	*     return item;
1866	+	*   }
1867	+	* }}</pre>
1868		*/
1869		public static interface ManagedBlocker {
1870		/**
#	Line 1828 | Line 1888 | public class ForkJoinPool extends Abstra
1888		* Blocks in accord with the given blocker.  If the current thread
1889		* is a {@link ForkJoinWorkerThread}, this method possibly
1890		* arranges for a spare thread to be activated if necessary to
1891	<	* ensure parallelism while the current thread is blocked.
1832	<	*
1833	<	* <p>If {@code maintainParallelism} is {@code true} and the pool
1834	<	* supports it ({@link #getMaintainsParallelism}), this method
1835	<	* attempts to maintain the pool's nominal parallelism. Otherwise
1836	<	* it activates a thread only if necessary to avoid complete
1837	<	* starvation. This option may be preferable when blockages use
1838	<	* timeouts, or are almost always brief.
1891	>	* ensure sufficient parallelism while the current thread is blocked.
1892		*
1893		* <p>If the caller is not a {@link ForkJoinTask}, this method is
1894		* behaviorally equivalent to
#	Line 1849 | Line 1902 | public class ForkJoinPool extends Abstra
1902		* first be expanded to ensure parallelism, and later adjusted.
1903		*
1904		* @param blocker the blocker
1852	–	* @param maintainParallelism if {@code true} and supported by
1853	–	* this pool, attempt to maintain the pool's nominal parallelism;
1854	–	* otherwise activate a thread only if necessary to avoid
1855	–	* complete starvation.
1905		* @throws InterruptedException if blocker.block did so
1906		*/
1907	<	public static void managedBlock(ManagedBlocker blocker,
1859	<	boolean maintainParallelism)
1907	>	public static void managedBlock(ManagedBlocker blocker)
1908		throws InterruptedException {
1909		Thread t = Thread.currentThread();
1910	<	ForkJoinPool pool = ((t instanceof ForkJoinWorkerThread) ?
1911	<	((ForkJoinWorkerThread) t).pool : null);
1912	<	if (!blocker.isReleasable()) {
1913	<	try {
1914	<	if (pool == null ||
1915	<	!pool.preBlock(blocker, maintainParallelism))
1868	<	awaitBlocker(blocker);
1869	<	} finally {
1870	<	if (pool != null)
1871	<	pool.updateRunningCount(1);
1872	<	}
1910	>	if (t instanceof ForkJoinWorkerThread) {
1911	>	ForkJoinWorkerThread w = (ForkJoinWorkerThread) t;
1912	>	w.pool.awaitBlocker(blocker);
1913	>	}
1914	>	else {
1915	>	do {} while (!blocker.isReleasable() && !blocker.block());
1916		}
1874	–	}
1875	–
1876	–	private static void awaitBlocker(ManagedBlocker blocker)
1877	–	throws InterruptedException {
1878	–	do {} while (!blocker.isReleasable() && !blocker.block());
1917		}
1918
1919		// AbstractExecutorService overrides.  These rely on undocumented
#	Line 1893 | Line 1931 | public class ForkJoinPool extends Abstra
1931		// Unsafe mechanics
1932
1933		private static final sun.misc.Unsafe UNSAFE = getUnsafe();
1896	–	private static final long eventCountOffset =
1897	–	objectFieldOffset("eventCount", ForkJoinPool.class);
1934		private static final long workerCountsOffset =
1935		objectFieldOffset("workerCounts", ForkJoinPool.class);
1936	<	private static final long runControlOffset =
1937	<	objectFieldOffset("runControl", ForkJoinPool.class);
1938	<	private static final long syncStackOffset =
1939	<	objectFieldOffset("syncStack",ForkJoinPool.class);
1940	<	private static final long spareStackOffset =
1941	<	objectFieldOffset("spareStack", ForkJoinPool.class);
1942	<
1943	<	private boolean casEventCount(long cmp, long val) {
1944	<	return UNSAFE.compareAndSwapLong(this, eventCountOffset, cmp, val);
1945	<	}
1910	<	private boolean casWorkerCounts(int cmp, int val) {
1911	<	return UNSAFE.compareAndSwapInt(this, workerCountsOffset, cmp, val);
1912	<	}
1913	<	private boolean casRunControl(int cmp, int val) {
1914	<	return UNSAFE.compareAndSwapInt(this, runControlOffset, cmp, val);
1915	<	}
1916	<	private boolean casSpareStack(WaitQueueNode cmp, WaitQueueNode val) {
1917	<	return UNSAFE.compareAndSwapObject(this, spareStackOffset, cmp, val);
1918	<	}
1919	<	private boolean casBarrierStack(WaitQueueNode cmp, WaitQueueNode val) {
1920	<	return UNSAFE.compareAndSwapObject(this, syncStackOffset, cmp, val);
1921	<	}
1936	>	private static final long runStateOffset =
1937	>	objectFieldOffset("runState", ForkJoinPool.class);
1938	>	private static final long eventCountOffset =
1939	>	objectFieldOffset("eventCount", ForkJoinPool.class);
1940	>	private static final long eventWaitersOffset =
1941	>	objectFieldOffset("eventWaiters",ForkJoinPool.class);
1942	>	private static final long stealCountOffset =
1943	>	objectFieldOffset("stealCount",ForkJoinPool.class);
1944	>	private static final long spareWaitersOffset =
1945	>	objectFieldOffset("spareWaiters",ForkJoinPool.class);
1946
1947		private static long objectFieldOffset(String field, Class<?> klazz) {
1948		try {

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