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Comparing jsr166/src/jsr166y/Phaser.java (file contents):
Revision 1.8 by jsr166, Mon Jan 5 05:50:47 2009 UTC vs.
Revision 1.63 by dl, Mon Nov 29 15:47:19 2010 UTC

#	Line 5 | Line 5
5		*/
6
7		package jsr166y;
8	<	import java.util.concurrent.*;
9	<	import java.util.concurrent.atomic.*;
8	>
9	>	import java.util.concurrent.TimeUnit;
10	>	import java.util.concurrent.TimeoutException;
11	>	import java.util.concurrent.atomic.AtomicReference;
12		import java.util.concurrent.locks.LockSupport;
11	–	import sun.misc.Unsafe;
12	–	import java.lang.reflect.*;
13
14		/**
15	<	* A reusable synchronization barrier, similar in functionality to a
16	<	* {@link java.util.concurrent.CyclicBarrier} and {@link
17	<	* java.util.concurrent.CountDownLatch} but supporting more flexible
18	<	* usage.
15	>	* A reusable synchronization barrier, similar in functionality to
16	>	* {@link java.util.concurrent.CyclicBarrier CyclicBarrier} and
17	>	* {@link java.util.concurrent.CountDownLatch CountDownLatch}
18	>	* but supporting more flexible usage.
19	>	*
20	>	* <p> <b>Registration.</b> Unlike the case for other barriers, the
21	>	* number of parties <em>registered</em> to synchronize on a phaser
22	>	* may vary over time.  Tasks may be registered at any time (using
23	>	* methods {@link #register}, {@link #bulkRegister}, or forms of
24	>	* constructors establishing initial numbers of parties), and
25	>	* optionally deregistered upon any arrival (using {@link
26	>	* #arriveAndDeregister}).  As is the case with most basic
27	>	* synchronization constructs, registration and deregistration affect
28	>	* only internal counts; they do not establish any further internal
29	>	* bookkeeping, so tasks cannot query whether they are registered.
30	>	* (However, you can introduce such bookkeeping by subclassing this
31	>	* class.)
32	>	*
33	>	* <p> <b>Synchronization.</b> Like a {@code CyclicBarrier}, a {@code
34	>	* Phaser} may be repeatedly awaited.  Method {@link
35	>	* #arriveAndAwaitAdvance} has effect analogous to {@link
36	>	* java.util.concurrent.CyclicBarrier#await CyclicBarrier.await}. Each
37	>	* generation of a phaser has an associated phase number. The phase
38	>	* number starts at zero, and advances when all parties arrive at the
39	>	* phaser, wrapping around to zero after reaching {@code
40	>	* Integer.MAX_VALUE}. The use of phase numbers enables independent
41	>	* control of actions upon arrival at a phaser and upon awaiting
42	>	* others, via two kinds of methods that may be invoked by any
43	>	* registered party:
44		*
45		* <ul>
46		*
47	<	* <li> The number of parties synchronizing on a phaser may vary over
48	<	* time.  A task may register to be a party at any time, and may
49	<	* deregister upon arriving at the barrier.  As is the case with most
50	<	* basic synchronization constructs, registration and deregistration
51	<	* affect only internal counts; they do not establish any further
52	<	* internal bookkeeping, so tasks cannot query whether they are
53	<	* registered. (However, you can introduce such bookkeeping in by
54	<	* subclassing this class.)
55	<	*
56	<	* <li> Each generation has an associated phase value, starting at
57	<	* zero, and advancing when all parties reach the barrier (wrapping
58	<	* around to zero after reaching {@code Integer.MAX_VALUE}).
59	<	*
60	<	* <li> Like a CyclicBarrier, a Phaser may be repeatedly awaited.
61	<	* Method {@code arriveAndAwaitAdvance} has effect analogous to
62	<	* {@code CyclicBarrier.await}.  However, Phasers separate two
63	<	* aspects of coordination, that may also be invoked independently:
64	<	*
65	<	* <ul>
47	>	*   <li> <b>Arrival.</b> Methods {@link #arrive} and
48	>	*       {@link #arriveAndDeregister} record arrival.  These methods
49	>	*       do not block, but return an associated <em>arrival phase
50	>	*       number</em>; that is, the phase number of the phaser to which
51	>	*       the arrival applied. When the final party for a given phase
52	>	*       arrives, an optional action is performed and the phase
53	>	*       advances.  These actions are performed by the party
54	>	*       triggering a phase advance, and are arranged by overriding
55	>	*       method {@link #onAdvance(int, int)}, which also controls
56	>	*       termination. Overriding this method is similar to, but more
57	>	*       flexible than, providing a barrier action to a {@code
58	>	*       CyclicBarrier}.
59	>	*
60	>	*   <li> <b>Waiting.</b> Method {@link #awaitAdvance} requires an
61	>	*       argument indicating an arrival phase number, and returns when
62	>	*       the phaser advances to (or is already at) a different phase.
63	>	*       Unlike similar constructions using {@code CyclicBarrier},
64	>	*       method {@code awaitAdvance} continues to wait even if the
65	>	*       waiting thread is interrupted. Interruptible and timeout
66	>	*       versions are also available, but exceptions encountered while
67	>	*       tasks wait interruptibly or with timeout do not change the
68	>	*       state of the phaser. If necessary, you can perform any
69	>	*       associated recovery within handlers of those exceptions,
70	>	*       often after invoking {@code forceTermination}.  Phasers may
71	>	*       also be used by tasks executing in a {@link ForkJoinPool},
72	>	*       which will ensure sufficient parallelism to execute tasks
73	>	*       when others are blocked waiting for a phase to advance.
74		*
42	–	*   <li> Arriving at a barrier. Methods {@code arrive} and
43	–	*       {@code arriveAndDeregister} do not block, but return
44	–	*       the phase value current upon entry to the method.
45	–	*
46	–	*   <li> Awaiting others. Method {@code awaitAdvance} requires an
47	–	*       argument indicating the entry phase, and returns when the
48	–	*       barrier advances to a new phase.
75		* </ul>
76		*
77	<	*
78	<	* <li> Barrier actions, performed by the task triggering a phase
79	<	* advance while others may be waiting, are arranged by overriding
80	<	* method {@code onAdvance}, that also controls termination.
81	<	* Overriding this method may be used to similar but more flexible
82	<	* effect as providing a barrier action to a CyclicBarrier.
83	<	*
84	<	* <li> Phasers may enter a <em>termination</em> state in which all
85	<	* await actions immediately return, indicating (via a negative phase
86	<	* value) that execution is complete.  Termination is triggered by
87	<	* executing the overridable {@code onAdvance} method that is invoked
88	<	* each time the barrier is about to be tripped. When a Phaser is
89	<	* controlling an action with a fixed number of iterations, it is
90	<	* often convenient to override this method to cause termination when
91	<	* the current phase number reaches a threshold. Method
92	<	* {@code forceTermination} is also available to abruptly release
93	<	* waiting threads and allow them to terminate.
94	<	*
95	<	* <li> Phasers may be tiered to reduce contention. Phasers with large
96	<	* numbers of parties that would otherwise experience heavy
97	<	* synchronization contention costs may instead be arranged in trees.
98	<	* This will typically greatly increase throughput even though it
99	<	* incurs somewhat greater per-operation overhead.
100	<	*
101	<	* <li> By default, {@code awaitAdvance} continues to wait even if
102	<	* the waiting thread is interrupted. And unlike the case in
103	<	* CyclicBarriers, exceptions encountered while tasks wait
104	<	* interruptibly or with timeout do not change the state of the
105	<	* barrier. If necessary, you can perform any associated recovery
106	<	* within handlers of those exceptions, often after invoking
107	<	* {@code forceTermination}.
108	<	*
109	<	* </ul>
77	>	* <p> <b>Termination.</b> A phaser may enter a <em>termination</em>
78	>	* state in which all synchronization methods immediately return
79	>	* without updating phaser state or waiting for advance, and
80	>	* indicating (via a negative phase value) that execution is complete.
81	>	* Termination is triggered when an invocation of {@code onAdvance}
82	>	* returns {@code true}. The default implementation returns {@code
83	>	* true} if a deregistration has caused the number of registered
84	>	* parties to become zero.  As illustrated below, when phasers control
85	>	* actions with a fixed number of iterations, it is often convenient
86	>	* to override this method to cause termination when the current phase
87	>	* number reaches a threshold. Method {@link #forceTermination} is
88	>	* also available to abruptly release waiting threads and allow them
89	>	* to terminate.
90	>	*
91	>	* <p> <b>Tiering.</b> Phasers may be <em>tiered</em> (i.e.,
92	>	* constructed in tree structures) to reduce contention. Phasers with
93	>	* large numbers of parties that would otherwise experience heavy
94	>	* synchronization contention costs may instead be set up so that
95	>	* groups of sub-phasers share a common parent.  This may greatly
96	>	* increase throughput even though it incurs greater per-operation
97	>	* overhead.
98	>	*
99	>	* <p><b>Monitoring.</b> While synchronization methods may be invoked
100	>	* only by registered parties, the current state of a phaser may be
101	>	* monitored by any caller.  At any given moment there are {@link
102	>	* #getRegisteredParties} parties in total, of which {@link
103	>	* #getArrivedParties} have arrived at the current phase ({@link
104	>	* #getPhase}).  When the remaining ({@link #getUnarrivedParties})
105	>	* parties arrive, the phase advances.  The values returned by these
106	>	* methods may reflect transient states and so are not in general
107	>	* useful for synchronization control.  Method {@link #toString}
108	>	* returns snapshots of these state queries in a form convenient for
109	>	* informal monitoring.
110		*
111		* <p><b>Sample usages:</b>
112		*
113	<	* <p>A Phaser may be used instead of a {@code CountDownLatch} to control
114	<	* a one-shot action serving a variable number of parties. The typical
115	<	* idiom is for the method setting this up to first register, then
116	<	* start the actions, then deregister, as in:
117	<	*
118	<	* <pre>
119	<	*  void runTasks(List&lt;Runnable&gt; list) {
120	<	*    final Phaser phaser = new Phaser(1); // "1" to register self
121	<	*    for (Runnable r : list) {
122	<	*      phaser.register();
123	<	*      new Thread() {
124	<	*        public void run() {
125	<	*          phaser.arriveAndAwaitAdvance(); // await all creation
126	<	*          r.run();
127	<	*          phaser.arriveAndDeregister();   // signal completion
128	<	*        }
129	<	*      }.start();
113	>	* <p>A {@code Phaser} may be used instead of a {@code CountDownLatch}
114	>	* to control a one-shot action serving a variable number of parties.
115	>	* The typical idiom is for the method setting this up to first
116	>	* register, then start the actions, then deregister, as in:
117	>	*
118	>	*  <pre> {@code
119	>	* void runTasks(List<Runnable> tasks) {
120	>	*   final Phaser phaser = new Phaser(1); // "1" to register self
121	>	*   // create and start threads
122	>	*   for (Runnable task : tasks) {
123	>	*     phaser.register();
124	>	*     new Thread() {
125	>	*       public void run() {
126	>	*         phaser.arriveAndAwaitAdvance(); // await all creation
127	>	*         task.run();
128	>	*       }
129	>	*     }.start();
130		*   }
131		*
132	<	*   doSomethingOnBehalfOfWorkers();
133	<	*   phaser.arrive(); // allow threads to start
134	<	*   int p = phaser.arriveAndDeregister(); // deregister self  ...
109	<	*   p = phaser.awaitAdvance(p); // ... and await arrival
110	<	*   otherActions(); // do other things while tasks execute
111	<	*   phaser.awaitAdvance(p); // await final completion
112	<	* }
113	<	* </pre>
132	>	*   // allow threads to start and deregister self
133	>	*   phaser.arriveAndDeregister();
134	>	* }}</pre>
135		*
136		* <p>One way to cause a set of threads to repeatedly perform actions
137		* for a given number of iterations is to override {@code onAdvance}:
138		*
139	<	* <pre>
140	<	*  void startTasks(List&lt;Runnable&gt; list, final int iterations) {
141	<	*    final Phaser phaser = new Phaser() {
142	<	*       public boolean onAdvance(int phase, int registeredParties) {
143	<	*         return phase &gt;= iterations || registeredParties == 0;
139	>	*  <pre> {@code
140	>	* void startTasks(List<Runnable> tasks, final int iterations) {
141	>	*   final Phaser phaser = new Phaser() {
142	>	*     protected boolean onAdvance(int phase, int registeredParties) {
143	>	*       return phase >= iterations || registeredParties == 0;
144	>	*     }
145	>	*   };
146	>	*   phaser.register();
147	>	*   for (final Runnable task : tasks) {
148	>	*     phaser.register();
149	>	*     new Thread() {
150	>	*       public void run() {
151	>	*         do {
152	>	*           task.run();
153	>	*           phaser.arriveAndAwaitAdvance();
154	>	*         } while (!phaser.isTerminated());
155		*       }
156	<	*    };
125	<	*    phaser.register();
126	<	*    for (Runnable r : list) {
127	<	*      phaser.register();
128	<	*      new Thread() {
129	<	*        public void run() {
130	<	*           do {
131	<	*             r.run();
132	<	*             phaser.arriveAndAwaitAdvance();
133	<	*           } while(!phaser.isTerminated();
134	<	*        }
135	<	*      }.start();
156	>	*     }.start();
157		*   }
158		*   phaser.arriveAndDeregister(); // deregister self, don't wait
159	<	* }
160	<	* </pre>
159	>	* }}</pre>
160	>	*
161	>	* If the main task must later await termination, it
162	>	* may re-register and then execute a similar loop:
163	>	*  <pre> {@code
164	>	*   // ...
165	>	*   phaser.register();
166	>	*   while (!phaser.isTerminated())
167	>	*     phaser.arriveAndAwaitAdvance();}</pre>
168	>	*
169	>	* <p>Related constructions may be used to await particular phase numbers
170	>	* in contexts where you are sure that the phase will never wrap around
171	>	* {@code Integer.MAX_VALUE}. For example:
172	>	*
173	>	*  <pre> {@code
174	>	* void awaitPhase(Phaser phaser, int phase) {
175	>	*   int p = phaser.register(); // assumes caller not already registered
176	>	*   while (p < phase) {
177	>	*     if (phaser.isTerminated())
178	>	*       // ... deal with unexpected termination
179	>	*     else
180	>	*       p = phaser.arriveAndAwaitAdvance();
181	>	*   }
182	>	*   phaser.arriveAndDeregister();
183	>	* }}</pre>
184	>	*
185		*
186	<	* <p> To create a set of tasks using a tree of Phasers,
186	>	* <p>To create a set of tasks using a tree of phasers,
187		* you could use code of the following form, assuming a
188	<	* Task class with a constructor accepting a Phaser that
189	<	* it registers for upon construction:
190	<	* <pre>
191	<	*  void build(Task[] actions, int lo, int hi, Phaser b) {
192	<	*    int step = (hi - lo) / TASKS_PER_PHASER;
193	<	*    if (step &gt; 1) {
194	<	*       int i = lo;
195	<	*       while (i &lt; hi) {
196	<	*         int r = Math.min(i + step, hi);
197	<	*         build(actions, i, r, new Phaser(b));
198	<	*         i = r;
199	<	*       }
200	<	*    }
201	<	*    else {
202	<	*      for (int i = lo; i &lt; hi; ++i)
203	<	*        actions[i] = new Task(b);
204	<	*        // assumes new Task(b) performs b.register()
205	<	*    }
161	<	*  }
162	<	*  // .. initially called, for n tasks via
163	<	*  build(new Task[n], 0, n, new Phaser());
164	<	* </pre>
188	>	* Task class with a constructor accepting a {@code Phaser} that
189	>	* it registers with upon construction:
190	>	*
191	>	*  <pre> {@code
192	>	* void build(Task[] actions, int lo, int hi, Phaser ph) {
193	>	*   if (hi - lo > TASKS_PER_PHASER) {
194	>	*     for (int i = lo; i < hi; i += TASKS_PER_PHASER) {
195	>	*       int j = Math.min(i + TASKS_PER_PHASER, hi);
196	>	*       build(actions, i, j, new Phaser(ph));
197	>	*     }
198	>	*   } else {
199	>	*     for (int i = lo; i < hi; ++i)
200	>	*       actions[i] = new Task(ph);
201	>	*       // assumes new Task(ph) performs ph.register()
202	>	*   }
203	>	* }
204	>	* // .. initially called, for n tasks via
205	>	* build(new Task[n], 0, n, new Phaser());}</pre>
206		*
207		* The best value of {@code TASKS_PER_PHASER} depends mainly on
208	<	* expected barrier synchronization rates. A value as low as four may
209	<	* be appropriate for extremely small per-barrier task bodies (thus
208	>	* expected synchronization rates. A value as low as four may
209	>	* be appropriate for extremely small per-phase task bodies (thus
210		* high rates), or up to hundreds for extremely large ones.
211		*
171	–	* </pre>
172	–	*
212		* <p><b>Implementation notes</b>: This implementation restricts the
213		* maximum number of parties to 65535. Attempts to register additional
214	<	* parties result in IllegalStateExceptions. However, you can and
214	>	* parties result in {@code IllegalStateException}. However, you can and
215		* should create tiered phasers to accommodate arbitrarily large sets
216		* of participants.
217	+	*
218	+	* @since 1.7
219	+	* @author Doug Lea
220		*/
221		public class Phaser {
222		/*
#	Line 184 | Line 226 | public class Phaser {
226		*/
227
228		/**
229	<	* Barrier state representation. Conceptually, a barrier contains
188	<	* four values:
229	>	* Primary state representation, holding four fields:
230		*
231	<	* * parties -- the number of parties to wait (16 bits)
232	<	* * unarrived -- the number of parties yet to hit barrier (16 bits)
233	<	* * phase -- the generation of the barrier (31 bits)
234	<	* * terminated -- set if barrier is terminated (1 bit)
231	>	* * unarrived -- the number of parties yet to hit barrier (bits  0-15)
232	>	* * parties -- the number of parties to wait              (bits 16-31)
233	>	* * phase -- the generation of the barrier                (bits 32-62)
234	>	* * terminated -- set if barrier is terminated            (bit  63 / sign)
235		*
236		* However, to efficiently maintain atomicity, these values are
237		* packed into a single (atomic) long. Termination uses the sign
238		* bit of 32 bit representation of phase, so phase is set to -1 on
239		* termination. Good performance relies on keeping state decoding
240		* and encoding simple, and keeping race windows short.
200	–	*
201	–	* Note: there are some cheats in arrive() that rely on unarrived
202	–	* being lowest 16 bits.
241		*/
242		private volatile long state;
243
244	<	private static final int ushortBits = 16;
245	<	private static final int ushortMask =  (1 << ushortBits) - 1;
246	<	private static final int phaseMask = 0x7fffffff;
244	>	private static final int  MAX_PARTIES     = 0xffff;
245	>	private static final int  MAX_PHASE       = 0x7fffffff;
246	>	private static final int  PARTIES_SHIFT   = 16;
247	>	private static final int  PHASE_SHIFT     = 32;
248	>	private static final int  UNARRIVED_MASK  = 0xffff;      // to mask ints
249	>	private static final long PARTIES_MASK    = 0xffff0000L; // to mask longs
250	>	private static final long ONE_ARRIVAL     = 1L;
251	>	private static final long ONE_PARTY       = 1L << PARTIES_SHIFT;
252	>	private static final long TERMINATION_BIT = 1L << 63;
253	>
254	>	// The following unpacking methods are usually manually inlined
255
256		private static int unarrivedOf(long s) {
257	<	return (int)(s & ushortMask);
257	>	return (int)s & UNARRIVED_MASK;
258		}
259
260		private static int partiesOf(long s) {
261	<	return (int)(s & (ushortMask << 16)) >>> 16;
261	>	return (int)s >>> PARTIES_SHIFT;
262		}
263
264		private static int phaseOf(long s) {
265	<	return (int)(s >>> 32);
265	>	return (int) (s >>> PHASE_SHIFT);
266		}
267
268		private static int arrivedOf(long s) {
269		return partiesOf(s) - unarrivedOf(s);
270		}
271
226	–	private static long stateFor(int phase, int parties, int unarrived) {
227	–	return (((long)phase) << 32) | ((parties << 16) | unarrived);
228	–	}
229	–
230	–	private static long trippedStateFor(int phase, int parties) {
231	–	return (((long)phase) << 32) | ((parties << 16) | parties);
232	–	}
233	–
234	–	private static IllegalStateException badBounds(int parties, int unarrived) {
235	–	return new IllegalStateException
236	–	("Attempt to set " + unarrived +
237	–	" unarrived of " + parties + " parties");
238	–	}
239	–
272		/**
273		* The parent of this phaser, or null if none
274		*/
275		private final Phaser parent;
276
277		/**
278	<	* The root of Phaser tree. Equals this if not in a tree.  Used to
278	>	* The root of phaser tree. Equals this if not in a tree.  Used to
279		* support faster state push-down.
280		*/
281		private final Phaser root;
282
251	–	// Wait queues
252	–
283		/**
284	<	* Heads of Treiber stacks waiting for nonFJ threads. To eliminate
285	<	* contention while releasing some threads while adding others, we
284	>	* Heads of Treiber stacks for waiting threads. To eliminate
285	>	* contention when releasing some threads while adding others, we
286		* use two of them, alternating across even and odd phases.
287	+	* Subphasers share queues with root to speed up releases.
288		*/
289	<	private final AtomicReference<QNode> evenQ = new AtomicReference<QNode>();
290	<	private final AtomicReference<QNode> oddQ  = new AtomicReference<QNode>();
289	>	private final AtomicReference<QNode> evenQ;
290	>	private final AtomicReference<QNode> oddQ;
291
292		private AtomicReference<QNode> queueFor(int phase) {
293	<	return (phase & 1) == 0? evenQ : oddQ;
293	>	return ((phase & 1) == 0) ? evenQ : oddQ;
294		}
295
296		/**
297	<	* Returns current state, first resolving lagged propagation from
267	<	* root if necessary.
297	>	* Returns message string for bounds exceptions on arrival.
298		*/
299	<	private long getReconciledState() {
300	<	return parent == null? state : reconcileState();
299	>	private String badArrive(long s) {
300	>	return "Attempted arrival of unregistered party for " +
301	>	stateToString(s);
302		}
303
304		/**
305	<	* Recursively resolves state.
305	>	* Returns message string for bounds exceptions on registration.
306		*/
307	<	private long reconcileState() {
308	<	Phaser p = parent;
309	<	long s = state;
310	<	if (p != null) {
311	<	while (unarrivedOf(s) == 0 && phaseOf(s) != phaseOf(root.state)) {
312	<	long parentState = p.getReconciledState();
313	<	int parentPhase = phaseOf(parentState);
314	<	int phase = phaseOf(s = state);
315	<	if (phase != parentPhase) {
316	<	long next = trippedStateFor(parentPhase, partiesOf(s));
317	<	if (casState(s, next)) {
307	>	private String badRegister(long s) {
308	>	return "Attempt to register more than " +
309	>	MAX_PARTIES + " parties for " + stateToString(s);
310	>	}
311	>
312	>	/**
313	>	* Main implementation for methods arrive and arriveAndDeregister.
314	>	* Manually tuned to speed up and minimize race windows for the
315	>	* common case of just decrementing unarrived field.
316	>	*
317	>	* @param adj - adjustment to apply to state -- either
318	>	* ONE_ARRIVAL (for arrive) or
319	>	* ONE_ARRIVAL|ONE_PARTY (for arriveAndDeregister)
320	>	*/
321	>	private int doArrive(long adj) {
322	>	for (;;) {
323	>	long s = state;
324	>	int unarrived = (int)s & UNARRIVED_MASK;
325	>	int phase = (int)(s >>> PHASE_SHIFT);
326	>	if (phase < 0)
327	>	return phase;
328	>	else if (unarrived == 0) {
329	>	if (reconcileState() == s)     // recheck
330	>	throw new IllegalStateException(badArrive(s));
331	>	}
332	>	else if (UNSAFE.compareAndSwapLong(this, stateOffset, s, s-=adj)) {
333	>	if (unarrived == 1) {
334	>	long p = s & PARTIES_MASK; // unshifted parties field
335	>	long lu = p >>> PARTIES_SHIFT;
336	>	int u = (int)lu;
337	>	int nextPhase = (phase + 1) & MAX_PHASE;
338	>	long next = ((long)nextPhase << PHASE_SHIFT) | p | lu;
339	>	final Phaser parent = this.parent;
340	>	if (parent == null) {
341	>	if (onAdvance(phase, u))
342	>	next |= TERMINATION_BIT;
343	>	UNSAFE.compareAndSwapLong(this, stateOffset, s, next);
344		releaseWaiters(phase);
345	<	s = next;
345	>	}
346	>	else {
347	>	parent.doArrive((u == 0) ?
348	>	ONE_ARRIVAL|ONE_PARTY : ONE_ARRIVAL);
349	>	if ((int)(parent.state >>> PHASE_SHIFT) != nextPhase)
350	>	reconcileState();
351	>	else if (state == s)
352	>	UNSAFE.compareAndSwapLong(this, stateOffset, s,
353	>	next);
354		}
355		}
356	+	return phase;
357	+	}
358	+	}
359	+	}
360	+
361	+	/**
362	+	* Implementation of register, bulkRegister
363	+	*
364	+	* @param registrations number to add to both parties and
365	+	* unarrived fields. Must be greater than zero.
366	+	*/
367	+	private int doRegister(int registrations) {
368	+	// adjustment to state
369	+	long adj = ((long)registrations << PARTIES_SHIFT) | registrations;
370	+	final Phaser parent = this.parent;
371	+	for (;;) {
372	+	long s = (parent == null) ? state : reconcileState();
373	+	int parties = (int)s >>> PARTIES_SHIFT;
374	+	int phase = (int)(s >>> PHASE_SHIFT);
375	+	if (phase < 0)
376	+	return phase;
377	+	else if (registrations > MAX_PARTIES - parties)
378	+	throw new IllegalStateException(badRegister(s));
379	+	else if ((parties == 0 && parent == null) || // first reg of root
380	+	((int)s & UNARRIVED_MASK) != 0) {   // not advancing
381	+	if (UNSAFE.compareAndSwapLong(this, stateOffset, s, s + adj))
382	+	return phase;
383	+	}
384	+	else if (parties != 0)               // wait for onAdvance
385	+	root.internalAwaitAdvance(phase, null);
386	+	else {                               // 1st registration of child
387	+	synchronized (this) {            // register parent first
388	+	if (reconcileState() == s) { // recheck under lock
389	+	parent.doRegister(1);    // OK if throws IllegalState
390	+	for (;;) {               // simpler form of outer loop
391	+	s = reconcileState();
392	+	phase = (int)(s >>> PHASE_SHIFT);
393	+	if (phase < 0 ||
394	+	UNSAFE.compareAndSwapLong(this, stateOffset,
395	+	s, s + adj))
396	+	return phase;
397	+	}
398	+	}
399	+	}
400	+	}
401	+	}
402	+	}
403	+
404	+	/**
405	+	* Recursively resolves lagged phase propagation from root if necessary.
406	+	*/
407	+	private long reconcileState() {
408	+	Phaser par = parent;
409	+	long s = state;
410	+	if (par != null) {
411	+	Phaser rt = root;
412	+	int phase, rPhase;
413	+	while ((phase = (int)(s >>> PHASE_SHIFT)) >= 0 &&
414	+	(rPhase = (int)(rt.state >>> PHASE_SHIFT)) != phase) {
415	+	if (par != rt && (int)(par.state >>> PHASE_SHIFT) != rPhase)
416	+	par.reconcileState();
417	+	else if (rPhase < 0 || ((int)s & UNARRIVED_MASK) == 0) {
418	+	long u = s & PARTIES_MASK; // reset unarrived to parties
419	+	long next = ((((long) rPhase) << PHASE_SHIFT) | u |
420	+	(u >>> PARTIES_SHIFT));
421	+	UNSAFE.compareAndSwapLong(this, stateOffset, s, next);
422	+	}
423	+	s = state;
424		}
425		}
426		return s;
427		}
428
429		/**
430	<	* Creates a new Phaser without any initially registered parties,
431	<	* initial phase number 0, and no parent.
430	>	* Creates a new phaser with no initially registered parties, no
431	>	* parent, and initial phase number 0. Any thread using this
432	>	* phaser will need to first register for it.
433		*/
434		public Phaser() {
435	<	this(null);
435	>	this(null, 0);
436		}
437
438		/**
439	<	* Creates a new Phaser with the given numbers of registered
440	<	* unarrived parties, initial phase number 0, and no parent.
441	<	* @param parties the number of parties required to trip barrier.
439	>	* Creates a new phaser with the given number of registered
440	>	* unarrived parties, no parent, and initial phase number 0.
441	>	*
442	>	* @param parties the number of parties required to advance to the
443	>	* next phase
444		* @throws IllegalArgumentException if parties less than zero
445	<	* or greater than the maximum number of parties supported.
445	>	* or greater than the maximum number of parties supported
446		*/
447		public Phaser(int parties) {
448		this(null, parties);
449		}
450
451		/**
452	<	* Creates a new Phaser with the given parent, without any
453	<	* initially registered parties. If parent is non-null this phaser
454	<	* is registered with the parent and its initial phase number is
319	<	* the same as that of parent phaser.
320	<	* @param parent the parent phaser.
452	>	* Equivalent to {@link #Phaser(Phaser, int) Phaser(parent, 0)}.
453	>	*
454	>	* @param parent the parent phaser
455		*/
456		public Phaser(Phaser parent) {
457	<	int phase = 0;
324	<	this.parent = parent;
325	<	if (parent != null) {
326	<	this.root = parent.root;
327	<	phase = parent.register();
328	<	}
329	<	else
330	<	this.root = this;
331	<	this.state = trippedStateFor(phase, 0);
457	>	this(parent, 0);
458		}
459
460		/**
461	<	* Creates a new Phaser with the given parent and numbers of
462	<	* registered unarrived parties. If parent is non-null this phaser
463	<	* is registered with the parent and its initial phase number is
464	<	* the same as that of parent phaser.
465	<	* @param parent the parent phaser.
466	<	* @param parties the number of parties required to trip barrier.
461	>	* Creates a new phaser with the given parent and number of
462	>	* registered unarrived parties. Registration and deregistration
463	>	* of this child phaser with its parent are managed automatically.
464	>	* If the given parent is non-null, whenever this child phaser has
465	>	* any registered parties (as established in this constructor,
466	>	* {@link #register}, or {@link #bulkRegister}), this child phaser
467	>	* is registered with its parent. Whenever the number of
468	>	* registered parties becomes zero as the result of an invocation
469	>	* of {@link #arriveAndDeregister}, this child phaser is
470	>	* deregistered from its parent.
471	>	*
472	>	* @param parent the parent phaser
473	>	* @param parties the number of parties required to advance to the
474	>	* next phase
475		* @throws IllegalArgumentException if parties less than zero
476	<	* or greater than the maximum number of parties supported.
476	>	* or greater than the maximum number of parties supported
477		*/
478		public Phaser(Phaser parent, int parties) {
479	<	if (parties < 0 || parties > ushortMask)
479	>	if (parties >>> PARTIES_SHIFT != 0)
480		throw new IllegalArgumentException("Illegal number of parties");
481	<	int phase = 0;
481	>	long s = ((long) parties) | (((long) parties) << PARTIES_SHIFT);
482		this.parent = parent;
483		if (parent != null) {
484	<	this.root = parent.root;
485	<	phase = parent.register();
484	>	Phaser r = parent.root;
485	>	this.root = r;
486	>	this.evenQ = r.evenQ;
487	>	this.oddQ = r.oddQ;
488	>	if (parties != 0)
489	>	s |= ((long)(parent.doRegister(1))) << PHASE_SHIFT;
490		}
491	<	else
491	>	else {
492		this.root = this;
493	<	this.state = trippedStateFor(phase, parties);
493	>	this.evenQ = new AtomicReference<QNode>();
494	>	this.oddQ = new AtomicReference<QNode>();
495	>	}
496	>	this.state = s;
497		}
498
499		/**
500	<	* Adds a new unarrived party to this phaser.
501	<	* @return the current barrier phase number upon registration
500	>	* Adds a new unarrived party to this phaser.  If an ongoing
501	>	* invocation of {@link #onAdvance} is in progress, this method
502	>	* may await its completion before returning.  If this phaser has
503	>	* a parent, and this phaser previously had no registered parties,
504	>	* this phaser is also registered with its parent.
505	>	*
506	>	* @return the arrival phase number to which this registration applied
507		* @throws IllegalStateException if attempting to register more
508	<	* than the maximum supported number of parties.
508	>	* than the maximum supported number of parties
509		*/
510		public int register() {
511		return doRegister(1);
#	Line 367 | Line 513 | public class Phaser {
513
514		/**
515		* Adds the given number of new unarrived parties to this phaser.
516	<	* @param parties the number of parties required to trip barrier.
517	<	* @return the current barrier phase number upon registration
516	>	* If an ongoing invocation of {@link #onAdvance} is in progress,
517	>	* this method may await its completion before returning.  If this
518	>	* phaser has a parent, and the given number of parities is
519	>	* greater than zero, and this phaser previously had no registered
520	>	* parties, this phaser is also registered with its parent.
521	>	*
522	>	* @param parties the number of additional parties required to
523	>	* advance to the next phase
524	>	* @return the arrival phase number to which this registration applied
525		* @throws IllegalStateException if attempting to register more
526	<	* than the maximum supported number of parties.
526	>	* than the maximum supported number of parties
527	>	* @throws IllegalArgumentException if {@code parties < 0}
528		*/
529		public int bulkRegister(int parties) {
530		if (parties < 0)
#	Line 381 | Line 535 | public class Phaser {
535		}
536
537		/**
538	<	* Shared code for register, bulkRegister
539	<	*/
540	<	private int doRegister(int registrations) {
541	<	int phase;
542	<	for (;;) {
543	<	long s = getReconciledState();
390	<	phase = phaseOf(s);
391	<	int unarrived = unarrivedOf(s) + registrations;
392	<	int parties = partiesOf(s) + registrations;
393	<	if (phase < 0)
394	<	break;
395	<	if (parties > ushortMask || unarrived > ushortMask)
396	<	throw badBounds(parties, unarrived);
397	<	if (phase == phaseOf(root.state) &&
398	<	casState(s, stateFor(phase, parties, unarrived)))
399	<	break;
400	<	}
401	<	return phase;
402	<	}
403	<
404	<	/**
405	<	* Arrives at the barrier, but does not wait for others.  (You can
406	<	* in turn wait for others via {@link #awaitAdvance}).
538	>	* Arrives at this phaser, without waiting for others to arrive.
539	>	*
540	>	* <p>It is a usage error for an unregistered party to invoke this
541	>	* method.  However, this error may result in an {@code
542	>	* IllegalStateException} only upon some subsequent operation on
543	>	* this phaser, if ever.
544		*
545	<	* @return the barrier phase number upon entry to this method, or a
409	<	* negative value if terminated;
545	>	* @return the arrival phase number, or a negative value if terminated
546		* @throws IllegalStateException if not terminated and the number
547	<	* of unarrived parties would become negative.
547	>	* of unarrived parties would become negative
548		*/
549		public int arrive() {
550	<	int phase;
415	<	for (;;) {
416	<	long s = state;
417	<	phase = phaseOf(s);
418	<	int parties = partiesOf(s);
419	<	int unarrived = unarrivedOf(s) - 1;
420	<	if (unarrived > 0) {        // Not the last arrival
421	<	if (casState(s, s - 1)) // s-1 adds one arrival
422	<	break;
423	<	}
424	<	else if (unarrived == 0) {  // the last arrival
425	<	Phaser par = parent;
426	<	if (par == null) {      // directly trip
427	<	if (casState
428	<	(s,
429	<	trippedStateFor(onAdvance(phase, parties)? -1 :
430	<	((phase + 1) & phaseMask), parties))) {
431	<	releaseWaiters(phase);
432	<	break;
433	<	}
434	<	}
435	<	else {                  // cascade to parent
436	<	if (casState(s, s - 1)) { // zeroes unarrived
437	<	par.arrive();
438	<	reconcileState();
439	<	break;
440	<	}
441	<	}
442	<	}
443	<	else if (phase < 0) // Don't throw exception if terminated
444	<	break;
445	<	else if (phase != phaseOf(root.state)) // or if unreconciled
446	<	reconcileState();
447	<	else
448	<	throw badBounds(parties, unarrived);
449	<	}
450	<	return phase;
550	>	return doArrive(ONE_ARRIVAL);
551		}
552
553		/**
554	<	* Arrives at the barrier, and deregisters from it, without
555	<	* waiting for others. Deregistration reduces number of parties
556	<	* required to trip the barrier in future phases.  If this phaser
554	>	* Arrives at this phaser and deregisters from it without waiting
555	>	* for others to arrive. Deregistration reduces the number of
556	>	* parties required to advance in future phases.  If this phaser
557		* has a parent, and deregistration causes this phaser to have
558		* zero parties, this phaser is also deregistered from its parent.
559		*
560	<	* @return the current barrier phase number upon entry to
561	<	* this method, or a negative value if terminated;
560	>	* <p>It is a usage error for an unregistered party to invoke this
561	>	* method.  However, this error may result in an {@code
562	>	* IllegalStateException} only upon some subsequent operation on
563	>	* this phaser, if ever.
564	>	*
565	>	* @return the arrival phase number, or a negative value if terminated
566		* @throws IllegalStateException if not terminated and the number
567	<	* of registered or unarrived parties would become negative.
567	>	* of registered or unarrived parties would become negative
568		*/
569		public int arriveAndDeregister() {
570	<	// similar code to arrive, but too different to merge
467	<	Phaser par = parent;
468	<	int phase;
469	<	for (;;) {
470	<	long s = state;
471	<	phase = phaseOf(s);
472	<	int parties = partiesOf(s) - 1;
473	<	int unarrived = unarrivedOf(s) - 1;
474	<	if (parties >= 0) {
475	<	if (unarrived > 0 || (unarrived == 0 && par != null)) {
476	<	if (casState
477	<	(s,
478	<	stateFor(phase, parties, unarrived))) {
479	<	if (unarrived == 0) {
480	<	par.arriveAndDeregister();
481	<	reconcileState();
482	<	}
483	<	break;
484	<	}
485	<	continue;
486	<	}
487	<	if (unarrived == 0) {
488	<	if (casState
489	<	(s,
490	<	trippedStateFor(onAdvance(phase, parties)? -1 :
491	<	((phase + 1) & phaseMask), parties))) {
492	<	releaseWaiters(phase);
493	<	break;
494	<	}
495	<	continue;
496	<	}
497	<	if (phase < 0)
498	<	break;
499	<	if (par != null && phase != phaseOf(root.state)) {
500	<	reconcileState();
501	<	continue;
502	<	}
503	<	}
504	<	throw badBounds(parties, unarrived);
505	<	}
506	<	return phase;
570	>	return doArrive(ONE_ARRIVAL|ONE_PARTY);
571		}
572
573		/**
574	<	* Arrives at the barrier and awaits others. Equivalent in effect
575	<	* to {@code awaitAdvance(arrive())}.  If you instead need to
576	<	* await with interruption of timeout, and/or deregister upon
577	<	* arrival, you can arrange them using analogous constructions.
578	<	* @return the phase on entry to this method
574	>	* Arrives at this phaser and awaits others. Equivalent in effect
575	>	* to {@code awaitAdvance(arrive())}.  If you need to await with
576	>	* interruption or timeout, you can arrange this with an analogous
577	>	* construction using one of the other forms of the {@code
578	>	* awaitAdvance} method.  If instead you need to deregister upon
579	>	* arrival, use {@code awaitAdvance(arriveAndDeregister())}.
580	>	*
581	>	* <p>It is a usage error for an unregistered party to invoke this
582	>	* method.  However, this error may result in an {@code
583	>	* IllegalStateException} only upon some subsequent operation on
584	>	* this phaser, if ever.
585	>	*
586	>	* @return the arrival phase number, or a negative number if terminated
587		* @throws IllegalStateException if not terminated and the number
588	<	* of unarrived parties would become negative.
588	>	* of unarrived parties would become negative
589		*/
590		public int arriveAndAwaitAdvance() {
591	<	return awaitAdvance(arrive());
591	>	return awaitAdvance(doArrive(ONE_ARRIVAL));
592		}
593
594		/**
595	<	* Awaits the phase of the barrier to advance from the given
596	<	* value, or returns immediately if argument is negative or this
597	<	* barrier is terminated.
598	<	* @param phase the phase on entry to this method
599	<	* @return the phase on exit from this method
595	>	* Awaits the phase of this phaser to advance from the given phase
596	>	* value, returning immediately if the current phase is not equal
597	>	* to the given phase value or this phaser is terminated.
598	>	*
599	>	* @param phase an arrival phase number, or negative value if
600	>	* terminated; this argument is normally the value returned by a
601	>	* previous call to {@code arrive} or {@code arriveAndDeregister}.
602	>	* @return the next arrival phase number, or a negative value
603	>	* if terminated or argument is negative
604		*/
605		public int awaitAdvance(int phase) {
606	+	Phaser rt;
607	+	int p = (int)(state >>> PHASE_SHIFT);
608		if (phase < 0)
609		return phase;
610	<	long s = getReconciledState();
611	<	int p = phaseOf(s);
612	<	if (p != phase)
613	<	return p;
536	<	if (unarrivedOf(s) == 0)
537	<	parent.awaitAdvance(phase);
538	<	// Fall here even if parent waited, to reconcile and help release
539	<	return untimedWait(phase);
610	>	if (p == phase &&
611	>	(p = (int)((rt = root).state >>> PHASE_SHIFT)) == phase)
612	>	return rt.internalAwaitAdvance(phase, null);
613	>	return p;
614		}
615
616		/**
617	<	* Awaits the phase of the barrier to advance from the given
618	<	* value, or returns immediately if argument is negative or this
619	<	* barrier is terminated, or throws InterruptedException if
620	<	* interrupted while waiting.
621	<	* @param phase the phase on entry to this method
622	<	* @return the phase on exit from this method
617	>	* Awaits the phase of this phaser to advance from the given phase
618	>	* value, throwing {@code InterruptedException} if interrupted
619	>	* while waiting, or returning immediately if the current phase is
620	>	* not equal to the given phase value or this phaser is
621	>	* terminated.
622	>	*
623	>	* @param phase an arrival phase number, or negative value if
624	>	* terminated; this argument is normally the value returned by a
625	>	* previous call to {@code arrive} or {@code arriveAndDeregister}.
626	>	* @return the next arrival phase number, or a negative value
627	>	* if terminated or argument is negative
628		* @throws InterruptedException if thread interrupted while waiting
629		*/
630	<	public int awaitAdvanceInterruptibly(int phase) throws InterruptedException {
630	>	public int awaitAdvanceInterruptibly(int phase)
631	>	throws InterruptedException {
632	>	Phaser rt;
633	>	int p = (int)(state >>> PHASE_SHIFT);
634		if (phase < 0)
635		return phase;
636	<	long s = getReconciledState();
637	<	int p = phaseOf(s);
638	<	if (p != phase)
639	<	return p;
640	<	if (unarrivedOf(s) != 0)
641	<	parent.awaitAdvanceInterruptibly(phase);
642	<	return interruptibleWait(phase);
636	>	if (p == phase &&
637	>	(p = (int)((rt = root).state >>> PHASE_SHIFT)) == phase) {
638	>	QNode node = new QNode(this, phase, true, false, 0L);
639	>	p = rt.internalAwaitAdvance(phase, node);
640	>	if (node.wasInterrupted)
641	>	throw new InterruptedException();
642	>	}
643	>	return p;
644		}
645
646		/**
647	<	* Awaits the phase of the barrier to advance from the given value
648	<	* or the given timeout elapses, or returns immediately if
649	<	* argument is negative or this barrier is terminated.
650	<	* @param phase the phase on entry to this method
651	<	* @return the phase on exit from this method
647	>	* Awaits the phase of this phaser to advance from the given phase
648	>	* value or the given timeout to elapse, throwing {@code
649	>	* InterruptedException} if interrupted while waiting, or
650	>	* returning immediately if the current phase is not equal to the
651	>	* given phase value or this phaser is terminated.
652	>	*
653	>	* @param phase an arrival phase number, or negative value if
654	>	* terminated; this argument is normally the value returned by a
655	>	* previous call to {@code arrive} or {@code arriveAndDeregister}.
656	>	* @param timeout how long to wait before giving up, in units of
657	>	*        {@code unit}
658	>	* @param unit a {@code TimeUnit} determining how to interpret the
659	>	*        {@code timeout} parameter
660	>	* @return the next arrival phase number, or a negative value
661	>	* if terminated or argument is negative
662		* @throws InterruptedException if thread interrupted while waiting
663		* @throws TimeoutException if timed out while waiting
664		*/
665	<	public int awaitAdvanceInterruptibly(int phase, long timeout, TimeUnit unit)
665	>	public int awaitAdvanceInterruptibly(int phase,
666	>	long timeout, TimeUnit unit)
667		throws InterruptedException, TimeoutException {
668	+	long nanos = unit.toNanos(timeout);
669	+	Phaser rt;
670	+	int p = (int)(state >>> PHASE_SHIFT);
671		if (phase < 0)
672		return phase;
673	<	long s = getReconciledState();
674	<	int p = phaseOf(s);
675	<	if (p != phase)
676	<	return p;
677	<	if (unarrivedOf(s) == 0)
678	<	parent.awaitAdvanceInterruptibly(phase, timeout, unit);
679	<	return timedWait(phase, unit.toNanos(timeout));
673	>	if (p == phase &&
674	>	(p = (int)((rt = root).state >>> PHASE_SHIFT)) == phase) {
675	>	QNode node = new QNode(this, phase, true, true, nanos);
676	>	p = rt.internalAwaitAdvance(phase, node);
677	>	if (node.wasInterrupted)
678	>	throw new InterruptedException();
679	>	else if (p == phase)
680	>	throw new TimeoutException();
681	>	}
682	>	return p;
683		}
684
685		/**
686	<	* Forces this barrier to enter termination state. Counts of
687	<	* arrived and registered parties are unaffected. If this phaser
688	<	* has a parent, it too is terminated. This method may be useful
689	<	* for coordinating recovery after one or more tasks encounter
690	<	* unexpected exceptions.
686	>	* Forces this phaser to enter termination state.  Counts of
687	>	* arrived and registered parties are unaffected.  If this phaser
688	>	* is a member of a tiered set of phasers, then all of the phasers
689	>	* in the set are terminated.  If this phaser is already
690	>	* terminated, this method has no effect.  This method may be
691	>	* useful for coordinating recovery after one or more tasks
692	>	* encounter unexpected exceptions.
693		*/
694		public void forceTermination() {
695	<	for (;;) {
696	<	long s = getReconciledState();
697	<	int phase = phaseOf(s);
698	<	int parties = partiesOf(s);
699	<	int unarrived = unarrivedOf(s);
700	<	if (phase < 0 ||
701	<	casState(s, stateFor(-1, parties, unarrived))) {
600	<	releaseWaiters(0);
695	>	// Only need to change root state
696	>	final Phaser root = this.root;
697	>	long s;
698	>	while ((s = root.state) >= 0) {
699	>	if (UNSAFE.compareAndSwapLong(root, stateOffset,
700	>	s, s | TERMINATION_BIT)) {
701	>	releaseWaiters(0); // signal all threads
702		releaseWaiters(1);
602	–	if (parent != null)
603	–	parent.forceTermination();
703		return;
704		}
705		}
#	Line 609 | Line 708 | public class Phaser {
708		/**
709		* Returns the current phase number. The maximum phase number is
710		* {@code Integer.MAX_VALUE}, after which it restarts at
711	<	* zero. Upon termination, the phase number is negative.
711	>	* zero. Upon termination, the phase number is negative,
712	>	* in which case the prevailing phase prior to termination
713	>	* may be obtained via {@code getPhase() + Integer.MIN_VALUE}.
714	>	*
715		* @return the phase number, or a negative value if terminated
716		*/
717		public final int getPhase() {
718	<	return phaseOf(getReconciledState());
617	<	}
618	<
619	<	/**
620	<	* Returns true if the current phase number equals the given phase.
621	<	* @param phase the phase
622	<	* @return true if the current phase number equals the given phase.
623	<	*/
624	<	public final boolean hasPhase(int phase) {
625	<	return phaseOf(getReconciledState()) == phase;
718	>	return (int)(root.state >>> PHASE_SHIFT);
719		}
720
721		/**
722	<	* Returns the number of parties registered at this barrier.
722	>	* Returns the number of parties registered at this phaser.
723	>	*
724		* @return the number of parties
725		*/
726		public int getRegisteredParties() {
#	Line 634 | Line 728 | public class Phaser {
728		}
729
730		/**
731	<	* Returns the number of parties that have arrived at the current
732	<	* phase of this barrier.
731	>	* Returns the number of registered parties that have arrived at
732	>	* the current phase of this phaser.
733	>	*
734		* @return the number of arrived parties
735		*/
736		public int getArrivedParties() {
737	<	return arrivedOf(state);
737	>	long s = state;
738	>	int u = unarrivedOf(s); // only reconcile if possibly needed
739	>	return (u != 0 || parent == null) ?
740	>	partiesOf(s) - u :
741	>	arrivedOf(reconcileState());
742		}
743
744		/**
745		* Returns the number of registered parties that have not yet
746	<	* arrived at the current phase of this barrier.
746	>	* arrived at the current phase of this phaser.
747	>	*
748		* @return the number of unarrived parties
749		*/
750		public int getUnarrivedParties() {
751	<	return unarrivedOf(state);
751	>	int u = unarrivedOf(state);
752	>	return (u != 0 || parent == null) ? u : unarrivedOf(reconcileState());
753		}
754
755		/**
756	<	* Returns the parent of this phaser, or null if none.
757	<	* @return the parent of this phaser, or null if none.
756	>	* Returns the parent of this phaser, or {@code null} if none.
757	>	*
758	>	* @return the parent of this phaser, or {@code null} if none
759		*/
760		public Phaser getParent() {
761		return parent;
#	Line 662 | Line 764 | public class Phaser {
764		/**
765		* Returns the root ancestor of this phaser, which is the same as
766		* this phaser if it has no parent.
767	<	* @return the root ancestor of this phaser.
767	>	*
768	>	* @return the root ancestor of this phaser
769		*/
770		public Phaser getRoot() {
771		return root;
772		}
773
774		/**
775	<	* Returns true if this barrier has been terminated.
776	<	* @return true if this barrier has been terminated
775	>	* Returns {@code true} if this phaser has been terminated.
776	>	*
777	>	* @return {@code true} if this phaser has been terminated
778		*/
779		public boolean isTerminated() {
780	<	return getPhase() < 0;
780	>	return root.state < 0L;
781		}
782
783		/**
784	<	* Overridable method to perform an action upon phase advance, and
785	<	* to control termination. This method is invoked whenever the
786	<	* barrier is tripped (and thus all other waiting parties are
787	<	* dormant). If it returns true, then, rather than advance the
788	<	* phase number, this barrier will be set to a final termination
789	<	* state, and subsequent calls to {@code isTerminated} will
790	<	* return true.
791	<	*
792	<	* <p> The default version returns true when the number of
793	<	* registered parties is zero. Normally, overrides that arrange
794	<	* termination for other reasons should also preserve this
795	<	* property.
796	<	*
797	<	* <p> You may override this method to perform an action with side
798	<	* effects visible to participating tasks, but it is in general
799	<	* only sensible to do so in designs where all parties register
800	<	* before any arrive, and all {@code awaitAdvance} at each phase.
801	<	* Otherwise, you cannot ensure lack of interference. In
802	<	* particular, this method may be invoked more than once per
803	<	* transition if other parties successfully register while the
804	<	* invocation of this method is in progress, thus postponing the
805	<	* transition until those parties also arrive, re-triggering this
806	<	* method.
807	<	*
808	<	* @param phase the phase number on entering the barrier
809	<	* @param registeredParties the current number of registered
810	<	* parties.
811	<	* @return true if this barrier should terminate
784	>	* Overridable method to perform an action upon impending phase
785	>	* advance, and to control termination. This method is invoked
786	>	* upon arrival of the party advancing this phaser (when all other
787	>	* waiting parties are dormant).  If this method returns {@code
788	>	* true}, then, rather than advance the phase number, this phaser
789	>	* will be set to a final termination state, and subsequent calls
790	>	* to {@link #isTerminated} will return true. Any (unchecked)
791	>	* Exception or Error thrown by an invocation of this method is
792	>	* propagated to the party attempting to advance this phaser, in
793	>	* which case no advance occurs.
794	>	*
795	>	* <p>The arguments to this method provide the state of the phaser
796	>	* prevailing for the current transition.  The effects of invoking
797	>	* arrival, registration, and waiting methods on this phaser from
798	>	* within {@code onAdvance} are unspecified and should not be
799	>	* relied on.
800	>	*
801	>	* <p>If this phaser is a member of a tiered set of phasers, then
802	>	* {@code onAdvance} is invoked only for its root phaser on each
803	>	* advance.
804	>	*
805	>	* <p>To support the most common use cases, the default
806	>	* implementation of this method returns {@code true} when the
807	>	* number of registered parties has become zero as the result of a
808	>	* party invoking {@code arriveAndDeregister}.  You can disable
809	>	* this behavior, thus enabling continuation upon future
810	>	* registrations, by overriding this method to always return
811	>	* {@code false}:
812	>	*
813	>	* <pre> {@code
814	>	* Phaser phaser = new Phaser() {
815	>	*   protected boolean onAdvance(int phase, int parties) { return false; }
816	>	* }}</pre>
817	>	*
818	>	* @param phase the current phase number on entry to this method,
819	>	* before this phaser is advanced
820	>	* @param registeredParties the current number of registered parties
821	>	* @return {@code true} if this phaser should terminate
822		*/
823		protected boolean onAdvance(int phase, int registeredParties) {
824	<	return registeredParties <= 0;
824	>	return registeredParties == 0;
825		}
826
827		/**
828		* Returns a string identifying this phaser, as well as its
829		* state.  The state, in brackets, includes the String {@code
830	<	* "phase ="} followed by the phase number, {@code "parties ="}
830	>	* "phase = "} followed by the phase number, {@code "parties = "}
831		* followed by the number of registered parties, and {@code
832	<	* "arrived ="} followed by the number of arrived parties
832	>	* "arrived = "} followed by the number of arrived parties.
833		*
834	<	* @return a string identifying this barrier, as well as its state
834	>	* @return a string identifying this phaser, as well as its state
835		*/
836		public String toString() {
837	<	long s = getReconciledState();
724	<	return super.toString() + "[phase = " + phaseOf(s) + " parties = " + partiesOf(s) + " arrived = " + arrivedOf(s) + "]";
837	>	return stateToString(reconcileState());
838		}
839
727	–	// methods for waiting
728	–
729	–	/** The number of CPUs, for spin control */
730	–	static final int NCPUS = Runtime.getRuntime().availableProcessors();
731	–
732	–	/**
733	–	* The number of times to spin before blocking in timed waits.
734	–	* The value is empirically derived.
735	–	*/
736	–	static final int maxTimedSpins = (NCPUS < 2)? 0 : 32;
737	–
840		/**
841	<	* The number of times to spin before blocking in untimed waits.
740	<	* This is greater than timed value because untimed waits spin
741	<	* faster since they don't need to check times on each spin.
841	>	* Implementation of toString and string-based error messages
842		*/
843	<	static final int maxUntimedSpins = maxTimedSpins * 32;
843	>	private String stateToString(long s) {
844	>	return super.toString() +
845	>	"[phase = " + phaseOf(s) +
846	>	" parties = " + partiesOf(s) +
847	>	" arrived = " + arrivedOf(s) + "]";
848	>	}
849
850	<	/**
746	<	* The number of nanoseconds for which it is faster to spin
747	<	* rather than to use timed park. A rough estimate suffices.
748	<	*/
749	<	static final long spinForTimeoutThreshold = 1000L;
850	>	// Waiting mechanics
851
852		/**
853	<	* Wait nodes for Treiber stack representing wait queue for non-FJ
753	<	* tasks.
853	>	* Removes and signals threads from queue for phase.
854		*/
855	<	static final class QNode {
856	<	QNode next;
857	<	volatile Thread thread; // nulled to cancel wait
858	<	QNode() {
859	<	thread = Thread.currentThread();
860	<	}
861	<	void signal() {
862	<	Thread t = thread;
863	<	if (t != null) {
864	<	thread = null;
855	>	private void releaseWaiters(int phase) {
856	>	QNode q;   // first element of queue
857	>	int p;     // its phase
858	>	Thread t;  // its thread
859	>	AtomicReference<QNode> head = (phase & 1) == 0 ? evenQ : oddQ;
860	>	while ((q = head.get()) != null &&
861	>	((p = q.phase) == phase ||
862	>	(int)(root.state >>> PHASE_SHIFT) != p)) {
863	>	if (head.compareAndSet(q, q.next) &&
864	>	(t = q.thread) != null) {
865	>	q.thread = null;
866		LockSupport.unpark(t);
867		}
868		}
869		}
870
871	+	/** The number of CPUs, for spin control */
872	+	private static final int NCPU = Runtime.getRuntime().availableProcessors();
873	+
874		/**
875	<	* Removes and signals waiting threads from wait queue
875	>	* The number of times to spin before blocking while waiting for
876	>	* advance, per arrival while waiting. On multiprocessors, fully
877	>	* blocking and waking up a large number of threads all at once is
878	>	* usually a very slow process, so we use rechargeable spins to
879	>	* avoid it when threads regularly arrive: When a thread in
880	>	* internalAwaitAdvance notices another arrival before blocking,
881	>	* and there appear to be enough CPUs available, it spins
882	>	* SPINS_PER_ARRIVAL more times before blocking. The value trades
883	>	* off good-citizenship vs big unnecessary slowdowns.
884		*/
885	<	private void releaseWaiters(int phase) {
774	<	AtomicReference<QNode> head = queueFor(phase);
775	<	QNode q;
776	<	while ((q = head.get()) != null) {
777	<	if (head.compareAndSet(q, q.next))
778	<	q.signal();
779	<	}
780	<	}
885	>	static final int SPINS_PER_ARRIVAL = (NCPU < 2) ? 1 : 1 << 8;
886
887		/**
888	<	* Enqueues node and waits unless aborted or signalled.
889	<	*/
890	<	private int untimedWait(int phase) {
891	<	int spins = maxUntimedSpins;
892	<	QNode node = null;
893	<	boolean interrupted = false;
894	<	boolean queued = false;
888	>	* Possibly blocks and waits for phase to advance unless aborted.
889	>	* Call only from root node.
890	>	*
891	>	* @param phase current phase
892	>	* @param node if non-null, the wait node to track interrupt and timeout;
893	>	* if null, denotes noninterruptible wait
894	>	* @return current phase
895	>	*/
896	>	private int internalAwaitAdvance(int phase, QNode node) {
897	>	releaseWaiters(phase-1);          // ensure old queue clean
898	>	boolean queued = false;           // true when node is enqueued
899	>	int lastUnarrived = 0;            // to increase spins upon change
900	>	int spins = SPINS_PER_ARRIVAL;
901	>	long s;
902		int p;
903	<	while ((p = getPhase()) == phase) {
904	<	interrupted = Thread.interrupted();
905	<	if (node != null) {
906	<	if (!queued) {
907	<	AtomicReference<QNode> head = queueFor(phase);
908	<	queued = head.compareAndSet(node.next = head.get(), node);
903	>	while ((p = (int)((s = state) >>> PHASE_SHIFT)) == phase) {
904	>	if (node == null) {           // spinning in noninterruptible mode
905	>	int unarrived = (int)s & UNARRIVED_MASK;
906	>	if (unarrived != lastUnarrived &&
907	>	(lastUnarrived = unarrived) < NCPU)
908	>	spins += SPINS_PER_ARRIVAL;
909	>	boolean interrupted = Thread.interrupted();
910	>	if (interrupted || --spins < 0) { // need node to record intr
911	>	node = new QNode(this, phase, false, false, 0L);
912	>	node.wasInterrupted = interrupted;
913		}
798	–	else if (node.thread != null)
799	–	LockSupport.park(this);
914		}
915	<	else if (spins <= 0)
802	<	node = new QNode();
803	<	else
804	<	--spins;
805	<	}
806	<	if (node != null)
807	<	node.thread = null;
808	<	if (interrupted)
809	<	Thread.currentThread().interrupt();
810	<	releaseWaiters(phase);
811	<	return p;
812	<	}
813	<
814	<	/**
815	<	* Messier interruptible version
816	<	*/
817	<	private int interruptibleWait(int phase) throws InterruptedException {
818	<	int spins = maxUntimedSpins;
819	<	QNode node = null;
820	<	boolean queued = false;
821	<	boolean interrupted = false;
822	<	int p;
823	<	while ((p = getPhase()) == phase) {
824	<	if (interrupted = Thread.interrupted())
915	>	else if (node.isReleasable()) // done or aborted
916		break;
917	<	if (node != null) {
918	<	if (!queued) {
919	<	AtomicReference<QNode> head = queueFor(phase);
920	<	queued = head.compareAndSet(node.next = head.get(), node);
917	>	else if (!queued) {           // push onto queue
918	>	AtomicReference<QNode> head = (phase & 1) == 0 ? evenQ : oddQ;
919	>	QNode q = node.next = head.get();
920	>	if ((q == null || q.phase == phase) &&
921	>	(int)(state >>> PHASE_SHIFT) == phase) // avoid stale enq
922	>	queued = head.compareAndSet(q, node);
923	>	}
924	>	else {
925	>	try {
926	>	ForkJoinPool.managedBlock(node);
927	>	} catch (InterruptedException ie) {
928	>	node.wasInterrupted = true;
929		}
831	–	else if (node.thread != null)
832	–	LockSupport.park(this);
930		}
931	<	else if (spins <= 0)
932	<	node = new QNode();
933	<	else
934	<	--spins;
935	<	}
936	<	if (node != null)
937	<	node.thread = null;
938	<	if (interrupted)
939	<	throw new InterruptedException();
931	>	}
932	>
933	>	if (node != null) {
934	>	if (node.thread != null)
935	>	node.thread = null;       // avoid need for unpark()
936	>	if (node.wasInterrupted && !node.interruptible)
937	>	Thread.currentThread().interrupt();
938	>	if ((p = (int)(state >>> PHASE_SHIFT)) == phase)
939	>	return p;                 // recheck abort
940	>	}
941		releaseWaiters(phase);
942		return p;
943		}
944
945		/**
946	<	* Even messier timeout version.
946	>	* Wait nodes for Treiber stack representing wait queue
947		*/
948	<	private int timedWait(int phase, long nanos)
949	<	throws InterruptedException, TimeoutException {
950	<	int p;
951	<	if ((p = getPhase()) == phase) {
952	<	long lastTime = System.nanoTime();
953	<	int spins = maxTimedSpins;
954	<	QNode node = null;
955	<	boolean queued = false;
956	<	boolean interrupted = false;
957	<	while ((p = getPhase()) == phase) {
958	<	if (interrupted = Thread.interrupted())
959	<	break;
960	<	long now = System.nanoTime();
961	<	if ((nanos -= now - lastTime) <= 0)
962	<	break;
963	<	lastTime = now;
964	<	if (node != null) {
965	<	if (!queued) {
966	<	AtomicReference<QNode> head = queueFor(phase);
967	<	queued = head.compareAndSet(node.next = head.get(), node);
968	<	}
969	<	else if (node.thread != null &&
970	<	nanos > spinForTimeoutThreshold) {
971	<	LockSupport.parkNanos(this, nanos);
972	<	}
948	>	static final class QNode implements ForkJoinPool.ManagedBlocker {
949	>	final Phaser phaser;
950	>	final int phase;
951	>	final boolean interruptible;
952	>	final boolean timed;
953	>	boolean wasInterrupted;
954	>	long nanos;
955	>	long lastTime;
956	>	volatile Thread thread; // nulled to cancel wait
957	>	QNode next;
958	>
959	>	QNode(Phaser phaser, int phase, boolean interruptible,
960	>	boolean timed, long nanos) {
961	>	this.phaser = phaser;
962	>	this.phase = phase;
963	>	this.interruptible = interruptible;
964	>	this.nanos = nanos;
965	>	this.timed = timed;
966	>	this.lastTime = timed? System.nanoTime() : 0L;
967	>	thread = Thread.currentThread();
968	>	}
969	>
970	>	public boolean isReleasable() {
971	>	if (thread == null)
972	>	return true;
973	>	if (phaser.getPhase() != phase) {
974	>	thread = null;
975	>	return true;
976	>	}
977	>	if (Thread.interrupted())
978	>	wasInterrupted = true;
979	>	if (wasInterrupted && interruptible) {
980	>	thread = null;
981	>	return true;
982	>	}
983	>	if (timed) {
984	>	if (nanos > 0L) {
985	>	long now = System.nanoTime();
986	>	nanos -= now - lastTime;
987	>	lastTime = now;
988		}
989	<	else if (spins <= 0)
990	<	node = new QNode();
991	<	else
992	<	--spins;
993	<	}
994	<	if (node != null)
995	<	node.thread = null;
996	<	if (interrupted)
997	<	throw new InterruptedException();
998	<	if (p == phase && (p = getPhase()) == phase)
999	<	throw new TimeoutException();
989	>	if (nanos <= 0L) {
990	>	thread = null;
991	>	return true;
992	>	}
993	>	}
994	>	return false;
995	>	}
996	>
997	>	public boolean block() {
998	>	if (isReleasable())
999	>	return true;
1000	>	else if (!timed)
1001	>	LockSupport.park(this);
1002	>	else if (nanos > 0)
1003	>	LockSupport.parkNanos(this, nanos);
1004	>	return isReleasable();
1005		}
888	–	releaseWaiters(phase);
889	–	return p;
1006		}
1007
1008	<	// Temporary Unsafe mechanics for preliminary release
1008	>	// Unsafe mechanics
1009
1010	<	static final Unsafe _unsafe;
1011	<	static final long stateOffset;
1010	>	private static final sun.misc.Unsafe UNSAFE = getUnsafe();
1011	>	private static final long stateOffset =
1012	>	objectFieldOffset("state", Phaser.class);
1013
1014	<	static {
1014	>	private static long objectFieldOffset(String field, Class<?> klazz) {
1015		try {
1016	<	if (Phaser.class.getClassLoader() != null) {
1017	<	Field f = Unsafe.class.getDeclaredField("theUnsafe");
1018	<	f.setAccessible(true);
1019	<	_unsafe = (Unsafe)f.get(null);
1020	<	}
1021	<	else
905	<	_unsafe = Unsafe.getUnsafe();
906	<	stateOffset = _unsafe.objectFieldOffset
907	<	(Phaser.class.getDeclaredField("state"));
908	<	} catch (Exception e) {
909	<	throw new RuntimeException("Could not initialize intrinsics", e);
1016	>	return UNSAFE.objectFieldOffset(klazz.getDeclaredField(field));
1017	>	} catch (NoSuchFieldException e) {
1018	>	// Convert Exception to corresponding Error
1019	>	NoSuchFieldError error = new NoSuchFieldError(field);
1020	>	error.initCause(e);
1021	>	throw error;
1022		}
1023		}
1024
1025	<	final boolean casState(long cmp, long val) {
1026	<	return _unsafe.compareAndSwapLong(this, stateOffset, cmp, val);
1025	>	/**
1026	>	* Returns a sun.misc.Unsafe.  Suitable for use in a 3rd party package.
1027	>	* Replace with a simple call to Unsafe.getUnsafe when integrating
1028	>	* into a jdk.
1029	>	*
1030	>	* @return a sun.misc.Unsafe
1031	>	*/
1032	>	private static sun.misc.Unsafe getUnsafe() {
1033	>	try {
1034	>	return sun.misc.Unsafe.getUnsafe();
1035	>	} catch (SecurityException se) {
1036	>	try {
1037	>	return java.security.AccessController.doPrivileged
1038	>	(new java.security
1039	>	.PrivilegedExceptionAction<sun.misc.Unsafe>() {
1040	>	public sun.misc.Unsafe run() throws Exception {
1041	>	java.lang.reflect.Field f = sun.misc
1042	>	.Unsafe.class.getDeclaredField("theUnsafe");
1043	>	f.setAccessible(true);
1044	>	return (sun.misc.Unsafe) f.get(null);
1045	>	}});
1046	>	} catch (java.security.PrivilegedActionException e) {
1047	>	throw new RuntimeException("Could not initialize intrinsics",
1048	>	e.getCause());
1049	>	}
1050	>	}
1051		}
1052		}

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