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Jersey JSR-166e Repackaged. See http://gee.cs.oswego.edu/dl/concurrency-interest/index.html

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/*
 * Written by Doug Lea with assistance from members of JCP JSR-166
 * Expert Group and released to the public domain, as explained at
 * http://creativecommons.org/publicdomain/zero/1.0/
 */

package jersey.repackaged.jsr166e;

import java.lang.Thread.UncaughtExceptionHandler;
import java.util.ArrayList;
import java.util.Arrays;
import java.util.Collection;
import java.util.Collections;
import java.util.List;
import java.util.concurrent.AbstractExecutorService;
import java.util.concurrent.Callable;
import java.util.concurrent.ExecutorService;
import java.util.concurrent.Future;
import java.util.concurrent.RejectedExecutionException;
import java.util.concurrent.RunnableFuture;
import java.util.concurrent.TimeUnit;

/**
 * An {@link ExecutorService} for running {@link ForkJoinTask}s.
 * A {@code ForkJoinPool} provides the entry point for submissions
 * from non-{@code ForkJoinTask} clients, as well as management and
 * monitoring operations.
 *
 * 

A {@code ForkJoinPool} differs from other kinds of {@link * ExecutorService} mainly by virtue of employing * work-stealing: all threads in the pool attempt to find and * execute tasks submitted to the pool and/or created by other active * tasks (eventually blocking waiting for work if none exist). This * enables efficient processing when most tasks spawn other subtasks * (as do most {@code ForkJoinTask}s), as well as when many small * tasks are submitted to the pool from external clients. Especially * when setting asyncMode to true in constructors, {@code * ForkJoinPool}s may also be appropriate for use with event-style * tasks that are never joined. * *

A static {@link #commonPool()} is available and appropriate for * most applications. The common pool is used by any ForkJoinTask that * is not explicitly submitted to a specified pool. Using the common * pool normally reduces resource usage (its threads are slowly * reclaimed during periods of non-use, and reinstated upon subsequent * use). * *

For applications that require separate or custom pools, a {@code * ForkJoinPool} may be constructed with a given target parallelism * level; by default, equal to the number of available processors. The * pool attempts to maintain enough active (or available) threads by * dynamically adding, suspending, or resuming internal worker * threads, even if some tasks are stalled waiting to join others. * However, no such adjustments are guaranteed in the face of blocked * I/O or other unmanaged synchronization. The nested {@link * ManagedBlocker} interface enables extension of the kinds of * synchronization accommodated. * *

In addition to execution and lifecycle control methods, this * class provides status check methods (for example * {@link #getStealCount}) that are intended to aid in developing, * tuning, and monitoring fork/join applications. Also, method * {@link #toString} returns indications of pool state in a * convenient form for informal monitoring. * *

As is the case with other ExecutorServices, there are three * main task execution methods summarized in the following table. * These are designed to be used primarily by clients not already * engaged in fork/join computations in the current pool. The main * forms of these methods accept instances of {@code ForkJoinTask}, * but overloaded forms also allow mixed execution of plain {@code * Runnable}- or {@code Callable}- based activities as well. However, * tasks that are already executing in a pool should normally instead * use the within-computation forms listed in the table unless using * async event-style tasks that are not usually joined, in which case * there is little difference among choice of methods. * *

* * * * * * * * * * * * * * * * * * * * * *
Summary of task execution methods
Call from non-fork/join clients Call from within fork/join computations
Arrange async execution {@link #execute(ForkJoinTask)} {@link ForkJoinTask#fork}
Await and obtain result {@link #invoke(ForkJoinTask)} {@link ForkJoinTask#invoke}
Arrange exec and obtain Future {@link #submit(ForkJoinTask)} {@link ForkJoinTask#fork} (ForkJoinTasks are Futures)
* *

The common pool is by default constructed with default * parameters, but these may be controlled by setting three * {@linkplain System#getProperty system properties}: *

    *
  • {@code java.util.concurrent.ForkJoinPool.common.parallelism} * - the parallelism level, a non-negative integer *
  • {@code java.util.concurrent.ForkJoinPool.common.threadFactory} * - the class name of a {@link ForkJoinWorkerThreadFactory} *
  • {@code java.util.concurrent.ForkJoinPool.common.exceptionHandler} * - the class name of a {@link UncaughtExceptionHandler} *
* The system class loader is used to load these classes. * Upon any error in establishing these settings, default parameters * are used. It is possible to disable or limit the use of threads in * the common pool by setting the parallelism property to zero, and/or * using a factory that may return {@code null}. * *

Implementation notes: This implementation restricts the * maximum number of running threads to 32767. Attempts to create * pools with greater than the maximum number result in * {@code IllegalArgumentException}. * *

This implementation rejects submitted tasks (that is, by throwing * {@link RejectedExecutionException}) only when the pool is shut down * or internal resources have been exhausted. * * @since 1.7 * @author Doug Lea */ public class ForkJoinPool extends AbstractExecutorService { /* * Implementation Overview * * This class and its nested classes provide the main * functionality and control for a set of worker threads: * Submissions from non-FJ threads enter into submission queues. * Workers take these tasks and typically split them into subtasks * that may be stolen by other workers. Preference rules give * first priority to processing tasks from their own queues (LIFO * or FIFO, depending on mode), then to randomized FIFO steals of * tasks in other queues. * * WorkQueues * ========== * * Most operations occur within work-stealing queues (in nested * class WorkQueue). These are special forms of Deques that * support only three of the four possible end-operations -- push, * pop, and poll (aka steal), under the further constraints that * push and pop are called only from the owning thread (or, as * extended here, under a lock), while poll may be called from * other threads. (If you are unfamiliar with them, you probably * want to read Herlihy and Shavit's book "The Art of * Multiprocessor programming", chapter 16 describing these in * more detail before proceeding.) The main work-stealing queue * design is roughly similar to those in the papers "Dynamic * Circular Work-Stealing Deque" by Chase and Lev, SPAA 2005 * (http://research.sun.com/scalable/pubs/index.html) and * "Idempotent work stealing" by Michael, Saraswat, and Vechev, * PPoPP 2009 (http://portal.acm.org/citation.cfm?id=1504186). * See also "Correct and Efficient Work-Stealing for Weak Memory * Models" by Le, Pop, Cohen, and Nardelli, PPoPP 2013 * (http://www.di.ens.fr/~zappa/readings/ppopp13.pdf) for an * analysis of memory ordering (atomic, volatile etc) issues. The * main differences ultimately stem from GC requirements that we * null out taken slots as soon as we can, to maintain as small a * footprint as possible even in programs generating huge numbers * of tasks. To accomplish this, we shift the CAS arbitrating pop * vs poll (steal) from being on the indices ("base" and "top") to * the slots themselves. So, both a successful pop and poll * mainly entail a CAS of a slot from non-null to null. Because * we rely on CASes of references, we do not need tag bits on base * or top. They are simple ints as used in any circular * array-based queue (see for example ArrayDeque). Updates to the * indices must still be ordered in a way that guarantees that top * == base means the queue is empty, but otherwise may err on the * side of possibly making the queue appear nonempty when a push, * pop, or poll have not fully committed. Note that this means * that the poll operation, considered individually, is not * wait-free. One thief cannot successfully continue until another * in-progress one (or, if previously empty, a push) completes. * However, in the aggregate, we ensure at least probabilistic * non-blockingness. If an attempted steal fails, a thief always * chooses a different random victim target to try next. So, in * order for one thief to progress, it suffices for any * in-progress poll or new push on any empty queue to * complete. (This is why we normally use method pollAt and its * variants that try once at the apparent base index, else * consider alternative actions, rather than method poll.) * * This approach also enables support of a user mode in which local * task processing is in FIFO, not LIFO order, simply by using * poll rather than pop. This can be useful in message-passing * frameworks in which tasks are never joined. However neither * mode considers affinities, loads, cache localities, etc, so * rarely provide the best possible performance on a given * machine, but portably provide good throughput by averaging over * these factors. (Further, even if we did try to use such * information, we do not usually have a basis for exploiting it. * For example, some sets of tasks profit from cache affinities, * but others are harmed by cache pollution effects.) * * WorkQueues are also used in a similar way for tasks submitted * to the pool. We cannot mix these tasks in the same queues used * for work-stealing (this would contaminate lifo/fifo * processing). Instead, we randomly associate submission queues * with submitting threads, using a form of hashing. The * Submitter probe value serves as a hash code for * choosing existing queues, and may be randomly repositioned upon * contention with other submitters. In essence, submitters act * like workers except that they are restricted to executing local * tasks that they submitted (or in the case of CountedCompleters, * others with the same root task). However, because most * shared/external queue operations are more expensive than * internal, and because, at steady state, external submitters * will compete for CPU with workers, ForkJoinTask.join and * related methods disable them from repeatedly helping to process * tasks if all workers are active. Insertion of tasks in shared * mode requires a lock (mainly to protect in the case of * resizing) but we use only a simple spinlock (using bits in * field qlock), because submitters encountering a busy queue move * on to try or create other queues -- they block only when * creating and registering new queues. * * Management * ========== * * The main throughput advantages of work-stealing stem from * decentralized control -- workers mostly take tasks from * themselves or each other. We cannot negate this in the * implementation of other management responsibilities. The main * tactic for avoiding bottlenecks is packing nearly all * essentially atomic control state into two volatile variables * that are by far most often read (not written) as status and * consistency checks. * * Field "ctl" contains 64 bits holding all the information needed * to atomically decide to add, inactivate, enqueue (on an event * queue), dequeue, and/or re-activate workers. To enable this * packing, we restrict maximum parallelism to (1<<15)-1 (which is * far in excess of normal operating range) to allow ids, counts, * and their negations (used for thresholding) to fit into 16bit * fields. * * Field "plock" is a form of sequence lock with a saturating * shutdown bit (similarly for per-queue "qlocks"), mainly * protecting updates to the workQueues array, as well as to * enable shutdown. When used as a lock, it is normally only very * briefly held, so is nearly always available after at most a * brief spin, but we use a monitor-based backup strategy to * block when needed. * * Recording WorkQueues. WorkQueues are recorded in the * "workQueues" array that is created upon first use and expanded * if necessary. Updates to the array while recording new workers * and unrecording terminated ones are protected from each other * by a lock but the array is otherwise concurrently readable, and * accessed directly. To simplify index-based operations, the * array size is always a power of two, and all readers must * tolerate null slots. Worker queues are at odd indices. Shared * (submission) queues are at even indices, up to a maximum of 64 * slots, to limit growth even if array needs to expand to add * more workers. Grouping them together in this way simplifies and * speeds up task scanning. * * All worker thread creation is on-demand, triggered by task * submissions, replacement of terminated workers, and/or * compensation for blocked workers. However, all other support * code is set up to work with other policies. To ensure that we * do not hold on to worker references that would prevent GC, ALL * accesses to workQueues are via indices into the workQueues * array (which is one source of some of the messy code * constructions here). In essence, the workQueues array serves as * a weak reference mechanism. Thus for example the wait queue * field of ctl stores indices, not references. Access to the * workQueues in associated methods (for example signalWork) must * both index-check and null-check the IDs. All such accesses * ignore bad IDs by returning out early from what they are doing, * since this can only be associated with termination, in which * case it is OK to give up. All uses of the workQueues array * also check that it is non-null (even if previously * non-null). This allows nulling during termination, which is * currently not necessary, but remains an option for * resource-revocation-based shutdown schemes. It also helps * reduce JIT issuance of uncommon-trap code, which tends to * unnecessarily complicate control flow in some methods. * * Event Queuing. Unlike HPC work-stealing frameworks, we cannot * let workers spin indefinitely scanning for tasks when none can * be found immediately, and we cannot start/resume workers unless * there appear to be tasks available. On the other hand, we must * quickly prod them into action when new tasks are submitted or * generated. In many usages, ramp-up time to activate workers is * the main limiting factor in overall performance (this is * compounded at program start-up by JIT compilation and * allocation). So we try to streamline this as much as possible. * We park/unpark workers after placing in an event wait queue * when they cannot find work. This "queue" is actually a simple * Treiber stack, headed by the "id" field of ctl, plus a 15bit * counter value (that reflects the number of times a worker has * been inactivated) to avoid ABA effects (we need only as many * version numbers as worker threads). Successors are held in * field WorkQueue.nextWait. Queuing deals with several intrinsic * races, mainly that a task-producing thread can miss seeing (and * signalling) another thread that gave up looking for work but * has not yet entered the wait queue. We solve this by requiring * a full sweep of all workers (via repeated calls to method * scan()) both before and after a newly waiting worker is added * to the wait queue. Because enqueued workers may actually be * rescanning rather than waiting, we set and clear the "parker" * field of WorkQueues to reduce unnecessary calls to unpark. * (This requires a secondary recheck to avoid missed signals.) * Note the unusual conventions about Thread.interrupts * surrounding parking and other blocking: Because interrupts are * used solely to alert threads to check termination, which is * checked anyway upon blocking, we clear status (using * Thread.interrupted) before any call to park, so that park does * not immediately return due to status being set via some other * unrelated call to interrupt in user code. * * Signalling. We create or wake up workers only when there * appears to be at least one task they might be able to find and * execute. When a submission is added or another worker adds a * task to a queue that has fewer than two tasks, they signal * waiting workers (or trigger creation of new ones if fewer than * the given parallelism level -- signalWork). These primary * signals are buttressed by others whenever other threads remove * a task from a queue and notice that there are other tasks there * as well. So in general, pools will be over-signalled. On most * platforms, signalling (unpark) overhead time is noticeably * long, and the time between signalling a thread and it actually * making progress can be very noticeably long, so it is worth * offloading these delays from critical paths as much as * possible. Additionally, workers spin-down gradually, by staying * alive so long as they see the ctl state changing. Similar * stability-sensing techniques are also used before blocking in * awaitJoin and helpComplete. * * Trimming workers. To release resources after periods of lack of * use, a worker starting to wait when the pool is quiescent will * time out and terminate if the pool has remained quiescent for a * given period -- a short period if there are more threads than * parallelism, longer as the number of threads decreases. This * will slowly propagate, eventually terminating all workers after * periods of non-use. * * Shutdown and Termination. A call to shutdownNow atomically sets * a plock bit and then (non-atomically) sets each worker's * qlock status, cancels all unprocessed tasks, and wakes up * all waiting workers. Detecting whether termination should * commence after a non-abrupt shutdown() call requires more work * and bookkeeping. We need consensus about quiescence (i.e., that * there is no more work). The active count provides a primary * indication but non-abrupt shutdown still requires a rechecking * scan for any workers that are inactive but not queued. * * Joining Tasks * ============= * * Any of several actions may be taken when one worker is waiting * to join a task stolen (or always held) by another. Because we * are multiplexing many tasks on to a pool of workers, we can't * just let them block (as in Thread.join). We also cannot just * reassign the joiner's run-time stack with another and replace * it later, which would be a form of "continuation", that even if * possible is not necessarily a good idea since we sometimes need * both an unblocked task and its continuation to progress. * Instead we combine two tactics: * * Helping: Arranging for the joiner to execute some task that it * would be running if the steal had not occurred. * * Compensating: Unless there are already enough live threads, * method tryCompensate() may create or re-activate a spare * thread to compensate for blocked joiners until they unblock. * * A third form (implemented in tryRemoveAndExec) amounts to * helping a hypothetical compensator: If we can readily tell that * a possible action of a compensator is to steal and execute the * task being joined, the joining thread can do so directly, * without the need for a compensation thread (although at the * expense of larger run-time stacks, but the tradeoff is * typically worthwhile). * * The ManagedBlocker extension API can't use helping so relies * only on compensation in method awaitBlocker. * * The algorithm in tryHelpStealer entails a form of "linear" * helping: Each worker records (in field currentSteal) the most * recent task it stole from some other worker. Plus, it records * (in field currentJoin) the task it is currently actively * joining. Method tryHelpStealer uses these markers to try to * find a worker to help (i.e., steal back a task from and execute * it) that could hasten completion of the actively joined task. * In essence, the joiner executes a task that would be on its own * local deque had the to-be-joined task not been stolen. This may * be seen as a conservative variant of the approach in Wagner & * Calder "Leapfrogging: a portable technique for implementing * efficient futures" SIGPLAN Notices, 1993 * (http://portal.acm.org/citation.cfm?id=155354). It differs in * that: (1) We only maintain dependency links across workers upon * steals, rather than use per-task bookkeeping. This sometimes * requires a linear scan of workQueues array to locate stealers, * but often doesn't because stealers leave hints (that may become * stale/wrong) of where to locate them. It is only a hint * because a worker might have had multiple steals and the hint * records only one of them (usually the most current). Hinting * isolates cost to when it is needed, rather than adding to * per-task overhead. (2) It is "shallow", ignoring nesting and * potentially cyclic mutual steals. (3) It is intentionally * racy: field currentJoin is updated only while actively joining, * which means that we miss links in the chain during long-lived * tasks, GC stalls etc (which is OK since blocking in such cases * is usually a good idea). (4) We bound the number of attempts * to find work (see MAX_HELP) and fall back to suspending the * worker and if necessary replacing it with another. * * Helping actions for CountedCompleters are much simpler: Method * helpComplete can take and execute any task with the same root * as the task being waited on. However, this still entails some * traversal of completer chains, so is less efficient than using * CountedCompleters without explicit joins. * * It is impossible to keep exactly the target parallelism number * of threads running at any given time. Determining the * existence of conservatively safe helping targets, the * availability of already-created spares, and the apparent need * to create new spares are all racy, so we rely on multiple * retries of each. Compensation in the apparent absence of * helping opportunities is challenging to control on JVMs, where * GC and other activities can stall progress of tasks that in * turn stall out many other dependent tasks, without us being * able to determine whether they will ever require compensation. * Even though work-stealing otherwise encounters little * degradation in the presence of more threads than cores, * aggressively adding new threads in such cases entails risk of * unwanted positive feedback control loops in which more threads * cause more dependent stalls (as well as delayed progress of * unblocked threads to the point that we know they are available) * leading to more situations requiring more threads, and so * on. This aspect of control can be seen as an (analytically * intractable) game with an opponent that may choose the worst * (for us) active thread to stall at any time. We take several * precautions to bound losses (and thus bound gains), mainly in * methods tryCompensate and awaitJoin. * * Common Pool * =========== * * The static common pool always exists after static * initialization. Since it (or any other created pool) need * never be used, we minimize initial construction overhead and * footprint to the setup of about a dozen fields, with no nested * allocation. Most bootstrapping occurs within method * fullExternalPush during the first submission to the pool. * * When external threads submit to the common pool, they can * perform subtask processing (see externalHelpJoin and related * methods). This caller-helps policy makes it sensible to set * common pool parallelism level to one (or more) less than the * total number of available cores, or even zero for pure * caller-runs. We do not need to record whether external * submissions are to the common pool -- if not, externalHelpJoin * returns quickly (at the most helping to signal some common pool * workers). These submitters would otherwise be blocked waiting * for completion, so the extra effort (with liberally sprinkled * task status checks) in inapplicable cases amounts to an odd * form of limited spin-wait before blocking in ForkJoinTask.join. * * Style notes * =========== * * There is a lot of representation-level coupling among classes * ForkJoinPool, ForkJoinWorkerThread, and ForkJoinTask. The * fields of WorkQueue maintain data structures managed by * ForkJoinPool, so are directly accessed. There is little point * trying to reduce this, since any associated future changes in * representations will need to be accompanied by algorithmic * changes anyway. Several methods intrinsically sprawl because * they must accumulate sets of consistent reads of volatiles held * in local variables. Methods signalWork() and scan() are the * main bottlenecks, so are especially heavily * micro-optimized/mangled. There are lots of inline assignments * (of form "while ((local = field) != 0)") which are usually the * simplest way to ensure the required read orderings (which are * sometimes critical). This leads to a "C"-like style of listing * declarations of these locals at the heads of methods or blocks. * There are several occurrences of the unusual "do {} while * (!cas...)" which is the simplest way to force an update of a * CAS'ed variable. There are also other coding oddities (including * several unnecessary-looking hoisted null checks) that help * some methods perform reasonably even when interpreted (not * compiled). * * The order of declarations in this file is: * (1) Static utility functions * (2) Nested (static) classes * (3) Static fields * (4) Fields, along with constants used when unpacking some of them * (5) Internal control methods * (6) Callbacks and other support for ForkJoinTask methods * (7) Exported methods * (8) Static block initializing statics in minimally dependent order */ // Static utilities /** * If there is a security manager, makes sure caller has * permission to modify threads. */ private static void checkPermission() { SecurityManager security = System.getSecurityManager(); if (security != null) security.checkPermission(modifyThreadPermission); } // Nested classes /** * Factory for creating new {@link ForkJoinWorkerThread}s. * A {@code ForkJoinWorkerThreadFactory} must be defined and used * for {@code ForkJoinWorkerThread} subclasses that extend base * functionality or initialize threads with different contexts. */ public static interface ForkJoinWorkerThreadFactory { /** * Returns a new worker thread operating in the given pool. * * @param pool the pool this thread works in * @return the new worker thread * @throws NullPointerException if the pool is null */ public ForkJoinWorkerThread newThread(ForkJoinPool pool); } /** * Default ForkJoinWorkerThreadFactory implementation; creates a * new ForkJoinWorkerThread. */ static final class DefaultForkJoinWorkerThreadFactory implements ForkJoinWorkerThreadFactory { public final ForkJoinWorkerThread newThread(ForkJoinPool pool) { return new ForkJoinWorkerThread(pool); } } /** * Class for artificial tasks that are used to replace the target * of local joins if they are removed from an interior queue slot * in WorkQueue.tryRemoveAndExec. We don't need the proxy to * actually do anything beyond having a unique identity. */ static final class EmptyTask extends ForkJoinTask { private static final long serialVersionUID = -7721805057305804111L; EmptyTask() { status = NORMAL; } // force done public final Void getRawResult() { return null; } public final void setRawResult(Void x) {} public final boolean exec() { return true; } } /** * Queues supporting work-stealing as well as external task * submission. See above for main rationale and algorithms. * Implementation relies heavily on "Unsafe" intrinsics * and selective use of "volatile": * * Field "base" is the index (mod array.length) of the least valid * queue slot, which is always the next position to steal (poll) * from if nonempty. Reads and writes require volatile orderings * but not CAS, because updates are only performed after slot * CASes. * * Field "top" is the index (mod array.length) of the next queue * slot to push to or pop from. It is written only by owner thread * for push, or under lock for external/shared push, and accessed * by other threads only after reading (volatile) base. Both top * and base are allowed to wrap around on overflow, but (top - * base) (or more commonly -(base - top) to force volatile read of * base before top) still estimates size. The lock ("qlock") is * forced to -1 on termination, causing all further lock attempts * to fail. (Note: we don't need CAS for termination state because * upon pool shutdown, all shared-queues will stop being used * anyway.) Nearly all lock bodies are set up so that exceptions * within lock bodies are "impossible" (modulo JVM errors that * would cause failure anyway.) * * The array slots are read and written using the emulation of * volatiles/atomics provided by Unsafe. Insertions must in * general use putOrderedObject as a form of releasing store to * ensure that all writes to the task object are ordered before * its publication in the queue. All removals entail a CAS to * null. The array is always a power of two. To ensure safety of * Unsafe array operations, all accesses perform explicit null * checks and implicit bounds checks via power-of-two masking. * * In addition to basic queuing support, this class contains * fields described elsewhere to control execution. It turns out * to work better memory-layout-wise to include them in this class * rather than a separate class. * * Performance on most platforms is very sensitive to placement of * instances of both WorkQueues and their arrays -- we absolutely * do not want multiple WorkQueue instances or multiple queue * arrays sharing cache lines. (It would be best for queue objects * and their arrays to share, but there is nothing available to * help arrange that). The @Contended annotation alerts JVMs to * try to keep instances apart. */ static final class WorkQueue { /** * Capacity of work-stealing queue array upon initialization. * Must be a power of two; at least 4, but should be larger to * reduce or eliminate cacheline sharing among queues. * Currently, it is much larger, as a partial workaround for * the fact that JVMs often place arrays in locations that * share GC bookkeeping (especially cardmarks) such that * per-write accesses encounter serious memory contention. */ static final int INITIAL_QUEUE_CAPACITY = 1 << 13; /** * Maximum size for queue arrays. Must be a power of two less * than or equal to 1 << (31 - width of array entry) to ensure * lack of wraparound of index calculations, but defined to a * value a bit less than this to help users trap runaway * programs before saturating systems. */ static final int MAXIMUM_QUEUE_CAPACITY = 1 << 26; // 64M // Heuristic padding to ameliorate unfortunate memory placements volatile long pad00, pad01, pad02, pad03, pad04, pad05, pad06; volatile int eventCount; // encoded inactivation count; < 0 if inactive int nextWait; // encoded record of next event waiter int nsteals; // number of steals int hint; // steal index hint short poolIndex; // index of this queue in pool final short mode; // 0: lifo, > 0: fifo, < 0: shared volatile int qlock; // 1: locked, -1: terminate; else 0 volatile int base; // index of next slot for poll int top; // index of next slot for push ForkJoinTask[] array; // the elements (initially unallocated) final ForkJoinPool pool; // the containing pool (may be null) final ForkJoinWorkerThread owner; // owning thread or null if shared volatile Thread parker; // == owner during call to park; else null volatile ForkJoinTask currentJoin; // task being joined in awaitJoin ForkJoinTask currentSteal; // current non-local task being executed volatile Object pad10, pad11, pad12, pad13, pad14, pad15, pad16, pad17; volatile Object pad18, pad19, pad1a, pad1b, pad1c, pad1d; WorkQueue(ForkJoinPool pool, ForkJoinWorkerThread owner, int mode, int seed) { this.pool = pool; this.owner = owner; this.mode = (short)mode; this.hint = seed; // store initial seed for runWorker // Place indices in the center of array (that is not yet allocated) base = top = INITIAL_QUEUE_CAPACITY >>> 1; } /** * Returns the approximate number of tasks in the queue. */ final int queueSize() { int n = base - top; // non-owner callers must read base first return (n >= 0) ? 0 : -n; // ignore transient negative } /** * Provides a more accurate estimate of whether this queue has * any tasks than does queueSize, by checking whether a * near-empty queue has at least one unclaimed task. */ final boolean isEmpty() { ForkJoinTask[] a; int m, s; int n = base - (s = top); return (n >= 0 || (n == -1 && ((a = array) == null || (m = a.length - 1) < 0 || U.getObject (a, (long)((m & (s - 1)) << ASHIFT) + ABASE) == null))); } /** * Pushes a task. Call only by owner in unshared queues. (The * shared-queue version is embedded in method externalPush.) * * @param task the task. Caller must ensure non-null. * @throws RejectedExecutionException if array cannot be resized */ final void push(ForkJoinTask task) { ForkJoinTask[] a; ForkJoinPool p; int s = top, n; if ((a = array) != null) { // ignore if queue removed int m = a.length - 1; U.putOrderedObject(a, ((m & s) << ASHIFT) + ABASE, task); if ((n = (top = s + 1) - base) <= 2) (p = pool).signalWork(p.workQueues, this); else if (n >= m) growArray(); } } /** * Initializes or doubles the capacity of array. Call either * by owner or with lock held -- it is OK for base, but not * top, to move while resizings are in progress. */ final ForkJoinTask[] growArray() { ForkJoinTask[] oldA = array; int size = oldA != null ? oldA.length << 1 : INITIAL_QUEUE_CAPACITY; if (size > MAXIMUM_QUEUE_CAPACITY) throw new RejectedExecutionException("Queue capacity exceeded"); int oldMask, t, b; ForkJoinTask[] a = array = new ForkJoinTask[size]; if (oldA != null && (oldMask = oldA.length - 1) >= 0 && (t = top) - (b = base) > 0) { int mask = size - 1; do { ForkJoinTask x; int oldj = ((b & oldMask) << ASHIFT) + ABASE; int j = ((b & mask) << ASHIFT) + ABASE; x = (ForkJoinTask)U.getObjectVolatile(oldA, oldj); if (x != null && U.compareAndSwapObject(oldA, oldj, x, null)) U.putObjectVolatile(a, j, x); } while (++b != t); } return a; } /** * Takes next task, if one exists, in LIFO order. Call only * by owner in unshared queues. */ final ForkJoinTask pop() { ForkJoinTask[] a; ForkJoinTask t; int m; if ((a = array) != null && (m = a.length - 1) >= 0) { for (int s; (s = top - 1) - base >= 0;) { long j = ((m & s) << ASHIFT) + ABASE; if ((t = (ForkJoinTask)U.getObject(a, j)) == null) break; if (U.compareAndSwapObject(a, j, t, null)) { top = s; return t; } } } return null; } /** * Takes a task in FIFO order if b is base of queue and a task * can be claimed without contention. Specialized versions * appear in ForkJoinPool methods scan and tryHelpStealer. */ final ForkJoinTask pollAt(int b) { ForkJoinTask t; ForkJoinTask[] a; if ((a = array) != null) { int j = (((a.length - 1) & b) << ASHIFT) + ABASE; if ((t = (ForkJoinTask)U.getObjectVolatile(a, j)) != null && base == b && U.compareAndSwapObject(a, j, t, null)) { U.putOrderedInt(this, QBASE, b + 1); return t; } } return null; } /** * Takes next task, if one exists, in FIFO order. */ final ForkJoinTask poll() { ForkJoinTask[] a; int b; ForkJoinTask t; while ((b = base) - top < 0 && (a = array) != null) { int j = (((a.length - 1) & b) << ASHIFT) + ABASE; t = (ForkJoinTask)U.getObjectVolatile(a, j); if (t != null) { if (U.compareAndSwapObject(a, j, t, null)) { U.putOrderedInt(this, QBASE, b + 1); return t; } } else if (base == b) { if (b + 1 == top) break; Thread.yield(); // wait for lagging update (very rare) } } return null; } /** * Takes next task, if one exists, in order specified by mode. */ final ForkJoinTask nextLocalTask() { return mode == 0 ? pop() : poll(); } /** * Returns next task, if one exists, in order specified by mode. */ final ForkJoinTask peek() { ForkJoinTask[] a = array; int m; if (a == null || (m = a.length - 1) < 0) return null; int i = mode == 0 ? top - 1 : base; int j = ((i & m) << ASHIFT) + ABASE; return (ForkJoinTask)U.getObjectVolatile(a, j); } /** * Pops the given task only if it is at the current top. * (A shared version is available only via FJP.tryExternalUnpush) */ final boolean tryUnpush(ForkJoinTask t) { ForkJoinTask[] a; int s; if ((a = array) != null && (s = top) != base && U.compareAndSwapObject (a, (((a.length - 1) & --s) << ASHIFT) + ABASE, t, null)) { top = s; return true; } return false; } /** * Removes and cancels all known tasks, ignoring any exceptions. */ final void cancelAll() { ForkJoinTask.cancelIgnoringExceptions(currentJoin); ForkJoinTask.cancelIgnoringExceptions(currentSteal); for (ForkJoinTask t; (t = poll()) != null; ) ForkJoinTask.cancelIgnoringExceptions(t); } // Specialized execution methods /** * Polls and runs tasks until empty. */ final void pollAndExecAll() { for (ForkJoinTask t; (t = poll()) != null;) t.doExec(); } /** * Executes a top-level task and any local tasks remaining * after execution. */ final void runTask(ForkJoinTask task) { if ((currentSteal = task) != null) { task.doExec(); ForkJoinTask[] a = array; int md = mode; ++nsteals; currentSteal = null; if (md != 0) pollAndExecAll(); else if (a != null) { int s, m = a.length - 1; while ((s = top - 1) - base >= 0) { long i = ((m & s) << ASHIFT) + ABASE; ForkJoinTask t = (ForkJoinTask)U.getObject(a, i); if (t == null) break; if (U.compareAndSwapObject(a, i, t, null)) { top = s; t.doExec(); } } } } } /** * If present, removes from queue and executes the given task, * or any other cancelled task. Returns (true) on any CAS * or consistency check failure so caller can retry. * * @return false if no progress can be made, else true */ final boolean tryRemoveAndExec(ForkJoinTask task) { boolean stat; ForkJoinTask[] a; int m, s, b, n; if (task != null && (a = array) != null && (m = a.length - 1) >= 0 && (n = (s = top) - (b = base)) > 0) { boolean removed = false, empty = true; stat = true; for (ForkJoinTask t;;) { // traverse from s to b long j = ((--s & m) << ASHIFT) + ABASE; t = (ForkJoinTask)U.getObject(a, j); if (t == null) // inconsistent length break; else if (t == task) { if (s + 1 == top) { // pop if (!U.compareAndSwapObject(a, j, task, null)) break; top = s; removed = true; } else if (base == b) // replace with proxy removed = U.compareAndSwapObject(a, j, task, new EmptyTask()); break; } else if (t.status >= 0) empty = false; else if (s + 1 == top) { // pop and throw away if (U.compareAndSwapObject(a, j, t, null)) top = s; break; } if (--n == 0) { if (!empty && base == b) stat = false; break; } } if (removed) task.doExec(); } else stat = false; return stat; } /** * Tries to poll for and execute the given task or any other * task in its CountedCompleter computation. */ final boolean pollAndExecCC(CountedCompleter root) { ForkJoinTask[] a; int b; Object o; CountedCompleter t, r; if ((b = base) - top < 0 && (a = array) != null) { long j = (((a.length - 1) & b) << ASHIFT) + ABASE; if ((o = U.getObjectVolatile(a, j)) == null) return true; // retry if (o instanceof CountedCompleter) { for (t = (CountedCompleter)o, r = t;;) { if (r == root) { if (base == b && U.compareAndSwapObject(a, j, t, null)) { U.putOrderedInt(this, QBASE, b + 1); t.doExec(); } return true; } else if ((r = r.completer) == null) break; // not part of root computation } } } return false; } /** * Tries to pop and execute the given task or any other task * in its CountedCompleter computation. */ final boolean externalPopAndExecCC(CountedCompleter root) { ForkJoinTask[] a; int s; Object o; CountedCompleter t, r; if (base - (s = top) < 0 && (a = array) != null) { long j = (((a.length - 1) & (s - 1)) << ASHIFT) + ABASE; if ((o = U.getObject(a, j)) instanceof CountedCompleter) { for (t = (CountedCompleter)o, r = t;;) { if (r == root) { if (U.compareAndSwapInt(this, QLOCK, 0, 1)) { if (top == s && array == a && U.compareAndSwapObject(a, j, t, null)) { top = s - 1; qlock = 0; t.doExec(); } else qlock = 0; } return true; } else if ((r = r.completer) == null) break; } } } return false; } /** * Internal version */ final boolean internalPopAndExecCC(CountedCompleter root) { ForkJoinTask[] a; int s; Object o; CountedCompleter t, r; if (base - (s = top) < 0 && (a = array) != null) { long j = (((a.length - 1) & (s - 1)) << ASHIFT) + ABASE; if ((o = U.getObject(a, j)) instanceof CountedCompleter) { for (t = (CountedCompleter)o, r = t;;) { if (r == root) { if (U.compareAndSwapObject(a, j, t, null)) { top = s - 1; t.doExec(); } return true; } else if ((r = r.completer) == null) break; } } } return false; } /** * Returns true if owned and not known to be blocked. */ final boolean isApparentlyUnblocked() { Thread wt; Thread.State s; return (eventCount >= 0 && (wt = owner) != null && (s = wt.getState()) != Thread.State.BLOCKED && s != Thread.State.WAITING && s != Thread.State.TIMED_WAITING); } // Unsafe mechanics private static final sun.misc.Unsafe U; private static final long QBASE; private static final long QLOCK; private static final int ABASE; private static final int ASHIFT; static { try { U = getUnsafe(); Class k = WorkQueue.class; Class ak = ForkJoinTask[].class; QBASE = U.objectFieldOffset (k.getDeclaredField("base")); QLOCK = U.objectFieldOffset (k.getDeclaredField("qlock")); ABASE = U.arrayBaseOffset(ak); int scale = U.arrayIndexScale(ak); if ((scale & (scale - 1)) != 0) throw new Error("data type scale not a power of two"); ASHIFT = 31 - Integer.numberOfLeadingZeros(scale); } catch (Exception e) { throw new Error(e); } } } // static fields (initialized in static initializer below) /** * Per-thread submission bookkeeping. Shared across all pools * to reduce ThreadLocal pollution and because random motion * to avoid contention in one pool is likely to hold for others. * Lazily initialized on first submission (but null-checked * in other contexts to avoid unnecessary initialization). */ static final ThreadLocal submitters; /** * Creates a new ForkJoinWorkerThread. This factory is used unless * overridden in ForkJoinPool constructors. */ public static final ForkJoinWorkerThreadFactory defaultForkJoinWorkerThreadFactory; /** * Permission required for callers of methods that may start or * kill threads. */ private static final RuntimePermission modifyThreadPermission; /** * Common (static) pool. Non-null for public use unless a static * construction exception, but internal usages null-check on use * to paranoically avoid potential initialization circularities * as well as to simplify generated code. */ static final ForkJoinPool common; /** * Common pool parallelism. To allow simpler use and management * when common pool threads are disabled, we allow the underlying * common.parallelism field to be zero, but in that case still report * parallelism as 1 to reflect resulting caller-runs mechanics. */ static final int commonParallelism; /** * Sequence number for creating workerNamePrefix. */ private static int poolNumberSequence; /** * Returns the next sequence number. We don't expect this to * ever contend, so use simple builtin sync. */ private static final synchronized int nextPoolId() { return ++poolNumberSequence; } // static constants /** * Initial timeout value (in nanoseconds) for the thread * triggering quiescence to park waiting for new work. On timeout, * the thread will instead try to shrink the number of * workers. The value should be large enough to avoid overly * aggressive shrinkage during most transient stalls (long GCs * etc). */ private static final long IDLE_TIMEOUT = 2000L * 1000L * 1000L; // 2sec /** * Timeout value when there are more threads than parallelism level */ private static final long FAST_IDLE_TIMEOUT = 200L * 1000L * 1000L; /** * Tolerance for idle timeouts, to cope with timer undershoots */ private static final long TIMEOUT_SLOP = 2000000L; /** * The maximum stolen->joining link depth allowed in method * tryHelpStealer. Must be a power of two. Depths for legitimate * chains are unbounded, but we use a fixed constant to avoid * (otherwise unchecked) cycles and to bound staleness of * traversal parameters at the expense of sometimes blocking when * we could be helping. */ private static final int MAX_HELP = 64; /** * Increment for seed generators. See class ThreadLocal for * explanation. */ private static final int SEED_INCREMENT = 0x61c88647; /* * Bits and masks for control variables * * Field ctl is a long packed with: * AC: Number of active running workers minus target parallelism (16 bits) * TC: Number of total workers minus target parallelism (16 bits) * ST: true if pool is terminating (1 bit) * EC: the wait count of top waiting thread (15 bits) * ID: poolIndex of top of Treiber stack of waiters (16 bits) * * When convenient, we can extract the upper 32 bits of counts and * the lower 32 bits of queue state, u = (int)(ctl >>> 32) and e = * (int)ctl. The ec field is never accessed alone, but always * together with id and st. The offsets of counts by the target * parallelism and the positionings of fields makes it possible to * perform the most common checks via sign tests of fields: When * ac is negative, there are not enough active workers, when tc is * negative, there are not enough total workers, and when e is * negative, the pool is terminating. To deal with these possibly * negative fields, we use casts in and out of "short" and/or * signed shifts to maintain signedness. * * When a thread is queued (inactivated), its eventCount field is * set negative, which is the only way to tell if a worker is * prevented from executing tasks, even though it must continue to * scan for them to avoid queuing races. Note however that * eventCount updates lag releases so usage requires care. * * Field plock is an int packed with: * SHUTDOWN: true if shutdown is enabled (1 bit) * SEQ: a sequence lock, with PL_LOCK bit set if locked (30 bits) * SIGNAL: set when threads may be waiting on the lock (1 bit) * * The sequence number enables simple consistency checks: * Staleness of read-only operations on the workQueues array can * be checked by comparing plock before vs after the reads. */ // bit positions/shifts for fields private static final int AC_SHIFT = 48; private static final int TC_SHIFT = 32; private static final int ST_SHIFT = 31; private static final int EC_SHIFT = 16; // bounds private static final int SMASK = 0xffff; // short bits private static final int MAX_CAP = 0x7fff; // max #workers - 1 private static final int EVENMASK = 0xfffe; // even short bits private static final int SQMASK = 0x007e; // max 64 (even) slots private static final int SHORT_SIGN = 1 << 15; private static final int INT_SIGN = 1 << 31; // masks private static final long STOP_BIT = 0x0001L << ST_SHIFT; private static final long AC_MASK = ((long)SMASK) << AC_SHIFT; private static final long TC_MASK = ((long)SMASK) << TC_SHIFT; // units for incrementing and decrementing private static final long TC_UNIT = 1L << TC_SHIFT; private static final long AC_UNIT = 1L << AC_SHIFT; // masks and units for dealing with u = (int)(ctl >>> 32) private static final int UAC_SHIFT = AC_SHIFT - 32; private static final int UTC_SHIFT = TC_SHIFT - 32; private static final int UAC_MASK = SMASK << UAC_SHIFT; private static final int UTC_MASK = SMASK << UTC_SHIFT; private static final int UAC_UNIT = 1 << UAC_SHIFT; private static final int UTC_UNIT = 1 << UTC_SHIFT; // masks and units for dealing with e = (int)ctl private static final int E_MASK = 0x7fffffff; // no STOP_BIT private static final int E_SEQ = 1 << EC_SHIFT; // plock bits private static final int SHUTDOWN = 1 << 31; private static final int PL_LOCK = 2; private static final int PL_SIGNAL = 1; private static final int PL_SPINS = 1 << 8; // access mode for WorkQueue static final int LIFO_QUEUE = 0; static final int FIFO_QUEUE = 1; static final int SHARED_QUEUE = -1; // Heuristic padding to ameliorate unfortunate memory placements volatile long pad00, pad01, pad02, pad03, pad04, pad05, pad06; // Instance fields volatile long stealCount; // collects worker counts volatile long ctl; // main pool control volatile int plock; // shutdown status and seqLock volatile int indexSeed; // worker/submitter index seed final short parallelism; // parallelism level final short mode; // LIFO/FIFO WorkQueue[] workQueues; // main registry final ForkJoinWorkerThreadFactory factory; final UncaughtExceptionHandler ueh; // per-worker UEH final String workerNamePrefix; // to create worker name string volatile Object pad10, pad11, pad12, pad13, pad14, pad15, pad16, pad17; volatile Object pad18, pad19, pad1a, pad1b; /** * Acquires the plock lock to protect worker array and related * updates. This method is called only if an initial CAS on plock * fails. This acts as a spinlock for normal cases, but falls back * to builtin monitor to block when (rarely) needed. This would be * a terrible idea for a highly contended lock, but works fine as * a more conservative alternative to a pure spinlock. */ private int acquirePlock() { int spins = PL_SPINS, ps, nps; for (;;) { if (((ps = plock) & PL_LOCK) == 0 && U.compareAndSwapInt(this, PLOCK, ps, nps = ps + PL_LOCK)) return nps; else if (spins >= 0) { if (ThreadLocalRandom.current().nextInt() >= 0) --spins; } else if (U.compareAndSwapInt(this, PLOCK, ps, ps | PL_SIGNAL)) { synchronized (this) { if ((plock & PL_SIGNAL) != 0) { try { wait(); } catch (InterruptedException ie) { try { Thread.currentThread().interrupt(); } catch (SecurityException ignore) { } } } else notifyAll(); } } } } /** * Unlocks and signals any thread waiting for plock. Called only * when CAS of seq value for unlock fails. */ private void releasePlock(int ps) { plock = ps; synchronized (this) { notifyAll(); } } /** * Tries to create and start one worker if fewer than target * parallelism level exist. Adjusts counts etc on failure. */ private void tryAddWorker() { long c; int u, e; while ((u = (int)((c = ctl) >>> 32)) < 0 && (u & SHORT_SIGN) != 0 && (e = (int)c) >= 0) { long nc = ((long)(((u + UTC_UNIT) & UTC_MASK) | ((u + UAC_UNIT) & UAC_MASK)) << 32) | (long)e; if (U.compareAndSwapLong(this, CTL, c, nc)) { ForkJoinWorkerThreadFactory fac; Throwable ex = null; ForkJoinWorkerThread wt = null; try { if ((fac = factory) != null && (wt = fac.newThread(this)) != null) { wt.start(); break; } } catch (Throwable rex) { ex = rex; } deregisterWorker(wt, ex); break; } } } // Registering and deregistering workers /** * Callback from ForkJoinWorkerThread to establish and record its * WorkQueue. To avoid scanning bias due to packing entries in * front of the workQueues array, we treat the array as a simple * power-of-two hash table using per-thread seed as hash, * expanding as needed. * * @param wt the worker thread * @return the worker's queue */ final WorkQueue registerWorker(ForkJoinWorkerThread wt) { UncaughtExceptionHandler handler; WorkQueue[] ws; int s, ps; wt.setDaemon(true); if ((handler = ueh) != null) wt.setUncaughtExceptionHandler(handler); do {} while (!U.compareAndSwapInt(this, INDEXSEED, s = indexSeed, s += SEED_INCREMENT) || s == 0); // skip 0 WorkQueue w = new WorkQueue(this, wt, mode, s); if (((ps = plock) & PL_LOCK) != 0 || !U.compareAndSwapInt(this, PLOCK, ps, ps += PL_LOCK)) ps = acquirePlock(); int nps = (ps & SHUTDOWN) | ((ps + PL_LOCK) & ~SHUTDOWN); try { if ((ws = workQueues) != null) { // skip if shutting down int n = ws.length, m = n - 1; int r = (s << 1) | 1; // use odd-numbered indices if (ws[r &= m] != null) { // collision int probes = 0; // step by approx half size int step = (n <= 4) ? 2 : ((n >>> 1) & EVENMASK) + 2; while (ws[r = (r + step) & m] != null) { if (++probes >= n) { workQueues = ws = Arrays.copyOf(ws, n <<= 1); m = n - 1; probes = 0; } } } w.poolIndex = (short)r; w.eventCount = r; // volatile write orders ws[r] = w; } } finally { if (!U.compareAndSwapInt(this, PLOCK, ps, nps)) releasePlock(nps); } wt.setName(workerNamePrefix.concat(Integer.toString(w.poolIndex >>> 1))); return w; } /** * Final callback from terminating worker, as well as upon failure * to construct or start a worker. Removes record of worker from * array, and adjusts counts. If pool is shutting down, tries to * complete termination. * * @param wt the worker thread, or null if construction failed * @param ex the exception causing failure, or null if none */ final void deregisterWorker(ForkJoinWorkerThread wt, Throwable ex) { WorkQueue w = null; if (wt != null && (w = wt.workQueue) != null) { int ps; long sc; w.qlock = -1; // ensure set do {} while (!U.compareAndSwapLong(this, STEALCOUNT, sc = stealCount, sc + w.nsteals)); if (((ps = plock) & PL_LOCK) != 0 || !U.compareAndSwapInt(this, PLOCK, ps, ps += PL_LOCK)) ps = acquirePlock(); int nps = (ps & SHUTDOWN) | ((ps + PL_LOCK) & ~SHUTDOWN); try { int idx = w.poolIndex; WorkQueue[] ws = workQueues; if (ws != null && idx >= 0 && idx < ws.length && ws[idx] == w) ws[idx] = null; } finally { if (!U.compareAndSwapInt(this, PLOCK, ps, nps)) releasePlock(nps); } } long c; // adjust ctl counts do {} while (!U.compareAndSwapLong (this, CTL, c = ctl, (((c - AC_UNIT) & AC_MASK) | ((c - TC_UNIT) & TC_MASK) | (c & ~(AC_MASK|TC_MASK))))); if (!tryTerminate(false, false) && w != null && w.array != null) { w.cancelAll(); // cancel remaining tasks WorkQueue[] ws; WorkQueue v; Thread p; int u, i, e; while ((u = (int)((c = ctl) >>> 32)) < 0 && (e = (int)c) >= 0) { if (e > 0) { // activate or create replacement if ((ws = workQueues) == null || (i = e & SMASK) >= ws.length || (v = ws[i]) == null) break; long nc = (((long)(v.nextWait & E_MASK)) | ((long)(u + UAC_UNIT) << 32)); if (v.eventCount != (e | INT_SIGN)) break; if (U.compareAndSwapLong(this, CTL, c, nc)) { v.eventCount = (e + E_SEQ) & E_MASK; if ((p = v.parker) != null) U.unpark(p); break; } } else { if ((short)u < 0) tryAddWorker(); break; } } } if (ex == null) // help clean refs on way out ForkJoinTask.helpExpungeStaleExceptions(); else // rethrow ForkJoinTask.rethrow(ex); } // Submissions /** * Per-thread records for threads that submit to pools. Currently * holds only pseudo-random seed / index that is used to choose * submission queues in method externalPush. In the future, this may * also incorporate a means to implement different task rejection * and resubmission policies. * * Seeds for submitters and workers/workQueues work in basically * the same way but are initialized and updated using slightly * different mechanics. Both are initialized using the same * approach as in class ThreadLocal, where successive values are * unlikely to collide with previous values. Seeds are then * randomly modified upon collisions using xorshifts, which * requires a non-zero seed. */ static final class Submitter { int seed; Submitter(int s) { seed = s; } } /** * Unless shutting down, adds the given task to a submission queue * at submitter's current queue index (modulo submission * range). Only the most common path is directly handled in this * method. All others are relayed to fullExternalPush. * * @param task the task. Caller must ensure non-null. */ final void externalPush(ForkJoinTask task) { Submitter z = submitters.get(); WorkQueue q; int r, m, s, n, am; ForkJoinTask[] a; int ps = plock; WorkQueue[] ws = workQueues; if (z != null && ps > 0 && ws != null && (m = (ws.length - 1)) >= 0 && (q = ws[m & (r = z.seed) & SQMASK]) != null && r != 0 && U.compareAndSwapInt(q, QLOCK, 0, 1)) { // lock if ((a = q.array) != null && (am = a.length - 1) > (n = (s = q.top) - q.base)) { int j = ((am & s) << ASHIFT) + ABASE; U.putOrderedObject(a, j, task); q.top = s + 1; // push on to deque q.qlock = 0; if (n <= 1) signalWork(ws, q); return; } q.qlock = 0; } fullExternalPush(task); } /** * Full version of externalPush. This method is called, among * other times, upon the first submission of the first task to the * pool, so must perform secondary initialization. It also * detects first submission by an external thread by looking up * its ThreadLocal, and creates a new shared queue if the one at * index if empty or contended. The plock lock body must be * exception-free (so no try/finally) so we optimistically * allocate new queues outside the lock and throw them away if * (very rarely) not needed. * * Secondary initialization occurs when plock is zero, to create * workQueue array and set plock to a valid value. This lock body * must also be exception-free. Because the plock seq value can * eventually wrap around zero, this method harmlessly fails to * reinitialize if workQueues exists, while still advancing plock. */ private void fullExternalPush(ForkJoinTask task) { int r = 0; // random index seed for (Submitter z = submitters.get();;) { WorkQueue[] ws; WorkQueue q; int ps, m, k; if (z == null) { if (U.compareAndSwapInt(this, INDEXSEED, r = indexSeed, r += SEED_INCREMENT) && r != 0) submitters.set(z = new Submitter(r)); } else if (r == 0) { // move to a different index r = z.seed; r ^= r << 13; // same xorshift as WorkQueues r ^= r >>> 17; z.seed = r ^= (r << 5); } if ((ps = plock) < 0) throw new RejectedExecutionException(); else if (ps == 0 || (ws = workQueues) == null || (m = ws.length - 1) < 0) { // initialize workQueues int p = parallelism; // find power of two table size int n = (p > 1) ? p - 1 : 1; // ensure at least 2 slots n |= n >>> 1; n |= n >>> 2; n |= n >>> 4; n |= n >>> 8; n |= n >>> 16; n = (n + 1) << 1; WorkQueue[] nws = ((ws = workQueues) == null || ws.length == 0 ? new WorkQueue[n] : null); if (((ps = plock) & PL_LOCK) != 0 || !U.compareAndSwapInt(this, PLOCK, ps, ps += PL_LOCK)) ps = acquirePlock(); if (((ws = workQueues) == null || ws.length == 0) && nws != null) workQueues = nws; int nps = (ps & SHUTDOWN) | ((ps + PL_LOCK) & ~SHUTDOWN); if (!U.compareAndSwapInt(this, PLOCK, ps, nps)) releasePlock(nps); } else if ((q = ws[k = r & m & SQMASK]) != null) { if (q.qlock == 0 && U.compareAndSwapInt(q, QLOCK, 0, 1)) { ForkJoinTask[] a = q.array; int s = q.top; boolean submitted = false; try { // locked version of push if ((a != null && a.length > s + 1 - q.base) || (a = q.growArray()) != null) { // must presize int j = (((a.length - 1) & s) << ASHIFT) + ABASE; U.putOrderedObject(a, j, task); q.top = s + 1; submitted = true; } } finally { q.qlock = 0; // unlock } if (submitted) { signalWork(ws, q); return; } } r = 0; // move on failure } else if (((ps = plock) & PL_LOCK) == 0) { // create new queue q = new WorkQueue(this, null, SHARED_QUEUE, r); q.poolIndex = (short)k; if (((ps = plock) & PL_LOCK) != 0 || !U.compareAndSwapInt(this, PLOCK, ps, ps += PL_LOCK)) ps = acquirePlock(); if ((ws = workQueues) != null && k < ws.length && ws[k] == null) ws[k] = q; int nps = (ps & SHUTDOWN) | ((ps + PL_LOCK) & ~SHUTDOWN); if (!U.compareAndSwapInt(this, PLOCK, ps, nps)) releasePlock(nps); } else r = 0; } } // Maintaining ctl counts /** * Increments active count; mainly called upon return from blocking. */ final void incrementActiveCount() { long c; do {} while (!U.compareAndSwapLong (this, CTL, c = ctl, ((c & ~AC_MASK) | ((c & AC_MASK) + AC_UNIT)))); } /** * Tries to create or activate a worker if too few are active. * * @param ws the worker array to use to find signallees * @param q if non-null, the queue holding tasks to be processed */ final void signalWork(WorkQueue[] ws, WorkQueue q) { for (;;) { long c; int e, u, i; WorkQueue w; Thread p; if ((u = (int)((c = ctl) >>> 32)) >= 0) break; if ((e = (int)c) <= 0) { if ((short)u < 0) tryAddWorker(); break; } if (ws == null || ws.length <= (i = e & SMASK) || (w = ws[i]) == null) break; long nc = (((long)(w.nextWait & E_MASK)) | ((long)(u + UAC_UNIT)) << 32); int ne = (e + E_SEQ) & E_MASK; if (w.eventCount == (e | INT_SIGN) && U.compareAndSwapLong(this, CTL, c, nc)) { w.eventCount = ne; if ((p = w.parker) != null) U.unpark(p); break; } if (q != null && q.base >= q.top) break; } } // Scanning for tasks /** * Top-level runloop for workers, called by ForkJoinWorkerThread.run. */ final void runWorker(WorkQueue w) { w.growArray(); // allocate queue for (int r = w.hint; scan(w, r) == 0; ) { r ^= r << 13; r ^= r >>> 17; r ^= r << 5; // xorshift } } /** * Scans for and, if found, runs one task, else possibly * inactivates the worker. This method operates on single reads of * volatile state and is designed to be re-invoked continuously, * in part because it returns upon detecting inconsistencies, * contention, or state changes that indicate possible success on * re-invocation. * * The scan searches for tasks across queues starting at a random * index, checking each at least twice. The scan terminates upon * either finding a non-empty queue, or completing the sweep. If * the worker is not inactivated, it takes and runs a task from * this queue. Otherwise, if not activated, it tries to activate * itself or some other worker by signalling. On failure to find a * task, returns (for retry) if pool state may have changed during * an empty scan, or tries to inactivate if active, else possibly * blocks or terminates via method awaitWork. * * @param w the worker (via its WorkQueue) * @param r a random seed * @return worker qlock status if would have waited, else 0 */ private final int scan(WorkQueue w, int r) { WorkQueue[] ws; int m; long c = ctl; // for consistency check if ((ws = workQueues) != null && (m = ws.length - 1) >= 0 && w != null) { for (int j = m + m + 1, ec = w.eventCount;;) { WorkQueue q; int b, e; ForkJoinTask[] a; ForkJoinTask t; if ((q = ws[(r - j) & m]) != null && (b = q.base) - q.top < 0 && (a = q.array) != null) { long i = (((a.length - 1) & b) << ASHIFT) + ABASE; if ((t = ((ForkJoinTask) U.getObjectVolatile(a, i))) != null) { if (ec < 0) helpRelease(c, ws, w, q, b); else if (q.base == b && U.compareAndSwapObject(a, i, t, null)) { U.putOrderedInt(q, QBASE, b + 1); if ((b + 1) - q.top < 0) signalWork(ws, q); w.runTask(t); } } break; } else if (--j < 0) { if ((ec | (e = (int)c)) < 0) // inactive or terminating return awaitWork(w, c, ec); else if (ctl == c) { // try to inactivate and enqueue long nc = (long)ec | ((c - AC_UNIT) & (AC_MASK|TC_MASK)); w.nextWait = e; w.eventCount = ec | INT_SIGN; if (!U.compareAndSwapLong(this, CTL, c, nc)) w.eventCount = ec; // back out } break; } } } return 0; } /** * A continuation of scan(), possibly blocking or terminating * worker w. Returns without blocking if pool state has apparently * changed since last invocation. Also, if inactivating w has * caused the pool to become quiescent, checks for pool * termination, and, so long as this is not the only worker, waits * for event for up to a given duration. On timeout, if ctl has * not changed, terminates the worker, which will in turn wake up * another worker to possibly repeat this process. * * @param w the calling worker * @param c the ctl value on entry to scan * @param ec the worker's eventCount on entry to scan */ private final int awaitWork(WorkQueue w, long c, int ec) { int stat, ns; long parkTime, deadline; if ((stat = w.qlock) >= 0 && w.eventCount == ec && ctl == c && !Thread.interrupted()) { int e = (int)c; int u = (int)(c >>> 32); int d = (u >> UAC_SHIFT) + parallelism; // active count if (e < 0 || (d <= 0 && tryTerminate(false, false))) stat = w.qlock = -1; // pool is terminating else if ((ns = w.nsteals) != 0) { // collect steals and retry long sc; w.nsteals = 0; do {} while (!U.compareAndSwapLong(this, STEALCOUNT, sc = stealCount, sc + ns)); } else { long pc = ((d > 0 || ec != (e | INT_SIGN)) ? 0L : ((long)(w.nextWait & E_MASK)) | // ctl to restore ((long)(u + UAC_UNIT)) << 32); if (pc != 0L) { // timed wait if last waiter int dc = -(short)(c >>> TC_SHIFT); parkTime = (dc < 0 ? FAST_IDLE_TIMEOUT: (dc + 1) * IDLE_TIMEOUT); deadline = System.nanoTime() + parkTime - TIMEOUT_SLOP; } else parkTime = deadline = 0L; if (w.eventCount == ec && ctl == c) { Thread wt = Thread.currentThread(); U.putObject(wt, PARKBLOCKER, this); w.parker = wt; // emulate LockSupport.park if (w.eventCount == ec && ctl == c) U.park(false, parkTime); // must recheck before park w.parker = null; U.putObject(wt, PARKBLOCKER, null); if (parkTime != 0L && ctl == c && deadline - System.nanoTime() <= 0L && U.compareAndSwapLong(this, CTL, c, pc)) stat = w.qlock = -1; // shrink pool } } } return stat; } /** * Possibly releases (signals) a worker. Called only from scan() * when a worker with apparently inactive status finds a non-empty * queue. This requires revalidating all of the associated state * from caller. */ private final void helpRelease(long c, WorkQueue[] ws, WorkQueue w, WorkQueue q, int b) { WorkQueue v; int e, i; Thread p; if (w != null && w.eventCount < 0 && (e = (int)c) > 0 && ws != null && ws.length > (i = e & SMASK) && (v = ws[i]) != null && ctl == c) { long nc = (((long)(v.nextWait & E_MASK)) | ((long)((int)(c >>> 32) + UAC_UNIT)) << 32); int ne = (e + E_SEQ) & E_MASK; if (q != null && q.base == b && w.eventCount < 0 && v.eventCount == (e | INT_SIGN) && U.compareAndSwapLong(this, CTL, c, nc)) { v.eventCount = ne; if ((p = v.parker) != null) U.unpark(p); } } } /** * Tries to locate and execute tasks for a stealer of the given * task, or in turn one of its stealers, Traces currentSteal -> * currentJoin links looking for a thread working on a descendant * of the given task and with a non-empty queue to steal back and * execute tasks from. The first call to this method upon a * waiting join will often entail scanning/search, (which is OK * because the joiner has nothing better to do), but this method * leaves hints in workers to speed up subsequent calls. The * implementation is very branchy to cope with potential * inconsistencies or loops encountering chains that are stale, * unknown, or so long that they are likely cyclic. * * @param joiner the joining worker * @param task the task to join * @return 0 if no progress can be made, negative if task * known complete, else positive */ private int tryHelpStealer(WorkQueue joiner, ForkJoinTask task) { int stat = 0, steps = 0; // bound to avoid cycles if (task != null && joiner != null && joiner.base - joiner.top >= 0) { // hoist checks restart: for (;;) { ForkJoinTask subtask = task; // current target for (WorkQueue j = joiner, v;;) { // v is stealer of subtask WorkQueue[] ws; int m, s, h; if ((s = task.status) < 0) { stat = s; break restart; } if ((ws = workQueues) == null || (m = ws.length - 1) <= 0) break restart; // shutting down if ((v = ws[h = (j.hint | 1) & m]) == null || v.currentSteal != subtask) { for (int origin = h;;) { // find stealer if (((h = (h + 2) & m) & 15) == 1 && (subtask.status < 0 || j.currentJoin != subtask)) continue restart; // occasional staleness check if ((v = ws[h]) != null && v.currentSteal == subtask) { j.hint = h; // save hint break; } if (h == origin) break restart; // cannot find stealer } } for (;;) { // help stealer or descend to its stealer ForkJoinTask[] a; int b; if (subtask.status < 0) // surround probes with continue restart; // consistency checks if ((b = v.base) - v.top < 0 && (a = v.array) != null) { int i = (((a.length - 1) & b) << ASHIFT) + ABASE; ForkJoinTask t = (ForkJoinTask)U.getObjectVolatile(a, i); if (subtask.status < 0 || j.currentJoin != subtask || v.currentSteal != subtask) continue restart; // stale stat = 1; // apparent progress if (v.base == b) { if (t == null) break restart; if (U.compareAndSwapObject(a, i, t, null)) { U.putOrderedInt(v, QBASE, b + 1); ForkJoinTask ps = joiner.currentSteal; int jt = joiner.top; do { joiner.currentSteal = t; t.doExec(); // clear local tasks too } while (task.status >= 0 && joiner.top != jt && (t = joiner.pop()) != null); joiner.currentSteal = ps; break restart; } } } else { // empty -- try to descend ForkJoinTask next = v.currentJoin; if (subtask.status < 0 || j.currentJoin != subtask || v.currentSteal != subtask) continue restart; // stale else if (next == null || ++steps == MAX_HELP) break restart; // dead-end or maybe cyclic else { subtask = next; j = v; break; } } } } } } return stat; } /** * Analog of tryHelpStealer for CountedCompleters. Tries to steal * and run tasks within the target's computation. * * @param task the task to join */ private int helpComplete(WorkQueue joiner, CountedCompleter task) { WorkQueue[] ws; int m; int s = 0; if ((ws = workQueues) != null && (m = ws.length - 1) >= 0 && joiner != null && task != null) { int j = joiner.poolIndex; int scans = m + m + 1; long c = 0L; // for stability check for (int k = scans; ; j += 2) { WorkQueue q; if ((s = task.status) < 0) break; else if (joiner.internalPopAndExecCC(task)) k = scans; else if ((s = task.status) < 0) break; else if ((q = ws[j & m]) != null && q.pollAndExecCC(task)) k = scans; else if (--k < 0) { if (c == (c = ctl)) break; k = scans; } } } return s; } /** * Tries to decrement active count (sometimes implicitly) and * possibly release or create a compensating worker in preparation * for blocking. Fails on contention or termination. Otherwise, * adds a new thread if no idle workers are available and pool * may become starved. * * @param c the assumed ctl value */ final boolean tryCompensate(long c) { WorkQueue[] ws = workQueues; int pc = parallelism, e = (int)c, m, tc; if (ws != null && (m = ws.length - 1) >= 0 && e >= 0 && ctl == c) { WorkQueue w = ws[e & m]; if (e != 0 && w != null) { Thread p; long nc = ((long)(w.nextWait & E_MASK) | (c & (AC_MASK|TC_MASK))); int ne = (e + E_SEQ) & E_MASK; if (w.eventCount == (e | INT_SIGN) && U.compareAndSwapLong(this, CTL, c, nc)) { w.eventCount = ne; if ((p = w.parker) != null) U.unpark(p); return true; // replace with idle worker } } else if ((tc = (short)(c >>> TC_SHIFT)) >= 0 && (int)(c >> AC_SHIFT) + pc > 1) { long nc = ((c - AC_UNIT) & AC_MASK) | (c & ~AC_MASK); if (U.compareAndSwapLong(this, CTL, c, nc)) return true; // no compensation } else if (tc + pc < MAX_CAP) { long nc = ((c + TC_UNIT) & TC_MASK) | (c & ~TC_MASK); if (U.compareAndSwapLong(this, CTL, c, nc)) { ForkJoinWorkerThreadFactory fac; Throwable ex = null; ForkJoinWorkerThread wt = null; try { if ((fac = factory) != null && (wt = fac.newThread(this)) != null) { wt.start(); return true; } } catch (Throwable rex) { ex = rex; } deregisterWorker(wt, ex); // clean up and return false } } } return false; } /** * Helps and/or blocks until the given task is done. * * @param joiner the joining worker * @param task the task * @return task status on exit */ final int awaitJoin(WorkQueue joiner, ForkJoinTask task) { int s = 0; if (task != null && (s = task.status) >= 0 && joiner != null) { ForkJoinTask prevJoin = joiner.currentJoin; joiner.currentJoin = task; do {} while (joiner.tryRemoveAndExec(task) && // process local tasks (s = task.status) >= 0); if (s >= 0 && (task instanceof CountedCompleter)) s = helpComplete(joiner, (CountedCompleter)task); long cc = 0; // for stability checks while (s >= 0 && (s = task.status) >= 0) { if ((s = tryHelpStealer(joiner, task)) == 0 && (s = task.status) >= 0) { if (!tryCompensate(cc)) cc = ctl; else { if (task.trySetSignal() && (s = task.status) >= 0) { synchronized (task) { if (task.status >= 0) { try { // see ForkJoinTask task.wait(); // for explanation } catch (InterruptedException ie) { } } else task.notifyAll(); } } long c; // reactivate do {} while (!U.compareAndSwapLong (this, CTL, c = ctl, ((c & ~AC_MASK) | ((c & AC_MASK) + AC_UNIT)))); } } } joiner.currentJoin = prevJoin; } return s; } /** * Stripped-down variant of awaitJoin used by timed joins. Tries * to help join only while there is continuous progress. (Caller * will then enter a timed wait.) * * @param joiner the joining worker * @param task the task */ final void helpJoinOnce(WorkQueue joiner, ForkJoinTask task) { int s; if (joiner != null && task != null && (s = task.status) >= 0) { ForkJoinTask prevJoin = joiner.currentJoin; joiner.currentJoin = task; do {} while (joiner.tryRemoveAndExec(task) && // process local tasks (s = task.status) >= 0); if (s >= 0) { if (task instanceof CountedCompleter) helpComplete(joiner, (CountedCompleter)task); do {} while (task.status >= 0 && tryHelpStealer(joiner, task) > 0); } joiner.currentJoin = prevJoin; } } /** * Returns a (probably) non-empty steal queue, if one is found * during a scan, else null. This method must be retried by * caller if, by the time it tries to use the queue, it is empty. */ private WorkQueue findNonEmptyStealQueue() { int r = ThreadLocalRandom.current().nextInt(); for (;;) { int ps = plock, m; WorkQueue[] ws; WorkQueue q; if ((ws = workQueues) != null && (m = ws.length - 1) >= 0) { for (int j = (m + 1) << 2; j >= 0; --j) { if ((q = ws[(((r - j) << 1) | 1) & m]) != null && q.base - q.top < 0) return q; } } if (plock == ps) return null; } } /** * Runs tasks until {@code isQuiescent()}. We piggyback on * active count ctl maintenance, but rather than blocking * when tasks cannot be found, we rescan until all others cannot * find tasks either. */ final void helpQuiescePool(WorkQueue w) { ForkJoinTask ps = w.currentSteal; for (boolean active = true;;) { long c; WorkQueue q; ForkJoinTask t; int b; while ((t = w.nextLocalTask()) != null) t.doExec(); if ((q = findNonEmptyStealQueue()) != null) { if (!active) { // re-establish active count active = true; do {} while (!U.compareAndSwapLong (this, CTL, c = ctl, ((c & ~AC_MASK) | ((c & AC_MASK) + AC_UNIT)))); } if ((b = q.base) - q.top < 0 && (t = q.pollAt(b)) != null) { (w.currentSteal = t).doExec(); w.currentSteal = ps; } } else if (active) { // decrement active count without queuing long nc = ((c = ctl) & ~AC_MASK) | ((c & AC_MASK) - AC_UNIT); if ((int)(nc >> AC_SHIFT) + parallelism == 0) break; // bypass decrement-then-increment if (U.compareAndSwapLong(this, CTL, c, nc)) active = false; } else if ((int)((c = ctl) >> AC_SHIFT) + parallelism <= 0 && U.compareAndSwapLong (this, CTL, c, ((c & ~AC_MASK) | ((c & AC_MASK) + AC_UNIT)))) break; } } /** * Gets and removes a local or stolen task for the given worker. * * @return a task, if available */ final ForkJoinTask nextTaskFor(WorkQueue w) { for (ForkJoinTask t;;) { WorkQueue q; int b; if ((t = w.nextLocalTask()) != null) return t; if ((q = findNonEmptyStealQueue()) == null) return null; if ((b = q.base) - q.top < 0 && (t = q.pollAt(b)) != null) return t; } } /** * Returns a cheap heuristic guide for task partitioning when * programmers, frameworks, tools, or languages have little or no * idea about task granularity. In essence by offering this * method, we ask users only about tradeoffs in overhead vs * expected throughput and its variance, rather than how finely to * partition tasks. * * In a steady state strict (tree-structured) computation, each * thread makes available for stealing enough tasks for other * threads to remain active. Inductively, if all threads play by * the same rules, each thread should make available only a * constant number of tasks. * * The minimum useful constant is just 1. But using a value of 1 * would require immediate replenishment upon each steal to * maintain enough tasks, which is infeasible. Further, * partitionings/granularities of offered tasks should minimize * steal rates, which in general means that threads nearer the top * of computation tree should generate more than those nearer the * bottom. In perfect steady state, each thread is at * approximately the same level of computation tree. However, * producing extra tasks amortizes the uncertainty of progress and * diffusion assumptions. * * So, users will want to use values larger (but not much larger) * than 1 to both smooth over transient shortages and hedge * against uneven progress; as traded off against the cost of * extra task overhead. We leave the user to pick a threshold * value to compare with the results of this call to guide * decisions, but recommend values such as 3. * * When all threads are active, it is on average OK to estimate * surplus strictly locally. In steady-state, if one thread is * maintaining say 2 surplus tasks, then so are others. So we can * just use estimated queue length. However, this strategy alone * leads to serious mis-estimates in some non-steady-state * conditions (ramp-up, ramp-down, other stalls). We can detect * many of these by further considering the number of "idle" * threads, that are known to have zero queued tasks, so * compensate by a factor of (#idle/#active) threads. * * Note: The approximation of #busy workers as #active workers is * not very good under current signalling scheme, and should be * improved. */ static int getSurplusQueuedTaskCount() { Thread t; ForkJoinWorkerThread wt; ForkJoinPool pool; WorkQueue q; if (((t = Thread.currentThread()) instanceof ForkJoinWorkerThread)) { int p = (pool = (wt = (ForkJoinWorkerThread)t).pool).parallelism; int n = (q = wt.workQueue).top - q.base; int a = (int)(pool.ctl >> AC_SHIFT) + p; return n - (a > (p >>>= 1) ? 0 : a > (p >>>= 1) ? 1 : a > (p >>>= 1) ? 2 : a > (p >>>= 1) ? 4 : 8); } return 0; } // Termination /** * Possibly initiates and/or completes termination. The caller * triggering termination runs three passes through workQueues: * (0) Setting termination status, followed by wakeups of queued * workers; (1) cancelling all tasks; (2) interrupting lagging * threads (likely in external tasks, but possibly also blocked in * joins). Each pass repeats previous steps because of potential * lagging thread creation. * * @param now if true, unconditionally terminate, else only * if no work and no active workers * @param enable if true, enable shutdown when next possible * @return true if now terminating or terminated */ private boolean tryTerminate(boolean now, boolean enable) { int ps; if (this == common) // cannot shut down return false; if ((ps = plock) >= 0) { // enable by setting plock if (!enable) return false; if ((ps & PL_LOCK) != 0 || !U.compareAndSwapInt(this, PLOCK, ps, ps += PL_LOCK)) ps = acquirePlock(); int nps = ((ps + PL_LOCK) & ~SHUTDOWN) | SHUTDOWN; if (!U.compareAndSwapInt(this, PLOCK, ps, nps)) releasePlock(nps); } for (long c;;) { if (((c = ctl) & STOP_BIT) != 0) { // already terminating if ((short)(c >>> TC_SHIFT) + parallelism <= 0) { synchronized (this) { notifyAll(); // signal when 0 workers } } return true; } if (!now) { // check if idle & no tasks WorkQueue[] ws; WorkQueue w; if ((int)(c >> AC_SHIFT) + parallelism > 0) return false; if ((ws = workQueues) != null) { for (int i = 0; i < ws.length; ++i) { if ((w = ws[i]) != null && (!w.isEmpty() || ((i & 1) != 0 && w.eventCount >= 0))) { signalWork(ws, w); return false; } } } } if (U.compareAndSwapLong(this, CTL, c, c | STOP_BIT)) { for (int pass = 0; pass < 3; ++pass) { WorkQueue[] ws; WorkQueue w; Thread wt; if ((ws = workQueues) != null) { int n = ws.length; for (int i = 0; i < n; ++i) { if ((w = ws[i]) != null) { w.qlock = -1; if (pass > 0) { w.cancelAll(); if (pass > 1 && (wt = w.owner) != null) { if (!wt.isInterrupted()) { try { wt.interrupt(); } catch (Throwable ignore) { } } U.unpark(wt); } } } } // Wake up workers parked on event queue int i, e; long cc; Thread p; while ((e = (int)(cc = ctl) & E_MASK) != 0 && (i = e & SMASK) < n && i >= 0 && (w = ws[i]) != null) { long nc = ((long)(w.nextWait & E_MASK) | ((cc + AC_UNIT) & AC_MASK) | (cc & (TC_MASK|STOP_BIT))); if (w.eventCount == (e | INT_SIGN) && U.compareAndSwapLong(this, CTL, cc, nc)) { w.eventCount = (e + E_SEQ) & E_MASK; w.qlock = -1; if ((p = w.parker) != null) U.unpark(p); } } } } } } } // external operations on common pool /** * Returns common pool queue for a thread that has submitted at * least one task. */ static WorkQueue commonSubmitterQueue() { Submitter z; ForkJoinPool p; WorkQueue[] ws; int m, r; return ((z = submitters.get()) != null && (p = common) != null && (ws = p.workQueues) != null && (m = ws.length - 1) >= 0) ? ws[m & z.seed & SQMASK] : null; } /** * Tries to pop the given task from submitter's queue in common pool. */ final boolean tryExternalUnpush(ForkJoinTask task) { WorkQueue joiner; ForkJoinTask[] a; int m, s; Submitter z = submitters.get(); WorkQueue[] ws = workQueues; boolean popped = false; if (z != null && ws != null && (m = ws.length - 1) >= 0 && (joiner = ws[z.seed & m & SQMASK]) != null && joiner.base != (s = joiner.top) && (a = joiner.array) != null) { long j = (((a.length - 1) & (s - 1)) << ASHIFT) + ABASE; if (U.getObject(a, j) == task && U.compareAndSwapInt(joiner, QLOCK, 0, 1)) { if (joiner.top == s && joiner.array == a && U.compareAndSwapObject(a, j, task, null)) { joiner.top = s - 1; popped = true; } joiner.qlock = 0; } } return popped; } final int externalHelpComplete(CountedCompleter task) { WorkQueue joiner; int m, j; Submitter z = submitters.get(); WorkQueue[] ws = workQueues; int s = 0; if (z != null && ws != null && (m = ws.length - 1) >= 0 && (joiner = ws[(j = z.seed) & m & SQMASK]) != null && task != null) { int scans = m + m + 1; long c = 0L; // for stability check j |= 1; // poll odd queues for (int k = scans; ; j += 2) { WorkQueue q; if ((s = task.status) < 0) break; else if (joiner.externalPopAndExecCC(task)) k = scans; else if ((s = task.status) < 0) break; else if ((q = ws[j & m]) != null && q.pollAndExecCC(task)) k = scans; else if (--k < 0) { if (c == (c = ctl)) break; k = scans; } } } return s; } // Exported methods // Constructors /** * Creates a {@code ForkJoinPool} with parallelism equal to {@link * java.lang.Runtime#availableProcessors}, using the {@linkplain * #defaultForkJoinWorkerThreadFactory default thread factory}, * no UncaughtExceptionHandler, and non-async LIFO processing mode. * * @throws SecurityException if a security manager exists and * the caller is not permitted to modify threads * because it does not hold {@link * java.lang.RuntimePermission}{@code ("modifyThread")} */ public ForkJoinPool() { this(Math.min(MAX_CAP, Runtime.getRuntime().availableProcessors()), defaultForkJoinWorkerThreadFactory, null, false); } /** * Creates a {@code ForkJoinPool} with the indicated parallelism * level, the {@linkplain * #defaultForkJoinWorkerThreadFactory default thread factory}, * no UncaughtExceptionHandler, and non-async LIFO processing mode. * * @param parallelism the parallelism level * @throws IllegalArgumentException if parallelism less than or * equal to zero, or greater than implementation limit * @throws SecurityException if a security manager exists and * the caller is not permitted to modify threads * because it does not hold {@link * java.lang.RuntimePermission}{@code ("modifyThread")} */ public ForkJoinPool(int parallelism) { this(parallelism, defaultForkJoinWorkerThreadFactory, null, false); } /** * Creates a {@code ForkJoinPool} with the given parameters. * * @param parallelism the parallelism level. For default value, * use {@link java.lang.Runtime#availableProcessors}. * @param factory the factory for creating new threads. For default value, * use {@link #defaultForkJoinWorkerThreadFactory}. * @param handler the handler for internal worker threads that * terminate due to unrecoverable errors encountered while executing * tasks. For default value, use {@code null}. * @param asyncMode if true, * establishes local first-in-first-out scheduling mode for forked * tasks that are never joined. This mode may be more appropriate * than default locally stack-based mode in applications in which * worker threads only process event-style asynchronous tasks. * For default value, use {@code false}. * @throws IllegalArgumentException if parallelism less than or * equal to zero, or greater than implementation limit * @throws NullPointerException if the factory is null * @throws SecurityException if a security manager exists and * the caller is not permitted to modify threads * because it does not hold {@link * java.lang.RuntimePermission}{@code ("modifyThread")} */ public ForkJoinPool(int parallelism, ForkJoinWorkerThreadFactory factory, UncaughtExceptionHandler handler, boolean asyncMode) { this(checkParallelism(parallelism), checkFactory(factory), handler, (asyncMode ? FIFO_QUEUE : LIFO_QUEUE), "ForkJoinPool-" + nextPoolId() + "-worker-"); checkPermission(); } private static int checkParallelism(int parallelism) { if (parallelism <= 0 || parallelism > MAX_CAP) throw new IllegalArgumentException(); return parallelism; } private static ForkJoinWorkerThreadFactory checkFactory (ForkJoinWorkerThreadFactory factory) { if (factory == null) throw new NullPointerException(); return factory; } /** * Creates a {@code ForkJoinPool} with the given parameters, without * any security checks or parameter validation. Invoked directly by * makeCommonPool. */ private ForkJoinPool(int parallelism, ForkJoinWorkerThreadFactory factory, UncaughtExceptionHandler handler, int mode, String workerNamePrefix) { this.workerNamePrefix = workerNamePrefix; this.factory = factory; this.ueh = handler; this.mode = (short)mode; this.parallelism = (short)parallelism; long np = (long)(-parallelism); // offset ctl counts this.ctl = ((np << AC_SHIFT) & AC_MASK) | ((np << TC_SHIFT) & TC_MASK); } /** * Returns the common pool instance. This pool is statically * constructed; its run state is unaffected by attempts to {@link * #shutdown} or {@link #shutdownNow}. However this pool and any * ongoing processing are automatically terminated upon program * {@link System#exit}. Any program that relies on asynchronous * task processing to complete before program termination should * invoke {@code commonPool().}{@link #awaitQuiescence awaitQuiescence}, * before exit. * * @return the common pool instance * @since 1.8 */ public static ForkJoinPool commonPool() { // assert common != null : "static init error"; return common; } // Execution methods /** * Performs the given task, returning its result upon completion. * If the computation encounters an unchecked Exception or Error, * it is rethrown as the outcome of this invocation. Rethrown * exceptions behave in the same way as regular exceptions, but, * when possible, contain stack traces (as displayed for example * using {@code ex.printStackTrace()}) of both the current thread * as well as the thread actually encountering the exception; * minimally only the latter. * * @param task the task * @param the type of the task's result * @return the task's result * @throws NullPointerException if the task is null * @throws RejectedExecutionException if the task cannot be * scheduled for execution */ public T invoke(ForkJoinTask task) { if (task == null) throw new NullPointerException(); externalPush(task); return task.join(); } /** * Arranges for (asynchronous) execution of the given task. * * @param task the task * @throws NullPointerException if the task is null * @throws RejectedExecutionException if the task cannot be * scheduled for execution */ public void execute(ForkJoinTask task) { if (task == null) throw new NullPointerException(); externalPush(task); } // AbstractExecutorService methods /** * @throws NullPointerException if the task is null * @throws RejectedExecutionException if the task cannot be * scheduled for execution */ public void execute(Runnable task) { if (task == null) throw new NullPointerException(); ForkJoinTask job; if (task instanceof ForkJoinTask) // avoid re-wrap job = (ForkJoinTask) task; else job = new ForkJoinTask.RunnableExecuteAction(task); externalPush(job); } /** * Submits a ForkJoinTask for execution. * * @param task the task to submit * @param the type of the task's result * @return the task * @throws NullPointerException if the task is null * @throws RejectedExecutionException if the task cannot be * scheduled for execution */ public ForkJoinTask submit(ForkJoinTask task) { if (task == null) throw new NullPointerException(); externalPush(task); return task; } /** * @throws NullPointerException if the task is null * @throws RejectedExecutionException if the task cannot be * scheduled for execution */ public ForkJoinTask submit(Callable task) { ForkJoinTask job = new ForkJoinTask.AdaptedCallable(task); externalPush(job); return job; } /** * @throws NullPointerException if the task is null * @throws RejectedExecutionException if the task cannot be * scheduled for execution */ public ForkJoinTask submit(Runnable task, T result) { ForkJoinTask job = new ForkJoinTask.AdaptedRunnable(task, result); externalPush(job); return job; } /** * @throws NullPointerException if the task is null * @throws RejectedExecutionException if the task cannot be * scheduled for execution */ public ForkJoinTask submit(Runnable task) { if (task == null) throw new NullPointerException(); ForkJoinTask job; if (task instanceof ForkJoinTask) // avoid re-wrap job = (ForkJoinTask) task; else job = new ForkJoinTask.AdaptedRunnableAction(task); externalPush(job); return job; } /** * @throws NullPointerException {@inheritDoc} * @throws RejectedExecutionException {@inheritDoc} */ public List> invokeAll(Collection> tasks) { // In previous versions of this class, this method constructed // a task to run ForkJoinTask.invokeAll, but now external // invocation of multiple tasks is at least as efficient. ArrayList> futures = new ArrayList>(tasks.size()); boolean done = false; try { for (Callable t : tasks) { ForkJoinTask f = new ForkJoinTask.AdaptedCallable(t); futures.add(f); externalPush(f); } for (int i = 0, size = futures.size(); i < size; i++) ((ForkJoinTask)futures.get(i)).quietlyJoin(); done = true; return futures; } finally { if (!done) for (int i = 0, size = futures.size(); i < size; i++) futures.get(i).cancel(false); } } /** * Returns the factory used for constructing new workers. * * @return the factory used for constructing new workers */ public ForkJoinWorkerThreadFactory getFactory() { return factory; } /** * Returns the handler for internal worker threads that terminate * due to unrecoverable errors encountered while executing tasks. * * @return the handler, or {@code null} if none */ public UncaughtExceptionHandler getUncaughtExceptionHandler() { return ueh; } /** * Returns the targeted parallelism level of this pool. * * @return the targeted parallelism level of this pool */ public int getParallelism() { int par; return ((par = parallelism) > 0) ? par : 1; } /** * Returns the targeted parallelism level of the common pool. * * @return the targeted parallelism level of the common pool * @since 1.8 */ public static int getCommonPoolParallelism() { return commonParallelism; } /** * Returns the number of worker threads that have started but not * yet terminated. The result returned by this method may differ * from {@link #getParallelism} when threads are created to * maintain parallelism when others are cooperatively blocked. * * @return the number of worker threads */ public int getPoolSize() { return parallelism + (short)(ctl >>> TC_SHIFT); } /** * Returns {@code true} if this pool uses local first-in-first-out * scheduling mode for forked tasks that are never joined. * * @return {@code true} if this pool uses async mode */ public boolean getAsyncMode() { return mode == FIFO_QUEUE; } /** * Returns an estimate of the number of worker threads that are * not blocked waiting to join tasks or for other managed * synchronization. This method may overestimate the * number of running threads. * * @return the number of worker threads */ public int getRunningThreadCount() { int rc = 0; WorkQueue[] ws; WorkQueue w; if ((ws = workQueues) != null) { for (int i = 1; i < ws.length; i += 2) { if ((w = ws[i]) != null && w.isApparentlyUnblocked()) ++rc; } } return rc; } /** * Returns an estimate of the number of threads that are currently * stealing or executing tasks. This method may overestimate the * number of active threads. * * @return the number of active threads */ public int getActiveThreadCount() { int r = parallelism + (int)(ctl >> AC_SHIFT); return (r <= 0) ? 0 : r; // suppress momentarily negative values } /** * Returns {@code true} if all worker threads are currently idle. * An idle worker is one that cannot obtain a task to execute * because none are available to steal from other threads, and * there are no pending submissions to the pool. This method is * conservative; it might not return {@code true} immediately upon * idleness of all threads, but will eventually become true if * threads remain inactive. * * @return {@code true} if all threads are currently idle */ public boolean isQuiescent() { return parallelism + (int)(ctl >> AC_SHIFT) <= 0; } /** * Returns an estimate of the total number of tasks stolen from * one thread's work queue by another. The reported value * underestimates the actual total number of steals when the pool * is not quiescent. This value may be useful for monitoring and * tuning fork/join programs: in general, steal counts should be * high enough to keep threads busy, but low enough to avoid * overhead and contention across threads. * * @return the number of steals */ public long getStealCount() { long count = stealCount; WorkQueue[] ws; WorkQueue w; if ((ws = workQueues) != null) { for (int i = 1; i < ws.length; i += 2) { if ((w = ws[i]) != null) count += w.nsteals; } } return count; } /** * Returns an estimate of the total number of tasks currently held * in queues by worker threads (but not including tasks submitted * to the pool that have not begun executing). This value is only * an approximation, obtained by iterating across all threads in * the pool. This method may be useful for tuning task * granularities. * * @return the number of queued tasks */ public long getQueuedTaskCount() { long count = 0; WorkQueue[] ws; WorkQueue w; if ((ws = workQueues) != null) { for (int i = 1; i < ws.length; i += 2) { if ((w = ws[i]) != null) count += w.queueSize(); } } return count; } /** * Returns an estimate of the number of tasks submitted to this * pool that have not yet begun executing. This method may take * time proportional to the number of submissions. * * @return the number of queued submissions */ public int getQueuedSubmissionCount() { int count = 0; WorkQueue[] ws; WorkQueue w; if ((ws = workQueues) != null) { for (int i = 0; i < ws.length; i += 2) { if ((w = ws[i]) != null) count += w.queueSize(); } } return count; } /** * Returns {@code true} if there are any tasks submitted to this * pool that have not yet begun executing. * * @return {@code true} if there are any queued submissions */ public boolean hasQueuedSubmissions() { WorkQueue[] ws; WorkQueue w; if ((ws = workQueues) != null) { for (int i = 0; i < ws.length; i += 2) { if ((w = ws[i]) != null && !w.isEmpty()) return true; } } return false; } /** * Removes and returns the next unexecuted submission if one is * available. This method may be useful in extensions to this * class that re-assign work in systems with multiple pools. * * @return the next submission, or {@code null} if none */ protected ForkJoinTask pollSubmission() { WorkQueue[] ws; WorkQueue w; ForkJoinTask t; if ((ws = workQueues) != null) { for (int i = 0; i < ws.length; i += 2) { if ((w = ws[i]) != null && (t = w.poll()) != null) return t; } } return null; } /** * Removes all available unexecuted submitted and forked tasks * from scheduling queues and adds them to the given collection, * without altering their execution status. These may include * artificially generated or wrapped tasks. This method is * designed to be invoked only when the pool is known to be * quiescent. Invocations at other times may not remove all * tasks. A failure encountered while attempting to add elements * to collection {@code c} may result in elements being in * neither, either or both collections when the associated * exception is thrown. The behavior of this operation is * undefined if the specified collection is modified while the * operation is in progress. * * @param c the collection to transfer elements into * @return the number of elements transferred */ protected int drainTasksTo(Collection> c) { int count = 0; WorkQueue[] ws; WorkQueue w; ForkJoinTask t; if ((ws = workQueues) != null) { for (int i = 0; i < ws.length; ++i) { if ((w = ws[i]) != null) { while ((t = w.poll()) != null) { c.add(t); ++count; } } } } return count; } /** * Returns a string identifying this pool, as well as its state, * including indications of run state, parallelism level, and * worker and task counts. * * @return a string identifying this pool, as well as its state */ public String toString() { // Use a single pass through workQueues to collect counts long qt = 0L, qs = 0L; int rc = 0; long st = stealCount; long c = ctl; WorkQueue[] ws; WorkQueue w; if ((ws = workQueues) != null) { for (int i = 0; i < ws.length; ++i) { if ((w = ws[i]) != null) { int size = w.queueSize(); if ((i & 1) == 0) qs += size; else { qt += size; st += w.nsteals; if (w.isApparentlyUnblocked()) ++rc; } } } } int pc = parallelism; int tc = pc + (short)(c >>> TC_SHIFT); int ac = pc + (int)(c >> AC_SHIFT); if (ac < 0) // ignore transient negative ac = 0; String level; if ((c & STOP_BIT) != 0) level = (tc == 0) ? "Terminated" : "Terminating"; else level = plock < 0 ? "Shutting down" : "Running"; return super.toString() + "[" + level + ", parallelism = " + pc + ", size = " + tc + ", active = " + ac + ", running = " + rc + ", steals = " + st + ", tasks = " + qt + ", submissions = " + qs + "]"; } /** * Possibly initiates an orderly shutdown in which previously * submitted tasks are executed, but no new tasks will be * accepted. Invocation has no effect on execution state if this * is the {@link #commonPool()}, and no additional effect if * already shut down. Tasks that are in the process of being * submitted concurrently during the course of this method may or * may not be rejected. * * @throws SecurityException if a security manager exists and * the caller is not permitted to modify threads * because it does not hold {@link * java.lang.RuntimePermission}{@code ("modifyThread")} */ public void shutdown() { checkPermission(); tryTerminate(false, true); } /** * Possibly attempts to cancel and/or stop all tasks, and reject * all subsequently submitted tasks. Invocation has no effect on * execution state if this is the {@link #commonPool()}, and no * additional effect if already shut down. Otherwise, tasks that * are in the process of being submitted or executed concurrently * during the course of this method may or may not be * rejected. This method cancels both existing and unexecuted * tasks, in order to permit termination in the presence of task * dependencies. So the method always returns an empty list * (unlike the case for some other Executors). * * @return an empty list * @throws SecurityException if a security manager exists and * the caller is not permitted to modify threads * because it does not hold {@link * java.lang.RuntimePermission}{@code ("modifyThread")} */ public List shutdownNow() { checkPermission(); tryTerminate(true, true); return Collections.emptyList(); } /** * Returns {@code true} if all tasks have completed following shut down. * * @return {@code true} if all tasks have completed following shut down */ public boolean isTerminated() { long c = ctl; return ((c & STOP_BIT) != 0L && (short)(c >>> TC_SHIFT) + parallelism <= 0); } /** * Returns {@code true} if the process of termination has * commenced but not yet completed. This method may be useful for * debugging. A return of {@code true} reported a sufficient * period after shutdown may indicate that submitted tasks have * ignored or suppressed interruption, or are waiting for I/O, * causing this executor not to properly terminate. (See the * advisory notes for class {@link ForkJoinTask} stating that * tasks should not normally entail blocking operations. But if * they do, they must abort them on interrupt.) * * @return {@code true} if terminating but not yet terminated */ public boolean isTerminating() { long c = ctl; return ((c & STOP_BIT) != 0L && (short)(c >>> TC_SHIFT) + parallelism > 0); } /** * Returns {@code true} if this pool has been shut down. * * @return {@code true} if this pool has been shut down */ public boolean isShutdown() { return plock < 0; } /** * Blocks until all tasks have completed execution after a * shutdown request, or the timeout occurs, or the current thread * is interrupted, whichever happens first. Because the {@link * #commonPool()} never terminates until program shutdown, when * applied to the common pool, this method is equivalent to {@link * #awaitQuiescence(long, TimeUnit)} but always returns {@code false}. * * @param timeout the maximum time to wait * @param unit the time unit of the timeout argument * @return {@code true} if this executor terminated and * {@code false} if the timeout elapsed before termination * @throws InterruptedException if interrupted while waiting */ public boolean awaitTermination(long timeout, TimeUnit unit) throws InterruptedException { if (Thread.interrupted()) throw new InterruptedException(); if (this == common) { awaitQuiescence(timeout, unit); return false; } long nanos = unit.toNanos(timeout); if (isTerminated()) return true; if (nanos <= 0L) return false; long deadline = System.nanoTime() + nanos; synchronized (this) { for (;;) { if (isTerminated()) return true; if (nanos <= 0L) return false; long millis = TimeUnit.NANOSECONDS.toMillis(nanos); wait(millis > 0L ? millis : 1L); nanos = deadline - System.nanoTime(); } } } /** * If called by a ForkJoinTask operating in this pool, equivalent * in effect to {@link ForkJoinTask#helpQuiesce}. Otherwise, * waits and/or attempts to assist performing tasks until this * pool {@link #isQuiescent} or the indicated timeout elapses. * * @param timeout the maximum time to wait * @param unit the time unit of the timeout argument * @return {@code true} if quiescent; {@code false} if the * timeout elapsed. */ public boolean awaitQuiescence(long timeout, TimeUnit unit) { long nanos = unit.toNanos(timeout); ForkJoinWorkerThread wt; Thread thread = Thread.currentThread(); if ((thread instanceof ForkJoinWorkerThread) && (wt = (ForkJoinWorkerThread)thread).pool == this) { helpQuiescePool(wt.workQueue); return true; } long startTime = System.nanoTime(); WorkQueue[] ws; int r = 0, m; boolean found = true; while (!isQuiescent() && (ws = workQueues) != null && (m = ws.length - 1) >= 0) { if (!found) { if ((System.nanoTime() - startTime) > nanos) return false; Thread.yield(); // cannot block } found = false; for (int j = (m + 1) << 2; j >= 0; --j) { ForkJoinTask t; WorkQueue q; int b; if ((q = ws[r++ & m]) != null && (b = q.base) - q.top < 0) { found = true; if ((t = q.pollAt(b)) != null) t.doExec(); break; } } } return true; } /** * Waits and/or attempts to assist performing tasks indefinitely * until the {@link #commonPool()} {@link #isQuiescent}. */ static void quiesceCommonPool() { common.awaitQuiescence(Long.MAX_VALUE, TimeUnit.NANOSECONDS); } /** * Interface for extending managed parallelism for tasks running * in {@link ForkJoinPool}s. * *

A {@code ManagedBlocker} provides two methods. Method * {@code isReleasable} must return {@code true} if blocking is * not necessary. Method {@code block} blocks the current thread * if necessary (perhaps internally invoking {@code isReleasable} * before actually blocking). These actions are performed by any * thread invoking {@link ForkJoinPool#managedBlock(ManagedBlocker)}. * The unusual methods in this API accommodate synchronizers that * may, but don't usually, block for long periods. Similarly, they * allow more efficient internal handling of cases in which * additional workers may be, but usually are not, needed to * ensure sufficient parallelism. Toward this end, * implementations of method {@code isReleasable} must be amenable * to repeated invocation. * *

For example, here is a ManagedBlocker based on a * ReentrantLock: *

 {@code
     * class ManagedLocker implements ManagedBlocker {
     *   final ReentrantLock lock;
     *   boolean hasLock = false;
     *   ManagedLocker(ReentrantLock lock) { this.lock = lock; }
     *   public boolean block() {
     *     if (!hasLock)
     *       lock.lock();
     *     return true;
     *   }
     *   public boolean isReleasable() {
     *     return hasLock || (hasLock = lock.tryLock());
     *   }
     * }}
* *

Here is a class that possibly blocks waiting for an * item on a given queue: *

 {@code
     * class QueueTaker implements ManagedBlocker {
     *   final BlockingQueue queue;
     *   volatile E item = null;
     *   QueueTaker(BlockingQueue q) { this.queue = q; }
     *   public boolean block() throws InterruptedException {
     *     if (item == null)
     *       item = queue.take();
     *     return true;
     *   }
     *   public boolean isReleasable() {
     *     return item != null || (item = queue.poll()) != null;
     *   }
     *   public E getItem() { // call after pool.managedBlock completes
     *     return item;
     *   }
     * }}
*/ public static interface ManagedBlocker { /** * Possibly blocks the current thread, for example waiting for * a lock or condition. * * @return {@code true} if no additional blocking is necessary * (i.e., if isReleasable would return true) * @throws InterruptedException if interrupted while waiting * (the method is not required to do so, but is allowed to) */ boolean block() throws InterruptedException; /** * Returns {@code true} if blocking is unnecessary. * @return {@code true} if blocking is unnecessary */ boolean isReleasable(); } /** * Blocks in accord with the given blocker. If the current thread * is a {@link ForkJoinWorkerThread}, this method possibly * arranges for a spare thread to be activated if necessary to * ensure sufficient parallelism while the current thread is blocked. * *

If the caller is not a {@link ForkJoinTask}, this method is * behaviorally equivalent to *

 {@code
     * while (!blocker.isReleasable())
     *   if (blocker.block())
     *     return;
     * }
* * If the caller is a {@code ForkJoinTask}, then the pool may * first be expanded to ensure parallelism, and later adjusted. * * @param blocker the blocker * @throws InterruptedException if blocker.block did so */ public static void managedBlock(ManagedBlocker blocker) throws InterruptedException { Thread t = Thread.currentThread(); if (t instanceof ForkJoinWorkerThread) { ForkJoinPool p = ((ForkJoinWorkerThread)t).pool; while (!blocker.isReleasable()) { if (p.tryCompensate(p.ctl)) { try { do {} while (!blocker.isReleasable() && !blocker.block()); } finally { p.incrementActiveCount(); } break; } } } else { do {} while (!blocker.isReleasable() && !blocker.block()); } } // AbstractExecutorService overrides. These rely on undocumented // fact that ForkJoinTask.adapt returns ForkJoinTasks that also // implement RunnableFuture. protected RunnableFuture newTaskFor(Runnable runnable, T value) { return new ForkJoinTask.AdaptedRunnable(runnable, value); } protected RunnableFuture newTaskFor(Callable callable) { return new ForkJoinTask.AdaptedCallable(callable); } // Unsafe mechanics private static final sun.misc.Unsafe U; private static final long CTL; private static final long PARKBLOCKER; private static final int ABASE; private static final int ASHIFT; private static final long STEALCOUNT; private static final long PLOCK; private static final long INDEXSEED; private static final long QBASE; private static final long QLOCK; static { // initialize field offsets for CAS etc try { U = getUnsafe(); Class k = ForkJoinPool.class; CTL = U.objectFieldOffset (k.getDeclaredField("ctl")); STEALCOUNT = U.objectFieldOffset (k.getDeclaredField("stealCount")); PLOCK = U.objectFieldOffset (k.getDeclaredField("plock")); INDEXSEED = U.objectFieldOffset (k.getDeclaredField("indexSeed")); Class tk = Thread.class; PARKBLOCKER = U.objectFieldOffset (tk.getDeclaredField("parkBlocker")); Class wk = WorkQueue.class; QBASE = U.objectFieldOffset (wk.getDeclaredField("base")); QLOCK = U.objectFieldOffset (wk.getDeclaredField("qlock")); Class ak = ForkJoinTask[].class; ABASE = U.arrayBaseOffset(ak); int scale = U.arrayIndexScale(ak); if ((scale & (scale - 1)) != 0) throw new Error("data type scale not a power of two"); ASHIFT = 31 - Integer.numberOfLeadingZeros(scale); } catch (Exception e) { throw new Error(e); } submitters = new ThreadLocal(); defaultForkJoinWorkerThreadFactory = new DefaultForkJoinWorkerThreadFactory(); modifyThreadPermission = new RuntimePermission("modifyThread"); common = java.security.AccessController.doPrivileged (new java.security.PrivilegedAction() { public ForkJoinPool run() { return makeCommonPool(); }}); int par = common.parallelism; // report 1 even if threads disabled commonParallelism = par > 0 ? par : 1; } /** * Creates and returns the common pool, respecting user settings * specified via system properties. */ private static ForkJoinPool makeCommonPool() { int parallelism = -1; ForkJoinWorkerThreadFactory factory = defaultForkJoinWorkerThreadFactory; UncaughtExceptionHandler handler = null; try { // ignore exceptions in accessing/parsing properties String pp = System.getProperty ("java.util.concurrent.ForkJoinPool.common.parallelism"); String fp = System.getProperty ("java.util.concurrent.ForkJoinPool.common.threadFactory"); String hp = System.getProperty ("java.util.concurrent.ForkJoinPool.common.exceptionHandler"); if (pp != null) parallelism = Integer.parseInt(pp); if (fp != null) factory = ((ForkJoinWorkerThreadFactory)ClassLoader. getSystemClassLoader().loadClass(fp).newInstance()); if (hp != null) handler = ((UncaughtExceptionHandler)ClassLoader. getSystemClassLoader().loadClass(hp).newInstance()); } catch (Exception ignore) { } if (parallelism < 0 && // default 1 less than #cores (parallelism = Runtime.getRuntime().availableProcessors() - 1) < 0) parallelism = 0; if (parallelism > MAX_CAP) parallelism = MAX_CAP; return new ForkJoinPool(parallelism, factory, handler, LIFO_QUEUE, "ForkJoinPool.commonPool-worker-"); } /** * Returns a sun.misc.Unsafe. Suitable for use in a 3rd party package. * Replace with a simple call to Unsafe.getUnsafe when integrating * into a jdk. * * @return a sun.misc.Unsafe */ private static sun.misc.Unsafe getUnsafe() { try { return sun.misc.Unsafe.getUnsafe(); } catch (SecurityException tryReflectionInstead) {} try { return java.security.AccessController.doPrivileged (new java.security.PrivilegedExceptionAction() { public sun.misc.Unsafe run() throws Exception { Class k = sun.misc.Unsafe.class; for (java.lang.reflect.Field f : k.getDeclaredFields()) { f.setAccessible(true); Object x = f.get(null); if (k.isInstance(x)) return k.cast(x); } throw new NoSuchFieldError("the Unsafe"); }}); } catch (java.security.PrivilegedActionException e) { throw new RuntimeException("Could not initialize intrinsics", e.getCause()); } } }




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