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*/ |
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package jsr166y; |
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import java.util.*; |
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|
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import java.util.concurrent.*; |
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import java.util.concurrent.atomic.*; |
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import java.util.concurrent.locks.*; |
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import sun.misc.Unsafe; |
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import java.lang.reflect.*; |
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|
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import java.util.Random; |
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import java.util.Collection; |
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import java.util.concurrent.locks.LockSupport; |
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|
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/** |
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* A thread managed by a {@link ForkJoinPool}. This class is |
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* subclassable solely for the sake of adding functionality -- there |
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* are no overridable methods dealing with scheduling or |
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* execution. However, you can override initialization and termination |
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* methods surrounding the main task processing loop. If you do |
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* create such a subclass, you will also need to supply a custom |
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* ForkJoinWorkerThreadFactory to use it in a ForkJoinPool. |
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* are no overridable methods dealing with scheduling or execution. |
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* However, you can override initialization and termination methods |
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* surrounding the main task processing loop. If you do create such a |
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* subclass, you will also need to supply a custom {@link |
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* ForkJoinPool.ForkJoinWorkerThreadFactory} to use it in a {@code |
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* ForkJoinPool}. |
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* |
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* @since 1.7 |
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* @author Doug Lea |
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*/ |
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public class ForkJoinWorkerThread extends Thread { |
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/* |
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* Algorithm overview: |
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* Overview: |
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* |
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* ForkJoinWorkerThreads are managed by ForkJoinPools and perform |
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* ForkJoinTasks. This class includes bookkeeping in support of |
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* worker activation, suspension, and lifecycle control described |
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* in more detail in the internal documentation of class |
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* ForkJoinPool. And as described further below, this class also |
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* includes special-cased support for some ForkJoinTask |
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* methods. But the main mechanics involve work-stealing: |
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* |
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* 1. Work-Stealing: Work-stealing queues are special forms of |
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* Deques that support only three of the four possible |
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* end-operations -- push, pop, and deq (aka steal), and only do |
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* so under the constraints that push and pop are called only from |
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* the owning thread, while deq may be called from other threads. |
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* (If you are unfamiliar with them, you probably want to read |
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* Herlihy and Shavit's book "The Art of Multiprocessor |
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* programming", chapter 16 describing these in more detail before |
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* proceeding.) The main work-stealing queue design is roughly |
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* similar to "Dynamic Circular Work-Stealing Deque" by David |
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* Chase and Yossi Lev, SPAA 2005 |
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* (http://research.sun.com/scalable/pubs/index.html). The main |
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* difference ultimately stems from gc requirements that we null |
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* out taken slots as soon as we can, to maintain as small a |
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* footprint as possible even in programs generating huge numbers |
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* of tasks. To accomplish this, we shift the CAS arbitrating pop |
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* vs deq (steal) from being on the indices ("base" and "sp") to |
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* the slots themselves (mainly via method "casSlotNull()"). So, |
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* both a successful pop and deq mainly entail CAS'ing a nonnull |
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* slot to null. Because we rely on CASes of references, we do |
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* not need tag bits on base or sp. They are simple ints as used |
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* in any circular array-based queue (see for example ArrayDeque). |
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* Updates to the indices must still be ordered in a way that |
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* guarantees that (sp - base) > 0 means the queue is empty, but |
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* otherwise may err on the side of possibly making the queue |
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* appear nonempty when a push, pop, or deq have not fully |
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* committed. Note that this means that the deq operation, |
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* considered individually, is not wait-free. One thief cannot |
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* successfully continue until another in-progress one (or, if |
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* previously empty, a push) completes. However, in the |
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* aggregate, we ensure at least probablistic non-blockingness. If |
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* an attempted steal fails, a thief always chooses a different |
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* Work-stealing queues are special forms of Deques that support |
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* only three of the four possible end-operations -- push, pop, |
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* and deq (aka steal), under the further constraints that push |
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* and pop are called only from the owning thread, while deq may |
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* be called from other threads. (If you are unfamiliar with |
45 |
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* them, you probably want to read Herlihy and Shavit's book "The |
46 |
> |
* Art of Multiprocessor programming", chapter 16 describing these |
47 |
> |
* in more detail before proceeding.) The main work-stealing |
48 |
> |
* queue design is roughly similar to those in the papers "Dynamic |
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* Circular Work-Stealing Deque" by Chase and Lev, SPAA 2005 |
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* (http://research.sun.com/scalable/pubs/index.html) and |
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* "Idempotent work stealing" by Michael, Saraswat, and Vechev, |
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* PPoPP 2009 (http://portal.acm.org/citation.cfm?id=1504186). |
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* The main differences ultimately stem from gc requirements that |
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* we null out taken slots as soon as we can, to maintain as small |
55 |
> |
* a footprint as possible even in programs generating huge |
56 |
> |
* numbers of tasks. To accomplish this, we shift the CAS |
57 |
> |
* arbitrating pop vs deq (steal) from being on the indices |
58 |
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* ("base" and "sp") to the slots themselves (mainly via method |
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* "casSlotNull()"). So, both a successful pop and deq mainly |
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> |
* entail a CAS of a slot from non-null to null. Because we rely |
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* on CASes of references, we do not need tag bits on base or sp. |
62 |
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* They are simple ints as used in any circular array-based queue |
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* (see for example ArrayDeque). Updates to the indices must |
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* still be ordered in a way that guarantees that sp == base means |
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* the queue is empty, but otherwise may err on the side of |
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* possibly making the queue appear nonempty when a push, pop, or |
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* deq have not fully committed. Note that this means that the deq |
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* operation, considered individually, is not wait-free. One thief |
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* cannot successfully continue until another in-progress one (or, |
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* if previously empty, a push) completes. However, in the |
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* aggregate, we ensure at least probabilistic non-blockingness. |
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* If an attempted steal fails, a thief always chooses a different |
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* random victim target to try next. So, in order for one thief to |
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* progress, it suffices for any in-progress deq or new push on |
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* any empty queue to complete. One reason this works well here is |
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* that apparently-nonempty often means soon-to-be-stealable, |
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* which gives threads a chance to activate if necessary before |
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* stealing (see below). |
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* which gives threads a chance to set activation status if |
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* necessary before stealing. |
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* |
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* This approach also enables support for "async mode" where local |
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* task processing is in FIFO, not LIFO order; simply by using a |
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* version of deq rather than pop when locallyFifo is true (as set |
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* by the ForkJoinPool). This allows use in message-passing |
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* frameworks in which tasks are never joined. |
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* |
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* When a worker would otherwise be blocked waiting to join a |
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* task, it first tries a form of linear helping: Each worker |
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* records (in field currentSteal) the most recent task it stole |
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* from some other worker. Plus, it records (in field currentJoin) |
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* the task it is currently actively joining. Method joinTask uses |
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* these markers to try to find a worker to help (i.e., steal back |
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* a task from and execute it) that could hasten completion of the |
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* actively joined task. In essence, the joiner executes a task |
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* that would be on its own local deque had the to-be-joined task |
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* not been stolen. This may be seen as a conservative variant of |
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* the approach in Wagner & Calder "Leapfrogging: a portable |
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* technique for implementing efficient futures" SIGPLAN Notices, |
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* 1993 (http://portal.acm.org/citation.cfm?id=155354). It differs |
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* in that: (1) We only maintain dependency links across workers |
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* upon steals, rather than use per-task bookkeeping. This may |
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* require a linear scan of workers array to locate stealers, but |
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* usually doesn't because stealers leave hints (that may become |
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* stale/wrong) of where to locate them. This isolates cost to |
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* when it is needed, rather than adding to per-task overhead. |
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* (2) It is "shallow", ignoring nesting and potentially cyclic |
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* mutual steals. (3) It is intentionally racy: field currentJoin |
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* is updated only while actively joining, which means that we |
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* miss links in the chain during long-lived tasks, GC stalls etc |
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* (which is OK since blocking in such cases is usually a good |
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* idea). (4) We bound the number of attempts to find work (see |
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* MAX_HELP_DEPTH) and fall back to suspending the worker and if |
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* necessary replacing it with a spare (see |
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* ForkJoinPool.tryAwaitJoin). |
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* |
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* Efficient implementation of this approach currently relies on |
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* an uncomfortable amount of "Unsafe" mechanics. To maintain |
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* Efficient implementation of these algorithms currently relies |
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* on an uncomfortable amount of "Unsafe" mechanics. To maintain |
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* correct orderings, reads and writes of variable base require |
118 |
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* volatile ordering. Variable sp does not require volatile write |
119 |
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* but needs cheaper store-ordering on writes. Because they are |
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* protected by volatile base reads, reads of the queue array and |
121 |
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* its slots do not need volatile load semantics, but writes (in |
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* push) require store order and CASes (in pop and deq) require |
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< |
* (volatile) CAS semantics. Since these combinations aren't |
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* supported using ordinary volatiles, the only way to accomplish |
125 |
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* these effciently is to use direct Unsafe calls. (Using external |
126 |
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* AtomicIntegers and AtomicReferenceArrays for the indices and |
127 |
< |
* array is significantly slower because of memory locality and |
128 |
< |
* indirection effects.) Further, performance on most platforms is |
129 |
< |
* very sensitive to placement and sizing of the (resizable) queue |
130 |
< |
* array. Even though these queues don't usually become all that |
131 |
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* big, the initial size must be large enough to counteract cache |
118 |
> |
* volatile ordering. Variable sp does not require volatile |
119 |
> |
* writes but still needs store-ordering, which we accomplish by |
120 |
> |
* pre-incrementing sp before filling the slot with an ordered |
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> |
* store. (Pre-incrementing also enables backouts used in |
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> |
* joinTask.) Because they are protected by volatile base reads, |
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> |
* reads of the queue array and its slots by other threads do not |
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> |
* need volatile load semantics, but writes (in push) require |
125 |
> |
* store order and CASes (in pop and deq) require (volatile) CAS |
126 |
> |
* semantics. (Michael, Saraswat, and Vechev's algorithm has |
127 |
> |
* similar properties, but without support for nulling slots.) |
128 |
> |
* Since these combinations aren't supported using ordinary |
129 |
> |
* volatiles, the only way to accomplish these efficiently is to |
130 |
> |
* use direct Unsafe calls. (Using external AtomicIntegers and |
131 |
> |
* AtomicReferenceArrays for the indices and array is |
132 |
> |
* significantly slower because of memory locality and indirection |
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> |
* effects.) |
134 |
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* |
135 |
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* Further, performance on most platforms is very sensitive to |
136 |
> |
* placement and sizing of the (resizable) queue array. Even |
137 |
> |
* though these queues don't usually become all that big, the |
138 |
> |
* initial size must be large enough to counteract cache |
139 |
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* contention effects across multiple queues (especially in the |
140 |
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* presence of GC cardmarking). Also, to improve thread-locality, |
141 |
< |
* queues are currently initialized immediately after the thread |
142 |
< |
* gets the initial signal to start processing tasks. However, |
143 |
< |
* all queue-related methods except pushTask are written in a way |
144 |
< |
* that allows them to instead be lazily allocated and/or disposed |
145 |
< |
* of when empty. All together, these low-level implementation |
92 |
< |
* choices produce as much as a factor of 4 performance |
93 |
< |
* improvement compared to naive implementations, and enable the |
94 |
< |
* processing of billions of tasks per second, sometimes at the |
95 |
< |
* expense of ugliness. |
96 |
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* |
97 |
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* 2. Run control: The primary run control is based on a global |
98 |
< |
* counter (activeCount) held by the pool. It uses an algorithm |
99 |
< |
* similar to that in Herlihy and Shavit section 17.6 to cause |
100 |
< |
* threads to eventually block when all threads declare they are |
101 |
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* inactive. (See variable "scans".) For this to work, threads |
102 |
< |
* must be declared active when executing tasks, and before |
103 |
< |
* stealing a task. They must be inactive before blocking on the |
104 |
< |
* Pool Barrier (awaiting a new submission or other Pool |
105 |
< |
* event). In between, there is some free play which we take |
106 |
< |
* advantage of to avoid contention and rapid flickering of the |
107 |
< |
* global activeCount: If inactive, we activate only if a victim |
108 |
< |
* queue appears to be nonempty (see above). Similarly, a thread |
109 |
< |
* tries to inactivate only after a full scan of other threads. |
110 |
< |
* The net effect is that contention on activeCount is rarely a |
111 |
< |
* measurable performance issue. (There are also a few other cases |
112 |
< |
* where we scan for work rather than retry/block upon |
113 |
< |
* contention.) |
114 |
< |
* |
115 |
< |
* 3. Selection control. We maintain policy of always choosing to |
116 |
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* run local tasks rather than stealing, and always trying to |
117 |
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* steal tasks before trying to run a new submission. All steals |
118 |
< |
* are currently performed in randomly-chosen deq-order. It may be |
119 |
< |
* worthwhile to bias these with locality / anti-locality |
120 |
< |
* information, but doing this well probably requires more |
121 |
< |
* lower-level information from JVMs than currently provided. |
141 |
> |
* queues are initialized after starting. All together, these |
142 |
> |
* low-level implementation choices produce as much as a factor of |
143 |
> |
* 4 performance improvement compared to naive implementations, |
144 |
> |
* and enable the processing of billions of tasks per second, |
145 |
> |
* sometimes at the expense of ugliness. |
146 |
|
*/ |
147 |
|
|
148 |
|
/** |
149 |
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* Generator for initial random seeds for random victim |
150 |
+ |
* selection. This is used only to create initial seeds. Random |
151 |
+ |
* steals use a cheaper xorshift generator per steal attempt. We |
152 |
+ |
* expect only rare contention on seedGenerator, so just use a |
153 |
+ |
* plain Random. |
154 |
+ |
*/ |
155 |
+ |
private static final Random seedGenerator = new Random(); |
156 |
+ |
|
157 |
+ |
/** |
158 |
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* The maximum stolen->joining link depth allowed in helpJoinTask. |
159 |
+ |
* Depths for legitimate chains are unbounded, but we use a fixed |
160 |
+ |
* constant to avoid (otherwise unchecked) cycles and bound |
161 |
+ |
* staleness of traversal parameters at the expense of sometimes |
162 |
+ |
* blocking when we could be helping. |
163 |
+ |
*/ |
164 |
+ |
private static final int MAX_HELP_DEPTH = 8; |
165 |
+ |
|
166 |
+ |
/** |
167 |
+ |
* The wakeup interval (in nanoseconds) for the first worker |
168 |
+ |
* suspended as spare. On each wakeup not signalled by a |
169 |
+ |
* resumption, it may ask the pool to reduce the number of spares. |
170 |
+ |
*/ |
171 |
+ |
private static final long TRIM_RATE_NANOS = 200L * 1000L * 1000L; |
172 |
+ |
|
173 |
+ |
/** |
174 |
|
* Capacity of work-stealing queue array upon initialization. |
175 |
< |
* Must be a power of two. Initial size must be at least 2, but is |
175 |
> |
* Must be a power of two. Initial size must be at least 4, but is |
176 |
|
* padded to minimize cache effects. |
177 |
|
*/ |
178 |
|
private static final int INITIAL_QUEUE_CAPACITY = 1 << 13; |
186 |
|
private static final int MAXIMUM_QUEUE_CAPACITY = 1 << 28; |
187 |
|
|
188 |
|
/** |
189 |
< |
* The pool this thread works in. Accessed directly by ForkJoinTask |
189 |
> |
* The pool this thread works in. Accessed directly by ForkJoinTask. |
190 |
|
*/ |
191 |
|
final ForkJoinPool pool; |
192 |
|
|
193 |
|
/** |
194 |
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* The work-stealing queue array. Size must be a power of two. |
195 |
< |
* Initialized when thread starts, to improve memory locality. |
195 |
> |
* Initialized in onStart, to improve memory locality. |
196 |
|
*/ |
197 |
|
private ForkJoinTask<?>[] queue; |
198 |
|
|
199 |
|
/** |
151 |
– |
* Index (mod queue.length) of next queue slot to push to or pop |
152 |
– |
* from. It is written only by owner thread, via ordered store. |
153 |
– |
* Both sp and base are allowed to wrap around on overflow, but |
154 |
– |
* (sp - base) still estimates size. |
155 |
– |
*/ |
156 |
– |
private volatile int sp; |
157 |
– |
|
158 |
– |
/** |
200 |
|
* Index (mod queue.length) of least valid queue slot, which is |
201 |
|
* always the next position to steal from if nonempty. |
202 |
|
*/ |
203 |
|
private volatile int base; |
204 |
|
|
205 |
|
/** |
206 |
< |
* Activity status. When true, this worker is considered active. |
207 |
< |
* Must be false upon construction. It must be true when executing |
208 |
< |
* tasks, and BEFORE stealing a task. It must be false before |
209 |
< |
* calling pool.sync |
206 |
> |
* Index (mod queue.length) of next queue slot to push to or pop |
207 |
> |
* from. It is written only by owner thread, and accessed by other |
208 |
> |
* threads only after reading (volatile) base. Both sp and base |
209 |
> |
* are allowed to wrap around on overflow, but (sp - base) still |
210 |
> |
* estimates size. |
211 |
> |
*/ |
212 |
> |
private int sp; |
213 |
> |
|
214 |
> |
/** |
215 |
> |
* The index of most recent stealer, used as a hint to avoid |
216 |
> |
* traversal in method helpJoinTask. This is only a hint because a |
217 |
> |
* worker might have had multiple steals and this only holds one |
218 |
> |
* of them (usually the most current). Declared non-volatile, |
219 |
> |
* relying on other prevailing sync to keep reasonably current. |
220 |
|
*/ |
221 |
< |
private boolean active; |
221 |
> |
private int stealHint; |
222 |
|
|
223 |
|
/** |
224 |
< |
* Run state of this worker. Supports simple versions of the usual |
225 |
< |
* shutdown/shutdownNow control. |
224 |
> |
* Run state of this worker. In addition to the usual run levels, |
225 |
> |
* tracks if this worker is suspended as a spare, and if it was |
226 |
> |
* killed (trimmed) while suspended. However, "active" status is |
227 |
> |
* maintained separately. |
228 |
|
*/ |
229 |
|
private volatile int runState; |
230 |
|
|
231 |
+ |
private static final int TERMINATING = 0x01; |
232 |
+ |
private static final int TERMINATED = 0x02; |
233 |
+ |
private static final int SUSPENDED = 0x04; // inactive spare |
234 |
+ |
private static final int TRIMMED = 0x08; // killed while suspended |
235 |
+ |
|
236 |
+ |
/** |
237 |
+ |
* Number of steals, transferred and reset in pool callbacks pool |
238 |
+ |
* when idle Accessed directly by pool. |
239 |
+ |
*/ |
240 |
+ |
int stealCount; |
241 |
+ |
|
242 |
|
/** |
243 |
|
* Seed for random number generator for choosing steal victims. |
244 |
< |
* Uses Marsaglia xorshift. Must be nonzero upon initialization. |
244 |
> |
* Uses Marsaglia xorshift. Must be initialized as nonzero. |
245 |
|
*/ |
246 |
|
private int seed; |
247 |
|
|
248 |
|
/** |
249 |
< |
* Number of steals, transferred to pool when idle |
249 |
> |
* Activity status. When true, this worker is considered active. |
250 |
> |
* Accessed directly by pool. Must be false upon construction. |
251 |
|
*/ |
252 |
< |
private int stealCount; |
252 |
> |
boolean active; |
253 |
> |
|
254 |
> |
/** |
255 |
> |
* True if use local fifo, not default lifo, for local polling. |
256 |
> |
* Shadows value from ForkJoinPool. |
257 |
> |
*/ |
258 |
> |
private final boolean locallyFifo; |
259 |
|
|
260 |
|
/** |
261 |
|
* Index of this worker in pool array. Set once by pool before |
262 |
< |
* running, and accessed directly by pool during cleanup etc |
262 |
> |
* running, and accessed directly by pool to locate this worker in |
263 |
> |
* its workers array. |
264 |
|
*/ |
265 |
|
int poolIndex; |
266 |
|
|
267 |
|
/** |
268 |
< |
* The last barrier event waited for. Accessed in pool callback |
269 |
< |
* methods, but only by current thread. |
268 |
> |
* The last pool event waited for. Accessed only by pool in |
269 |
> |
* callback methods invoked within this thread. |
270 |
|
*/ |
271 |
< |
long lastEventCount; |
271 |
> |
int lastEventCount; |
272 |
|
|
273 |
|
/** |
274 |
< |
* True if use local fifo, not default lifo, for local polling |
274 |
> |
* Encoded index and event count of next event waiter. Used only |
275 |
> |
* by ForkJoinPool for managing event waiters. |
276 |
|
*/ |
277 |
< |
private boolean locallyFifo; |
277 |
> |
volatile long nextWaiter; |
278 |
> |
|
279 |
> |
/** |
280 |
> |
* Number of times this thread suspended as spare |
281 |
> |
*/ |
282 |
> |
int spareCount; |
283 |
> |
|
284 |
> |
/** |
285 |
> |
* Encoded index and count of next spare waiter. Used only |
286 |
> |
* by ForkJoinPool for managing spares. |
287 |
> |
*/ |
288 |
> |
volatile int nextSpare; |
289 |
> |
|
290 |
> |
/** |
291 |
> |
* The task currently being joined, set only when actively trying |
292 |
> |
* to helpStealer. Written only by current thread, but read by |
293 |
> |
* others. |
294 |
> |
*/ |
295 |
> |
private volatile ForkJoinTask<?> currentJoin; |
296 |
> |
|
297 |
> |
/** |
298 |
> |
* The task most recently stolen from another worker (or |
299 |
> |
* submission queue). Not volatile because always read/written in |
300 |
> |
* presence of related volatiles in those cases where it matters. |
301 |
> |
*/ |
302 |
> |
private ForkJoinTask<?> currentSteal; |
303 |
|
|
304 |
|
/** |
305 |
|
* Creates a ForkJoinWorkerThread operating in the given pool. |
306 |
+ |
* |
307 |
|
* @param pool the pool this thread works in |
308 |
|
* @throws NullPointerException if pool is null |
309 |
|
*/ |
310 |
|
protected ForkJoinWorkerThread(ForkJoinPool pool) { |
212 |
– |
if (pool == null) throw new NullPointerException(); |
311 |
|
this.pool = pool; |
312 |
< |
// Note: poolIndex is set by pool during construction |
313 |
< |
// Remaining initialization is deferred to onStart |
312 |
> |
this.locallyFifo = pool.locallyFifo; |
313 |
> |
setDaemon(true); |
314 |
> |
// To avoid exposing construction details to subclasses, |
315 |
> |
// remaining initialization is in start() and onStart() |
316 |
> |
} |
317 |
> |
|
318 |
> |
/** |
319 |
> |
* Performs additional initialization and starts this thread |
320 |
> |
*/ |
321 |
> |
final void start(int poolIndex, UncaughtExceptionHandler ueh) { |
322 |
> |
this.poolIndex = poolIndex; |
323 |
> |
if (ueh != null) |
324 |
> |
setUncaughtExceptionHandler(ueh); |
325 |
> |
start(); |
326 |
|
} |
327 |
|
|
328 |
< |
// Public access methods |
328 |
> |
// Public/protected methods |
329 |
|
|
330 |
|
/** |
331 |
< |
* Returns the pool hosting this thread |
331 |
> |
* Returns the pool hosting this thread. |
332 |
> |
* |
333 |
|
* @return the pool |
334 |
|
*/ |
335 |
|
public ForkJoinPool getPool() { |
342 |
|
* threads (minus one) that have ever been created in the pool. |
343 |
|
* This method may be useful for applications that track status or |
344 |
|
* collect results per-worker rather than per-task. |
345 |
< |
* @return the index number. |
345 |
> |
* |
346 |
> |
* @return the index number |
347 |
|
*/ |
348 |
|
public int getPoolIndex() { |
349 |
|
return poolIndex; |
350 |
|
} |
351 |
|
|
352 |
|
/** |
353 |
< |
* Establishes local first-in-first-out scheduling mode for forked |
354 |
< |
* tasks that are never joined. |
355 |
< |
* @param async if true, use locally FIFO scheduling |
353 |
> |
* Initializes internal state after construction but before |
354 |
> |
* processing any tasks. If you override this method, you must |
355 |
> |
* invoke super.onStart() at the beginning of the method. |
356 |
> |
* Initialization requires care: Most fields must have legal |
357 |
> |
* default values, to ensure that attempted accesses from other |
358 |
> |
* threads work correctly even before this thread starts |
359 |
> |
* processing tasks. |
360 |
|
*/ |
361 |
< |
void setAsyncMode(boolean async) { |
362 |
< |
locallyFifo = async; |
363 |
< |
} |
248 |
< |
|
249 |
< |
// Runstate management |
250 |
< |
|
251 |
< |
// Runstate values. Order matters |
252 |
< |
private static final int RUNNING = 0; |
253 |
< |
private static final int SHUTDOWN = 1; |
254 |
< |
private static final int TERMINATING = 2; |
255 |
< |
private static final int TERMINATED = 3; |
256 |
< |
|
257 |
< |
final boolean isShutdown() { return runState >= SHUTDOWN; } |
258 |
< |
final boolean isTerminating() { return runState >= TERMINATING; } |
259 |
< |
final boolean isTerminated() { return runState == TERMINATED; } |
260 |
< |
final boolean shutdown() { return transitionRunStateTo(SHUTDOWN); } |
261 |
< |
final boolean shutdownNow() { return transitionRunStateTo(TERMINATING); } |
361 |
> |
protected void onStart() { |
362 |
> |
int rs = seedGenerator.nextInt(); |
363 |
> |
seed = rs == 0? 1 : rs; // seed must be nonzero |
364 |
|
|
365 |
< |
/** |
366 |
< |
* Transition to at least the given state. Return true if not |
367 |
< |
* already at least given state. |
368 |
< |
*/ |
267 |
< |
private boolean transitionRunStateTo(int state) { |
268 |
< |
for (;;) { |
269 |
< |
int s = runState; |
270 |
< |
if (s >= state) |
271 |
< |
return false; |
272 |
< |
if (_unsafe.compareAndSwapInt(this, runStateOffset, s, state)) |
273 |
< |
return true; |
274 |
< |
} |
275 |
< |
} |
365 |
> |
// Allocate name string and arrays in this thread |
366 |
> |
String pid = Integer.toString(pool.getPoolNumber()); |
367 |
> |
String wid = Integer.toString(poolIndex); |
368 |
> |
setName("ForkJoinPool-" + pid + "-worker-" + wid); |
369 |
|
|
370 |
< |
/** |
278 |
< |
* Try to set status to active; fail on contention |
279 |
< |
*/ |
280 |
< |
private boolean tryActivate() { |
281 |
< |
if (!active) { |
282 |
< |
if (!pool.tryIncrementActiveCount()) |
283 |
< |
return false; |
284 |
< |
active = true; |
285 |
< |
} |
286 |
< |
return true; |
370 |
> |
queue = new ForkJoinTask<?>[INITIAL_QUEUE_CAPACITY]; |
371 |
|
} |
372 |
|
|
373 |
|
/** |
374 |
< |
* Try to set status to active; fail on contention |
374 |
> |
* Performs cleanup associated with termination of this worker |
375 |
> |
* thread. If you override this method, you must invoke |
376 |
> |
* {@code super.onTermination} at the end of the overridden method. |
377 |
> |
* |
378 |
> |
* @param exception the exception causing this thread to abort due |
379 |
> |
* to an unrecoverable error, or {@code null} if completed normally |
380 |
|
*/ |
381 |
< |
private boolean tryInactivate() { |
382 |
< |
if (active) { |
383 |
< |
if (!pool.tryDecrementActiveCount()) |
384 |
< |
return false; |
385 |
< |
active = false; |
381 |
> |
protected void onTermination(Throwable exception) { |
382 |
> |
try { |
383 |
> |
cancelTasks(); |
384 |
> |
while (active) // force inactive |
385 |
> |
active = !pool.tryDecrementActiveCount(); |
386 |
> |
setTerminated(); |
387 |
> |
pool.workerTerminated(this); |
388 |
> |
} catch (Throwable ex) { // Shouldn't ever happen |
389 |
> |
if (exception == null) // but if so, at least rethrown |
390 |
> |
exception = ex; |
391 |
> |
} finally { |
392 |
> |
if (exception != null) |
393 |
> |
UNSAFE.throwException(exception); |
394 |
|
} |
298 |
– |
return true; |
395 |
|
} |
396 |
|
|
397 |
|
/** |
302 |
– |
* Computes next value for random victim probe. Scans don't |
303 |
– |
* require a very high quality generator, but also not a crummy |
304 |
– |
* one. Marsaglia xor-shift is cheap and works well. |
305 |
– |
*/ |
306 |
– |
private static int xorShift(int r) { |
307 |
– |
r ^= r << 1; |
308 |
– |
r ^= r >>> 3; |
309 |
– |
r ^= r << 10; |
310 |
– |
return r; |
311 |
– |
} |
312 |
– |
|
313 |
– |
// Lifecycle methods |
314 |
– |
|
315 |
– |
/** |
398 |
|
* This method is required to be public, but should never be |
399 |
|
* called explicitly. It performs the main run loop to execute |
400 |
|
* ForkJoinTasks. |
403 |
|
Throwable exception = null; |
404 |
|
try { |
405 |
|
onStart(); |
324 |
– |
pool.sync(this); // await first pool event |
406 |
|
mainLoop(); |
407 |
|
} catch (Throwable ex) { |
408 |
|
exception = ex; |
411 |
|
} |
412 |
|
} |
413 |
|
|
414 |
+ |
// helpers for run() |
415 |
+ |
|
416 |
|
/** |
417 |
< |
* Execute tasks until shut down. |
417 |
> |
* Find and execute tasks and check status while running |
418 |
|
*/ |
419 |
|
private void mainLoop() { |
420 |
< |
while (!isShutdown()) { |
421 |
< |
ForkJoinTask<?> t = pollTask(); |
422 |
< |
if (t != null || (t = pollSubmission()) != null) |
423 |
< |
t.quietlyExec(); |
424 |
< |
else if (tryInactivate()) |
425 |
< |
pool.sync(this); |
420 |
> |
int misses = 0; // track consecutive times failed to find work; max 2 |
421 |
> |
ForkJoinPool p = pool; |
422 |
> |
for (;;) { |
423 |
> |
p.preStep(this, misses); |
424 |
> |
if (runState != 0) |
425 |
> |
break; |
426 |
> |
misses = ((tryExecSteal() || tryExecSubmission()) ? 0 : |
427 |
> |
(misses < 2 ? misses + 1 : 2)); |
428 |
|
} |
429 |
|
} |
430 |
|
|
431 |
|
/** |
432 |
< |
* Initializes internal state after construction but before |
433 |
< |
* processing any tasks. If you override this method, you must |
434 |
< |
* invoke super.onStart() at the beginning of the method. |
350 |
< |
* Initialization requires care: Most fields must have legal |
351 |
< |
* default values, to ensure that attempted accesses from other |
352 |
< |
* threads work correctly even before this thread starts |
353 |
< |
* processing tasks. |
432 |
> |
* Try to steal a task and execute it |
433 |
> |
* |
434 |
> |
* @return true if ran a task |
435 |
|
*/ |
436 |
< |
protected void onStart() { |
437 |
< |
// Allocate while starting to improve chances of thread-local |
438 |
< |
// isolation |
439 |
< |
queue = new ForkJoinTask<?>[INITIAL_QUEUE_CAPACITY]; |
440 |
< |
// Initial value of seed need not be especially random but |
441 |
< |
// should differ across workers and must be nonzero |
442 |
< |
int p = poolIndex + 1; |
443 |
< |
seed = p + (p << 8) + (p << 16) + (p << 24); // spread bits |
436 |
> |
private boolean tryExecSteal() { |
437 |
> |
ForkJoinTask<?> t; |
438 |
> |
if ((t = scan()) != null) { |
439 |
> |
t.quietlyExec(); |
440 |
> |
currentSteal = null; |
441 |
> |
if (sp != base) |
442 |
> |
execLocalTasks(); |
443 |
> |
return true; |
444 |
> |
} |
445 |
> |
return false; |
446 |
|
} |
447 |
|
|
448 |
|
/** |
449 |
< |
* Perform cleanup associated with termination of this worker |
367 |
< |
* thread. If you override this method, you must invoke |
368 |
< |
* super.onTermination at the end of the overridden method. |
449 |
> |
* If a submission exists, try to activate and run it; |
450 |
|
* |
451 |
< |
* @param exception the exception causing this thread to abort due |
371 |
< |
* to an unrecoverable error, or null if completed normally. |
451 |
> |
* @return true if ran a task |
452 |
|
*/ |
453 |
< |
protected void onTermination(Throwable exception) { |
454 |
< |
// Execute remaining local tasks unless aborting or terminating |
455 |
< |
while (exception == null && !pool.isTerminating() && base != sp) { |
456 |
< |
try { |
457 |
< |
ForkJoinTask<?> t = popTask(); |
458 |
< |
if (t != null) |
453 |
> |
private boolean tryExecSubmission() { |
454 |
> |
ForkJoinPool p = pool; |
455 |
> |
while (p.hasQueuedSubmissions()) { |
456 |
> |
ForkJoinTask<?> t; |
457 |
> |
if (active || (active = p.tryIncrementActiveCount())) { |
458 |
> |
if ((t = p.pollSubmission()) != null) { |
459 |
> |
currentSteal = t; |
460 |
|
t.quietlyExec(); |
461 |
< |
} catch(Throwable ex) { |
462 |
< |
exception = ex; |
461 |
> |
currentSteal = null; |
462 |
> |
if (sp != base) |
463 |
> |
execLocalTasks(); |
464 |
> |
return true; |
465 |
> |
} |
466 |
|
} |
467 |
|
} |
468 |
< |
// Cancel other tasks, transition status, notify pool, and |
385 |
< |
// propagate exception to uncaught exception handler |
386 |
< |
try { |
387 |
< |
do;while (!tryInactivate()); // ensure inactive |
388 |
< |
cancelTasks(); |
389 |
< |
runState = TERMINATED; |
390 |
< |
pool.workerTerminated(this); |
391 |
< |
} catch (Throwable ex) { // Shouldn't ever happen |
392 |
< |
if (exception == null) // but if so, at least rethrown |
393 |
< |
exception = ex; |
394 |
< |
} finally { |
395 |
< |
if (exception != null) |
396 |
< |
ForkJoinTask.rethrowException(exception); |
397 |
< |
} |
468 |
> |
return false; |
469 |
|
} |
470 |
|
|
400 |
– |
// Intrinsics-based support for queue operations. |
401 |
– |
|
471 |
|
/** |
472 |
< |
* Add in store-order the given task at given slot of q to |
473 |
< |
* null. Caller must ensure q is nonnull and index is in range. |
472 |
> |
* Runs local tasks until queue is empty or shut down. Call only |
473 |
> |
* while active. |
474 |
|
*/ |
475 |
< |
private static void setSlot(ForkJoinTask<?>[] q, int i, |
476 |
< |
ForkJoinTask<?> t){ |
477 |
< |
_unsafe.putOrderedObject(q, (i << qShift) + qBase, t); |
475 |
> |
private void execLocalTasks() { |
476 |
> |
while (runState == 0) { |
477 |
> |
ForkJoinTask<?> t = locallyFifo? locallyDeqTask() : popTask(); |
478 |
> |
if (t != null) |
479 |
> |
t.quietlyExec(); |
480 |
> |
else if (sp == base) |
481 |
> |
break; |
482 |
> |
} |
483 |
|
} |
484 |
|
|
485 |
+ |
/* |
486 |
+ |
* Intrinsics-based atomic writes for queue slots. These are |
487 |
+ |
* basically the same as methods in AtomicObjectArray, but |
488 |
+ |
* specialized for (1) ForkJoinTask elements (2) requirement that |
489 |
+ |
* nullness and bounds checks have already been performed by |
490 |
+ |
* callers and (3) effective offsets are known not to overflow |
491 |
+ |
* from int to long (because of MAXIMUM_QUEUE_CAPACITY). We don't |
492 |
+ |
* need corresponding version for reads: plain array reads are OK |
493 |
+ |
* because they protected by other volatile reads and are |
494 |
+ |
* confirmed by CASes. |
495 |
+ |
* |
496 |
+ |
* Most uses don't actually call these methods, but instead contain |
497 |
+ |
* inlined forms that enable more predictable optimization. We |
498 |
+ |
* don't define the version of write used in pushTask at all, but |
499 |
+ |
* instead inline there a store-fenced array slot write. |
500 |
+ |
*/ |
501 |
+ |
|
502 |
|
/** |
503 |
< |
* CAS given slot of q to null. Caller must ensure q is nonnull |
504 |
< |
* and index is in range. |
503 |
> |
* CASes slot i of array q from t to null. Caller must ensure q is |
504 |
> |
* non-null and index is in range. |
505 |
|
*/ |
506 |
< |
private static boolean casSlotNull(ForkJoinTask<?>[] q, int i, |
507 |
< |
ForkJoinTask<?> t) { |
508 |
< |
return _unsafe.compareAndSwapObject(q, (i << qShift) + qBase, t, null); |
506 |
> |
private static final boolean casSlotNull(ForkJoinTask<?>[] q, int i, |
507 |
> |
ForkJoinTask<?> t) { |
508 |
> |
return UNSAFE.compareAndSwapObject(q, (i << qShift) + qBase, t, null); |
509 |
|
} |
510 |
|
|
511 |
|
/** |
512 |
< |
* Sets sp in store-order. |
512 |
> |
* Performs a volatile write of the given task at given slot of |
513 |
> |
* array q. Caller must ensure q is non-null and index is in |
514 |
> |
* range. This method is used only during resets and backouts. |
515 |
|
*/ |
516 |
< |
private void storeSp(int s) { |
517 |
< |
_unsafe.putOrderedInt(this, spOffset, s); |
516 |
> |
private static final void writeSlot(ForkJoinTask<?>[] q, int i, |
517 |
> |
ForkJoinTask<?> t) { |
518 |
> |
UNSAFE.putObjectVolatile(q, (i << qShift) + qBase, t); |
519 |
|
} |
520 |
|
|
521 |
< |
// Main queue methods |
521 |
> |
// queue methods |
522 |
|
|
523 |
|
/** |
524 |
< |
* Pushes a task. Called only by current thread. |
525 |
< |
* @param t the task. Caller must ensure nonnull |
524 |
> |
* Pushes a task. Call only from this thread. |
525 |
> |
* |
526 |
> |
* @param t the task. Caller must ensure non-null. |
527 |
|
*/ |
528 |
|
final void pushTask(ForkJoinTask<?> t) { |
529 |
|
ForkJoinTask<?>[] q = queue; |
530 |
< |
int mask = q.length - 1; |
531 |
< |
int s = sp; |
532 |
< |
setSlot(q, s & mask, t); |
533 |
< |
storeSp(++s); |
534 |
< |
if ((s -= base) == 1) |
535 |
< |
pool.signalWork(); |
536 |
< |
else if (s >= mask) |
442 |
< |
growQueue(); |
530 |
> |
int mask = q.length - 1; // implicit assert q != null |
531 |
> |
int s = sp++; // ok to increment sp before slot write |
532 |
> |
UNSAFE.putOrderedObject(q, ((s & mask) << qShift) + qBase, t); |
533 |
> |
if ((s -= base) == 0) |
534 |
> |
pool.signalWork(); // was empty |
535 |
> |
else if (s == mask) |
536 |
> |
growQueue(); // is full |
537 |
|
} |
538 |
|
|
539 |
|
/** |
540 |
|
* Tries to take a task from the base of the queue, failing if |
541 |
< |
* either empty or contended. |
542 |
< |
* @return a task, or null if none or contended. |
541 |
> |
* empty or contended. Note: Specializations of this code appear |
542 |
> |
* in locallyDeqTask and elsewhere. |
543 |
> |
* |
544 |
> |
* @return a task, or null if none or contended |
545 |
|
*/ |
546 |
|
final ForkJoinTask<?> deqTask() { |
547 |
|
ForkJoinTask<?> t; |
548 |
|
ForkJoinTask<?>[] q; |
549 |
< |
int i; |
454 |
< |
int b; |
549 |
> |
int b, i; |
550 |
|
if (sp != (b = base) && |
551 |
|
(q = queue) != null && // must read q after b |
552 |
< |
(t = q[i = (q.length - 1) & b]) != null && |
553 |
< |
casSlotNull(q, i, t)) { |
552 |
> |
(t = q[i = (q.length - 1) & b]) != null && base == b && |
553 |
> |
UNSAFE.compareAndSwapObject(q, (i << qShift) + qBase, t, null)) { |
554 |
|
base = b + 1; |
555 |
|
return t; |
556 |
|
} |
558 |
|
} |
559 |
|
|
560 |
|
/** |
561 |
< |
* Returns a popped task, or null if empty. Ensures active status |
562 |
< |
* if nonnull. Called only by current thread. |
561 |
> |
* Tries to take a task from the base of own queue. Assumes active |
562 |
> |
* status. Called only by current thread. |
563 |
> |
* |
564 |
> |
* @return a task, or null if none |
565 |
|
*/ |
566 |
< |
final ForkJoinTask<?> popTask() { |
567 |
< |
int s = sp; |
568 |
< |
while (s != base) { |
569 |
< |
if (tryActivate()) { |
570 |
< |
ForkJoinTask<?>[] q = queue; |
571 |
< |
int mask = q.length - 1; |
572 |
< |
int i = (s - 1) & mask; |
566 |
> |
final ForkJoinTask<?> locallyDeqTask() { |
567 |
> |
ForkJoinTask<?>[] q = queue; |
568 |
> |
if (q != null) { |
569 |
> |
ForkJoinTask<?> t; |
570 |
> |
int b, i; |
571 |
> |
while (sp != (b = base)) { |
572 |
> |
if ((t = q[i = (q.length - 1) & b]) != null && base == b && |
573 |
> |
UNSAFE.compareAndSwapObject(q, (i << qShift) + qBase, |
574 |
> |
t, null)) { |
575 |
> |
base = b + 1; |
576 |
> |
return t; |
577 |
> |
} |
578 |
> |
} |
579 |
> |
} |
580 |
> |
return null; |
581 |
> |
} |
582 |
> |
|
583 |
> |
/** |
584 |
> |
* Returns a popped task, or null if empty. Assumes active status. |
585 |
> |
* Called only by current thread. |
586 |
> |
*/ |
587 |
> |
private ForkJoinTask<?> popTask() { |
588 |
> |
ForkJoinTask<?>[] q = queue; |
589 |
> |
if (q != null) { |
590 |
> |
int s; |
591 |
> |
while ((s = sp) != base) { |
592 |
> |
int i = (q.length - 1) & --s; |
593 |
> |
long u = (i << qShift) + qBase; // raw offset |
594 |
|
ForkJoinTask<?> t = q[i]; |
595 |
< |
if (t == null || !casSlotNull(q, i, t)) |
595 |
> |
if (t == null) // lost to stealer |
596 |
|
break; |
597 |
< |
storeSp(s - 1); |
598 |
< |
return t; |
597 |
> |
if (UNSAFE.compareAndSwapObject(q, u, t, null)) { |
598 |
> |
sp = s; // putOrderedInt may encourage more timely write |
599 |
> |
// UNSAFE.putOrderedInt(this, spOffset, s); |
600 |
> |
return t; |
601 |
> |
} |
602 |
|
} |
603 |
|
} |
604 |
|
return null; |
605 |
|
} |
606 |
|
|
607 |
|
/** |
608 |
< |
* Specialized version of popTask to pop only if |
609 |
< |
* topmost element is the given task. Called only |
610 |
< |
* by current thread while active. |
611 |
< |
* @param t the task. Caller must ensure nonnull |
608 |
> |
* Specialized version of popTask to pop only if topmost element |
609 |
> |
* is the given task. Called only by current thread while |
610 |
> |
* active. |
611 |
> |
* |
612 |
> |
* @param t the task. Caller must ensure non-null. |
613 |
|
*/ |
614 |
|
final boolean unpushTask(ForkJoinTask<?> t) { |
615 |
+ |
int s; |
616 |
|
ForkJoinTask<?>[] q = queue; |
617 |
< |
int mask = q.length - 1; |
618 |
< |
int s = sp - 1; |
619 |
< |
if (casSlotNull(q, s & mask, t)) { |
620 |
< |
storeSp(s); |
617 |
> |
if ((s = sp) != base && q != null && |
618 |
> |
UNSAFE.compareAndSwapObject |
619 |
> |
(q, (((q.length - 1) & --s) << qShift) + qBase, t, null)) { |
620 |
> |
sp = s; |
621 |
> |
// UNSAFE.putOrderedInt(this, spOffset, s); |
622 |
|
return true; |
623 |
|
} |
624 |
|
return false; |
625 |
|
} |
626 |
|
|
627 |
|
/** |
628 |
< |
* Returns next task. |
628 |
> |
* Returns next task or null if empty or contended |
629 |
|
*/ |
630 |
|
final ForkJoinTask<?> peekTask() { |
631 |
|
ForkJoinTask<?>[] q = queue; |
632 |
|
if (q == null) |
633 |
|
return null; |
634 |
|
int mask = q.length - 1; |
635 |
< |
int i = locallyFifo? base : (sp - 1); |
635 |
> |
int i = locallyFifo ? base : (sp - 1); |
636 |
|
return q[i & mask]; |
637 |
|
} |
638 |
|
|
658 |
|
ForkJoinTask<?> t = oldQ[oldIndex]; |
659 |
|
if (t != null && !casSlotNull(oldQ, oldIndex, t)) |
660 |
|
t = null; |
661 |
< |
setSlot(newQ, b & newMask, t); |
661 |
> |
writeSlot(newQ, b & newMask, t); |
662 |
|
} while (++b != bf); |
663 |
|
pool.signalWork(); |
664 |
|
} |
665 |
|
|
666 |
|
/** |
667 |
+ |
* Computes next value for random victim probe in scan(). Scans |
668 |
+ |
* don't require a very high quality generator, but also not a |
669 |
+ |
* crummy one. Marsaglia xor-shift is cheap and works well enough. |
670 |
+ |
* Note: This is manually inlined in scan() |
671 |
+ |
*/ |
672 |
+ |
private static final int xorShift(int r) { |
673 |
+ |
r ^= r << 13; |
674 |
+ |
r ^= r >>> 17; |
675 |
+ |
return r ^ (r << 5); |
676 |
+ |
} |
677 |
+ |
|
678 |
+ |
/** |
679 |
|
* Tries to steal a task from another worker. Starts at a random |
680 |
|
* index of workers array, and probes workers until finding one |
681 |
|
* with non-empty queue or finding that all are empty. It |
682 |
|
* randomly selects the first n probes. If these are empty, it |
683 |
< |
* resorts to a full circular traversal, which is necessary to |
684 |
< |
* accurately set active status by caller. Also restarts if pool |
685 |
< |
* events occurred since last scan, which forces refresh of |
686 |
< |
* workers array, in case barrier was associated with resize. |
683 |
> |
* resorts to a circular sweep, which is necessary to accurately |
684 |
> |
* set active status. (The circular sweep uses steps of |
685 |
> |
* approximately half the array size plus 1, to avoid bias |
686 |
> |
* stemming from leftmost packing of the array in ForkJoinPool.) |
687 |
|
* |
688 |
|
* This method must be both fast and quiet -- usually avoiding |
689 |
|
* memory accesses that could disrupt cache sharing etc other than |
690 |
< |
* those needed to check for and take tasks. This accounts for, |
691 |
< |
* among other things, updating random seed in place without |
692 |
< |
* storing it until exit. |
690 |
> |
* those needed to check for and take tasks (or to activate if not |
691 |
> |
* already active). This accounts for, among other things, |
692 |
> |
* updating random seed in place without storing it until exit. |
693 |
|
* |
694 |
|
* @return a task, or null if none found |
695 |
|
*/ |
696 |
|
private ForkJoinTask<?> scan() { |
697 |
< |
ForkJoinTask<?> t = null; |
698 |
< |
int r = seed; // extract once to keep scan quiet |
699 |
< |
ForkJoinWorkerThread[] ws; // refreshed on outer loop |
700 |
< |
int mask; // must be power 2 minus 1 and > 0 |
701 |
< |
outer:do { |
702 |
< |
if ((ws = pool.workers) != null && (mask = ws.length - 1) > 0) { |
703 |
< |
int idx = r; |
704 |
< |
int probes = ~mask; // use random index while negative |
705 |
< |
for (;;) { |
706 |
< |
r = xorShift(r); // update random seed |
707 |
< |
ForkJoinWorkerThread v = ws[mask & idx]; |
708 |
< |
if (v == null || v.sp == v.base) { |
709 |
< |
if (probes <= mask) |
710 |
< |
idx = (probes++ < 0)? r : (idx + 1); |
711 |
< |
else |
712 |
< |
break; |
697 |
> |
ForkJoinPool p = pool; |
698 |
> |
ForkJoinWorkerThread[] ws; // worker array |
699 |
> |
int n; // upper bound of #workers |
700 |
> |
if ((ws = p.workers) != null && (n = ws.length) > 1) { |
701 |
> |
boolean canSteal = active; // shadow active status |
702 |
> |
int r = seed; // extract seed once |
703 |
> |
int mask = n - 1; |
704 |
> |
int j = -n; // loop counter |
705 |
> |
int k = r; // worker index, random if j < 0 |
706 |
> |
for (;;) { |
707 |
> |
ForkJoinWorkerThread v = ws[k & mask]; |
708 |
> |
r ^= r << 13; r ^= r >>> 17; r ^= r << 5; // inline xorshift |
709 |
> |
if (v != null && v.base != v.sp) { |
710 |
> |
ForkJoinTask<?>[] q; int b; |
711 |
> |
if ((canSteal || // ensure active status |
712 |
> |
(canSteal = active = p.tryIncrementActiveCount())) && |
713 |
> |
(q = v.queue) != null && (b = v.base) != v.sp) { |
714 |
> |
int i = (q.length - 1) & b; |
715 |
> |
long u = (i << qShift) + qBase; // raw offset |
716 |
> |
ForkJoinTask<?> t = q[i]; |
717 |
> |
if (v.base == b && t != null && |
718 |
> |
UNSAFE.compareAndSwapObject(q, u, t, null)) { |
719 |
> |
int pid = poolIndex; |
720 |
> |
currentSteal = t; |
721 |
> |
v.stealHint = pid; |
722 |
> |
v.base = b + 1; |
723 |
> |
seed = r; |
724 |
> |
++stealCount; |
725 |
> |
return t; |
726 |
> |
} |
727 |
|
} |
728 |
< |
else if (!tryActivate() || (t = v.deqTask()) == null) |
729 |
< |
continue outer; // restart on contention |
580 |
< |
else |
581 |
< |
break outer; |
728 |
> |
j = -n; |
729 |
> |
k = r; // restart on contention |
730 |
|
} |
731 |
+ |
else if (++j <= 0) |
732 |
+ |
k = r; |
733 |
+ |
else if (j <= n) |
734 |
+ |
k += (n >>> 1) | 1; |
735 |
+ |
else |
736 |
+ |
break; |
737 |
|
} |
738 |
< |
} while (pool.hasNewSyncEvent(this)); // retry on pool events |
739 |
< |
seed = r; |
586 |
< |
return t; |
738 |
> |
} |
739 |
> |
return null; |
740 |
|
} |
741 |
|
|
742 |
+ |
// Run State management |
743 |
+ |
|
744 |
+ |
// status check methods used mainly by ForkJoinPool |
745 |
+ |
final boolean isRunning() { return runState == 0; } |
746 |
+ |
final boolean isTerminating() { return (runState & TERMINATING) != 0; } |
747 |
+ |
final boolean isTerminated() { return (runState & TERMINATED) != 0; } |
748 |
+ |
final boolean isSuspended() { return (runState & SUSPENDED) != 0; } |
749 |
+ |
final boolean isTrimmed() { return (runState & TRIMMED) != 0; } |
750 |
+ |
|
751 |
|
/** |
752 |
< |
* gets and removes a local or stolen a task |
753 |
< |
* @return a task, if available |
752 |
> |
* Sets state to TERMINATING, also, unless "quiet", unparking if |
753 |
> |
* not already terminated |
754 |
> |
* |
755 |
> |
* @param quiet don't unpark (used for faster status updates on |
756 |
> |
* pool termination) |
757 |
|
*/ |
758 |
< |
final ForkJoinTask<?> pollTask() { |
759 |
< |
ForkJoinTask<?> t = locallyFifo? deqTask() : popTask(); |
760 |
< |
if (t == null && (t = scan()) != null) |
761 |
< |
++stealCount; |
762 |
< |
return t; |
758 |
> |
final void shutdown(boolean quiet) { |
759 |
> |
for (;;) { |
760 |
> |
int s = runState; |
761 |
> |
if ((s & (TERMINATING|TERMINATED)) != 0) |
762 |
> |
break; |
763 |
> |
if ((s & SUSPENDED) != 0) { // kill and wakeup if suspended |
764 |
> |
if (UNSAFE.compareAndSwapInt(this, runStateOffset, s, |
765 |
> |
(s & ~SUSPENDED) | |
766 |
> |
(TRIMMED|TERMINATING))) |
767 |
> |
break; |
768 |
> |
} |
769 |
> |
else if (UNSAFE.compareAndSwapInt(this, runStateOffset, s, |
770 |
> |
s | TERMINATING)) |
771 |
> |
break; |
772 |
> |
} |
773 |
> |
if (!quiet && (runState & TERMINATED) != 0) |
774 |
> |
LockSupport.unpark(this); |
775 |
|
} |
776 |
|
|
777 |
|
/** |
778 |
< |
* gets a local task |
602 |
< |
* @return a task, if available |
778 |
> |
* Sets state to TERMINATED. Called only by onTermination() |
779 |
|
*/ |
780 |
< |
final ForkJoinTask<?> pollLocalTask() { |
781 |
< |
return locallyFifo? deqTask() : popTask(); |
780 |
> |
private void setTerminated() { |
781 |
> |
int s; |
782 |
> |
do {} while (!UNSAFE.compareAndSwapInt(this, runStateOffset, |
783 |
> |
s = runState, |
784 |
> |
s | (TERMINATING|TERMINATED))); |
785 |
|
} |
786 |
|
|
787 |
|
/** |
788 |
< |
* Returns a pool submission, if one exists, activating first. |
789 |
< |
* @return a submission, if available |
788 |
> |
* If suspended, tries to set status to unsuspended and unparks. |
789 |
> |
* |
790 |
> |
* @return true if successful |
791 |
|
*/ |
792 |
< |
private ForkJoinTask<?> pollSubmission() { |
792 |
> |
final boolean tryUnsuspend() { |
793 |
> |
int s; |
794 |
> |
while (((s = runState) & SUSPENDED) != 0) { |
795 |
> |
if (UNSAFE.compareAndSwapInt(this, runStateOffset, s, |
796 |
> |
s & ~SUSPENDED)) |
797 |
> |
return true; |
798 |
> |
} |
799 |
> |
return false; |
800 |
> |
} |
801 |
> |
|
802 |
> |
/** |
803 |
> |
* Sets suspended status and blocks as spare until resumed |
804 |
> |
* or shutdown. |
805 |
> |
* @returns true if still running on exit |
806 |
> |
*/ |
807 |
> |
final boolean suspendAsSpare() { |
808 |
> |
lastEventCount = 0; // reset upon resume |
809 |
> |
for (;;) { // set suspended unless terminating |
810 |
> |
int s = runState; |
811 |
> |
if ((s & TERMINATING) != 0) { // must kill |
812 |
> |
if (UNSAFE.compareAndSwapInt(this, runStateOffset, s, |
813 |
> |
s | (TRIMMED | TERMINATING))) |
814 |
> |
return false; |
815 |
> |
} |
816 |
> |
else if (UNSAFE.compareAndSwapInt(this, runStateOffset, s, |
817 |
> |
s | SUSPENDED)) |
818 |
> |
break; |
819 |
> |
} |
820 |
|
ForkJoinPool p = pool; |
821 |
< |
while (p.hasQueuedSubmissions()) { |
822 |
< |
ForkJoinTask<?> t; |
823 |
< |
if (tryActivate() && (t = p.pollSubmission()) != null) |
824 |
< |
return t; |
821 |
> |
p.pushSpare(this); |
822 |
> |
while ((runState & SUSPENDED) != 0) { |
823 |
> |
if (!p.tryAccumulateStealCount(this)) |
824 |
> |
continue; |
825 |
> |
interrupted(); // clear/ignore interrupts |
826 |
> |
if ((runState & SUSPENDED) == 0) |
827 |
> |
break; |
828 |
> |
if (nextSpare != 0) // untimed |
829 |
> |
LockSupport.park(this); |
830 |
> |
else { |
831 |
> |
long startTime = System.nanoTime(); |
832 |
> |
LockSupport.parkNanos(this, TRIM_RATE_NANOS); |
833 |
> |
if ((runState & SUSPENDED) == 0) |
834 |
> |
break; |
835 |
> |
long now = System.nanoTime(); |
836 |
> |
if (now - startTime >= TRIM_RATE_NANOS) |
837 |
> |
pool.tryTrimSpare(now); |
838 |
> |
} |
839 |
|
} |
840 |
< |
return null; |
840 |
> |
return runState == 0; |
841 |
|
} |
842 |
|
|
843 |
< |
// Methods accessed only by Pool |
843 |
> |
// Misc support methods for ForkJoinPool |
844 |
> |
|
845 |
> |
/** |
846 |
> |
* Returns an estimate of the number of tasks in the queue. Also |
847 |
> |
* used by ForkJoinTask. |
848 |
> |
*/ |
849 |
> |
final int getQueueSize() { |
850 |
> |
int n; // external calls must read base first |
851 |
> |
return (n = -base + sp) <= 0 ? 0 : n; |
852 |
> |
} |
853 |
|
|
854 |
|
/** |
855 |
|
* Removes and cancels all tasks in queue. Can be called from any |
856 |
|
* thread. |
857 |
|
*/ |
858 |
|
final void cancelTasks() { |
859 |
< |
ForkJoinTask<?> t; |
860 |
< |
while (base != sp && (t = deqTask()) != null) |
861 |
< |
t.cancelIgnoringExceptions(); |
859 |
> |
ForkJoinTask<?> cj = currentJoin; // try to cancel ongoing tasks |
860 |
> |
if (cj != null) { |
861 |
> |
currentJoin = null; |
862 |
> |
cj.cancelIgnoringExceptions(); |
863 |
> |
try { |
864 |
> |
this.interrupt(); // awaken wait |
865 |
> |
} catch (SecurityException ignore) { |
866 |
> |
} |
867 |
> |
} |
868 |
> |
ForkJoinTask<?> cs = currentSteal; |
869 |
> |
if (cs != null) { |
870 |
> |
currentSteal = null; |
871 |
> |
cs.cancelIgnoringExceptions(); |
872 |
> |
} |
873 |
> |
while (base != sp) { |
874 |
> |
ForkJoinTask<?> t = deqTask(); |
875 |
> |
if (t != null) |
876 |
> |
t.cancelIgnoringExceptions(); |
877 |
> |
} |
878 |
|
} |
879 |
|
|
880 |
|
/** |
881 |
< |
* Drains tasks to given collection c |
881 |
> |
* Drains tasks to given collection c. |
882 |
> |
* |
883 |
|
* @return the number of tasks drained |
884 |
|
*/ |
885 |
< |
final int drainTasksTo(Collection<ForkJoinTask<?>> c) { |
885 |
> |
final int drainTasksTo(Collection<? super ForkJoinTask<?>> c) { |
886 |
|
int n = 0; |
887 |
< |
ForkJoinTask<?> t; |
888 |
< |
while (base != sp && (t = deqTask()) != null) { |
889 |
< |
c.add(t); |
890 |
< |
++n; |
887 |
> |
while (base != sp) { |
888 |
> |
ForkJoinTask<?> t = deqTask(); |
889 |
> |
if (t != null) { |
890 |
> |
c.add(t); |
891 |
> |
++n; |
892 |
> |
} |
893 |
|
} |
894 |
|
return n; |
895 |
|
} |
896 |
|
|
897 |
+ |
// Support methods for ForkJoinTask |
898 |
+ |
|
899 |
|
/** |
900 |
< |
* Get and clear steal count for accumulation by pool. Called |
901 |
< |
* only when known to be idle (in pool.sync and termination). |
900 |
> |
* Gets and removes a local task. |
901 |
> |
* |
902 |
> |
* @return a task, if available |
903 |
|
*/ |
904 |
< |
final int getAndClearStealCount() { |
905 |
< |
int sc = stealCount; |
906 |
< |
stealCount = 0; |
907 |
< |
return sc; |
904 |
> |
final ForkJoinTask<?> pollLocalTask() { |
905 |
> |
while (sp != base) { |
906 |
> |
if (active || (active = pool.tryIncrementActiveCount())) |
907 |
> |
return locallyFifo? locallyDeqTask() : popTask(); |
908 |
> |
} |
909 |
> |
return null; |
910 |
|
} |
911 |
|
|
912 |
|
/** |
913 |
< |
* Returns true if at least one worker in the given array appears |
914 |
< |
* to have at least one queued task. |
915 |
< |
* @param ws array of workers |
916 |
< |
*/ |
917 |
< |
static boolean hasQueuedTasks(ForkJoinWorkerThread[] ws) { |
918 |
< |
if (ws != null) { |
919 |
< |
int len = ws.length; |
920 |
< |
for (int j = 0; j < 2; ++j) { // need two passes for clean sweep |
921 |
< |
for (int i = 0; i < len; ++i) { |
668 |
< |
ForkJoinWorkerThread w = ws[i]; |
669 |
< |
if (w != null && w.sp != w.base) |
670 |
< |
return true; |
671 |
< |
} |
672 |
< |
} |
913 |
> |
* Gets and removes a local or stolen task. |
914 |
> |
* |
915 |
> |
* @return a task, if available |
916 |
> |
*/ |
917 |
> |
final ForkJoinTask<?> pollTask() { |
918 |
> |
ForkJoinTask<?> t = pollLocalTask(); |
919 |
> |
if (t == null) { |
920 |
> |
t = scan(); |
921 |
> |
currentSteal = null; // cannot retain/track/help |
922 |
|
} |
923 |
< |
return false; |
923 |
> |
return t; |
924 |
|
} |
925 |
|
|
677 |
– |
// Support methods for ForkJoinTask |
678 |
– |
|
926 |
|
/** |
927 |
< |
* Returns an estimate of the number of tasks in the queue. |
927 |
> |
* Possibly runs some tasks and/or blocks, until task is done. |
928 |
> |
* |
929 |
> |
* @param joinMe the task to join |
930 |
|
*/ |
931 |
< |
final int getQueueSize() { |
932 |
< |
int n = sp - base; |
933 |
< |
return n < 0? 0 : n; // suppress momentarily negative values |
931 |
> |
final void joinTask(ForkJoinTask<?> joinMe) { |
932 |
> |
// currentJoin only written by this thread; only need ordered store |
933 |
> |
ForkJoinTask<?> prevJoin = currentJoin; |
934 |
> |
UNSAFE.putOrderedObject(this, currentJoinOffset, joinMe); |
935 |
> |
if (sp != base) |
936 |
> |
localHelpJoinTask(joinMe); |
937 |
> |
if (joinMe.status >= 0) |
938 |
> |
pool.awaitJoin(joinMe, this); |
939 |
> |
UNSAFE.putOrderedObject(this, currentJoinOffset, prevJoin); |
940 |
|
} |
941 |
|
|
942 |
|
/** |
943 |
< |
* Returns an estimate of the number of tasks, offset by a |
944 |
< |
* function of number of idle workers. |
943 |
> |
* Run tasks in local queue until given task is done. |
944 |
> |
* |
945 |
> |
* @param joinMe the task to join |
946 |
|
*/ |
947 |
< |
final int getEstimatedSurplusTaskCount() { |
948 |
< |
// The halving approximates weighting idle vs non-idle workers |
949 |
< |
return (sp - base) - (pool.getIdleThreadCount() >>> 1); |
947 |
> |
private void localHelpJoinTask(ForkJoinTask<?> joinMe) { |
948 |
> |
int s; |
949 |
> |
ForkJoinTask<?>[] q; |
950 |
> |
while (joinMe.status >= 0 && (s = sp) != base && (q = queue) != null) { |
951 |
> |
int i = (q.length - 1) & --s; |
952 |
> |
long u = (i << qShift) + qBase; // raw offset |
953 |
> |
ForkJoinTask<?> t = q[i]; |
954 |
> |
if (t == null) // lost to a stealer |
955 |
> |
break; |
956 |
> |
if (UNSAFE.compareAndSwapObject(q, u, t, null)) { |
957 |
> |
/* |
958 |
> |
* This recheck (and similarly in helpJoinTask) |
959 |
> |
* handles cases where joinMe is independently |
960 |
> |
* cancelled or forced even though there is other work |
961 |
> |
* available. Back out of the pop by putting t back |
962 |
> |
* into slot before we commit by writing sp. |
963 |
> |
*/ |
964 |
> |
if (joinMe.status < 0) { |
965 |
> |
UNSAFE.putObjectVolatile(q, u, t); |
966 |
> |
break; |
967 |
> |
} |
968 |
> |
sp = s; |
969 |
> |
// UNSAFE.putOrderedInt(this, spOffset, s); |
970 |
> |
t.quietlyExec(); |
971 |
> |
} |
972 |
> |
} |
973 |
|
} |
974 |
|
|
975 |
|
/** |
976 |
< |
* Scan, returning early if joinMe done |
976 |
> |
* Tries to locate and help perform tasks for a stealer of the |
977 |
> |
* given task, or in turn one of its stealers. Traces |
978 |
> |
* currentSteal->currentJoin links looking for a thread working on |
979 |
> |
* a descendant of the given task and with a non-empty queue to |
980 |
> |
* steal back and execute tasks from. |
981 |
> |
* |
982 |
> |
* The implementation is very branchy to cope with the potential |
983 |
> |
* inconsistencies or loops encountering chains that are stale, |
984 |
> |
* unknown, or of length greater than MAX_HELP_DEPTH links. All |
985 |
> |
* of these cases are dealt with by just returning back to the |
986 |
> |
* caller, who is expected to retry if other join mechanisms also |
987 |
> |
* don't work out. |
988 |
> |
* |
989 |
> |
* @param joinMe the task to join |
990 |
|
*/ |
991 |
< |
final ForkJoinTask<?> scanWhileJoining(ForkJoinTask<?> joinMe) { |
992 |
< |
ForkJoinTask<?> t = pollTask(); |
993 |
< |
if (t != null && joinMe.status < 0 && sp == base) { |
994 |
< |
pushTask(t); // unsteal if done and this task would be stealable |
995 |
< |
t = null; |
991 |
> |
final void helpJoinTask(ForkJoinTask<?> joinMe) { |
992 |
> |
ForkJoinWorkerThread[] ws = pool.workers; |
993 |
> |
int n; // need at least 2 workers |
994 |
> |
if (ws != null && (n = ws.length) > 1 && joinMe.status >= 0) { |
995 |
> |
ForkJoinTask<?> task = joinMe; // base of chain |
996 |
> |
ForkJoinWorkerThread thread = this; // thread with stolen task |
997 |
> |
for (int d = 0; d < MAX_HELP_DEPTH; ++d) { // chain length |
998 |
> |
// Try to find v, the stealer of task, by first using hint |
999 |
> |
ForkJoinWorkerThread v = ws[thread.stealHint & (n - 1)]; |
1000 |
> |
if (v == null || v.currentSteal != task) { |
1001 |
> |
for (int j = 0; ; ++j) { // search array |
1002 |
> |
if (j < n) { |
1003 |
> |
if ((v = ws[j]) != null) { |
1004 |
> |
if (task.status < 0) |
1005 |
> |
return; // stale or done |
1006 |
> |
if (v.currentSteal == task) { |
1007 |
> |
thread.stealHint = j; |
1008 |
> |
break; // save hint for next time |
1009 |
> |
} |
1010 |
> |
} |
1011 |
> |
} |
1012 |
> |
else |
1013 |
> |
return; // no stealer |
1014 |
> |
} |
1015 |
> |
} |
1016 |
> |
// Try to help v, using specialized form of deqTask |
1017 |
> |
int b; |
1018 |
> |
ForkJoinTask<?>[] q; |
1019 |
> |
while ((b = v.base) != v.sp && (q = v.queue) != null) { |
1020 |
> |
int i = (q.length - 1) & b; |
1021 |
> |
long u = (i << qShift) + qBase; |
1022 |
> |
ForkJoinTask<?> t = q[i]; |
1023 |
> |
if (task.status < 0) |
1024 |
> |
return; // stale or done |
1025 |
> |
if (v.base == b) { |
1026 |
> |
if (t == null) |
1027 |
> |
return; // producer stalled |
1028 |
> |
if (UNSAFE.compareAndSwapObject(q, u, t, null)) { |
1029 |
> |
if (joinMe.status < 0) { |
1030 |
> |
UNSAFE.putObjectVolatile(q, u, t); |
1031 |
> |
return; // back out on cancel |
1032 |
> |
} |
1033 |
> |
int pid = poolIndex; |
1034 |
> |
ForkJoinTask<?> prevSteal = currentSteal; |
1035 |
> |
currentSteal = t; |
1036 |
> |
v.stealHint = pid; |
1037 |
> |
v.base = b + 1; |
1038 |
> |
t.quietlyExec(); |
1039 |
> |
currentSteal = prevSteal; |
1040 |
> |
} |
1041 |
> |
} |
1042 |
> |
if (joinMe.status < 0) |
1043 |
> |
return; |
1044 |
> |
} |
1045 |
> |
// Try to descend to find v's stealer |
1046 |
> |
ForkJoinTask<?> next = v.currentJoin; |
1047 |
> |
if (task.status < 0 || next == null || next == task || |
1048 |
> |
joinMe.status < 0) |
1049 |
> |
return; |
1050 |
> |
task = next; |
1051 |
> |
thread = v; |
1052 |
> |
} |
1053 |
|
} |
705 |
– |
return t; |
1054 |
|
} |
1055 |
|
|
1056 |
|
/** |
1057 |
< |
* Runs tasks until pool isQuiescent |
1057 |
> |
* Returns an estimate of the number of tasks, offset by a |
1058 |
> |
* function of number of idle workers. |
1059 |
> |
* |
1060 |
> |
* This method provides a cheap heuristic guide for task |
1061 |
> |
* partitioning when programmers, frameworks, tools, or languages |
1062 |
> |
* have little or no idea about task granularity. In essence by |
1063 |
> |
* offering this method, we ask users only about tradeoffs in |
1064 |
> |
* overhead vs expected throughput and its variance, rather than |
1065 |
> |
* how finely to partition tasks. |
1066 |
> |
* |
1067 |
> |
* In a steady state strict (tree-structured) computation, each |
1068 |
> |
* thread makes available for stealing enough tasks for other |
1069 |
> |
* threads to remain active. Inductively, if all threads play by |
1070 |
> |
* the same rules, each thread should make available only a |
1071 |
> |
* constant number of tasks. |
1072 |
> |
* |
1073 |
> |
* The minimum useful constant is just 1. But using a value of 1 |
1074 |
> |
* would require immediate replenishment upon each steal to |
1075 |
> |
* maintain enough tasks, which is infeasible. Further, |
1076 |
> |
* partitionings/granularities of offered tasks should minimize |
1077 |
> |
* steal rates, which in general means that threads nearer the top |
1078 |
> |
* of computation tree should generate more than those nearer the |
1079 |
> |
* bottom. In perfect steady state, each thread is at |
1080 |
> |
* approximately the same level of computation tree. However, |
1081 |
> |
* producing extra tasks amortizes the uncertainty of progress and |
1082 |
> |
* diffusion assumptions. |
1083 |
> |
* |
1084 |
> |
* So, users will want to use values larger, but not much larger |
1085 |
> |
* than 1 to both smooth over transient shortages and hedge |
1086 |
> |
* against uneven progress; as traded off against the cost of |
1087 |
> |
* extra task overhead. We leave the user to pick a threshold |
1088 |
> |
* value to compare with the results of this call to guide |
1089 |
> |
* decisions, but recommend values such as 3. |
1090 |
> |
* |
1091 |
> |
* When all threads are active, it is on average OK to estimate |
1092 |
> |
* surplus strictly locally. In steady-state, if one thread is |
1093 |
> |
* maintaining say 2 surplus tasks, then so are others. So we can |
1094 |
> |
* just use estimated queue length (although note that (sp - base) |
1095 |
> |
* can be an overestimate because of stealers lagging increments |
1096 |
> |
* of base). However, this strategy alone leads to serious |
1097 |
> |
* mis-estimates in some non-steady-state conditions (ramp-up, |
1098 |
> |
* ramp-down, other stalls). We can detect many of these by |
1099 |
> |
* further considering the number of "idle" threads, that are |
1100 |
> |
* known to have zero queued tasks, so compensate by a factor of |
1101 |
> |
* (#idle/#active) threads. |
1102 |
> |
*/ |
1103 |
> |
final int getEstimatedSurplusTaskCount() { |
1104 |
> |
return sp - base - pool.idlePerActive(); |
1105 |
> |
} |
1106 |
> |
|
1107 |
> |
/** |
1108 |
> |
* Runs tasks until {@code pool.isQuiescent()}. |
1109 |
|
*/ |
1110 |
|
final void helpQuiescePool() { |
1111 |
|
for (;;) { |
1112 |
< |
ForkJoinTask<?> t = pollTask(); |
1113 |
< |
if (t != null) |
1112 |
> |
ForkJoinTask<?> t = pollLocalTask(); |
1113 |
> |
if (t != null || (t = scan()) != null) { |
1114 |
|
t.quietlyExec(); |
1115 |
< |
else if (tryInactivate() && pool.isQuiescent()) |
1116 |
< |
break; |
1115 |
> |
currentSteal = null; |
1116 |
> |
} |
1117 |
> |
else { |
1118 |
> |
ForkJoinPool p = pool; |
1119 |
> |
if (active) { |
1120 |
> |
if (!p.tryDecrementActiveCount()) |
1121 |
> |
continue; // retry later |
1122 |
> |
active = false; // inactivate |
1123 |
> |
} |
1124 |
> |
if (p.isQuiescent()) { |
1125 |
> |
active = true; // re-activate |
1126 |
> |
do {} while (!p.tryIncrementActiveCount()); |
1127 |
> |
return; |
1128 |
> |
} |
1129 |
> |
} |
1130 |
> |
} |
1131 |
> |
} |
1132 |
> |
|
1133 |
> |
// Unsafe mechanics |
1134 |
> |
|
1135 |
> |
private static final sun.misc.Unsafe UNSAFE = getUnsafe(); |
1136 |
> |
private static final long spOffset = |
1137 |
> |
objectFieldOffset("sp", ForkJoinWorkerThread.class); |
1138 |
> |
private static final long runStateOffset = |
1139 |
> |
objectFieldOffset("runState", ForkJoinWorkerThread.class); |
1140 |
> |
private static final long currentJoinOffset = |
1141 |
> |
objectFieldOffset("currentJoin", ForkJoinWorkerThread.class); |
1142 |
> |
private static final long currentStealOffset = |
1143 |
> |
objectFieldOffset("currentSteal", ForkJoinWorkerThread.class); |
1144 |
> |
private static final long qBase = |
1145 |
> |
UNSAFE.arrayBaseOffset(ForkJoinTask[].class); |
1146 |
> |
|
1147 |
> |
private static final int qShift; |
1148 |
> |
|
1149 |
> |
static { |
1150 |
> |
int s = UNSAFE.arrayIndexScale(ForkJoinTask[].class); |
1151 |
> |
if ((s & (s-1)) != 0) |
1152 |
> |
throw new Error("data type scale not a power of two"); |
1153 |
> |
qShift = 31 - Integer.numberOfLeadingZeros(s); |
1154 |
> |
} |
1155 |
> |
|
1156 |
> |
private static long objectFieldOffset(String field, Class<?> klazz) { |
1157 |
> |
try { |
1158 |
> |
return UNSAFE.objectFieldOffset(klazz.getDeclaredField(field)); |
1159 |
> |
} catch (NoSuchFieldException e) { |
1160 |
> |
// Convert Exception to corresponding Error |
1161 |
> |
NoSuchFieldError error = new NoSuchFieldError(field); |
1162 |
> |
error.initCause(e); |
1163 |
> |
throw error; |
1164 |
|
} |
719 |
– |
do;while (!tryActivate()); // re-activate on exit |
1165 |
|
} |
1166 |
|
|
1167 |
< |
// Temporary Unsafe mechanics for preliminary release |
1168 |
< |
private static Unsafe getUnsafe() throws Throwable { |
1167 |
> |
/** |
1168 |
> |
* Returns a sun.misc.Unsafe. Suitable for use in a 3rd party package. |
1169 |
> |
* Replace with a simple call to Unsafe.getUnsafe when integrating |
1170 |
> |
* into a jdk. |
1171 |
> |
* |
1172 |
> |
* @return a sun.misc.Unsafe |
1173 |
> |
*/ |
1174 |
> |
private static sun.misc.Unsafe getUnsafe() { |
1175 |
|
try { |
1176 |
< |
return Unsafe.getUnsafe(); |
1176 |
> |
return sun.misc.Unsafe.getUnsafe(); |
1177 |
|
} catch (SecurityException se) { |
1178 |
|
try { |
1179 |
|
return java.security.AccessController.doPrivileged |
1180 |
< |
(new java.security.PrivilegedExceptionAction<Unsafe>() { |
1181 |
< |
public Unsafe run() throws Exception { |
1182 |
< |
return getUnsafePrivileged(); |
1180 |
> |
(new java.security |
1181 |
> |
.PrivilegedExceptionAction<sun.misc.Unsafe>() { |
1182 |
> |
public sun.misc.Unsafe run() throws Exception { |
1183 |
> |
java.lang.reflect.Field f = sun.misc |
1184 |
> |
.Unsafe.class.getDeclaredField("theUnsafe"); |
1185 |
> |
f.setAccessible(true); |
1186 |
> |
return (sun.misc.Unsafe) f.get(null); |
1187 |
|
}}); |
1188 |
|
} catch (java.security.PrivilegedActionException e) { |
1189 |
< |
throw e.getCause(); |
1189 |
> |
throw new RuntimeException("Could not initialize intrinsics", |
1190 |
> |
e.getCause()); |
1191 |
|
} |
1192 |
|
} |
1193 |
|
} |
738 |
– |
|
739 |
– |
private static Unsafe getUnsafePrivileged() |
740 |
– |
throws NoSuchFieldException, IllegalAccessException { |
741 |
– |
Field f = Unsafe.class.getDeclaredField("theUnsafe"); |
742 |
– |
f.setAccessible(true); |
743 |
– |
return (Unsafe) f.get(null); |
744 |
– |
} |
745 |
– |
|
746 |
– |
private static long fieldOffset(String fieldName) |
747 |
– |
throws NoSuchFieldException { |
748 |
– |
return _unsafe.objectFieldOffset |
749 |
– |
(ForkJoinWorkerThread.class.getDeclaredField(fieldName)); |
750 |
– |
} |
751 |
– |
|
752 |
– |
static final Unsafe _unsafe; |
753 |
– |
static final long baseOffset; |
754 |
– |
static final long spOffset; |
755 |
– |
static final long runStateOffset; |
756 |
– |
static final long qBase; |
757 |
– |
static final int qShift; |
758 |
– |
static { |
759 |
– |
try { |
760 |
– |
_unsafe = getUnsafe(); |
761 |
– |
baseOffset = fieldOffset("base"); |
762 |
– |
spOffset = fieldOffset("sp"); |
763 |
– |
runStateOffset = fieldOffset("runState"); |
764 |
– |
qBase = _unsafe.arrayBaseOffset(ForkJoinTask[].class); |
765 |
– |
int s = _unsafe.arrayIndexScale(ForkJoinTask[].class); |
766 |
– |
if ((s & (s-1)) != 0) |
767 |
– |
throw new Error("data type scale not a power of two"); |
768 |
– |
qShift = 31 - Integer.numberOfLeadingZeros(s); |
769 |
– |
} catch (Throwable e) { |
770 |
– |
throw new RuntimeException("Could not initialize intrinsics", e); |
771 |
– |
} |
772 |
– |
} |
1194 |
|
} |