CountedCompleter
public
abstract
class
CountedCompleter
extends ForkJoinTask<T>
java.lang.Object | ||
↳ | java.util.concurrent.ForkJoinTask<T> | |
↳ | java.util.concurrent.CountedCompleter<T> |
A ForkJoinTask
with a completion action performed when
triggered and there are no remaining pending actions.
CountedCompleters are in general more robust in the
presence of subtask stalls and blockage than are other forms of
ForkJoinTasks, but are less intuitive to program. Uses of
CountedCompleter are similar to those of other completion based
components (such as CompletionHandler
)
except that multiple pending completions may be necessary
to trigger the completion action onCompletion(java.util.concurrent.CountedCompleter)
,
not just one.
Unless initialized otherwise, the pending
count starts at zero, but may be (atomically) changed using
methods setPendingCount(int)
, addToPendingCount(int)
, and
compareAndSetPendingCount(int, int)
. Upon invocation of tryComplete()
, if the pending action count is nonzero, it is
decremented; otherwise, the completion action is performed, and if
this completer itself has a completer, the process is continued
with its completer. As is the case with related synchronization
components such as Phaser
and Semaphore
, these methods
affect only internal counts; they do not establish any further
internal bookkeeping. In particular, the identities of pending
tasks are not maintained. As illustrated below, you can create
subclasses that do record some or all pending tasks or their
results when needed. As illustrated below, utility methods
supporting customization of completion traversals are also
provided. However, because CountedCompleters provide only basic
synchronization mechanisms, it may be useful to create further
abstract subclasses that maintain linkages, fields, and additional
support methods appropriate for a set of related usages.
A concrete CountedCompleter class must define method compute()
, that should in most cases (as illustrated below), invoke
tryComplete()
once before returning. The class may also
optionally override method onCompletion(java.util.concurrent.CountedCompleter)
to perform an action upon normal completion, and method
onExceptionalCompletion(java.lang.Throwable, java.util.concurrent.CountedCompleter)
to
perform an action upon any exception.
CountedCompleters most often do not bear results, in which case
they are normally declared as CountedCompleter<Void>
, and
will always return null
as a result value. In other cases,
you should override method getRawResult()
to provide a
result from join(), invoke()
, and related methods. In
general, this method should return the value of a field (or a
function of one or more fields) of the CountedCompleter object that
holds the result upon completion. Method setRawResult(T)
by
default plays no role in CountedCompleters. It is possible, but
rarely applicable, to override this method to maintain other
objects or fields holding result data.
A CountedCompleter that does not itself have a completer (i.e.,
one for which getCompleter()
returns null
) can be
used as a regular ForkJoinTask with this added functionality.
However, any completer that in turn has another completer serves
only as an internal helper for other computations, so its own task
status (as reported in methods such as ForkJoinTask#isDone
)
is arbitrary; this status changes only upon explicit invocations of
complete(T)
, ForkJoinTask#cancel
,
ForkJoinTask#completeExceptionally(Throwable)
or upon
exceptional completion of method compute
. Upon any
exceptional completion, the exception may be relayed to a task's
completer (and its completer, and so on), if one exists and it has
not otherwise already completed. Similarly, cancelling an internal
CountedCompleter has only a local effect on that completer, so is
not often useful.
Sample Usages.
Parallel recursive decomposition. CountedCompleters may
be arranged in trees similar to those often used with RecursiveAction
s, although the constructions involved in setting
them up typically vary. Here, the completer of each task is its
parent in the computation tree. Even though they entail a bit more
bookkeeping, CountedCompleters may be better choices when applying
a possibly time-consuming operation (that cannot be further
subdivided) to each element of an array or collection; especially
when the operation takes a significantly different amount of time
to complete for some elements than others, either because of
intrinsic variation (for example I/O) or auxiliary effects such as
garbage collection. Because CountedCompleters provide their own
continuations, other tasks need not block waiting to perform them.
For example, here is an initial version of a utility method that
uses divide-by-two recursive decomposition to divide work into
single pieces (leaf tasks). Even when work is split into individual
calls, tree-based techniques are usually preferable to directly
forking leaf tasks, because they reduce inter-thread communication
and improve load balancing. In the recursive case, the second of
each pair of subtasks to finish triggers completion of their parent
(because no result combination is performed, the default no-op
implementation of method onCompletion
is not overridden).
The utility method sets up the root task and invokes it (here,
implicitly using the ForkJoinPool#commonPool()
). It is
straightforward and reliable (but not optimal) to always set the
pending count to the number of child tasks and call tryComplete()
immediately before returning.
public static <E> void forEach(E[] array, Consumer<E> action) {
class Task extends CountedCompleter<Void> {
final int lo, hi;
Task(Task parent, int lo, int hi) {
super(parent); this.lo = lo; this.hi = hi;
}
public void compute() {
if (hi - lo >= 2) {
int mid = (lo + hi) >>> 1;
// must set pending count before fork
setPendingCount(2);
new Task(this, mid, hi).fork(); // right child
new Task(this, lo, mid).fork(); // left child
}
else if (hi > lo)
action.accept(array[lo]);
tryComplete();
}
}
new Task(null, 0, array.length).invoke();
}
This design can be improved by noticing that in the recursive case,
the task has nothing to do after forking its right task, so can
directly invoke its left task before returning. (This is an analog
of tail recursion removal.) Also, when the last action in a task
is to fork or invoke a subtask (a "tail call"), the call to tryComplete()
can be optimized away, at the cost of making the
pending count look "off by one".
public void compute() {
if (hi - lo >= 2) {
int mid = (lo + hi) >>> 1;
setPendingCount(1); // looks off by one, but correct!
new Task(this, mid, hi).fork(); // right child
new Task(this, lo, mid).compute(); // direct invoke
} else {
if (hi > lo)
action.accept(array[lo]);
tryComplete();
}
}
As a further optimization, notice that the left task need not even exist.
Instead of creating a new one, we can continue using the original task,
and add a pending count for each fork. Additionally, because no task
in this tree implements an onCompletion(java.util.concurrent.CountedCompleter)
method,
tryComplete
can be replaced with propagateCompletion()
.
public void compute() {
int n = hi - lo;
for (; n >= 2; n /= 2) {
addToPendingCount(1);
new Task(this, lo + n/2, lo + n).fork();
}
if (n > 0)
action.accept(array[lo]);
propagateCompletion();
}
When pending counts can be precomputed, they can be established in
the constructor:
public static <E> void forEach(E[] array, Consumer<E> action) {
class Task extends CountedCompleter<Void> {
final int lo, hi;
Task(Task parent, int lo, int hi) {
super(parent, 31 - Integer.numberOfLeadingZeros(hi - lo));
this.lo = lo; this.hi = hi;
}
public void compute() {
for (int n = hi - lo; n >= 2; n /= 2)
new Task(this, lo + n/2, lo + n).fork();
action.accept(array[lo]);
propagateCompletion();
}
}
if (array.length > 0)
new Task(null, 0, array.length).invoke();
}
Additional optimizations of such classes might entail specializing
classes for leaf steps, subdividing by say, four, instead of two
per iteration, and using an adaptive threshold instead of always
subdividing down to single elements.
Searching. A tree of CountedCompleters can search for a
value or property in different parts of a data structure, and
report a result in an AtomicReference
as
soon as one is found. The others can poll the result to avoid
unnecessary work. (You could additionally cancel other tasks, but it is usually simpler and more efficient
to just let them notice that the result is set and if so skip
further processing.) Illustrating again with an array using full
partitioning (again, in practice, leaf tasks will almost always
process more than one element):
class Searcher<E> extends CountedCompleter<E> {
final E[] array; final AtomicReference<E> result; final int lo, hi;
Searcher(CountedCompleter<?> p, E[] array, AtomicReference<E> result, int lo, int hi) {
super(p);
this.array = array; this.result = result; this.lo = lo; this.hi = hi;
}
public E getRawResult() { return result.get(); }
public void compute() { // similar to ForEach version 3
int l = lo, h = hi;
while (result.get() == null && h >= l) {
if (h - l >= 2) {
int mid = (l + h) >>> 1;
addToPendingCount(1);
new Searcher(this, array, result, mid, h).fork();
h = mid;
}
else {
E x = array[l];
if (matches(x) && result.compareAndSet(null, x))
quietlyCompleteRoot(); // root task is now joinable
break;
}
}
tryComplete(); // normally complete whether or not found
}
boolean matches(E e) { ... } // return true if found
public static <E> E search(E[] array) {
return new Searcher<E>(null, array, new AtomicReference<E>(), 0, array.length).invoke();
}
}
In this example, as well as others in which tasks have no other
effects except to compareAndSet
a common result, the
trailing unconditional invocation of tryComplete
could be
made conditional (if (result.get() == null) tryComplete();
)
because no further bookkeeping is required to manage completions
once the root task completes.
Recording subtasks. CountedCompleter tasks that combine
results of multiple subtasks usually need to access these results
in method onCompletion(java.util.concurrent.CountedCompleter)
. As illustrated in the following
class (that performs a simplified form of map-reduce where mappings
and reductions are all of type E
), one way to do this in
divide and conquer designs is to have each subtask record its
sibling, so that it can be accessed in method onCompletion
.
This technique applies to reductions in which the order of
combining left and right results does not matter; ordered
reductions require explicit left/right designations. Variants of
other streamlinings seen in the above examples may also apply.
class MyMapper<E> { E apply(E v) { ... } }
class MyReducer<E> { E apply(E x, E y) { ... } }
class MapReducer<E> extends CountedCompleter<E> {
final E[] array; final MyMapper<E> mapper;
final MyReducer<E> reducer; final int lo, hi;
MapReducer<E> sibling;
E result;
MapReducer(CountedCompleter<?> p, E[] array, MyMapper<E> mapper,
MyReducer<E> reducer, int lo, int hi) {
super(p);
this.array = array; this.mapper = mapper;
this.reducer = reducer; this.lo = lo; this.hi = hi;
}
public void compute() {
if (hi - lo >= 2) {
int mid = (lo + hi) >>> 1;
MapReducer<E> left = new MapReducer(this, array, mapper, reducer, lo, mid);
MapReducer<E> right = new MapReducer(this, array, mapper, reducer, mid, hi);
left.sibling = right;
right.sibling = left;
setPendingCount(1); // only right is pending
right.fork();
left.compute(); // directly execute left
}
else {
if (hi > lo)
result = mapper.apply(array[lo]);
tryComplete();
}
}
public void onCompletion(CountedCompleter<?> caller) {
if (caller != this) {
MapReducer<E> child = (MapReducer<E>)caller;
MapReducer<E> sib = child.sibling;
if (sib == null || sib.result == null)
result = child.result;
else
result = reducer.apply(child.result, sib.result);
}
}
public E getRawResult() { return result; }
public static <E> E mapReduce(E[] array, MyMapper<E> mapper, MyReducer<E> reducer) {
return new MapReducer<E>(null, array, mapper, reducer,
0, array.length).invoke();
}
}
Here, method onCompletion
takes a form common to many
completion designs that combine results. This callback-style method
is triggered once per task, in either of the two different contexts
in which the pending count is, or becomes, zero: (1) by a task
itself, if its pending count is zero upon invocation of tryComplete
, or (2) by any of its subtasks when they complete and
decrement the pending count to zero. The caller
argument
distinguishes cases. Most often, when the caller is this
,
no action is necessary. Otherwise the caller argument can be used
(usually via a cast) to supply a value (and/or links to other
values) to be combined. Assuming proper use of pending counts, the
actions inside onCompletion
occur (once) upon completion of
a task and its subtasks. No additional synchronization is required
within this method to ensure thread safety of accesses to fields of
this task or other completed tasks.
Completion Traversals. If using onCompletion
to
process completions is inapplicable or inconvenient, you can use
methods firstComplete()
and nextComplete()
to create
custom traversals. For example, to define a MapReducer that only
splits out right-hand tasks in the form of the third ForEach
example, the completions must cooperatively reduce along
unexhausted subtask links, which can be done as follows:
class MapReducer<E> extends CountedCompleter<E> { // version 2
final E[] array; final MyMapper<E> mapper;
final MyReducer<E> reducer; final int lo, hi;
MapReducer<E> forks, next; // record subtask forks in list
E result;
MapReducer(CountedCompleter<?> p, E[] array, MyMapper<E> mapper,
MyReducer<E> reducer, int lo, int hi, MapReducer<E> next) {
super(p);
this.array = array; this.mapper = mapper;
this.reducer = reducer; this.lo = lo; this.hi = hi;
this.next = next;
}
public void compute() {
int l = lo, h = hi;
while (h - l >= 2) {
int mid = (l + h) >>> 1;
addToPendingCount(1);
(forks = new MapReducer(this, array, mapper, reducer, mid, h, forks)).fork();
h = mid;
}
if (h > l)
result = mapper.apply(array[l]);
// process completions by reducing along and advancing subtask links
for (CountedCompleter<?> c = firstComplete(); c != null; c = c.nextComplete()) {
for (MapReducer t = (MapReducer)c, s = t.forks; s != null; s = t.forks = s.next)
t.result = reducer.apply(t.result, s.result);
}
}
public E getRawResult() { return result; }
public static <E> E mapReduce(E[] array, MyMapper<E> mapper, MyReducer<E> reducer) {
return new MapReducer<E>(null, array, mapper, reducer,
0, array.length, null).invoke();
}
}
Triggers. Some CountedCompleters are themselves never forked, but instead serve as bits of plumbing in other designs; including those in which the completion of one or more async tasks triggers another async task. For example:
class HeaderBuilder extends CountedCompleter<...> { ... }
class BodyBuilder extends CountedCompleter<...> { ... }
class PacketSender extends CountedCompleter<...> {
PacketSender(...) { super(null, 1); ... } // trigger on second completion
public void compute() { } // never called
public void onCompletion(CountedCompleter<?> caller) { sendPacket(); }
}
// sample use:
PacketSender p = new PacketSender();
new HeaderBuilder(p, ...).fork();
new BodyBuilder(p, ...).fork();
Summary
Protected constructors | |
---|---|
CountedCompleter(CountedCompleter<?> completer, int initialPendingCount)
Creates a new CountedCompleter with the given completer and initial pending count. |
|
CountedCompleter(CountedCompleter<?> completer)
Creates a new CountedCompleter with the given completer and an initial pending count of zero. |
|
CountedCompleter()
Creates a new CountedCompleter with no completer and an initial pending count of zero. |
Public methods | |
---|---|
final
void
|
addToPendingCount(int delta)
Adds (atomically) the given value to the pending count. |
final
boolean
|
compareAndSetPendingCount(int expected, int count)
Sets (atomically) the pending count to the given count only if it currently holds the given expected value. |
void
|
complete(T rawResult)
Regardless of pending count, invokes
|
abstract
void
|
compute()
The main computation performed by this task. |
final
int
|
decrementPendingCountUnlessZero()
If the pending count is nonzero, (atomically) decrements it. |
final
CountedCompleter<?>
|
firstComplete()
If this task's pending count is zero, returns this task;
otherwise decrements its pending count and returns |
final
CountedCompleter<?>
|
getCompleter()
Returns the completer established in this task's constructor,
or |
final
int
|
getPendingCount()
Returns the current pending count. |
T
|
getRawResult()
Returns the result of the computation. |
final
CountedCompleter<?>
|
getRoot()
Returns the root of the current computation; i.e., this task if it has no completer, else its completer's root. |
final
void
|
helpComplete(int maxTasks)
If this task has not completed, attempts to process at most the given number of other unprocessed tasks for which this task is on the completion path, if any are known to exist. |
final
CountedCompleter<?>
|
nextComplete()
If this task does not have a completer, invokes |
void
|
onCompletion(CountedCompleter<?> caller)
Performs an action when method |
boolean
|
onExceptionalCompletion(Throwable ex, CountedCompleter<?> caller)
Performs an action when method |
final
void
|
propagateCompletion()
Equivalent to |
final
void
|
quietlyCompleteRoot()
Equivalent to |
final
void
|
setPendingCount(int count)
Sets the pending count to the given value. |
final
void
|
tryComplete()
If the pending count is nonzero, decrements the count;
otherwise invokes |
Protected methods | |
---|---|
final
boolean
|
exec()
Implements execution conventions for CountedCompleters. |
void
|
setRawResult(T t)
A method that result-bearing CountedCompleters may optionally use to help maintain result data. |
Inherited methods | |
---|---|
Protected constructors
CountedCompleter
protected CountedCompleter (CountedCompleter<?> completer, int initialPendingCount)
Creates a new CountedCompleter with the given completer and initial pending count.
Parameters | |
---|---|
completer |
CountedCompleter : this task's completer, or null if none |
initialPendingCount |
int : the initial pending count |
CountedCompleter
protected CountedCompleter (CountedCompleter<?> completer)
Creates a new CountedCompleter with the given completer and an initial pending count of zero.
Parameters | |
---|---|
completer |
CountedCompleter : this task's completer, or null if none |
CountedCompleter
protected CountedCompleter ()
Creates a new CountedCompleter with no completer and an initial pending count of zero.
Public methods
addToPendingCount
public final void addToPendingCount (int delta)
Adds (atomically) the given value to the pending count.
Parameters | |
---|---|
delta |
int : the value to add |
compareAndSetPendingCount
public final boolean compareAndSetPendingCount (int expected, int count)
Sets (atomically) the pending count to the given count only if it currently holds the given expected value.
Parameters | |
---|---|
expected |
int : the expected value |
count |
int : the new value |
Returns | |
---|---|
boolean |
true if successful |
complete
public void complete (T rawResult)
Regardless of pending count, invokes
onCompletion(java.util.concurrent.CountedCompleter)
, marks this task as
complete and further triggers tryComplete()
on this
task's completer, if one exists. The given rawResult is
used as an argument to setRawResult(T)
before invoking
onCompletion(java.util.concurrent.CountedCompleter)
or marking this task
as complete; its value is meaningful only for classes
overriding setRawResult
. This method does not modify
the pending count.
This method may be useful when forcing completion as soon as
any one (versus all) of several subtask results are obtained.
However, in the common (and recommended) case in which setRawResult
is not overridden, this effect can be obtained
more simply using quietlyCompleteRoot()
.
Parameters | |
---|---|
rawResult |
T : the raw result |
compute
public abstract void compute ()
The main computation performed by this task.
decrementPendingCountUnlessZero
public final int decrementPendingCountUnlessZero ()
If the pending count is nonzero, (atomically) decrements it.
Returns | |
---|---|
int |
the initial (undecremented) pending count holding on entry to this method |
firstComplete
public final CountedCompleter<?> firstComplete ()
If this task's pending count is zero, returns this task;
otherwise decrements its pending count and returns null
.
This method is designed to be used with nextComplete()
in
completion traversal loops.
Returns | |
---|---|
CountedCompleter<?> |
this task, if pending count was zero, else null |
getCompleter
public final CountedCompleter<?> getCompleter ()
Returns the completer established in this task's constructor,
or null
if none.
Returns | |
---|---|
CountedCompleter<?> |
the completer |
getPendingCount
public final int getPendingCount ()
Returns the current pending count.
Returns | |
---|---|
int |
the current pending count |
getRawResult
public T getRawResult ()
Returns the result of the computation. By default,
returns null
, which is appropriate for Void
actions, but in other cases should be overridden, almost
always to return a field or function of a field that
holds the result upon completion.
Returns | |
---|---|
T |
the result of the computation |
getRoot
public final CountedCompleter<?> getRoot ()
Returns the root of the current computation; i.e., this task if it has no completer, else its completer's root.
Returns | |
---|---|
CountedCompleter<?> |
the root of the current computation |
helpComplete
public final void helpComplete (int maxTasks)
If this task has not completed, attempts to process at most the given number of other unprocessed tasks for which this task is on the completion path, if any are known to exist.
Parameters | |
---|---|
maxTasks |
int : the maximum number of tasks to process. If
less than or equal to zero, then no tasks are
processed. |
nextComplete
public final CountedCompleter<?> nextComplete ()
If this task does not have a completer, invokes ForkJoinTask.quietlyComplete()
and returns null
. Or, if
the completer's pending count is non-zero, decrements that
pending count and returns null
. Otherwise, returns the
completer. This method can be used as part of a completion
traversal loop for homogeneous task hierarchies:
for (CountedCompleter<?> c = firstComplete();
c != null;
c = c.nextComplete()) {
// ... process c ...
}
Returns | |
---|---|
CountedCompleter<?> |
the completer, or null if none |
onCompletion
public void onCompletion (CountedCompleter<?> caller)
Performs an action when method tryComplete()
is invoked
and the pending count is zero, or when the unconditional
method complete(T)
is invoked. By default, this method
does nothing. You can distinguish cases by checking the
identity of the given caller argument. If not equal to this
, then it is typically a subtask that may contain results
(and/or links to other results) to combine.
Parameters | |
---|---|
caller |
CountedCompleter : the task invoking this method (which may
be this task itself) |
onExceptionalCompletion
public boolean onExceptionalCompletion (Throwable ex, CountedCompleter<?> caller)
Performs an action when method ForkJoinTask.completeExceptionally(java.lang.Throwable)
is invoked or method compute()
throws an exception, and this task has not already
otherwise completed normally. On entry to this method, this task
ForkJoinTask#isCompletedAbnormally
. The return value
of this method controls further propagation: If true
and this task has a completer that has not completed, then that
completer is also completed exceptionally, with the same
exception as this completer. The default implementation of
this method does nothing except return true
.
Parameters | |
---|---|
ex |
Throwable : the exception |
caller |
CountedCompleter : the task invoking this method (which may
be this task itself) |
Returns | |
---|---|
boolean |
true if this exception should be propagated to this
task's completer, if one exists |
propagateCompletion
public final void propagateCompletion ()
Equivalent to tryComplete()
but does not invoke onCompletion(java.util.concurrent.CountedCompleter)
along the completion path:
If the pending count is nonzero, decrements the count;
otherwise, similarly tries to complete this task's completer, if
one exists, else marks this task as complete. This method may be
useful in cases where onCompletion
should not, or need
not, be invoked for each completer in a computation.
quietlyCompleteRoot
public final void quietlyCompleteRoot ()
Equivalent to getRoot().quietlyComplete()
.
setPendingCount
public final void setPendingCount (int count)
Sets the pending count to the given value.
Parameters | |
---|---|
count |
int : the count |
tryComplete
public final void tryComplete ()
If the pending count is nonzero, decrements the count;
otherwise invokes onCompletion(java.util.concurrent.CountedCompleter)
and then similarly tries to complete this task's completer,
if one exists, else marks this task as complete.
Protected methods
exec
protected final boolean exec ()
Implements execution conventions for CountedCompleters.
Returns | |
---|---|
boolean |
true if this task is known to have completed normally |
setRawResult
protected void setRawResult (T t)
A method that result-bearing CountedCompleters may optionally use to help maintain result data. By default, does nothing. Overrides are not recommended. However, if this method is overridden to update existing objects or fields, then it must in general be defined to be thread-safe.
Parameters | |
---|---|
t |
T : the value |