8020061: Clarify reporting characteristics between splits
Reviewed-by: alanb, chegar
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package java.util;
import java.util.function.Consumer;
import java.util.function.DoubleConsumer;
import java.util.function.IntConsumer;
import java.util.function.LongConsumer;
/**
* An object for traversing and partitioning elements of a source. The source
* of elements covered by a Spliterator could be, for example, an array, a
* {@link Collection}, an IO channel, or a generator function.
*
* <p>A Spliterator may traverse elements individually ({@link
* #tryAdvance tryAdvance()}) or sequentially in bulk
* ({@link #forEachRemaining forEachRemaining()}).
*
* <p>A Spliterator may also partition off some of its elements (using
* {@link #trySplit}) as another Spliterator, to be used in
* possibly-parallel operations. Operations using a Spliterator that
* cannot split, or does so in a highly imbalanced or inefficient
* manner, are unlikely to benefit from parallelism. Traversal
* and splitting exhaust elements; each Spliterator is useful for only a single
* bulk computation.
*
* <p>A Spliterator also reports a set of {@link #characteristics()} of its
* structure, source, and elements from among {@link #ORDERED},
* {@link #DISTINCT}, {@link #SORTED}, {@link #SIZED}, {@link #NONNULL},
* {@link #IMMUTABLE}, {@link #CONCURRENT}, and {@link #SUBSIZED}. These may
* be employed by Spliterator clients to control, specialize or simplify
* computation. For example, a Spliterator for a {@link Collection} would
* report {@code SIZED}, a Spliterator for a {@link Set} would report
* {@code DISTINCT}, and a Spliterator for a {@link SortedSet} would also
* report {@code SORTED}. Characteristics are reported as a simple unioned bit
* set.
*
* Some characteristics additionally constrain method behavior; for example if
* {@code ORDERED}, traversal methods must conform to their documented ordering.
* New characteristics may be defined in the future, so implementors should not
* assign meanings to unlisted values.
*
* <p><a name="binding">A Spliterator that does not report {@code IMMUTABLE} or
* {@code CONCURRENT} is expected to have a documented policy concerning:
* when the spliterator <em>binds</em> to the element source; and detection of
* structural interference of the element source detected after binding.</a> A
* <em>late-binding</em> Spliterator binds to the source of elements at the
* point of first traversal, first split, or first query for estimated size,
* rather than at the time the Spliterator is created. A Spliterator that is
* not <em>late-binding</em> binds to the source of elements at the point of
* construction or first invocation of any method. Modifications made to the
* source prior to binding are reflected when the Spliterator is traversed.
* After binding a Spliterator should, on a best-effort basis, throw
* {@link ConcurrentModificationException} if structural interference is
* detected. Spliterators that do this are called <em>fail-fast</em>. The
* bulk traversal method ({@link #forEachRemaining forEachRemaining()}) of a
* Spliterator may optimize traversal and check for structural interference
* after all elements have been traversed, rather than checking per-element and
* failing immediately.
*
* <p>Spliterators can provide an estimate of the number of remaining elements
* via the {@link #estimateSize} method. Ideally, as reflected in characteristic
* {@link #SIZED}, this value corresponds exactly to the number of elements
* that would be encountered in a successful traversal. However, even when not
* exactly known, an estimated value value may still be useful to operations
* being performed on the source, such as helping to determine whether it is
* preferable to split further or traverse the remaining elements sequentially.
*
* <p>Despite their obvious utility in parallel algorithms, spliterators are not
* expected to be thread-safe; instead, implementations of parallel algorithms
* using spliterators should ensure that the spliterator is only used by one
* thread at a time. This is generally easy to attain via <em>serial
* thread-confinement</em>, which often is a natural consequence of typical
* parallel algorithms that work by recursive decomposition. A thread calling
* {@link #trySplit()} may hand over the returned Spliterator to another thread,
* which in turn may traverse or further split that Spliterator. The behaviour
* of splitting and traversal is undefined if two or more threads operate
* concurrently on the same spliterator. If the original thread hands a
* spliterator off to another thread for processing, it is best if that handoff
* occurs before any elements are consumed with {@link #tryAdvance(Consumer)
* tryAdvance()}, as certain guarantees (such as the accuracy of
* {@link #estimateSize()} for {@code SIZED} spliterators) are only valid before
* traversal has begun.
*
* <p>Primitive subtype specializations of {@code Spliterator} are provided for
* {@link OfInt int}, {@link OfLong long}, and {@link OfDouble double} values.
* The subtype default implementations of
* {@link Spliterator#tryAdvance(java.util.function.Consumer)}
* and {@link Spliterator#forEachRemaining(java.util.function.Consumer)} box
* primitive values to instances of their corresponding wrapper class. Such
* boxing may undermine any performance advantages gained by using the primitive
* specializations. To avoid boxing, the corresponding primitive-based methods
* should be used. For example,
* {@link Spliterator.OfInt#tryAdvance(java.util.function.IntConsumer)}
* and {@link Spliterator.OfInt#forEachRemaining(java.util.function.IntConsumer)}
* should be used in preference to
* {@link Spliterator.OfInt#tryAdvance(java.util.function.Consumer)} and
* {@link Spliterator.OfInt#forEachRemaining(java.util.function.Consumer)}.
* Traversal of primitive values using boxing-based methods
* {@link #tryAdvance tryAdvance()} and
* {@link #forEachRemaining(java.util.function.Consumer) forEachRemaining()}
* does not affect the order in which the values, transformed to boxed values,
* are encountered.
*
* @apiNote
* <p>Spliterators, like {@code Iterators}s, are for traversing the elements of
* a source. The {@code Spliterator} API was designed to support efficient
* parallel traversal in addition to sequential traversal, by supporting
* decomposition as well as single-element iteration. In addition, the
* protocol for accessing elements via a Spliterator is designed to impose
* smaller per-element overhead than {@code Iterator}, and to avoid the inherent
* race involved in having separate methods for {@code hasNext()} and
* {@code next()}.
*
* <p>For mutable sources, arbitrary and non-deterministic behavior may occur if
* the source is structurally interfered with (elements added, replaced, or
* removed) between the time that the Spliterator binds to its data source and
* the end of traversal. For example, such interference will produce arbitrary,
* non-deterministic results when using the {@code java.util.stream} framework.
*
* <p>Structural interference of a source can be managed in the following ways
* (in approximate order of decreasing desirability):
* <ul>
* <li>The source cannot be structurally interfered with.
* <br>For example, an instance of
* {@link java.util.concurrent.CopyOnWriteArrayList} is an immutable source.
* A Spliterator created from the source reports a characteristic of
* {@code IMMUTABLE}.</li>
* <li>The source manages concurrent modifications.
* <br>For example, a key set of a {@link java.util.concurrent.ConcurrentHashMap}
* is a concurrent source. A Spliterator created from the source reports a
* characteristic of {@code CONCURRENT}.</li>
* <li>The mutable source provides a late-binding and fail-fast Spliterator.
* <br>Late binding narrows the window during which interference can affect
* the calculation; fail-fast detects, on a best-effort basis, that structural
* interference has occurred after traversal has commenced and throws
* {@link ConcurrentModificationException}. For example, {@link ArrayList},
* and many other non-concurrent {@code Collection} classes in the JDK, provide
* a late-binding, fail-fast spliterator.</li>
* <li>The mutable source provides a non-late-binding but fail-fast Spliterator.
* <br>The source increases the likelihood of throwing
* {@code ConcurrentModificationException} since the window of potential
* interference is larger.</li>
* <li>The mutable source provides a late-binding and non-fail-fast Spliterator.
* <br>The source risks arbitrary, non-deterministic behavior after traversal
* has commenced since interference is not detected.
* </li>
* <li>The mutable source provides a non-late-binding and non-fail-fast
* Spliterator.
* <br>The source increases the risk of arbitrary, non-deterministic behavior
* since non-detected interference may occur after construction.
* </li>
* </ul>
*
* <p><b>Example.</b> Here is a class (not a very useful one, except
* for illustration) that maintains an array in which the actual data
* are held in even locations, and unrelated tag data are held in odd
* locations. Its Spliterator ignores the tags.
*
* <pre> {@code
* class TaggedArray<T> {
* private final Object[] elements; // immutable after construction
* TaggedArray(T[] data, Object[] tags) {
* int size = data.length;
* if (tags.length != size) throw new IllegalArgumentException();
* this.elements = new Object[2 * size];
* for (int i = 0, j = 0; i < size; ++i) {
* elements[j++] = data[i];
* elements[j++] = tags[i];
* }
* }
*
* public Spliterator<T> spliterator() {
* return new TaggedArraySpliterator<>(elements, 0, elements.length);
* }
*
* static class TaggedArraySpliterator<T> implements Spliterator<T> {
* private final Object[] array;
* private int origin; // current index, advanced on split or traversal
* private final int fence; // one past the greatest index
*
* TaggedArraySpliterator(Object[] array, int origin, int fence) {
* this.array = array; this.origin = origin; this.fence = fence;
* }
*
* public void forEachRemaining(Consumer<? super T> action) {
* for (; origin < fence; origin += 2)
* action.accept((T) array[origin]);
* }
*
* public boolean tryAdvance(Consumer<? super T> action) {
* if (origin < fence) {
* action.accept((T) array[origin]);
* origin += 2;
* return true;
* }
* else // cannot advance
* return false;
* }
*
* public Spliterator<T> trySplit() {
* int lo = origin; // divide range in half
* int mid = ((lo + fence) >>> 1) & ~1; // force midpoint to be even
* if (lo < mid) { // split out left half
* origin = mid; // reset this Spliterator's origin
* return new TaggedArraySpliterator<>(array, lo, mid);
* }
* else // too small to split
* return null;
* }
*
* public long estimateSize() {
* return (long)((fence - origin) / 2);
* }
*
* public int characteristics() {
* return ORDERED | SIZED | IMMUTABLE | SUBSIZED;
* }
* }
* }}</pre>
*
* <p>As an example how a parallel computation framework, such as the
* {@code java.util.stream} package, would use Spliterator in a parallel
* computation, here is one way to implement an associated parallel forEach,
* that illustrates the primary usage idiom of splitting off subtasks until
* the estimated amount of work is small enough to perform
* sequentially. Here we assume that the order of processing across
* subtasks doesn't matter; different (forked) tasks may further split
* and process elements concurrently in undetermined order. This
* example uses a {@link java.util.concurrent.CountedCompleter};
* similar usages apply to other parallel task constructions.
*
* <pre>{@code
* static <T> void parEach(TaggedArray<T> a, Consumer<T> action) {
* Spliterator<T> s = a.spliterator();
* long targetBatchSize = s.estimateSize() / (ForkJoinPool.getCommonPoolParallelism() * 8);
* new ParEach(null, s, action, targetBatchSize).invoke();
* }
*
* static class ParEach<T> extends CountedCompleter<Void> {
* final Spliterator<T> spliterator;
* final Consumer<T> action;
* final long targetBatchSize;
*
* ParEach(ParEach<T> parent, Spliterator<T> spliterator,
* Consumer<T> action, long targetBatchSize) {
* super(parent);
* this.spliterator = spliterator; this.action = action;
* this.targetBatchSize = targetBatchSize;
* }
*
* public void compute() {
* Spliterator<T> sub;
* while (spliterator.estimateSize() > targetBatchSize &&
* (sub = spliterator.trySplit()) != null) {
* addToPendingCount(1);
* new ParEach<>(this, sub, action, targetBatchSize).fork();
* }
* spliterator.forEachRemaining(action);
* propagateCompletion();
* }
* }}</pre>
*
* @implNote
* If the boolean system property {@code org.openjdk.java.util.stream.tripwire}
* is set to {@code true} then diagnostic warnings are reported if boxing of
* primitive values occur when operating on primitive subtype specializations.
*
* @param <T> the type of elements returned by this Spliterator
*
* @see Collection
* @since 1.8
*/
public interface Spliterator<T> {
/**
* If a remaining element exists, performs the given action on it,
* returning {@code true}; else returns {@code false}. If this
* Spliterator is {@link #ORDERED} the action is performed on the
* next element in encounter order. Exceptions thrown by the
* action are relayed to the caller.
*
* @param action The action
* @return {@code false} if no remaining elements existed
* upon entry to this method, else {@code true}.
* @throws NullPointerException if the specified action is null
*/
boolean tryAdvance(Consumer<? super T> action);
/**
* Performs the given action for each remaining element, sequentially in
* the current thread, until all elements have been processed or the action
* throws an exception. If this Spliterator is {@link #ORDERED}, actions
* are performed in encounter order. Exceptions thrown by the action
* are relayed to the caller.
*
* @implSpec
* The default implementation repeatedly invokes {@link #tryAdvance} until
* it returns {@code false}. It should be overridden whenever possible.
*
* @param action The action
* @throws NullPointerException if the specified action is null
*/
default void forEachRemaining(Consumer<? super T> action) {
do { } while (tryAdvance(action));
}
/**
* If this spliterator can be partitioned, returns a Spliterator
* covering elements, that will, upon return from this method, not
* be covered by this Spliterator.
*
* <p>If this Spliterator is {@link #ORDERED}, the returned Spliterator
* must cover a strict prefix of the elements.
*
* <p>Unless this Spliterator covers an infinite number of elements,
* repeated calls to {@code trySplit()} must eventually return {@code null}.
* Upon non-null return:
* <ul>
* <li>the value reported for {@code estimateSize()} before splitting,
* must, after splitting, be greater than or equal to {@code estimateSize()}
* for this and the returned Spliterator; and</li>
* <li>if this Spliterator is {@code SUBSIZED}, then {@code estimateSize()}
* for this spliterator before splitting must be equal to the sum of
* {@code estimateSize()} for this and the returned Spliterator after
* splitting.</li>
* </ul>
*
* <p>This method may return {@code null} for any reason,
* including emptiness, inability to split after traversal has
* commenced, data structure constraints, and efficiency
* considerations.
*
* @apiNote
* An ideal {@code trySplit} method efficiently (without
* traversal) divides its elements exactly in half, allowing
* balanced parallel computation. Many departures from this ideal
* remain highly effective; for example, only approximately
* splitting an approximately balanced tree, or for a tree in
* which leaf nodes may contain either one or two elements,
* failing to further split these nodes. However, large
* deviations in balance and/or overly inefficient {@code
* trySplit} mechanics typically result in poor parallel
* performance.
*
* @return a {@code Spliterator} covering some portion of the
* elements, or {@code null} if this spliterator cannot be split
*/
Spliterator<T> trySplit();
/**
* Returns an estimate of the number of elements that would be
* encountered by a {@link #forEachRemaining} traversal, or returns {@link
* Long#MAX_VALUE} if infinite, unknown, or too expensive to compute.
*
* <p>If this Spliterator is {@link #SIZED} and has not yet been partially
* traversed or split, or this Spliterator is {@link #SUBSIZED} and has
* not yet been partially traversed, this estimate must be an accurate
* count of elements that would be encountered by a complete traversal.
* Otherwise, this estimate may be arbitrarily inaccurate, but must decrease
* as specified across invocations of {@link #trySplit}.
*
* @apiNote
* Even an inexact estimate is often useful and inexpensive to compute.
* For example, a sub-spliterator of an approximately balanced binary tree
* may return a value that estimates the number of elements to be half of
* that of its parent; if the root Spliterator does not maintain an
* accurate count, it could estimate size to be the power of two
* corresponding to its maximum depth.
*
* @return the estimated size, or {@code Long.MAX_VALUE} if infinite,
* unknown, or too expensive to compute.
*/
long estimateSize();
/**
* Convenience method that returns {@link #estimateSize()} if this
* Spliterator is {@link #SIZED}, else {@code -1}.
* @implSpec
* The default implementation returns the result of {@code estimateSize()}
* if the Spliterator reports a characteristic of {@code SIZED}, and
* {@code -1} otherwise.
*
* @return the exact size, if known, else {@code -1}.
*/
default long getExactSizeIfKnown() {
return (characteristics() & SIZED) == 0 ? -1L : estimateSize();
}
/**
* Returns a set of characteristics of this Spliterator and its
* elements. The result is represented as ORed values from {@link
* #ORDERED}, {@link #DISTINCT}, {@link #SORTED}, {@link #SIZED},
* {@link #NONNULL}, {@link #IMMUTABLE}, {@link #CONCURRENT},
* {@link #SUBSIZED}. Repeated calls to {@code characteristics()} on
* a given spliterator, prior to or in-between calls to {@code trySplit},
* should always return the same result.
*
* <p>If a Spliterator reports an inconsistent set of
* characteristics (either those returned from a single invocation
* or across multiple invocations), no guarantees can be made
* about any computation using this Spliterator.
*
* @apiNote The characteristics of a given spliterator before splitting
* may differ from the characteristics after splitting. For specific
* examples see the characteristic values {@link #SIZED}, {@link #SUBSIZED}
* and {@link #CONCURRENT}.
*
* @return a representation of characteristics
*/
int characteristics();
/**
* Returns {@code true} if this Spliterator's {@link
* #characteristics} contain all of the given characteristics.
*
* @implSpec
* The default implementation returns true if the corresponding bits
* of the given characteristics are set.
*
* @param characteristics the characteristics to check for
* @return {@code true} if all the specified characteristics are present,
* else {@code false}
*/
default boolean hasCharacteristics(int characteristics) {
return (characteristics() & characteristics) == characteristics;
}
/**
* If this Spliterator's source is {@link #SORTED} by a {@link Comparator},
* returns that {@code Comparator}. If the source is {@code SORTED} in
* {@linkplain Comparable natural order}, returns {@code null}. Otherwise,
* if the source is not {@code SORTED}, throws {@link IllegalStateException}.
*
* @implSpec
* The default implementation always throws {@link IllegalStateException}.
*
* @return a Comparator, or {@code null} if the elements are sorted in the
* natural order.
* @throws IllegalStateException if the spliterator does not report
* a characteristic of {@code SORTED}.
*/
default Comparator<? super T> getComparator() {
throw new IllegalStateException();
}
/**
* Characteristic value signifying that an encounter order is defined for
* elements. If so, this Spliterator guarantees that method
* {@link #trySplit} splits a strict prefix of elements, that method
* {@link #tryAdvance} steps by one element in prefix order, and that
* {@link #forEachRemaining} performs actions in encounter order.
*
* <p>A {@link Collection} has an encounter order if the corresponding
* {@link Collection#iterator} documents an order. If so, the encounter
* order is the same as the documented order. Otherwise, a collection does
* not have an encounter order.
*
* @apiNote Encounter order is guaranteed to be ascending index order for
* any {@link List}. But no order is guaranteed for hash-based collections
* such as {@link HashSet}. Clients of a Spliterator that reports
* {@code ORDERED} are expected to preserve ordering constraints in
* non-commutative parallel computations.
*/
public static final int ORDERED = 0x00000010;
/**
* Characteristic value signifying that, for each pair of
* encountered elements {@code x, y}, {@code !x.equals(y)}. This
* applies for example, to a Spliterator based on a {@link Set}.
*/
public static final int DISTINCT = 0x00000001;
/**
* Characteristic value signifying that encounter order follows a defined
* sort order. If so, method {@link #getComparator()} returns the associated
* Comparator, or {@code null} if all elements are {@link Comparable} and
* are sorted by their natural ordering.
*
* <p>A Spliterator that reports {@code SORTED} must also report
* {@code ORDERED}.
*
* @apiNote The spliterators for {@code Collection} classes in the JDK that
* implement {@link NavigableSet} or {@link SortedSet} report {@code SORTED}.
*/
public static final int SORTED = 0x00000004;
/**
* Characteristic value signifying that the value returned from
* {@code estimateSize()} prior to traversal or splitting represents a
* finite size that, in the absence of structural source modification,
* represents an exact count of the number of elements that would be
* encountered by a complete traversal.
*
* @apiNote Most Spliterators for Collections, that cover all elements of a
* {@code Collection} report this characteristic. Sub-spliterators, such as
* those for {@link HashSet}, that cover a sub-set of elements and
* approximate their reported size do not.
*/
public static final int SIZED = 0x00000040;
/**
* Characteristic value signifying that the source guarantees that
* encountered elements will not be {@code null}. (This applies,
* for example, to most concurrent collections, queues, and maps.)
*/
public static final int NONNULL = 0x00000100;
/**
* Characteristic value signifying that the element source cannot be
* structurally modified; that is, elements cannot be added, replaced, or
* removed, so such changes cannot occur during traversal. A Spliterator
* that does not report {@code IMMUTABLE} or {@code CONCURRENT} is expected
* to have a documented policy (for example throwing
* {@link ConcurrentModificationException}) concerning structural
* interference detected during traversal.
*/
public static final int IMMUTABLE = 0x00000400;
/**
* Characteristic value signifying that the element source may be safely
* concurrently modified (allowing additions, replacements, and/or removals)
* by multiple threads without external synchronization. If so, the
* Spliterator is expected to have a documented policy concerning the impact
* of modifications during traversal.
*
* <p>A top-level Spliterator should not report both {@code CONCURRENT} and
* {@code SIZED}, since the finite size, if known, may change if the source
* is concurrently modified during traversal. Such a Spliterator is
* inconsistent and no guarantees can be made about any computation using
* that Spliterator. Sub-spliterators may report {@code SIZED} if the
* sub-split size is known and additions or removals to the source are not
* reflected when traversing.
*
* @apiNote Most concurrent collections maintain a consistency policy
* guaranteeing accuracy with respect to elements present at the point of
* Spliterator construction, but possibly not reflecting subsequent
* additions or removals.
*/
public static final int CONCURRENT = 0x00001000;
/**
* Characteristic value signifying that all Spliterators resulting from
* {@code trySplit()} will be both {@link #SIZED} and {@link #SUBSIZED}.
* (This means that all child Spliterators, whether direct or indirect, will
* be {@code SIZED}.)
*
* <p>A Spliterator that does not report {@code SIZED} as required by
* {@code SUBSIZED} is inconsistent and no guarantees can be made about any
* computation using that Spliterator.
*
* @apiNote Some spliterators, such as the top-level spliterator for an
* approximately balanced binary tree, will report {@code SIZED} but not
* {@code SUBSIZED}, since it is common to know the size of the entire tree
* but not the exact sizes of subtrees.
*/
public static final int SUBSIZED = 0x00004000;
/**
* A Spliterator specialized for primitive values.
*
* @param <T> the type of elements returned by this Spliterator. The
* type must be a wrapper type for a primitive type, such as {@code Integer}
* for the primitive {@code int} type.
* @param <T_CONS> the type of primitive consumer. The type must be a
* primitive specialization of {@link java.util.function.Consumer} for
* {@code T}, such as {@link java.util.function.IntConsumer} for
* {@code Integer}.
* @param <T_SPLITR> the type of primitive Spliterator. The type must be
* a primitive specialization of Spliterator for {@code T}, such as
* {@link Spliterator.OfInt} for {@code Integer}.
*
* @see Spliterator.OfInt
* @see Spliterator.OfLong
* @see Spliterator.OfDouble
* @since 1.8
*/
public interface OfPrimitive<T, T_CONS, T_SPLITR extends Spliterator.OfPrimitive<T, T_CONS, T_SPLITR>>
extends Spliterator<T> {
@Override
T_SPLITR trySplit();
/**
* If a remaining element exists, performs the given action on it,
* returning {@code true}; else returns {@code false}. If this
* Spliterator is {@link #ORDERED} the action is performed on the
* next element in encounter order. Exceptions thrown by the
* action are relayed to the caller.
*
* @param action The action
* @return {@code false} if no remaining elements existed
* upon entry to this method, else {@code true}.
* @throws NullPointerException if the specified action is null
*/
boolean tryAdvance(T_CONS action);
/**
* Performs the given action for each remaining element, sequentially in
* the current thread, until all elements have been processed or the
* action throws an exception. If this Spliterator is {@link #ORDERED},
* actions are performed in encounter order. Exceptions thrown by the
* action are relayed to the caller.
*
* @implSpec
* The default implementation repeatedly invokes {@link #tryAdvance}
* until it returns {@code false}. It should be overridden whenever
* possible.
*
* @param action The action
* @throws NullPointerException if the specified action is null
*/
default void forEachRemaining(T_CONS action) {
do { } while (tryAdvance(action));
}
}
/**
* A Spliterator specialized for {@code int} values.
* @since 1.8
*/
public interface OfInt extends OfPrimitive<Integer, IntConsumer, OfInt> {
@Override
OfInt trySplit();
@Override
boolean tryAdvance(IntConsumer action);
@Override
default void forEachRemaining(IntConsumer action) {
do { } while (tryAdvance(action));
}
/**
* {@inheritDoc}
* @implSpec
* If the action is an instance of {@code IntConsumer} then it is cast
* to {@code IntConsumer} and passed to
* {@link #tryAdvance(java.util.function.IntConsumer)}; otherwise
* the action is adapted to an instance of {@code IntConsumer}, by
* boxing the argument of {@code IntConsumer}, and then passed to
* {@link #tryAdvance(java.util.function.IntConsumer)}.
*/
@Override
default boolean tryAdvance(Consumer<? super Integer> action) {
if (action instanceof IntConsumer) {
return tryAdvance((IntConsumer) action);
}
else {
if (Tripwire.ENABLED)
Tripwire.trip(getClass(),
"{0} calling Spliterator.OfInt.tryAdvance((IntConsumer) action::accept)");
return tryAdvance((IntConsumer) action::accept);
}
}
/**
* {@inheritDoc}
* @implSpec
* If the action is an instance of {@code IntConsumer} then it is cast
* to {@code IntConsumer} and passed to
* {@link #forEachRemaining(java.util.function.IntConsumer)}; otherwise
* the action is adapted to an instance of {@code IntConsumer}, by
* boxing the argument of {@code IntConsumer}, and then passed to
* {@link #forEachRemaining(java.util.function.IntConsumer)}.
*/
@Override
default void forEachRemaining(Consumer<? super Integer> action) {
if (action instanceof IntConsumer) {
forEachRemaining((IntConsumer) action);
}
else {
if (Tripwire.ENABLED)
Tripwire.trip(getClass(),
"{0} calling Spliterator.OfInt.forEachRemaining((IntConsumer) action::accept)");
forEachRemaining((IntConsumer) action::accept);
}
}
}
/**
* A Spliterator specialized for {@code long} values.
* @since 1.8
*/
public interface OfLong extends OfPrimitive<Long, LongConsumer, OfLong> {
@Override
OfLong trySplit();
@Override
boolean tryAdvance(LongConsumer action);
@Override
default void forEachRemaining(LongConsumer action) {
do { } while (tryAdvance(action));
}
/**
* {@inheritDoc}
* @implSpec
* If the action is an instance of {@code LongConsumer} then it is cast
* to {@code LongConsumer} and passed to
* {@link #tryAdvance(java.util.function.LongConsumer)}; otherwise
* the action is adapted to an instance of {@code LongConsumer}, by
* boxing the argument of {@code LongConsumer}, and then passed to
* {@link #tryAdvance(java.util.function.LongConsumer)}.
*/
@Override
default boolean tryAdvance(Consumer<? super Long> action) {
if (action instanceof LongConsumer) {
return tryAdvance((LongConsumer) action);
}
else {
if (Tripwire.ENABLED)
Tripwire.trip(getClass(),
"{0} calling Spliterator.OfLong.tryAdvance((LongConsumer) action::accept)");
return tryAdvance((LongConsumer) action::accept);
}
}
/**
* {@inheritDoc}
* @implSpec
* If the action is an instance of {@code LongConsumer} then it is cast
* to {@code LongConsumer} and passed to
* {@link #forEachRemaining(java.util.function.LongConsumer)}; otherwise
* the action is adapted to an instance of {@code LongConsumer}, by
* boxing the argument of {@code LongConsumer}, and then passed to
* {@link #forEachRemaining(java.util.function.LongConsumer)}.
*/
@Override
default void forEachRemaining(Consumer<? super Long> action) {
if (action instanceof LongConsumer) {
forEachRemaining((LongConsumer) action);
}
else {
if (Tripwire.ENABLED)
Tripwire.trip(getClass(),
"{0} calling Spliterator.OfLong.forEachRemaining((LongConsumer) action::accept)");
forEachRemaining((LongConsumer) action::accept);
}
}
}
/**
* A Spliterator specialized for {@code double} values.
* @since 1.8
*/
public interface OfDouble extends OfPrimitive<Double, DoubleConsumer, OfDouble> {
@Override
OfDouble trySplit();
@Override
boolean tryAdvance(DoubleConsumer action);
@Override
default void forEachRemaining(DoubleConsumer action) {
do { } while (tryAdvance(action));
}
/**
* {@inheritDoc}
* @implSpec
* If the action is an instance of {@code DoubleConsumer} then it is
* cast to {@code DoubleConsumer} and passed to
* {@link #tryAdvance(java.util.function.DoubleConsumer)}; otherwise
* the action is adapted to an instance of {@code DoubleConsumer}, by
* boxing the argument of {@code DoubleConsumer}, and then passed to
* {@link #tryAdvance(java.util.function.DoubleConsumer)}.
*/
@Override
default boolean tryAdvance(Consumer<? super Double> action) {
if (action instanceof DoubleConsumer) {
return tryAdvance((DoubleConsumer) action);
}
else {
if (Tripwire.ENABLED)
Tripwire.trip(getClass(),
"{0} calling Spliterator.OfDouble.tryAdvance((DoubleConsumer) action::accept)");
return tryAdvance((DoubleConsumer) action::accept);
}
}
/**
* {@inheritDoc}
* @implSpec
* If the action is an instance of {@code DoubleConsumer} then it is
* cast to {@code DoubleConsumer} and passed to
* {@link #forEachRemaining(java.util.function.DoubleConsumer)};
* otherwise the action is adapted to an instance of
* {@code DoubleConsumer}, by boxing the argument of
* {@code DoubleConsumer}, and then passed to
* {@link #forEachRemaining(java.util.function.DoubleConsumer)}.
*/
@Override
default void forEachRemaining(Consumer<? super Double> action) {
if (action instanceof DoubleConsumer) {
forEachRemaining((DoubleConsumer) action);
}
else {
if (Tripwire.ENABLED)
Tripwire.trip(getClass(),
"{0} calling Spliterator.OfDouble.forEachRemaining((DoubleConsumer) action::accept)");
forEachRemaining((DoubleConsumer) action::accept);
}
}
}
}