-
DoublePipeline
-
DoublePipeline(Supplier<Spliterator>, int, boolean): void
-
DoublePipeline(Spliterator<Double>, int, boolean): void
-
DoublePipeline(AbstractPipeline<Object, Object, BaseStream>, int): void
-
adapt(Sink<Double>): DoubleConsumer
-
adapt(Spliterator<Double>): OfDouble
-
getOutputShape(): StreamShape
-
evaluateToNode(PipelineHelper<Double>, Spliterator<Object>, boolean, IntFunction<Double[]>): Node<Double>
-
wrap(PipelineHelper<Double>, Supplier<Spliterator<Object>>, boolean): Spliterator<Double>
-
lazySpliterator(Supplier<Spliterator>): OfDouble
-
forEachWithCancel(Spliterator<Double>, Sink<Double>): boolean
-
makeNodeBuilder(long, IntFunction<Double[]>): Builder<Double>
-
mapToObj(DoubleFunction<Object>, int): Stream<Object>
-
iterator(): OfDouble
-
spliterator(): OfDouble
-
boxed(): Stream<Double>
-
map(DoubleUnaryOperator): DoubleStream
-
mapToObj(DoubleFunction<Object>): Stream<Object>
-
mapToInt(DoubleToIntFunction): IntStream
-
mapToLong(DoubleToLongFunction): LongStream
-
flatMap(DoubleFunction<DoubleStream>): DoubleStream
-
unordered(): DoubleStream
-
filter(DoublePredicate): DoubleStream
-
peek(DoubleConsumer): DoubleStream
-
limit(long): DoubleStream
-
skip(long): DoubleStream
-
takeWhile(DoublePredicate): DoubleStream
-
dropWhile(DoublePredicate): DoubleStream
-
sorted(): DoubleStream
-
distinct(): DoubleStream
-
forEach(DoubleConsumer): void
-
forEachOrdered(DoubleConsumer): void
-
sum(): double
-
min(): OptionalDouble
-
max(): OptionalDouble
-
average(): OptionalDouble
-
count(): long
-
summaryStatistics(): DoubleSummaryStatistics
-
reduce(double, DoubleBinaryOperator): double
-
reduce(DoubleBinaryOperator): OptionalDouble
-
collect(Supplier<Object>, ObjDoubleConsumer<Object>, BiConsumer<Object, Object>): Object
-
anyMatch(DoublePredicate): boolean
-
allMatch(DoublePredicate): boolean
-
noneMatch(DoublePredicate): boolean
-
findFirst(): OptionalDouble
-
findAny(): OptionalDouble
-
toArray(): double[]
-
Head
-
StatelessOp
-
StatefulOp
-
/*
* Copyright (c) 2013, 2017, Oracle and/or its affiliates. All rights reserved.
* DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER.
*
* This code is free software; you can redistribute it and/or modify it
* under the terms of the GNU General Public License version 2 only, as
* published by the Free Software Foundation. Oracle designates this
* particular file as subject to the "Classpath" exception as provided
* by Oracle in the LICENSE file that accompanied this code.
*
* This code is distributed in the hope that it will be useful, but WITHOUT
* ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
* FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
* version 2 for more details (a copy is included in the LICENSE file that
* accompanied this code).
*
* You should have received a copy of the GNU General Public License version
* 2 along with this work; if not, write to the Free Software Foundation,
* Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA.
*
* Please contact Oracle, 500 Oracle Parkway, Redwood Shores, CA 94065 USA
* or visit www.oracle.com if you need additional information or have any
* questions.
*/
package java.util.stream;
import java.util.DoubleSummaryStatistics;
import java.util.Objects;
import java.util.OptionalDouble;
import java.util.PrimitiveIterator;
import java.util.Spliterator;
import java.util.Spliterators;
import java.util.function.BiConsumer;
import java.util.function.BinaryOperator;
import java.util.function.DoubleBinaryOperator;
import java.util.function.DoubleConsumer;
import java.util.function.DoubleFunction;
import java.util.function.DoublePredicate;
import java.util.function.DoubleToIntFunction;
import java.util.function.DoubleToLongFunction;
import java.util.function.DoubleUnaryOperator;
import java.util.function.IntFunction;
import java.util.function.ObjDoubleConsumer;
import java.util.function.Supplier;
Abstract base class for an intermediate pipeline stage or pipeline source stage implementing whose elements are of type double. Type parameters: - <E_IN> – type of elements in the upstream source
Since: 1.8
/**
* Abstract base class for an intermediate pipeline stage or pipeline source
* stage implementing whose elements are of type {@code double}.
*
* @param <E_IN> type of elements in the upstream source
*
* @since 1.8
*/
abstract class DoublePipeline<E_IN>
extends AbstractPipeline<E_IN, Double, DoubleStream>
implements DoubleStream {
Constructor for the head of a stream pipeline.
Params: - source –
Supplier<Spliterator> describing the stream source - sourceFlags – the source flags for the stream source, described in
StreamOpFlag
/**
* Constructor for the head of a stream pipeline.
*
* @param source {@code Supplier<Spliterator>} describing the stream source
* @param sourceFlags the source flags for the stream source, described in
* {@link StreamOpFlag}
*/
DoublePipeline(Supplier<? extends Spliterator<Double>> source,
int sourceFlags, boolean parallel) {
super(source, sourceFlags, parallel);
}
Constructor for the head of a stream pipeline.
Params: - source –
Spliterator describing the stream source - sourceFlags – the source flags for the stream source, described in
StreamOpFlag
/**
* Constructor for the head of a stream pipeline.
*
* @param source {@code Spliterator} describing the stream source
* @param sourceFlags the source flags for the stream source, described in
* {@link StreamOpFlag}
*/
DoublePipeline(Spliterator<Double> source,
int sourceFlags, boolean parallel) {
super(source, sourceFlags, parallel);
}
Constructor for appending an intermediate operation onto an existing
pipeline.
Params: - upstream – the upstream element source.
- opFlags – the operation flags
/**
* Constructor for appending an intermediate operation onto an existing
* pipeline.
*
* @param upstream the upstream element source.
* @param opFlags the operation flags
*/
DoublePipeline(AbstractPipeline<?, E_IN, ?> upstream, int opFlags) {
super(upstream, opFlags);
}
Adapt a Sink<Double> to a {@code DoubleConsumer}, ideally simply
by casting.
/**
* Adapt a {@code Sink<Double> to a {@code DoubleConsumer}, ideally simply
* by casting.
*/
private static DoubleConsumer adapt(Sink<Double> sink) {
if (sink instanceof DoubleConsumer) {
return (DoubleConsumer) sink;
} else {
if (Tripwire.ENABLED)
Tripwire.trip(AbstractPipeline.class,
"using DoubleStream.adapt(Sink<Double> s)");
return sink::accept;
}
}
Adapt a Spliterator<Double> to a Spliterator.OfDouble. Implementation Note:
The implementation attempts to cast to a Spliterator.OfDouble, and throws
an exception if this cast is not possible.
/**
* Adapt a {@code Spliterator<Double>} to a {@code Spliterator.OfDouble}.
*
* @implNote
* The implementation attempts to cast to a Spliterator.OfDouble, and throws
* an exception if this cast is not possible.
*/
private static Spliterator.OfDouble adapt(Spliterator<Double> s) {
if (s instanceof Spliterator.OfDouble) {
return (Spliterator.OfDouble) s;
} else {
if (Tripwire.ENABLED)
Tripwire.trip(AbstractPipeline.class,
"using DoubleStream.adapt(Spliterator<Double> s)");
throw new UnsupportedOperationException("DoubleStream.adapt(Spliterator<Double> s)");
}
}
// Shape-specific methods
@Override
final StreamShape getOutputShape() {
return StreamShape.DOUBLE_VALUE;
}
@Override
final <P_IN> Node<Double> evaluateToNode(PipelineHelper<Double> helper,
Spliterator<P_IN> spliterator,
boolean flattenTree,
IntFunction<Double[]> generator) {
return Nodes.collectDouble(helper, spliterator, flattenTree);
}
@Override
final <P_IN> Spliterator<Double> wrap(PipelineHelper<Double> ph,
Supplier<Spliterator<P_IN>> supplier,
boolean isParallel) {
return new StreamSpliterators.DoubleWrappingSpliterator<>(ph, supplier, isParallel);
}
@Override
@SuppressWarnings("unchecked")
final Spliterator.OfDouble lazySpliterator(Supplier<? extends Spliterator<Double>> supplier) {
return new StreamSpliterators.DelegatingSpliterator.OfDouble((Supplier<Spliterator.OfDouble>) supplier);
}
@Override
final boolean forEachWithCancel(Spliterator<Double> spliterator, Sink<Double> sink) {
Spliterator.OfDouble spl = adapt(spliterator);
DoubleConsumer adaptedSink = adapt(sink);
boolean cancelled;
do { } while (!(cancelled = sink.cancellationRequested()) && spl.tryAdvance(adaptedSink));
return cancelled;
}
@Override
final Node.Builder<Double> makeNodeBuilder(long exactSizeIfKnown, IntFunction<Double[]> generator) {
return Nodes.doubleBuilder(exactSizeIfKnown);
}
private <U> Stream<U> mapToObj(DoubleFunction<? extends U> mapper, int opFlags) {
return new ReferencePipeline.StatelessOp<Double, U>(this, StreamShape.DOUBLE_VALUE, opFlags) {
@Override
Sink<Double> opWrapSink(int flags, Sink<U> sink) {
return new Sink.ChainedDouble<U>(sink) {
@Override
public void accept(double t) {
downstream.accept(mapper.apply(t));
}
};
}
};
}
// DoubleStream
@Override
public final PrimitiveIterator.OfDouble iterator() {
return Spliterators.iterator(spliterator());
}
@Override
public final Spliterator.OfDouble spliterator() {
return adapt(super.spliterator());
}
// Stateless intermediate ops from DoubleStream
@Override
public final Stream<Double> boxed() {
return mapToObj(Double::valueOf, 0);
}
@Override
public final DoubleStream map(DoubleUnaryOperator mapper) {
Objects.requireNonNull(mapper);
return new StatelessOp<Double>(this, StreamShape.DOUBLE_VALUE,
StreamOpFlag.NOT_SORTED | StreamOpFlag.NOT_DISTINCT) {
@Override
Sink<Double> opWrapSink(int flags, Sink<Double> sink) {
return new Sink.ChainedDouble<Double>(sink) {
@Override
public void accept(double t) {
downstream.accept(mapper.applyAsDouble(t));
}
};
}
};
}
@Override
public final <U> Stream<U> mapToObj(DoubleFunction<? extends U> mapper) {
Objects.requireNonNull(mapper);
return mapToObj(mapper, StreamOpFlag.NOT_SORTED | StreamOpFlag.NOT_DISTINCT);
}
@Override
public final IntStream mapToInt(DoubleToIntFunction mapper) {
Objects.requireNonNull(mapper);
return new IntPipeline.StatelessOp<Double>(this, StreamShape.DOUBLE_VALUE,
StreamOpFlag.NOT_SORTED | StreamOpFlag.NOT_DISTINCT) {
@Override
Sink<Double> opWrapSink(int flags, Sink<Integer> sink) {
return new Sink.ChainedDouble<Integer>(sink) {
@Override
public void accept(double t) {
downstream.accept(mapper.applyAsInt(t));
}
};
}
};
}
@Override
public final LongStream mapToLong(DoubleToLongFunction mapper) {
Objects.requireNonNull(mapper);
return new LongPipeline.StatelessOp<Double>(this, StreamShape.DOUBLE_VALUE,
StreamOpFlag.NOT_SORTED | StreamOpFlag.NOT_DISTINCT) {
@Override
Sink<Double> opWrapSink(int flags, Sink<Long> sink) {
return new Sink.ChainedDouble<Long>(sink) {
@Override
public void accept(double t) {
downstream.accept(mapper.applyAsLong(t));
}
};
}
};
}
@Override
public final DoubleStream flatMap(DoubleFunction<? extends DoubleStream> mapper) {
Objects.requireNonNull(mapper);
return new StatelessOp<Double>(this, StreamShape.DOUBLE_VALUE,
StreamOpFlag.NOT_SORTED | StreamOpFlag.NOT_DISTINCT | StreamOpFlag.NOT_SIZED) {
@Override
Sink<Double> opWrapSink(int flags, Sink<Double> sink) {
return new Sink.ChainedDouble<Double>(sink) {
// true if cancellationRequested() has been called
boolean cancellationRequestedCalled;
// cache the consumer to avoid creation on every accepted element
DoubleConsumer downstreamAsDouble = downstream::accept;
@Override
public void begin(long size) {
downstream.begin(-1);
}
@Override
public void accept(double t) {
try (DoubleStream result = mapper.apply(t)) {
if (result != null) {
if (!cancellationRequestedCalled) {
result.sequential().forEach(downstreamAsDouble);
}
else {
var s = result.sequential().spliterator();
do { } while (!downstream.cancellationRequested() && s.tryAdvance(downstreamAsDouble));
}
}
}
}
@Override
public boolean cancellationRequested() {
// If this method is called then an operation within the stream
// pipeline is short-circuiting (see AbstractPipeline.copyInto).
// Note that we cannot differentiate between an upstream or
// downstream operation
cancellationRequestedCalled = true;
return downstream.cancellationRequested();
}
};
}
};
}
@Override
public DoubleStream unordered() {
if (!isOrdered())
return this;
return new StatelessOp<Double>(this, StreamShape.DOUBLE_VALUE, StreamOpFlag.NOT_ORDERED) {
@Override
Sink<Double> opWrapSink(int flags, Sink<Double> sink) {
return sink;
}
};
}
@Override
public final DoubleStream filter(DoublePredicate predicate) {
Objects.requireNonNull(predicate);
return new StatelessOp<Double>(this, StreamShape.DOUBLE_VALUE,
StreamOpFlag.NOT_SIZED) {
@Override
Sink<Double> opWrapSink(int flags, Sink<Double> sink) {
return new Sink.ChainedDouble<Double>(sink) {
@Override
public void begin(long size) {
downstream.begin(-1);
}
@Override
public void accept(double t) {
if (predicate.test(t))
downstream.accept(t);
}
};
}
};
}
@Override
public final DoubleStream peek(DoubleConsumer action) {
Objects.requireNonNull(action);
return new StatelessOp<Double>(this, StreamShape.DOUBLE_VALUE,
0) {
@Override
Sink<Double> opWrapSink(int flags, Sink<Double> sink) {
return new Sink.ChainedDouble<Double>(sink) {
@Override
public void accept(double t) {
action.accept(t);
downstream.accept(t);
}
};
}
};
}
// Stateful intermediate ops from DoubleStream
@Override
public final DoubleStream limit(long maxSize) {
if (maxSize < 0)
throw new IllegalArgumentException(Long.toString(maxSize));
return SliceOps.makeDouble(this, (long) 0, maxSize);
}
@Override
public final DoubleStream skip(long n) {
if (n < 0)
throw new IllegalArgumentException(Long.toString(n));
if (n == 0)
return this;
else {
long limit = -1;
return SliceOps.makeDouble(this, n, limit);
}
}
@Override
public final DoubleStream takeWhile(DoublePredicate predicate) {
return WhileOps.makeTakeWhileDouble(this, predicate);
}
@Override
public final DoubleStream dropWhile(DoublePredicate predicate) {
return WhileOps.makeDropWhileDouble(this, predicate);
}
@Override
public final DoubleStream sorted() {
return SortedOps.makeDouble(this);
}
@Override
public final DoubleStream distinct() {
// While functional and quick to implement, this approach is not very efficient.
// An efficient version requires a double-specific map/set implementation.
return boxed().distinct().mapToDouble(i -> (double) i);
}
// Terminal ops from DoubleStream
@Override
public void forEach(DoubleConsumer consumer) {
evaluate(ForEachOps.makeDouble(consumer, false));
}
@Override
public void forEachOrdered(DoubleConsumer consumer) {
evaluate(ForEachOps.makeDouble(consumer, true));
}
@Override
public final double sum() {
/*
* In the arrays allocated for the collect operation, index 0
* holds the high-order bits of the running sum, index 1 holds
* the low-order bits of the sum computed via compensated
* summation, and index 2 holds the simple sum used to compute
* the proper result if the stream contains infinite values of
* the same sign.
*/
double[] summation = collect(() -> new double[3],
(ll, d) -> {
Collectors.sumWithCompensation(ll, d);
ll[2] += d;
},
(ll, rr) -> {
Collectors.sumWithCompensation(ll, rr[0]);
Collectors.sumWithCompensation(ll, rr[1]);
ll[2] += rr[2];
});
return Collectors.computeFinalSum(summation);
}
@Override
public final OptionalDouble min() {
return reduce(Math::min);
}
@Override
public final OptionalDouble max() {
return reduce(Math::max);
}
{@inheritDoc}
Implementation Note: The double format can represent all consecutive integers in the range -253 to
253. If the pipeline has more than 253
values, the divisor in the average computation will saturate at
253, leading to additional numerical errors.
/**
* {@inheritDoc}
*
* @implNote The {@code double} format can represent all
* consecutive integers in the range -2<sup>53</sup> to
* 2<sup>53</sup>. If the pipeline has more than 2<sup>53</sup>
* values, the divisor in the average computation will saturate at
* 2<sup>53</sup>, leading to additional numerical errors.
*/
@Override
public final OptionalDouble average() {
/*
* In the arrays allocated for the collect operation, index 0
* holds the high-order bits of the running sum, index 1 holds
* the low-order bits of the sum computed via compensated
* summation, index 2 holds the number of values seen, index 3
* holds the simple sum.
*/
double[] avg = collect(() -> new double[4],
(ll, d) -> {
ll[2]++;
Collectors.sumWithCompensation(ll, d);
ll[3] += d;
},
(ll, rr) -> {
Collectors.sumWithCompensation(ll, rr[0]);
Collectors.sumWithCompensation(ll, rr[1]);
ll[2] += rr[2];
ll[3] += rr[3];
});
return avg[2] > 0
? OptionalDouble.of(Collectors.computeFinalSum(avg) / avg[2])
: OptionalDouble.empty();
}
@Override
public final long count() {
return evaluate(ReduceOps.makeDoubleCounting());
}
@Override
public final DoubleSummaryStatistics summaryStatistics() {
return collect(DoubleSummaryStatistics::new, DoubleSummaryStatistics::accept,
DoubleSummaryStatistics::combine);
}
@Override
public final double reduce(double identity, DoubleBinaryOperator op) {
return evaluate(ReduceOps.makeDouble(identity, op));
}
@Override
public final OptionalDouble reduce(DoubleBinaryOperator op) {
return evaluate(ReduceOps.makeDouble(op));
}
@Override
public final <R> R collect(Supplier<R> supplier,
ObjDoubleConsumer<R> accumulator,
BiConsumer<R, R> combiner) {
Objects.requireNonNull(combiner);
BinaryOperator<R> operator = (left, right) -> {
combiner.accept(left, right);
return left;
};
return evaluate(ReduceOps.makeDouble(supplier, accumulator, operator));
}
@Override
public final boolean anyMatch(DoublePredicate predicate) {
return evaluate(MatchOps.makeDouble(predicate, MatchOps.MatchKind.ANY));
}
@Override
public final boolean allMatch(DoublePredicate predicate) {
return evaluate(MatchOps.makeDouble(predicate, MatchOps.MatchKind.ALL));
}
@Override
public final boolean noneMatch(DoublePredicate predicate) {
return evaluate(MatchOps.makeDouble(predicate, MatchOps.MatchKind.NONE));
}
@Override
public final OptionalDouble findFirst() {
return evaluate(FindOps.makeDouble(true));
}
@Override
public final OptionalDouble findAny() {
return evaluate(FindOps.makeDouble(false));
}
@Override
public final double[] toArray() {
return Nodes.flattenDouble((Node.OfDouble) evaluateToArrayNode(Double[]::new))
.asPrimitiveArray();
}
//
Source stage of a DoubleStream
Type parameters: - <E_IN> – type of elements in the upstream source
/**
* Source stage of a DoubleStream
*
* @param <E_IN> type of elements in the upstream source
*/
static class Head<E_IN> extends DoublePipeline<E_IN> {
Constructor for the source stage of a DoubleStream.
Params: - source –
Supplier<Spliterator> describing the stream source - sourceFlags – the source flags for the stream source, described in
StreamOpFlag - parallel –
true if the pipeline is parallel
/**
* Constructor for the source stage of a DoubleStream.
*
* @param source {@code Supplier<Spliterator>} describing the stream
* source
* @param sourceFlags the source flags for the stream source, described
* in {@link StreamOpFlag}
* @param parallel {@code true} if the pipeline is parallel
*/
Head(Supplier<? extends Spliterator<Double>> source,
int sourceFlags, boolean parallel) {
super(source, sourceFlags, parallel);
}
Constructor for the source stage of a DoubleStream.
Params: - source –
Spliterator describing the stream source - sourceFlags – the source flags for the stream source, described in
StreamOpFlag - parallel –
true if the pipeline is parallel
/**
* Constructor for the source stage of a DoubleStream.
*
* @param source {@code Spliterator} describing the stream source
* @param sourceFlags the source flags for the stream source, described
* in {@link StreamOpFlag}
* @param parallel {@code true} if the pipeline is parallel
*/
Head(Spliterator<Double> source,
int sourceFlags, boolean parallel) {
super(source, sourceFlags, parallel);
}
@Override
final boolean opIsStateful() {
throw new UnsupportedOperationException();
}
@Override
final Sink<E_IN> opWrapSink(int flags, Sink<Double> sink) {
throw new UnsupportedOperationException();
}
// Optimized sequential terminal operations for the head of the pipeline
@Override
public void forEach(DoubleConsumer consumer) {
if (!isParallel()) {
adapt(sourceStageSpliterator()).forEachRemaining(consumer);
}
else {
super.forEach(consumer);
}
}
@Override
public void forEachOrdered(DoubleConsumer consumer) {
if (!isParallel()) {
adapt(sourceStageSpliterator()).forEachRemaining(consumer);
}
else {
super.forEachOrdered(consumer);
}
}
}
Base class for a stateless intermediate stage of a DoubleStream.
Type parameters: - <E_IN> – type of elements in the upstream source
Since: 1.8
/**
* Base class for a stateless intermediate stage of a DoubleStream.
*
* @param <E_IN> type of elements in the upstream source
* @since 1.8
*/
abstract static class StatelessOp<E_IN> extends DoublePipeline<E_IN> {
Construct a new DoubleStream by appending a stateless intermediate
operation to an existing stream.
Params: - upstream – the upstream pipeline stage
- inputShape – the stream shape for the upstream pipeline stage
- opFlags – operation flags for the new stage
/**
* Construct a new DoubleStream by appending a stateless intermediate
* operation to an existing stream.
*
* @param upstream the upstream pipeline stage
* @param inputShape the stream shape for the upstream pipeline stage
* @param opFlags operation flags for the new stage
*/
StatelessOp(AbstractPipeline<?, E_IN, ?> upstream,
StreamShape inputShape,
int opFlags) {
super(upstream, opFlags);
assert upstream.getOutputShape() == inputShape;
}
@Override
final boolean opIsStateful() {
return false;
}
}
Base class for a stateful intermediate stage of a DoubleStream.
Type parameters: - <E_IN> – type of elements in the upstream source
Since: 1.8
/**
* Base class for a stateful intermediate stage of a DoubleStream.
*
* @param <E_IN> type of elements in the upstream source
* @since 1.8
*/
abstract static class StatefulOp<E_IN> extends DoublePipeline<E_IN> {
Construct a new DoubleStream by appending a stateful intermediate
operation to an existing stream.
Params: - upstream – the upstream pipeline stage
- inputShape – the stream shape for the upstream pipeline stage
- opFlags – operation flags for the new stage
/**
* Construct a new DoubleStream by appending a stateful intermediate
* operation to an existing stream.
*
* @param upstream the upstream pipeline stage
* @param inputShape the stream shape for the upstream pipeline stage
* @param opFlags operation flags for the new stage
*/
StatefulOp(AbstractPipeline<?, E_IN, ?> upstream,
StreamShape inputShape,
int opFlags) {
super(upstream, opFlags);
assert upstream.getOutputShape() == inputShape;
}
@Override
final boolean opIsStateful() {
return true;
}
@Override
abstract <P_IN> Node<Double> opEvaluateParallel(PipelineHelper<Double> helper,
Spliterator<P_IN> spliterator,
IntFunction<Double[]> generator);
}
}