Stream.java

/*
 * Copyright (c) 2012, 2023, Oracle and/or its affiliates. All rights reserved.
 * DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER.
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 * 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).
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 * Please contact Oracle, 500 Oracle Parkway, Redwood Shores, CA 94065 USA
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package java.util.stream;

import org.jspecify.annotations.NonNull;
import org.jspecify.annotations.NullMarked;
import org.jspecify.annotations.Nullable;
import jdk.internal.javac.PreviewFeature;

import java.nio.file.Files;
import java.nio.file.Path;
import java.util.*;
import java.util.concurrent.ConcurrentHashMap;
import java.util.function.BiConsumer;
import java.util.function.BiFunction;
import java.util.function.BinaryOperator;
import java.util.function.Consumer;
import java.util.function.DoubleConsumer;
import java.util.function.Function;
import java.util.function.IntConsumer;
import java.util.function.IntFunction;
import java.util.function.LongConsumer;
import java.util.function.Predicate;
import java.util.function.Supplier;
import java.util.function.ToDoubleFunction;
import java.util.function.ToIntFunction;
import java.util.function.ToLongFunction;
import java.util.function.UnaryOperator;

/**
 * A sequence of elements supporting sequential and parallel aggregate
 * operations.  The following example illustrates an aggregate operation using
 * {@link Stream} and {@link IntStream}:
 *
 * <pre>{@code
 *     int sum = widgets.stream()
 *                      .filter(w -> w.getColor() == RED)
 *                      .mapToInt(w -> w.getWeight())
 *                      .sum();
 * }</pre>
 *
 * In this example, {@code widgets} is a {@code Collection<Widget>}.  We create
 * a stream of {@code Widget} objects via {@link Collection#stream Collection.stream()},
 * filter it to produce a stream containing only the red widgets, and then
 * transform it into a stream of {@code int} values representing the weight of
 * each red widget. Then this stream is summed to produce a total weight.
 *
 * <p>In addition to {@code Stream}, which is a stream of object references,
 * there are primitive specializations for {@link IntStream}, {@link LongStream},
 * and {@link DoubleStream}, all of which are referred to as "streams" and
 * conform to the characteristics and restrictions described here.
 *
 * <p>To perform a computation, stream
 * <a href="package-summary.html#StreamOps">operations</a> are composed into a
 * <em>stream pipeline</em>.  A stream pipeline consists of a source (which
 * might be an array, a collection, a generator function, an I/O channel,
 * etc), zero or more <em>intermediate operations</em> (which transform a
 * stream into another stream, such as {@link Stream#filter(Predicate)}), and a
 * <em>terminal operation</em> (which produces a result or side-effect, such
 * as {@link Stream#count()} or {@link Stream#forEach(Consumer)}).
 * Streams are lazy; computation on the source data is only performed when the
 * terminal operation is initiated, and source elements are consumed only
 * as needed.
 *
 * <p>A stream implementation is permitted significant latitude in optimizing
 * the computation of the result.  For example, a stream implementation is free
 * to elide operations (or entire stages) from a stream pipeline -- and
 * therefore elide invocation of behavioral parameters -- if it can prove that
 * it would not affect the result of the computation.  This means that
 * side-effects of behavioral parameters may not always be executed and should
 * not be relied upon, unless otherwise specified (such as by the terminal
 * operations {@code forEach} and {@code forEachOrdered}). (For a specific
 * example of such an optimization, see the API note documented on the
 * {@link #count} operation.  For more detail, see the
 * <a href="package-summary.html#SideEffects">side-effects</a> section of the
 * stream package documentation.)
 *
 * <p>Collections and streams, while bearing some superficial similarities,
 * have different goals.  Collections are primarily concerned with the efficient
 * management of, and access to, their elements.  By contrast, streams do not
 * provide a means to directly access or manipulate their elements, and are
 * instead concerned with declaratively describing their source and the
 * computational operations which will be performed in aggregate on that source.
 * However, if the provided stream operations do not offer the desired
 * functionality, the {@link #iterator()} and {@link #spliterator()} operations
 * can be used to perform a controlled traversal.
 *
 * <p>A stream pipeline, like the "widgets" example above, can be viewed as
 * a <em>query</em> on the stream source.  Unless the source was explicitly
 * designed for concurrent modification (such as a {@link ConcurrentHashMap}),
 * unpredictable or erroneous behavior may result from modifying the stream
 * source while it is being queried.
 *
 * <p>Most stream operations accept parameters that describe user-specified
 * behavior, such as the lambda expression {@code w -> w.getWeight()} passed to
 * {@code mapToInt} in the example above.  To preserve correct behavior,
 * these <em>behavioral parameters</em>:
 * <ul>
 * <li>must be <a href="package-summary.html#NonInterference">non-interfering</a>
 * (they do not modify the stream source); and</li>
 * <li>in most cases must be <a href="package-summary.html#Statelessness">stateless</a>
 * (their result should not depend on any state that might change during execution
 * of the stream pipeline).</li>
 * </ul>
 *
 * <p>Such parameters are always instances of a
 * <a href="../function/package-summary.html">functional interface</a> such
 * as {@link java.util.function.Function}, and are often lambda expressions or
 * method references.  Unless otherwise specified these parameters must be
 * <em>non-null</em>.
 *
 * <p>A stream should be operated on (invoking an intermediate or terminal stream
 * operation) only once.  This rules out, for example, "forked" streams, where
 * the same source feeds two or more pipelines, or multiple traversals of the
 * same stream.  A stream implementation may throw {@link IllegalStateException}
 * if it detects that the stream is being reused. However, since some stream
 * operations may return their receiver rather than a new stream object, it may
 * not be possible to detect reuse in all cases.
 *
 * <p>Streams have a {@link #close()} method and implement {@link AutoCloseable}.
 * Operating on a stream after it has been closed will throw {@link IllegalStateException}.
 * Most stream instances do not actually need to be closed after use, as they
 * are backed by collections, arrays, or generating functions, which require no
 * special resource management. Generally, only streams whose source is an IO channel,
 * such as those returned by {@link Files#lines(Path)}, will require closing. If a
 * stream does require closing, it must be opened as a resource within a try-with-resources
 * statement or similar control structure to ensure that it is closed promptly after its
 * operations have completed.
 *
 * <p>Stream pipelines may execute either sequentially or in
 * <a href="package-summary.html#Parallelism">parallel</a>.  This
 * execution mode is a property of the stream.  Streams are created
 * with an initial choice of sequential or parallel execution.  (For example,
 * {@link Collection#stream() Collection.stream()} creates a sequential stream,
 * and {@link Collection#parallelStream() Collection.parallelStream()} creates
 * a parallel one.)  This choice of execution mode may be modified by the
 * {@link #sequential()} or {@link #parallel()} methods, and may be queried with
 * the {@link #isParallel()} method.
 *
 * @param <T> the type of the stream elements
 * @since 1.8
 * @see IntStream
 * @see LongStream
 * @see DoubleStream
 * @see <a href="package-summary.html">java.util.stream</a>
 */
@NullMarked
public interface Stream<T extends @Nullable Object> extends BaseStream<T, Stream<T>> {

    /**
     * Returns a stream consisting of the elements of this stream that match
     * the given predicate.
     *
     * <p>This is an <a href="package-summary.html#StreamOps">intermediate
     * operation</a>.
     *
     * @param predicate a <a href="package-summary.html#NonInterference">non-interfering</a>,
     *                  <a href="package-summary.html#Statelessness">stateless</a>
     *                  predicate to apply to each element to determine if it
     *                  should be included
     * @return the new stream
     */
    Stream<T> filter(Predicate<? super T> predicate);

    /**
     * Returns a stream consisting of the results of applying the given
     * function to the elements of this stream.
     *
     * <p>This is an <a href="package-summary.html#StreamOps">intermediate
     * operation</a>.
     *
     * @param <R> The element type of the new stream
     * @param mapper a <a href="package-summary.html#NonInterference">non-interfering</a>,
     *               <a href="package-summary.html#Statelessness">stateless</a>
     *               function to apply to each element
     * @return the new stream
     */
    <R extends @Nullable Object> Stream<R> map(Function<? super T, ? extends R> mapper);

    /**
     * Returns an {@code IntStream} consisting of the results of applying the
     * given function to the elements of this stream.
     *
     * <p>This is an <a href="package-summary.html#StreamOps">
     *     intermediate operation</a>.
     *
     * @param mapper a <a href="package-summary.html#NonInterference">non-interfering</a>,
     *               <a href="package-summary.html#Statelessness">stateless</a>
     *               function to apply to each element
     * @return the new stream
     */
    IntStream mapToInt(ToIntFunction<? super T> mapper);

    /**
     * Returns a {@code LongStream} consisting of the results of applying the
     * given function to the elements of this stream.
     *
     * <p>This is an <a href="package-summary.html#StreamOps">intermediate
     * operation</a>.
     *
     * @param mapper a <a href="package-summary.html#NonInterference">non-interfering</a>,
     *               <a href="package-summary.html#Statelessness">stateless</a>
     *               function to apply to each element
     * @return the new stream
     */
    LongStream mapToLong(ToLongFunction<? super T> mapper);

    /**
     * Returns a {@code DoubleStream} consisting of the results of applying the
     * given function to the elements of this stream.
     *
     * <p>This is an <a href="package-summary.html#StreamOps">intermediate
     * operation</a>.
     *
     * @param mapper a <a href="package-summary.html#NonInterference">non-interfering</a>,
     *               <a href="package-summary.html#Statelessness">stateless</a>
     *               function to apply to each element
     * @return the new stream
     */
    DoubleStream mapToDouble(ToDoubleFunction<? super T> mapper);

    /**
     * Returns a stream consisting of the results of replacing each element of
     * this stream with the contents of a mapped stream produced by applying
     * the provided mapping function to each element.  Each mapped stream is
     * {@link java.util.stream.BaseStream#close() closed} after its contents
     * have been placed into this stream.  (If a mapped stream is {@code null}
     * an empty stream is used, instead.)
     *
     * <p>This is an <a href="package-summary.html#StreamOps">intermediate
     * operation</a>.
     *
     * @apiNote
     * The {@code flatMap()} operation has the effect of applying a one-to-many
     * transformation to the elements of the stream, and then flattening the
     * resulting elements into a new stream.
     *
     * <p><b>Examples.</b>
     *
     * <p>If {@code orders} is a stream of purchase orders, and each purchase
     * order contains a collection of line items, then the following produces a
     * stream containing all the line items in all the orders:
     * <pre>{@code
     *     orders.flatMap(order -> order.getLineItems().stream())...
     * }</pre>
     *
     * <p>If {@code path} is the path to a file, then the following produces a
     * stream of the {@code words} contained in that file:
     * <pre>{@code
     *     Stream<String> lines = Files.lines(path, StandardCharsets.UTF_8);
     *     Stream<String> words = lines.flatMap(line -> Stream.of(line.split(" +")));
     * }</pre>
     * The {@code mapper} function passed to {@code flatMap} splits a line,
     * using a simple regular expression, into an array of words, and then
     * creates a stream of words from that array.
     *
     * @param <R> The element type of the new stream
     * @param mapper a <a href="package-summary.html#NonInterference">non-interfering</a>,
     *               <a href="package-summary.html#Statelessness">stateless</a>
     *               function to apply to each element which produces a stream
     *               of new values
     * @return the new stream
     * @see #mapMulti mapMulti
     */
    <R extends @Nullable Object> Stream<R> flatMap(Function<? super T, ? extends @Nullable Stream<? extends R>> mapper);

    /**
     * Returns an {@code IntStream} consisting of the results of replacing each
     * element of this stream with the contents of a mapped stream produced by
     * applying the provided mapping function to each element.  Each mapped
     * stream is {@link java.util.stream.BaseStream#close() closed} after its
     * contents have been placed into this stream.  (If a mapped stream is
     * {@code null} an empty stream is used, instead.)
     *
     * <p>This is an <a href="package-summary.html#StreamOps">intermediate
     * operation</a>.
     *
     * @param mapper a <a href="package-summary.html#NonInterference">non-interfering</a>,
     *               <a href="package-summary.html#Statelessness">stateless</a>
     *               function to apply to each element which produces a stream
     *               of new values
     * @return the new stream
     * @see #flatMap flatMap
     */
    IntStream flatMapToInt(Function<? super T, ? extends @Nullable IntStream> mapper);

    /**
     * Returns an {@code LongStream} consisting of the results of replacing each
     * element of this stream with the contents of a mapped stream produced by
     * applying the provided mapping function to each element.  Each mapped
     * stream is {@link java.util.stream.BaseStream#close() closed} after its
     * contents have been placed into this stream.  (If a mapped stream is
     * {@code null} an empty stream is used, instead.)
     *
     * <p>This is an <a href="package-summary.html#StreamOps">intermediate
     * operation</a>.
     *
     * @param mapper a <a href="package-summary.html#NonInterference">non-interfering</a>,
     *               <a href="package-summary.html#Statelessness">stateless</a>
     *               function to apply to each element which produces a stream
     *               of new values
     * @return the new stream
     * @see #flatMap flatMap
     */
    LongStream flatMapToLong(Function<? super T, ? extends @Nullable LongStream> mapper);

    /**
     * Returns an {@code DoubleStream} consisting of the results of replacing
     * each element of this stream with the contents of a mapped stream produced
     * by applying the provided mapping function to each element.  Each mapped
     * stream is {@link java.util.stream.BaseStream#close() closed} after its
     * contents have placed been into this stream.  (If a mapped stream is
     * {@code null} an empty stream is used, instead.)
     *
     * <p>This is an <a href="package-summary.html#StreamOps">intermediate
     * operation</a>.
     *
     * @param mapper a <a href="package-summary.html#NonInterference">non-interfering</a>,
     *               <a href="package-summary.html#Statelessness">stateless</a>
     *               function to apply to each element which produces a stream
     *               of new values
     * @return the new stream
     * @see #flatMap flatMap
     */
    DoubleStream flatMapToDouble(Function<? super T, ? extends @Nullable DoubleStream> mapper);

    // THE EXAMPLES USED IN THE JAVADOC MUST BE IN SYNC WITH THEIR CORRESPONDING
    // TEST IN test/jdk/java/util/stream/examples/JavadocExamples.java.
    /**
     * Returns a stream consisting of the results of replacing each element of
     * this stream with multiple elements, specifically zero or more elements.
     * Replacement is performed by applying the provided mapping function to each
     * element in conjunction with a {@linkplain Consumer consumer} argument
     * that accepts replacement elements. The mapping function calls the consumer
     * zero or more times to provide the replacement elements.
     *
     * <p>This is an <a href="package-summary.html#StreamOps">intermediate
     * operation</a>.
     *
     * <p>If the {@linkplain Consumer consumer} argument is used outside the scope of
     * its application to the mapping function, the results are undefined.
     *
     * @implSpec
     * The default implementation invokes {@link #flatMap flatMap} on this stream,
     * passing a function that behaves as follows. First, it calls the mapper function
     * with a {@code Consumer} that accumulates replacement elements into a newly created
     * internal buffer. When the mapper function returns, it creates a stream from the
     * internal buffer. Finally, it returns this stream to {@code flatMap}.
     *
     * @apiNote
     * This method is similar to {@link #flatMap flatMap} in that it applies a one-to-many
     * transformation to the elements of the stream and flattens the result elements
     * into a new stream. This method is preferable to {@code flatMap} in the following
     * circumstances:
     * <ul>
     * <li>When replacing each stream element with a small (possibly zero) number of
     * elements. Using this method avoids the overhead of creating a new Stream instance
     * for every group of result elements, as required by {@code flatMap}.</li>
     * <li>When it is easier to use an imperative approach for generating result
     * elements than it is to return them in the form of a Stream.</li>
     * </ul>
     *
     * <p>If a lambda expression is provided as the mapper function argument, additional type
     * information may be necessary for proper inference of the element type {@code <R>} of
     * the returned stream. This can be provided in the form of explicit type declarations for
     * the lambda parameters or as an explicit type argument to the {@code mapMulti} call.
     *
     * <p><b>Examples</b>
     *
     * <p>Given a stream of {@code Number} objects, the following
     * produces a list containing only the {@code Integer} objects:
     * <pre>{@code
     *     Stream<Number> numbers = ... ;
     *     List<Integer> integers = numbers.<Integer>mapMulti((number, consumer) -> {
     *             if (number instanceof Integer i)
     *                 consumer.accept(i);
     *         })
     *         .collect(Collectors.toList());
     * }</pre>
     *
     * <p>If we have an {@code Iterable<Object>} and need to recursively expand its elements
     * that are themselves of type {@code Iterable}, we can use {@code mapMulti} as follows:
     * <pre>{@code
     * class C {
     *     static void expandIterable(Object e, Consumer<Object> c) {
     *         if (e instanceof Iterable<?> elements) {
     *             for (Object ie : elements) {
     *                 expandIterable(ie, c);
     *             }
     *         } else if (e != null) {
     *             c.accept(e);
     *         }
     *     }
     *
     *     public static void main(String[] args) {
     *         var nestedList = List.of(1, List.of(2, List.of(3, 4)), 5);
     *         Stream<Object> expandedStream = nestedList.stream().mapMulti(C::expandIterable);
     *     }
     * }
     * }</pre>
     *
     * @param <R> The element type of the new stream
     * @param mapper a <a href="package-summary.html#NonInterference">non-interfering</a>,
     *               <a href="package-summary.html#Statelessness">stateless</a>
     *               function that generates replacement elements
     * @return the new stream
     * @see #flatMap flatMap
     * @since 16
     */
    default <R> Stream<R> mapMulti(BiConsumer<? super T, ? super Consumer<R>> mapper) {
        Objects.requireNonNull(mapper);
        return flatMap(e -> {
            SpinedBuffer<R> buffer = new SpinedBuffer<>();
            mapper.accept(e, buffer);
            return StreamSupport.stream(buffer.spliterator(), false);
        });
    }

    /**
     * Returns an {@code IntStream} consisting of the results of replacing each
     * element of this stream with multiple elements, specifically zero or more
     * elements.
     * Replacement is performed by applying the provided mapping function to each
     * element in conjunction with a {@linkplain IntConsumer consumer} argument
     * that accepts replacement elements. The mapping function calls the consumer
     * zero or more times to provide the replacement elements.
     *
     * <p>This is an <a href="package-summary.html#StreamOps">intermediate
     * operation</a>.
     *
     * <p>If the {@linkplain IntConsumer consumer} argument is used outside the scope of
     * its application to the mapping function, the results are undefined.
     *
     * @implSpec
     * The default implementation invokes {@link #flatMapToInt flatMapToInt} on this stream,
     * passing a function that behaves as follows. First, it calls the mapper function
     * with an {@code IntConsumer} that accumulates replacement elements into a newly created
     * internal buffer. When the mapper function returns, it creates an {@code IntStream} from
     * the internal buffer. Finally, it returns this stream to {@code flatMapToInt}.
     *
     * @param mapper a <a href="package-summary.html#NonInterference">non-interfering</a>,
     *               <a href="package-summary.html#Statelessness">stateless</a>
     *               function that generates replacement elements
     * @return the new stream
     * @see #mapMulti mapMulti
     * @since 16
     */
    default IntStream mapMultiToInt(BiConsumer<? super T, ? super IntConsumer> mapper) {
        Objects.requireNonNull(mapper);
        return flatMapToInt(e -> {
            SpinedBuffer.OfInt buffer = new SpinedBuffer.OfInt();
            mapper.accept(e, buffer);
            return StreamSupport.intStream(buffer.spliterator(), false);
        });
    }

    /**
     * Returns a {@code LongStream} consisting of the results of replacing each
     * element of this stream with multiple elements, specifically zero or more
     * elements.
     * Replacement is performed by applying the provided mapping function to each
     * element in conjunction with a {@linkplain LongConsumer consumer} argument
     * that accepts replacement elements. The mapping function calls the consumer
     * zero or more times to provide the replacement elements.
     *
     * <p>This is an <a href="package-summary.html#StreamOps">intermediate
     * operation</a>.
     *
     * <p>If the {@linkplain LongConsumer consumer} argument is used outside the scope of
     * its application to the mapping function, the results are undefined.
     *
     * @implSpec
     * The default implementation invokes {@link #flatMapToLong flatMapToLong} on this stream,
     * passing a function that behaves as follows. First, it calls the mapper function
     * with a {@code LongConsumer} that accumulates replacement elements into a newly created
     * internal buffer. When the mapper function returns, it creates a {@code LongStream} from
     * the internal buffer. Finally, it returns this stream to {@code flatMapToLong}.
     *
     * @param mapper a <a href="package-summary.html#NonInterference">non-interfering</a>,
     *               <a href="package-summary.html#Statelessness">stateless</a>
     *               function that generates replacement elements
     * @return the new stream
     * @see #mapMulti mapMulti
     * @since 16
     */
    default LongStream mapMultiToLong(BiConsumer<? super T, ? super LongConsumer> mapper) {
        Objects.requireNonNull(mapper);
        return flatMapToLong(e -> {
            SpinedBuffer.OfLong buffer = new SpinedBuffer.OfLong();
            mapper.accept(e, buffer);
            return StreamSupport.longStream(buffer.spliterator(), false);
        });
    }

    /**
     * Returns a {@code DoubleStream} consisting of the results of replacing each
     * element of this stream with multiple elements, specifically zero or more
     * elements.
     * Replacement is performed by applying the provided mapping function to each
     * element in conjunction with a {@linkplain DoubleConsumer consumer} argument
     * that accepts replacement elements. The mapping function calls the consumer
     * zero or more times to provide the replacement elements.
     *
     * <p>This is an <a href="package-summary.html#StreamOps">intermediate
     * operation</a>.
     *
     * <p>If the {@linkplain DoubleConsumer consumer} argument is used outside the scope of
     * its application to the mapping function, the results are undefined.
     *
     * @implSpec
     * The default implementation invokes {@link #flatMapToDouble flatMapToDouble} on this stream,
     * passing a function that behaves as follows. First, it calls the mapper function
     * with an {@code DoubleConsumer} that accumulates replacement elements into a newly created
     * internal buffer. When the mapper function returns, it creates a {@code DoubleStream} from
     * the internal buffer. Finally, it returns this stream to {@code flatMapToDouble}.
     *
     * @param mapper a <a href="package-summary.html#NonInterference">non-interfering</a>,
     *               <a href="package-summary.html#Statelessness">stateless</a>
     *               function that generates replacement elements
     * @return the new stream
     * @see #mapMulti mapMulti
     * @since 16
     */
    default DoubleStream mapMultiToDouble(BiConsumer<? super T, ? super DoubleConsumer> mapper) {
        Objects.requireNonNull(mapper);
        return flatMapToDouble(e -> {
            SpinedBuffer.OfDouble buffer = new SpinedBuffer.OfDouble();
            mapper.accept(e, buffer);
            return StreamSupport.doubleStream(buffer.spliterator(), false);
        });
    }

    /**
     * Returns a stream consisting of the distinct elements (according to
     * {@link Object#equals(Object)}) of this stream.
     *
     * <p>For ordered streams, the selection of distinct elements is stable
     * (for duplicated elements, the element appearing first in the encounter
     * order is preserved.)  For unordered streams, no stability guarantees
     * are made.
     *
     * <p>This is a <a href="package-summary.html#StreamOps">stateful
     * intermediate operation</a>.
     *
     * @apiNote
     * Preserving stability for {@code distinct()} in parallel pipelines is
     * relatively expensive (requires that the operation act as a full barrier,
     * with substantial buffering overhead), and stability is often not needed.
     * Using an unordered stream source (such as {@link #generate(Supplier)})
     * or removing the ordering constraint with {@link #unordered()} may result
     * in significantly more efficient execution for {@code distinct()} in parallel
     * pipelines, if the semantics of your situation permit.  If consistency
     * with encounter order is required, and you are experiencing poor performance
     * or memory utilization with {@code distinct()} in parallel pipelines,
     * switching to sequential execution with {@link #sequential()} may improve
     * performance.
     *
     * @return the new stream
     */
    Stream<T> distinct();

    /**
     * Returns a stream consisting of the elements of this stream, sorted
     * according to natural order.  If the elements of this stream are not
     * {@code Comparable}, a {@code java.lang.ClassCastException} may be thrown
     * when the terminal operation is executed.
     *
     * <p>For ordered streams, the sort is stable.  For unordered streams, no
     * stability guarantees are made.
     *
     * <p>This is a <a href="package-summary.html#StreamOps">stateful
     * intermediate operation</a>.
     *
     * @return the new stream
     */
    Stream<T> sorted();

    /**
     * Returns a stream consisting of the elements of this stream, sorted
     * according to the provided {@code Comparator}.
     *
     * <p>For ordered streams, the sort is stable.  For unordered streams, no
     * stability guarantees are made.
     *
     * <p>This is a <a href="package-summary.html#StreamOps">stateful
     * intermediate operation</a>.
     *
     * @param comparator a <a href="package-summary.html#NonInterference">non-interfering</a>,
     *                   <a href="package-summary.html#Statelessness">stateless</a>
     *                   {@code Comparator} to be used to compare stream elements
     * @return the new stream
     */
    Stream<T> sorted(Comparator<? super T> comparator);

    /**
     * Returns a stream consisting of the elements of this stream, additionally
     * performing the provided action on each element as elements are consumed
     * from the resulting stream.
     *
     * <p>This is an <a href="package-summary.html#StreamOps">intermediate
     * operation</a>.
     *
     * <p>For parallel stream pipelines, the action may be called at
     * whatever time and in whatever thread the element is made available by the
     * upstream operation.  If the action modifies shared state,
     * it is responsible for providing the required synchronization.
     *
     * @apiNote This method exists mainly to support debugging, where you want
     * to see the elements as they flow past a certain point in a pipeline:
     * <pre>{@code
     *     Stream.of("one", "two", "three", "four")
     *         .filter(e -> e.length() > 3)
     *         .peek(e -> System.out.println("Filtered value: " + e))
     *         .map(String::toUpperCase)
     *         .peek(e -> System.out.println("Mapped value: " + e))
     *         .collect(Collectors.toList());
     * }</pre>
     *
     * <p>In cases where the stream implementation is able to optimize away the
     * production of some or all the elements (such as with short-circuiting
     * operations like {@code findFirst}, or in the example described in
     * {@link #count}), the action will not be invoked for those elements.
     *
     * @param action a <a href="package-summary.html#NonInterference">
     *                 non-interfering</a> action to perform on the elements as
     *                 they are consumed from the stream
     * @return the new stream
     */
    Stream<T> peek(Consumer<? super T> action);

    /**
     * Returns a stream consisting of the elements of this stream, truncated
     * to be no longer than {@code maxSize} in length.
     *
     * <p>This is a <a href="package-summary.html#StreamOps">short-circuiting
     * stateful intermediate operation</a>.
     *
     * @apiNote
     * While {@code limit()} is generally a cheap operation on sequential
     * stream pipelines, it can be quite expensive on ordered parallel pipelines,
     * especially for large values of {@code maxSize}, since {@code limit(n)}
     * is constrained to return not just any <em>n</em> elements, but the
     * <em>first n</em> elements in the encounter order.  Using an unordered
     * stream source (such as {@link #generate(Supplier)}) or removing the
     * ordering constraint with {@link #unordered()} may result in significant
     * speedups of {@code limit()} in parallel pipelines, if the semantics of
     * your situation permit.  If consistency with encounter order is required,
     * and you are experiencing poor performance or memory utilization with
     * {@code limit()} in parallel pipelines, switching to sequential execution
     * with {@link #sequential()} may improve performance.
     *
     * @param maxSize the number of elements the stream should be limited to
     * @return the new stream
     * @throws IllegalArgumentException if {@code maxSize} is negative
     */
    Stream<T> limit(long maxSize);

    /**
     * Returns a stream consisting of the remaining elements of this stream
     * after discarding the first {@code n} elements of the stream.
     * If this stream contains fewer than {@code n} elements then an
     * empty stream will be returned.
     *
     * <p>This is a <a href="package-summary.html#StreamOps">stateful
     * intermediate operation</a>.
     *
     * @apiNote
     * While {@code skip()} is generally a cheap operation on sequential
     * stream pipelines, it can be quite expensive on ordered parallel pipelines,
     * especially for large values of {@code n}, since {@code skip(n)}
     * is constrained to skip not just any <em>n</em> elements, but the
     * <em>first n</em> elements in the encounter order.  Using an unordered
     * stream source (such as {@link #generate(Supplier)}) or removing the
     * ordering constraint with {@link #unordered()} may result in significant
     * speedups of {@code skip()} in parallel pipelines, if the semantics of
     * your situation permit.  If consistency with encounter order is required,
     * and you are experiencing poor performance or memory utilization with
     * {@code skip()} in parallel pipelines, switching to sequential execution
     * with {@link #sequential()} may improve performance.
     *
     * @param n the number of leading elements to skip
     * @return the new stream
     * @throws IllegalArgumentException if {@code n} is negative
     */
    Stream<T> skip(long n);

    /**
     * Returns, if this stream is ordered, a stream consisting of the longest
     * prefix of elements taken from this stream that match the given predicate.
     * Otherwise returns, if this stream is unordered, a stream consisting of a
     * subset of elements taken from this stream that match the given predicate.
     *
     * <p>If this stream is ordered then the longest prefix is a contiguous
     * sequence of elements of this stream that match the given predicate.  The
     * first element of the sequence is the first element of this stream, and
     * the element immediately following the last element of the sequence does
     * not match the given predicate.
     *
     * <p>If this stream is unordered, and some (but not all) elements of this
     * stream match the given predicate, then the behavior of this operation is
     * nondeterministic; it is free to take any subset of matching elements
     * (which includes the empty set).
     *
     * <p>Independent of whether this stream is ordered or unordered if all
     * elements of this stream match the given predicate then this operation
     * takes all elements (the result is the same as the input), or if no
     * elements of the stream match the given predicate then no elements are
     * taken (the result is an empty stream).
     *
     * <p>This is a <a href="package-summary.html#StreamOps">short-circuiting
     * stateful intermediate operation</a>.
     *
     * @implSpec
     * The default implementation obtains the {@link #spliterator() spliterator}
     * of this stream, wraps that spliterator so as to support the semantics
     * of this operation on traversal, and returns a new stream associated with
     * the wrapped spliterator.  The returned stream preserves the execution
     * characteristics of this stream (namely parallel or sequential execution
     * as per {@link #isParallel()}) but the wrapped spliterator may choose to
     * not support splitting.  When the returned stream is closed, the close
     * handlers for both the returned and this stream are invoked.
     *
     * @apiNote
     * While {@code takeWhile()} is generally a cheap operation on sequential
     * stream pipelines, it can be quite expensive on ordered parallel
     * pipelines, since the operation is constrained to return not just any
     * valid prefix, but the longest prefix of elements in the encounter order.
     * Using an unordered stream source (such as {@link #generate(Supplier)}) or
     * removing the ordering constraint with {@link #unordered()} may result in
     * significant speedups of {@code takeWhile()} in parallel pipelines, if the
     * semantics of your situation permit.  If consistency with encounter order
     * is required, and you are experiencing poor performance or memory
     * utilization with {@code takeWhile()} in parallel pipelines, switching to
     * sequential execution with {@link #sequential()} may improve performance.
     *
     * @param predicate a <a href="package-summary.html#NonInterference">non-interfering</a>,
     *                  <a href="package-summary.html#Statelessness">stateless</a>
     *                  predicate to apply to elements to determine the longest
     *                  prefix of elements.
     * @return the new stream
     * @since 9
     */
    default Stream<T> takeWhile(Predicate<? super T> predicate) {
        Objects.requireNonNull(predicate);
        // Reuses the unordered spliterator, which, when encounter is present,
        // is safe to use as long as it configured not to split
        return StreamSupport.stream(
                new WhileOps.UnorderedWhileSpliterator.OfRef.Taking<>(spliterator(), true, predicate),
                isParallel()).onClose(this::close);
    }

    /**
     * Returns, if this stream is ordered, a stream consisting of the remaining
     * elements of this stream after dropping the longest prefix of elements
     * that match the given predicate.  Otherwise returns, if this stream is
     * unordered, a stream consisting of the remaining elements of this stream
     * after dropping a subset of elements that match the given predicate.
     *
     * <p>If this stream is ordered then the longest prefix is a contiguous
     * sequence of elements of this stream that match the given predicate.  The
     * first element of the sequence is the first element of this stream, and
     * the element immediately following the last element of the sequence does
     * not match the given predicate.
     *
     * <p>If this stream is unordered, and some (but not all) elements of this
     * stream match the given predicate, then the behavior of this operation is
     * nondeterministic; it is free to drop any subset of matching elements
     * (which includes the empty set).
     *
     * <p>Independent of whether this stream is ordered or unordered if all
     * elements of this stream match the given predicate then this operation
     * drops all elements (the result is an empty stream), or if no elements of
     * the stream match the given predicate then no elements are dropped (the
     * result is the same as the input).
     *
     * <p>This is a <a href="package-summary.html#StreamOps">stateful
     * intermediate operation</a>.
     *
     * @implSpec
     * The default implementation obtains the {@link #spliterator() spliterator}
     * of this stream, wraps that spliterator so as to support the semantics
     * of this operation on traversal, and returns a new stream associated with
     * the wrapped spliterator.  The returned stream preserves the execution
     * characteristics of this stream (namely parallel or sequential execution
     * as per {@link #isParallel()}) but the wrapped spliterator may choose to
     * not support splitting.  When the returned stream is closed, the close
     * handlers for both the returned and this stream are invoked.
     *
     * @apiNote
     * While {@code dropWhile()} is generally a cheap operation on sequential
     * stream pipelines, it can be quite expensive on ordered parallel
     * pipelines, since the operation is constrained to return not just any
     * valid prefix, but the longest prefix of elements in the encounter order.
     * Using an unordered stream source (such as {@link #generate(Supplier)}) or
     * removing the ordering constraint with {@link #unordered()} may result in
     * significant speedups of {@code dropWhile()} in parallel pipelines, if the
     * semantics of your situation permit.  If consistency with encounter order
     * is required, and you are experiencing poor performance or memory
     * utilization with {@code dropWhile()} in parallel pipelines, switching to
     * sequential execution with {@link #sequential()} may improve performance.
     *
     * @param predicate a <a href="package-summary.html#NonInterference">non-interfering</a>,
     *                  <a href="package-summary.html#Statelessness">stateless</a>
     *                  predicate to apply to elements to determine the longest
     *                  prefix of elements.
     * @return the new stream
     * @since 9
     */
    default Stream<T> dropWhile(Predicate<? super T> predicate) {
        Objects.requireNonNull(predicate);
        // Reuses the unordered spliterator, which, when encounter is present,
        // is safe to use as long as it configured not to split
        return StreamSupport.stream(
                new WhileOps.UnorderedWhileSpliterator.OfRef.Dropping<>(spliterator(), true, predicate),
                isParallel()).onClose(this::close);
    }

    /**
     * Performs an action for each element of this stream.
     *
     * <p>This is a <a href="package-summary.html#StreamOps">terminal
     * operation</a>.
     *
     * <p>The behavior of this operation is explicitly nondeterministic.
     * For parallel stream pipelines, this operation does <em>not</em>
     * guarantee to respect the encounter order of the stream, as doing so
     * would sacrifice the benefit of parallelism.  For any given element, the
     * action may be performed at whatever time and in whatever thread the
     * library chooses.  If the action accesses shared state, it is
     * responsible for providing the required synchronization.
     *
     * @param action a <a href="package-summary.html#NonInterference">
     *               non-interfering</a> action to perform on the elements
     */
    void forEach(Consumer<? super T> action);

    /**
     * Performs an action for each element of this stream, in the encounter
     * order of the stream if the stream has a defined encounter order.
     *
     * <p>This is a <a href="package-summary.html#StreamOps">terminal
     * operation</a>.
     *
     * <p>This operation processes the elements one at a time, in encounter
     * order if one exists.  Performing the action for one element
     * <a href="../concurrent/package-summary.html#MemoryVisibility"><i>happens-before</i></a>
     * performing the action for subsequent elements, but for any given element,
     * the action may be performed in whatever thread the library chooses.
     *
     * @param action a <a href="package-summary.html#NonInterference">
     *               non-interfering</a> action to perform on the elements
     * @see #forEach(Consumer)
     */
    void forEachOrdered(Consumer<? super T> action);

    /**
     * Returns an array containing the elements of this stream.
     *
     * <p>This is a <a href="package-summary.html#StreamOps">terminal
     * operation</a>.
     *
     * @return an array, whose {@linkplain Class#getComponentType runtime component
     * type} is {@code Object}, containing the elements of this stream
     */
    
    @Nullable Object[] toArray();

    /**
     * Returns an array containing the elements of this stream, using the
     * provided {@code generator} function to allocate the returned array, as
     * well as any additional arrays that might be required for a partitioned
     * execution or for resizing.
     *
     * <p>This is a <a href="package-summary.html#StreamOps">terminal
     * operation</a>.
     *
     * @apiNote
     * The generator function takes an integer, which is the size of the
     * desired array, and produces an array of the desired size.  This can be
     * concisely expressed with an array constructor reference:
     * <pre>{@code
     *     Person[] men = people.stream()
     *                          .filter(p -> p.getGender() == MALE)
     *                          .toArray(Person[]::new);
     * }</pre>
     *
     * @param <A> the component type of the resulting array
     * @param generator a function which produces a new array of the desired
     *                  type and the provided length
     * @return an array containing the elements in this stream
     * @throws ArrayStoreException if the runtime type of any element of this
     *         stream is not assignable to the {@linkplain Class#getComponentType
     *         runtime component type} of the generated array
     */
    
    <A extends @Nullable Object> A[] toArray(IntFunction<A[]> generator);

    /**
     * Performs a <a href="package-summary.html#Reduction">reduction</a> on the
     * elements of this stream, using the provided identity value and an
     * <a href="package-summary.html#Associativity">associative</a>
     * accumulation function, and returns the reduced value.  This is equivalent
     * to:
     * <pre>{@code
     *     T result = identity;
     *     for (T element : this stream)
     *         result = accumulator.apply(result, element)
     *     return result;
     * }</pre>
     *
     * but is not constrained to execute sequentially.
     *
     * <p>The {@code identity} value must be an identity for the accumulator
     * function. This means that for all {@code t},
     * {@code accumulator.apply(identity, t)} is equal to {@code t}.
     * The {@code accumulator} function must be an
     * <a href="package-summary.html#Associativity">associative</a> function.
     *
     * <p>This is a <a href="package-summary.html#StreamOps">terminal
     * operation</a>.
     *
     * @apiNote Sum, min, max, average, and string concatenation are all special
     * cases of reduction. Summing a stream of numbers can be expressed as:
     *
     * <pre>{@code
     *     Integer sum = integers.reduce(0, (a, b) -> a+b);
     * }</pre>
     *
     * or:
     *
     * <pre>{@code
     *     Integer sum = integers.reduce(0, Integer::sum);
     * }</pre>
     *
     * <p>While this may seem a more roundabout way to perform an aggregation
     * compared to simply mutating a running total in a loop, reduction
     * operations parallelize more gracefully, without needing additional
     * synchronization and with greatly reduced risk of data races.
     *
     * @param identity the identity value for the accumulating function
     * @param accumulator an <a href="package-summary.html#Associativity">associative</a>,
     *                    <a href="package-summary.html#NonInterference">non-interfering</a>,
     *                    <a href="package-summary.html#Statelessness">stateless</a>
     *                    function for combining two values
     * @return the result of the reduction
     */
    T reduce(T identity, BinaryOperator<T> accumulator);

    /**
     * Performs a <a href="package-summary.html#Reduction">reduction</a> on the
     * elements of this stream, using an
     * <a href="package-summary.html#Associativity">associative</a> accumulation
     * function, and returns an {@code Optional} describing the reduced value,
     * if any. This is equivalent to:
     * <pre>{@code
     *     boolean foundAny = false;
     *     T result = null;
     *     for (T element : this stream) {
     *         if (!foundAny) {
     *             foundAny = true;
     *             result = element;
     *         }
     *         else
     *             result = accumulator.apply(result, element);
     *     }
     *     return foundAny ? Optional.of(result) : Optional.empty();
     * }</pre>
     *
     * but is not constrained to execute sequentially.
     *
     * <p>The {@code accumulator} function must be an
     * <a href="package-summary.html#Associativity">associative</a> function.
     *
     * <p>This is a <a href="package-summary.html#StreamOps">terminal
     * operation</a>.
     *
     * @param accumulator an <a href="package-summary.html#Associativity">associative</a>,
     *                    <a href="package-summary.html#NonInterference">non-interfering</a>,
     *                    <a href="package-summary.html#Statelessness">stateless</a>
     *                    function for combining two values
     * @return an {@link Optional} describing the result of the reduction
     * @throws NullPointerException if the result of the reduction is null
     * @see #reduce(Object, BinaryOperator)
     * @see #min(Comparator)
     * @see #max(Comparator)
     */
    Optional<@NonNull T> reduce(BinaryOperator<T> accumulator);

    /**
     * Performs a <a href="package-summary.html#Reduction">reduction</a> on the
     * elements of this stream, using the provided identity, accumulation and
     * combining functions.  This is equivalent to:
     * <pre>{@code
     *     U result = identity;
     *     for (T element : this stream)
     *         result = accumulator.apply(result, element)
     *     return result;
     * }</pre>
     *
     * but is not constrained to execute sequentially.
     *
     * <p>The {@code identity} value must be an identity for the combiner
     * function.  This means that for all {@code u}, {@code combiner(identity, u)}
     * is equal to {@code u}.  Additionally, the {@code combiner} function
     * must be compatible with the {@code accumulator} function; for all
     * {@code u} and {@code t}, the following must hold:
     * <pre>{@code
     *     combiner.apply(u, accumulator.apply(identity, t)) == accumulator.apply(u, t)
     * }</pre>
     *
     * <p>This is a <a href="package-summary.html#StreamOps">terminal
     * operation</a>.
     *
     * @apiNote Many reductions using this form can be represented more simply
     * by an explicit combination of {@code map} and {@code reduce} operations.
     * The {@code accumulator} function acts as a fused mapper and accumulator,
     * which can sometimes be more efficient than separate mapping and reduction,
     * such as when knowing the previously reduced value allows you to avoid
     * some computation.
     *
     * @param <U> The type of the result
     * @param identity the identity value for the combiner function
     * @param accumulator an <a href="package-summary.html#Associativity">associative</a>,
     *                    <a href="package-summary.html#NonInterference">non-interfering</a>,
     *                    <a href="package-summary.html#Statelessness">stateless</a>
     *                    function for incorporating an additional element into a result
     * @param combiner an <a href="package-summary.html#Associativity">associative</a>,
     *                    <a href="package-summary.html#NonInterference">non-interfering</a>,
     *                    <a href="package-summary.html#Statelessness">stateless</a>
     *                    function for combining two values, which must be
     *                    compatible with the accumulator function
     * @return the result of the reduction
     * @see #reduce(BinaryOperator)
     * @see #reduce(Object, BinaryOperator)
     */
    <U extends @Nullable Object> U reduce(U identity,
                 BiFunction<U, ? super T, U> accumulator,
                 BinaryOperator<U> combiner);

    /**
     * Returns a stream consisting of the results of applying the given
     * {@link Gatherer} to the elements of this stream.
     *
     * <p>This is a <a href="package-summary.html#StreamOps">stateful
     * intermediate operation</a> that is an
     * <a href="package-summary.html#Extensibility">extension point</a>.
     *
     * <p>Gatherers are highly flexible and can describe a vast array of
     * possibly stateful operations, with support for short-circuiting, and
     * parallelization.
     *
     * <p>When executed in parallel, multiple intermediate results may be
     * instantiated, populated, and merged so as to maintain isolation of
     * mutable data structures.  Therefore, even when executed in parallel
     * with non-thread-safe data structures (such as {@code ArrayList}), no
     * additional synchronization is needed for a parallel reduction.
     *
     * <p>Implementations are allowed, but not required, to detect consecutive
     * invocations and compose them into a single, fused, operation. This would
     * make the first expression below behave like the second:
     *
     * <pre>{@code
     *     var stream1 = Stream.of(...).gather(gatherer1).gather(gatherer2);
     *     var stream2 = Stream.of(...).gather(gatherer1.andThen(gatherer2));
     * }</pre>
     *
     * @implSpec
     * The default implementation obtains the {@link #spliterator() spliterator}
     * of this stream, wraps that spliterator so as to support the semantics
     * of this operation on traversal, and returns a new stream associated with
     * the wrapped spliterator.  The returned stream preserves the execution
     * characteristics of this stream (namely parallel or sequential execution
     * as per {@link #isParallel()}) but the wrapped spliterator may choose to
     * not support splitting.  When the returned stream is closed, the close
     * handlers for both the returned and this stream are invoked.
     * Implementations of this interface should provide their own
     * implementation of this method.
     *
     * @see Gatherers
     * @param <R> The element type of the new stream
     * @param gatherer a gatherer
     * @return the new stream
     * @since 22
     */
    @PreviewFeature(feature = PreviewFeature.Feature.STREAM_GATHERERS)
    default <R> Stream<R> gather(Gatherer<? super T, ?, R> gatherer) {
        return StreamSupport.stream(spliterator(), isParallel())
                            .gather(gatherer)
                            .onClose(this::close);
    }

    /**
     * Performs a <a href="package-summary.html#MutableReduction">mutable
     * reduction</a> operation on the elements of this stream.  A mutable
     * reduction is one in which the reduced value is a mutable result container,
     * such as an {@code ArrayList}, and elements are incorporated by updating
     * the state of the result rather than by replacing the result.  This
     * produces a result equivalent to:
     * <pre>{@code
     *     R result = supplier.get();
     *     for (T element : this stream)
     *         accumulator.accept(result, element);
     *     return result;
     * }</pre>
     *
     * <p>Like {@link #reduce(Object, BinaryOperator)}, {@code collect} operations
     * can be parallelized without requiring additional synchronization.
     *
     * <p>This is a <a href="package-summary.html#StreamOps">terminal
     * operation</a>.
     *
     * @apiNote There are many existing classes in the JDK whose signatures are
     * well-suited for use with method references as arguments to {@code collect()}.
     * For example, the following will accumulate strings into an {@code ArrayList}:
     * <pre>{@code
     *     List<String> asList = stringStream.collect(ArrayList::new, ArrayList::add,
     *                                                ArrayList::addAll);
     * }</pre>
     *
     * <p>The following will take a stream of strings and concatenates them into a
     * single string:
     * <pre>{@code
     *     String concat = stringStream.collect(StringBuilder::new, StringBuilder::append,
     *                                          StringBuilder::append)
     *                                 .toString();
     * }</pre>
     *
     * @param <R> the type of the mutable result container
     * @param supplier a function that creates a new mutable result container.
     *                 For a parallel execution, this function may be called
     *                 multiple times and must return a fresh value each time.
     * @param accumulator an <a href="package-summary.html#Associativity">associative</a>,
     *                    <a href="package-summary.html#NonInterference">non-interfering</a>,
     *                    <a href="package-summary.html#Statelessness">stateless</a>
     *                    function that must fold an element into a result
     *                    container.
     * @param combiner an <a href="package-summary.html#Associativity">associative</a>,
     *                    <a href="package-summary.html#NonInterference">non-interfering</a>,
     *                    <a href="package-summary.html#Statelessness">stateless</a>
     *                    function that accepts two partial result containers
     *                    and merges them, which must be compatible with the
     *                    accumulator function.  The combiner function must fold
     *                    the elements from the second result container into the
     *                    first result container.
     * @return the result of the reduction
     */
    <R extends @Nullable Object> R collect(Supplier<R> supplier,
                  BiConsumer<R, ? super T> accumulator,
                  BiConsumer<R, R> combiner);

    /**
     * Performs a <a href="package-summary.html#MutableReduction">mutable
     * reduction</a> operation on the elements of this stream using a
     * {@code Collector}.  A {@code Collector}
     * encapsulates the functions used as arguments to
     * {@link #collect(Supplier, BiConsumer, BiConsumer)}, allowing for reuse of
     * collection strategies and composition of collect operations such as
     * multiple-level grouping or partitioning.
     *
     * <p>If the stream is parallel, and the {@code Collector}
     * is {@link Collector.Characteristics#CONCURRENT concurrent}, and
     * either the stream is unordered or the collector is
     * {@link Collector.Characteristics#UNORDERED unordered},
     * then a concurrent reduction will be performed (see {@link Collector} for
     * details on concurrent reduction.)
     *
     * <p>This is a <a href="package-summary.html#StreamOps">terminal
     * operation</a>.
     *
     * <p>When executed in parallel, multiple intermediate results may be
     * instantiated, populated, and merged so as to maintain isolation of
     * mutable data structures.  Therefore, even when executed in parallel
     * with non-thread-safe data structures (such as {@code ArrayList}), no
     * additional synchronization is needed for a parallel reduction.
     *
     * @apiNote
     * The following will accumulate strings into a List:
     * <pre>{@code
     *     List<String> asList = stringStream.collect(Collectors.toList());
     * }</pre>
     *
     * <p>The following will classify {@code Person} objects by city:
     * <pre>{@code
     *     Map<String, List<Person>> peopleByCity
     *         = personStream.collect(Collectors.groupingBy(Person::getCity));
     * }</pre>
     *
     * <p>The following will classify {@code Person} objects by state and city,
     * cascading two {@code Collector}s together:
     * <pre>{@code
     *     Map<String, Map<String, List<Person>>> peopleByStateAndCity
     *         = personStream.collect(Collectors.groupingBy(Person::getState,
     *                                                      Collectors.groupingBy(Person::getCity)));
     * }</pre>
     *
     * @param <R> the type of the result
     * @param <A> the intermediate accumulation type of the {@code Collector}
     * @param collector the {@code Collector} describing the reduction
     * @return the result of the reduction
     * @see #collect(Supplier, BiConsumer, BiConsumer)
     * @see Collectors
     */
    <R extends @Nullable Object, A extends @Nullable Object> R collect(Collector<? super T, A, R> collector);

    /**
     * Accumulates the elements of this stream into a {@code List}. The elements in
     * the list will be in this stream's encounter order, if one exists. The returned List
     * is unmodifiable; calls to any mutator method will always cause
     * {@code UnsupportedOperationException} to be thrown. There are no
     * guarantees on the implementation type or serializability of the returned List.
     *
     * <p>The returned instance may be <a href="{@docRoot}/java.base/java/lang/doc-files/ValueBased.html">value-based</a>.
     * Callers should make no assumptions about the identity of the returned instances.
     * Identity-sensitive operations on these instances (reference equality ({@code ==}),
     * identity hash code, and synchronization) are unreliable and should be avoided.
     *
     * <p>This is a <a href="package-summary.html#StreamOps">terminal operation</a>.
     *
     * @apiNote If more control over the returned object is required, use
     * {@link Collectors#toCollection(Supplier)}.
     *
     * @implSpec The implementation in this interface returns a List produced as if by the following:
     * <pre>{@code
     * Collections.unmodifiableList(new ArrayList<>(Arrays.asList(this.toArray())))
     * }</pre>
     *
     * @implNote Most instances of Stream will override this method and provide an implementation
     * that is highly optimized compared to the implementation in this interface.
     *
     * @return a List containing the stream elements
     *
     * @since 16
     */
    @SuppressWarnings("unchecked")
    default List<T> toList() {
        return (List<T>) Collections.unmodifiableList(new ArrayList<>(Arrays.asList(this.toArray())));
    }

    /**
     * Returns the minimum element of this stream according to the provided
     * {@code Comparator}.  This is a special case of a
     * <a href="package-summary.html#Reduction">reduction</a>.
     *
     * <p>This is a <a href="package-summary.html#StreamOps">terminal operation</a>.
     *
     * @param comparator a <a href="package-summary.html#NonInterference">non-interfering</a>,
     *                   <a href="package-summary.html#Statelessness">stateless</a>
     *                   {@code Comparator} to compare elements of this stream
     * @return an {@code Optional} describing the minimum element of this stream,
     * or an empty {@code Optional} if the stream is empty
     * @throws NullPointerException if the minimum element is null
     */
    Optional<@NonNull T> min(Comparator<? super T> comparator);

    /**
     * Returns the maximum element of this stream according to the provided
     * {@code Comparator}.  This is a special case of a
     * <a href="package-summary.html#Reduction">reduction</a>.
     *
     * <p>This is a <a href="package-summary.html#StreamOps">terminal
     * operation</a>.
     *
     * @param comparator a <a href="package-summary.html#NonInterference">non-interfering</a>,
     *                   <a href="package-summary.html#Statelessness">stateless</a>
     *                   {@code Comparator} to compare elements of this stream
     * @return an {@code Optional} describing the maximum element of this stream,
     * or an empty {@code Optional} if the stream is empty
     * @throws NullPointerException if the maximum element is null
     */
    Optional<@NonNull T> max(Comparator<? super T> comparator);

    /**
     * Returns the count of elements in this stream.  This is a special case of
     * a <a href="package-summary.html#Reduction">reduction</a> and is
     * equivalent to:
     * <pre>{@code
     *     return mapToLong(e -> 1L).sum();
     * }</pre>
     *
     * <p>This is a <a href="package-summary.html#StreamOps">terminal operation</a>.
     *
     * @apiNote
     * An implementation may choose to not execute the stream pipeline (either
     * sequentially or in parallel) if it is capable of computing the count
     * directly from the stream source.  In such cases no source elements will
     * be traversed and no intermediate operations will be evaluated.
     * Behavioral parameters with side-effects, which are strongly discouraged
     * except for harmless cases such as debugging, may be affected.  For
     * example, consider the following stream:
     * <pre>{@code
     *     List<String> l = Arrays.asList("A", "B", "C", "D");
     *     long count = l.stream().peek(System.out::println).count();
     * }</pre>
     * The number of elements covered by the stream source, a {@code List}, is
     * known and the intermediate operation, {@code peek}, does not inject into
     * or remove elements from the stream (as may be the case for
     * {@code flatMap} or {@code filter} operations).  Thus the count is the
     * size of the {@code List} and there is no need to execute the pipeline
     * and, as a side-effect, print out the list elements.
     *
     * @return the count of elements in this stream
     */
    long count();

    /**
     * Returns whether any elements of this stream match the provided
     * predicate.  May not evaluate the predicate on all elements if not
     * necessary for determining the result.  If the stream is empty then
     * {@code false} is returned and the predicate is not evaluated.
     *
     * <p>This is a <a href="package-summary.html#StreamOps">short-circuiting
     * terminal operation</a>.
     *
     * @apiNote
     * This method evaluates the <em>existential quantification</em> of the
     * predicate over the elements of the stream (for some x P(x)).
     *
     * @param predicate a <a href="package-summary.html#NonInterference">non-interfering</a>,
     *                  <a href="package-summary.html#Statelessness">stateless</a>
     *                  predicate to apply to elements of this stream
     * @return {@code true} if any elements of the stream match the provided
     * predicate, otherwise {@code false}
     */
    boolean anyMatch(Predicate<? super T> predicate);

    /**
     * Returns whether all elements of this stream match the provided predicate.
     * May not evaluate the predicate on all elements if not necessary for
     * determining the result.  If the stream is empty then {@code true} is
     * returned and the predicate is not evaluated.
     *
     * <p>This is a <a href="package-summary.html#StreamOps">short-circuiting
     * terminal operation</a>.
     *
     * @apiNote
     * This method evaluates the <em>universal quantification</em> of the
     * predicate over the elements of the stream (for all x P(x)).  If the
     * stream is empty, the quantification is said to be <em>vacuously
     * satisfied</em> and is always {@code true} (regardless of P(x)).
     *
     * @param predicate a <a href="package-summary.html#NonInterference">non-interfering</a>,
     *                  <a href="package-summary.html#Statelessness">stateless</a>
     *                  predicate to apply to elements of this stream
     * @return {@code true} if either all elements of the stream match the
     * provided predicate or the stream is empty, otherwise {@code false}
     */
    boolean allMatch(Predicate<? super T> predicate);

    /**
     * Returns whether no elements of this stream match the provided predicate.
     * May not evaluate the predicate on all elements if not necessary for
     * determining the result.  If the stream is empty then {@code true} is
     * returned and the predicate is not evaluated.
     *
     * <p>This is a <a href="package-summary.html#StreamOps">short-circuiting
     * terminal operation</a>.
     *
     * @apiNote
     * This method evaluates the <em>universal quantification</em> of the
     * negated predicate over the elements of the stream (for all x ~P(x)).  If
     * the stream is empty, the quantification is said to be vacuously satisfied
     * and is always {@code true}, regardless of P(x).
     *
     * @param predicate a <a href="package-summary.html#NonInterference">non-interfering</a>,
     *                  <a href="package-summary.html#Statelessness">stateless</a>
     *                  predicate to apply to elements of this stream
     * @return {@code true} if either no elements of the stream match the
     * provided predicate or the stream is empty, otherwise {@code false}
     */
    boolean noneMatch(Predicate<? super T> predicate);

    /**
     * Returns an {@link Optional} describing the first element of this stream,
     * or an empty {@code Optional} if the stream is empty.  If the stream has
     * no encounter order, then any element may be returned.
     *
     * <p>This is a <a href="package-summary.html#StreamOps">short-circuiting
     * terminal operation</a>.
     *
     * @return an {@code Optional} describing the first element of this stream,
     * or an empty {@code Optional} if the stream is empty
     * @throws NullPointerException if the element selected is null
     */
    Optional<@NonNull T> findFirst();

    /**
     * Returns an {@link Optional} describing some element of the stream, or an
     * empty {@code Optional} if the stream is empty.
     *
     * <p>This is a <a href="package-summary.html#StreamOps">short-circuiting
     * terminal operation</a>.
     *
     * <p>The behavior of this operation is explicitly nondeterministic; it is
     * free to select any element in the stream.  This is to allow for maximal
     * performance in parallel operations; the cost is that multiple invocations
     * on the same source may not return the same result.  (If a stable result
     * is desired, use {@link #findFirst()} instead.)
     *
     * @return an {@code Optional} describing some element of this stream, or an
     * empty {@code Optional} if the stream is empty
     * @throws NullPointerException if the element selected is null
     * @see #findFirst()
     */
    Optional<@NonNull T> findAny();

    // Static factories

    /**
     * Returns a builder for a {@code Stream}.
     *
     * @param <T> type of elements
     * @return a stream builder
     */
    public static<T extends @Nullable Object> Builder<T> builder() {
        return new Streams.StreamBuilderImpl<>();
    }

    /**
     * Returns an empty sequential {@code Stream}.
     *
     * @param <T> the type of stream elements
     * @return an empty sequential stream
     */
    public static<T extends @Nullable Object> Stream<T> empty() {
        return StreamSupport.stream(Spliterators.emptySpliterator(), false);
    }

    /**
     * Returns a sequential {@code Stream} containing a single element.
     *
     * @param t the single element
     * @param <T> the type of stream elements
     * @return a singleton sequential stream
     */
    public static<T extends @Nullable Object> Stream<T> of(T t) {
        return StreamSupport.stream(new Streams.StreamBuilderImpl<>(t), false);
    }

    /**
     * Returns a sequential {@code Stream} containing a single element, if
     * non-null, otherwise returns an empty {@code Stream}.
     *
     * @param t the single element
     * @param <T> the type of stream elements
     * @return a stream with a single element if the specified element
     *         is non-null, otherwise an empty stream
     * @since 9
     */
    public static<T extends @Nullable Object> Stream<T> ofNullable(@Nullable T t) {
        return t == null ? Stream.empty()
                         : StreamSupport.stream(new Streams.StreamBuilderImpl<>(t), false);
    }

    /**
     * Returns a sequential ordered stream whose elements are the specified values.
     *
     * @param <T> the type of stream elements
     * @param values the elements of the new stream
     * @return the new stream
     */
    @SafeVarargs
    @SuppressWarnings("varargs") // Creating a stream from an array is safe
    public static<T extends @Nullable Object> Stream<T> of(T... values) {
        return Arrays.stream(values);
    }

    /**
     * Returns an infinite sequential ordered {@code Stream} produced by iterative
     * application of a function {@code f} to an initial element {@code seed},
     * producing a {@code Stream} consisting of {@code seed}, {@code f(seed)},
     * {@code f(f(seed))}, etc.
     *
     * <p>The first element (position {@code 0}) in the {@code Stream} will be
     * the provided {@code seed}.  For {@code n > 0}, the element at position
     * {@code n}, will be the result of applying the function {@code f} to the
     * element at position {@code n - 1}.
     *
     * <p>The action of applying {@code f} for one element
     * <a href="../concurrent/package-summary.html#MemoryVisibility"><i>happens-before</i></a>
     * the action of applying {@code f} for subsequent elements.  For any given
     * element the action may be performed in whatever thread the library
     * chooses.
     *
     * @param <T> the type of stream elements
     * @param seed the initial element
     * @param f a function to be applied to the previous element to produce
     *          a new element
     * @return a new sequential {@code Stream}
     */
    public static<T extends @Nullable Object> Stream<T> iterate(final T seed, final UnaryOperator<T> f) {
        Objects.requireNonNull(f);
        Spliterator<T> spliterator = new Spliterators.AbstractSpliterator<>(Long.MAX_VALUE,
               Spliterator.ORDERED | Spliterator.IMMUTABLE) {
            T prev;
            boolean started;

            @Override
            public boolean tryAdvance(Consumer<? super T> action) {
                Objects.requireNonNull(action);
                T t;
                if (started)
                    t = f.apply(prev);
                else {
                    t = seed;
                    started = true;
                }
                action.accept(prev = t);
                return true;
            }
        };
        return StreamSupport.stream(spliterator, false);
    }

    /**
     * Returns a sequential ordered {@code Stream} produced by iterative
     * application of the given {@code next} function to an initial element,
     * conditioned on satisfying the given {@code hasNext} predicate.  The
     * stream terminates as soon as the {@code hasNext} predicate returns false.
     *
     * <p>{@code Stream.iterate} should produce the same sequence of elements as
     * produced by the corresponding for-loop:
     * <pre>{@code
     *     for (T index=seed; hasNext.test(index); index = next.apply(index)) {
     *         ...
     *     }
     * }</pre>
     *
     * <p>The resulting sequence may be empty if the {@code hasNext} predicate
     * does not hold on the seed value.  Otherwise the first element will be the
     * supplied {@code seed} value, the next element (if present) will be the
     * result of applying the {@code next} function to the {@code seed} value,
     * and so on iteratively until the {@code hasNext} predicate indicates that
     * the stream should terminate.
     *
     * <p>The action of applying the {@code hasNext} predicate to an element
     * <a href="../concurrent/package-summary.html#MemoryVisibility"><i>happens-before</i></a>
     * the action of applying the {@code next} function to that element.  The
     * action of applying the {@code next} function for one element
     * <i>happens-before</i> the action of applying the {@code hasNext}
     * predicate for subsequent elements.  For any given element an action may
     * be performed in whatever thread the library chooses.
     *
     * @param <T> the type of stream elements
     * @param seed the initial element
     * @param hasNext a predicate to apply to elements to determine when the
     *                stream must terminate.
     * @param next a function to be applied to the previous element to produce
     *             a new element
     * @return a new sequential {@code Stream}
     * @since 9
     */
    public static<T extends @Nullable Object> Stream<T> iterate(T seed, Predicate<? super T> hasNext, UnaryOperator<T> next) {
        Objects.requireNonNull(next);
        Objects.requireNonNull(hasNext);
        Spliterator<T> spliterator = new Spliterators.AbstractSpliterator<>(Long.MAX_VALUE,
               Spliterator.ORDERED | Spliterator.IMMUTABLE) {
            T prev;
            boolean started, finished;

            @Override
            public boolean tryAdvance(Consumer<? super T> action) {
                Objects.requireNonNull(action);
                if (finished)
                    return false;
                T t;
                if (started)
                    t = next.apply(prev);
                else {
                    t = seed;
                    started = true;
                }
                if (!hasNext.test(t)) {
                    prev = null;
                    finished = true;
                    return false;
                }
                action.accept(prev = t);
                return true;
            }

            @Override
            public void forEachRemaining(Consumer<? super T> action) {
                Objects.requireNonNull(action);
                if (finished)
                    return;
                finished = true;
                T t = started ? next.apply(prev) : seed;
                prev = null;
                while (hasNext.test(t)) {
                    action.accept(t);
                    t = next.apply(t);
                }
            }
        };
        return StreamSupport.stream(spliterator, false);
    }

    /**
     * Returns an infinite sequential unordered stream where each element is
     * generated by the provided {@code Supplier}.  This is suitable for
     * generating constant streams, streams of random elements, etc.
     *
     * @param <T> the type of stream elements
     * @param s the {@code Supplier} of generated elements
     * @return a new infinite sequential unordered {@code Stream}
     */
    public static<T extends @Nullable Object> Stream<T> generate(Supplier<? extends T> s) {
        Objects.requireNonNull(s);
        return StreamSupport.stream(
                new StreamSpliterators.InfiniteSupplyingSpliterator.OfRef<>(Long.MAX_VALUE, s), false);
    }

    /**
     * Creates a lazily concatenated stream whose elements are all the
     * elements of the first stream followed by all the elements of the
     * second stream.  The resulting stream is ordered if both
     * of the input streams are ordered, and parallel if either of the input
     * streams is parallel.  When the resulting stream is closed, the close
     * handlers for both input streams are invoked.
     *
     * <p>This method operates on the two input streams and binds each stream
     * to its source.  As a result subsequent modifications to an input stream
     * source may not be reflected in the concatenated stream result.
     *
     * @implNote
     * Use caution when constructing streams from repeated concatenation.
     * Accessing an element of a deeply concatenated stream can result in deep
     * call chains, or even {@code StackOverflowError}.
     *
     * <p>Subsequent changes to the sequential/parallel execution mode of the
     * returned stream are not guaranteed to be propagated to the input streams.
     *
     * @apiNote
     * To preserve optimization opportunities this method binds each stream to
     * its source and accepts only two streams as parameters.  For example, the
     * exact size of the concatenated stream source can be computed if the exact
     * size of each input stream source is known.
     * To concatenate more streams without binding, or without nested calls to
     * this method, try creating a stream of streams and flat-mapping with the
     * identity function, for example:
     * <pre>{@code
     *     Stream<T> concat = Stream.of(s1, s2, s3, s4).flatMap(s -> s);
     * }</pre>
     *
     * @param <T> The type of stream elements
     * @param a the first stream
     * @param b the second stream
     * @return the concatenation of the two input streams
     */
    public static <T extends @Nullable Object> Stream<T> concat(Stream<? extends T> a, Stream<? extends T> b) {
        Objects.requireNonNull(a);
        Objects.requireNonNull(b);

        @SuppressWarnings("unchecked")
        Spliterator<T> split = new Streams.ConcatSpliterator.OfRef<>(
                (Spliterator<T>) a.spliterator(), (Spliterator<T>) b.spliterator());
        Stream<T> stream = StreamSupport.stream(split, a.isParallel() || b.isParallel());
        return stream.onClose(Streams.composedClose(a, b));
    }

    /**
     * A mutable builder for a {@code Stream}.  This allows the creation of a
     * {@code Stream} by generating elements individually and adding them to the
     * {@code Builder} (without the copying overhead that comes from using
     * an {@code ArrayList} as a temporary buffer.)
     *
     * <p>A stream builder has a lifecycle, which starts in a building
     * phase, during which elements can be added, and then transitions to a built
     * phase, after which elements may not be added.  The built phase begins
     * when the {@link #build()} method is called, which creates an ordered
     * {@code Stream} whose elements are the elements that were added to the stream
     * builder, in the order they were added.
     *
     * @param <T> the type of stream elements
     * @see Stream#builder()
     * @since 1.8
     */
    public interface Builder<T extends @Nullable Object> extends Consumer<T> {

        /**
         * Adds an element to the stream being built.
         *
         * @throws IllegalStateException if the builder has already transitioned to
         * the built state
         */
        @Override
        void accept(T t);

        /**
         * Adds an element to the stream being built.
         *
         * @implSpec
         * The default implementation behaves as if:
         * <pre>{@code
         *     accept(t)
         *     return this;
         * }</pre>
         *
         * @param t the element to add
         * @return {@code this} builder
         * @throws IllegalStateException if the builder has already transitioned to
         * the built state
         */
        default Builder<T> add(T t) {
            accept(t);
            return this;
        }

        /**
         * Builds the stream, transitioning this builder to the built state.
         * An {@code IllegalStateException} is thrown if there are further attempts
         * to operate on the builder after it has entered the built state.
         *
         * @return the built stream
         * @throws IllegalStateException if the builder has already transitioned to
         * the built state
         */
        Stream<T> build();

    }
}