/* * Copyright (c) 2012, 2013, 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.Arrays; import java.util.IntSummaryStatistics; import java.util.Objects; import java.util.OptionalDouble; import java.util.OptionalInt; import java.util.PrimitiveIterator; import java.util.Spliterator; import java.util.Spliterators; import java.util.function.BiConsumer; import java.util.function.Function; import java.util.function.IntBinaryOperator; import java.util.function.IntConsumer; import java.util.function.IntFunction; import java.util.function.IntPredicate; import java.util.function.IntSupplier; import java.util.function.IntToDoubleFunction; import java.util.function.IntToLongFunction; import java.util.function.IntUnaryOperator; import java.util.function.ObjIntConsumer; import java.util.function.Supplier; /** * A sequence of primitive integer elements supporting sequential and parallel * bulk operations. Streams support lazy intermediate operations (transforming * a stream to another stream) such as {@code filter} and {@code map}, and terminal * operations (consuming the contents of a stream to produce a result or * side-effect), such as {@code forEach}, {@code findFirst}, and {@code * iterator}. Once an operation has been performed on a stream, it * is considered consumed and no longer usable for other operations. * *

For sequential stream pipelines, all operations are performed in the * encounter order of the pipeline * source, if the pipeline source has a defined encounter order. * *

For parallel stream pipelines, unless otherwise specified, intermediate * stream operations preserve the * encounter order of their source, and terminal operations * respect the encounter order of their source, if the source * has an encounter order. Provided that and parameters to stream operations * satisfy the non-interference * requirements, and excepting differences arising from the absence of * a defined encounter order, the result of a stream pipeline should be the * stable across multiple executions of the same operations on the same source. * However, the timing and thread in which side-effects occur (for those * operations which are allowed to produce side-effects, such as * {@link #forEach(IntConsumer)}), are explicitly nondeterministic for parallel * execution of stream pipelines. * *

Unless otherwise noted, passing a {@code null} argument to any stream * method may result in a {@link NullPointerException}. * * @apiNote * Streams are not data structures; they do not manage the storage for their * elements, nor do they support access to individual elements. However, * you can use the {@link #iterator()} or {@link #spliterator()} operations to * perform a controlled traversal. * * @since 1.8 * @see java.util.stream */ public interface IntStream extends BaseStream { /** * Returns a stream consisting of the elements of this stream that match * the given predicate. * *

This is an intermediate * operation. * * @param predicate a * non-interfering, stateless predicate to apply to * each element to determine if it should be included * @return the new stream */ IntStream filter(IntPredicate predicate); /** * Returns a stream consisting of the results of applying the given * function to the elements of this stream. * *

This is an intermediate * operation. * * @param mapper a * non-interfering, stateless function to apply to each * element * @return the new stream */ IntStream map(IntUnaryOperator mapper); /** * Returns an object-valued {@code Stream} consisting of the results of * applying the given function to the elements of this stream. * *

This is an * intermediate operation. * * @param the element type of the new stream * @param mapper a * non-interfering, stateless function to apply to each * element * @return the new stream */ Stream mapToObj(IntFunction mapper); /** * Returns a {@code LongStream} consisting of the results of applying the * given function to the elements of this stream. * *

This is an intermediate * operation. * * @param mapper a * non-interfering, stateless function to apply to each * element * @return the new stream */ LongStream mapToLong(IntToLongFunction mapper); /** * Returns a {@code DoubleStream} consisting of the results of applying the * given function to the elements of this stream. * *

This is an intermediate * operation. * * @param mapper a * non-interfering, stateless function to apply to each * element * @return the new stream */ DoubleStream mapToDouble(IntToDoubleFunction mapper); /** * Returns a stream consisting of the results of replacing each element of * this stream with the contents of the stream produced by applying the * provided mapping function to each element. * *

This is an intermediate * operation. * * @apiNote * The {@code flatMap()} operation has the effect of applying a one-to-many * tranformation to the elements of the stream, and then flattening the * resulting elements into a new stream. For example, 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 of line * items: *

{@code
     *     orderStream.flatMap(order -> order.getLineItems().stream())...
     * }
* * @param mapper a * non-interfering, stateless function to apply to * each element which produces an {@code IntStream} of new * values * @return the new stream * @see Stream#flatMap(Function) */ IntStream flatMap(IntFunction mapper); /** * Returns a stream consisting of the distinct elements of this stream. * *

This is a stateful * intermediate operation. * * @return the new stream */ IntStream distinct(); /** * Returns a stream consisting of the elements of this stream in sorted * order. * *

This is a stateful * intermediate operation. * * @return the new stream */ IntStream sorted(); /** * 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. * *

This is an intermediate * operation. * *

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: *

{@code
     *     list.stream()
     *         .filter(filteringFunction)
     *         .peek(e -> {System.out.println("Filtered value: " + e); });
     *         .map(mappingFunction)
     *         .peek(e -> {System.out.println("Mapped value: " + e); });
     *         .collect(Collectors.toIntSummaryStastistics());
     * }
* * @param consumer a * non-interfering action to perform on the elements as * they are consumed from the stream * @return the new stream */ IntStream peek(IntConsumer consumer); /** * Returns a stream consisting of the elements of this stream, truncated * to be no longer than {@code maxSize} in length. * *

This is a short-circuiting * stateful intermediate operation. * * @param maxSize the number of elements the stream should be limited to * @return the new stream * @throws IllegalArgumentException if {@code maxSize} is negative */ IntStream limit(long maxSize); /** * Returns a stream consisting of the remaining elements of this stream * after indexing {@code startInclusive} elements into the stream. If the * {@code startInclusive} index lies past the end of this stream then an * empty stream will be returned. * *

This is a stateful * intermediate operation. * * @param startInclusive the number of leading elements to skip * @return the new stream * @throws IllegalArgumentException if {@code startInclusive} is negative */ IntStream substream(long startInclusive); /** * Returns a stream consisting of the remaining elements of this stream * after indexing {@code startInclusive} elements into the stream and * truncated to contain no more than {@code endExclusive - startInclusive} * elements. If the {@code startInclusive} index lies past the end * of this stream then an empty stream will be returned. * *

This is a short-circuiting * stateful intermediate operation. * * @param startInclusive the starting position of the substream, inclusive * @param endExclusive the ending position of the substream, exclusive * @return the new stream * @throws IllegalArgumentException if {@code startInclusive} or * {@code endExclusive} is negative or {@code startInclusive} is greater * than {@code endExclusive} */ IntStream substream(long startInclusive, long endExclusive); /** * Performs an action for each element of this stream. * *

This is a terminal * operation. * *

For parallel stream pipelines, this operation does not * 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 * non-interfering action to perform on the elements */ void forEach(IntConsumer action); /** * Performs an action for each element of this stream, guaranteeing that * each element is processed in encounter order for streams that have a * defined encounter order. * *

This is a terminal * operation. * * @param action a * non-interfering action to perform on the elements * @see #forEach(IntConsumer) */ void forEachOrdered(IntConsumer action); /** * Returns an array containing the elements of this stream. * *

This is a terminal * operation. * * @return an array containing the elements of this stream */ int[] toArray(); /** * Performs a reduction on the * elements of this stream, using the provided identity value and an * associative * accumulation function, and returns the reduced value. This is equivalent * to: *

{@code
     *     int result = identity;
     *     for (int element : this stream)
     *         result = accumulator.apply(result, element)
     *     return result;
     * }
* * but is not constrained to execute sequentially. * *

The {@code identity} value must be an identity for the accumulator * function. This means that for all {@code x}, * {@code accumulator.apply(identity, x)} is equal to {@code x}. * The {@code accumulator} function must be an * associative function. * *

This is a terminal * operation. * * @apiNote Sum, min, max, and average are all special cases of reduction. * Summing a stream of numbers can be expressed as: * *

{@code
     *     int sum = integers.reduce(0, (a, b) -> a+b);
     * }
* * or more compactly: * *
{@code
     *     int sum = integers.reduce(0, Integer::sum);
     * }
* *

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 op an associative * non-interfering, * stateless function for combining two values * @return the result of the reduction * @see #sum() * @see #min() * @see #max() * @see #average() */ int reduce(int identity, IntBinaryOperator op); /** * Performs a reduction on the * elements of this stream, using an * associative accumulation * function, and returns an {@code OptionalInt} describing the reduced value, * if any. This is equivalent to: *

{@code
     *     boolean foundAny = false;
     *     int result = null;
     *     for (int element : this stream) {
     *         if (!foundAny) {
     *             foundAny = true;
     *             result = element;
     *         }
     *         else
     *             result = accumulator.apply(result, element);
     *     }
     *     return foundAny ? OptionalInt.of(result) : OptionalInt.empty();
     * }
* * but is not constrained to execute sequentially. * *

The {@code accumulator} function must be an * associative function. * *

This is a terminal * operation. * * @param op an associative * non-interfering, * stateless function for combining two values * @return the result of the reduction * @see #reduce(int, IntBinaryOperator) */ OptionalInt reduce(IntBinaryOperator op); /** * Performs a mutable * reduction operation on the elements of this stream. A mutable * reduction is one in which the reduced value is a mutable value holder, * 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: *

{@code
     *     R result = resultFactory.get();
     *     for (int element : this stream)
     *         accumulator.accept(result, element);
     *     return result;
     * }
* *

Like {@link #reduce(int, IntBinaryOperator)}, {@code collect} operations * can be parallelized without requiring additional synchronization. * *

This is a terminal * operation. * * @param type of the result * @param resultFactory a function that creates a new result container. * For a parallel execution, this function may be * called multiple times and must return a fresh value * each time. * @param accumulator an associative * non-interfering, * stateless function for incorporating an additional * element into a result * @param combiner an associative * non-interfering, * stateless function for combining two values, which * must be compatible with the accumulator function * @return the result of the reduction * @see Stream#collect(Supplier, BiConsumer, BiConsumer) */ R collect(Supplier resultFactory, ObjIntConsumer accumulator, BiConsumer combiner); /** * Returns the sum of elements in this stream. This is a special case * of a reduction * and is equivalent to: *

{@code
     *     return reduce(0, Integer::sum);
     * }
* * @return the sum of elements in this stream */ int sum(); /** * Returns an {@code OptionalInt} describing the minimum element of this * stream, or an empty optional if this stream is empty. This is a special * case of a reduction * and is equivalent to: *
{@code
     *     return reduce(Integer::min);
     * }
* *

This is a terminal operation. * * @return an {@code OptionalInt} containing the minimum element of this * stream, or an empty {@code OptionalInt} if the stream is empty */ OptionalInt min(); /** * Returns an {@code OptionalInt} describing the maximum element of this * stream, or an empty optional if this stream is empty. This is a special * case of a reduction * and is equivalent to: *

{@code
     *     return reduce(Integer::max);
     * }
* *

This is a terminal * operation. * * @return an {@code OptionalInt} containing the maximum element of this * stream, or an empty {@code OptionalInt} if the stream is empty */ OptionalInt max(); /** * Returns the count of elements in this stream. This is a special case of * a reduction and is * equivalent to: *

{@code
     *     return mapToLong(e -> 1L).sum();
     * }
* *

This is a terminal operation. * * @return the count of elements in this stream */ long count(); /** * Returns an {@code OptionalDouble} describing the arithmetic mean of elements of * this stream, or an empty optional if this stream is empty. This is a * special case of a * reduction. * * @return an {@code OptionalDouble} containing the average element of this * stream, or an empty optional if the stream is empty */ OptionalDouble average(); /** * Returns an {@code IntSummaryStatistics} describing various * summary data about the elements of this stream. This is a special * case of a reduction. * * @return an {@code IntSummaryStatistics} describing various summary data * about the elements of this stream */ IntSummaryStatistics summaryStatistics(); /** * 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. * *

This is a short-circuiting * terminal operation. * * @param predicate a non-interfering, * stateless 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(IntPredicate 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. * *

This is a short-circuiting * terminal operation. * * @param predicate a non-interfering, * stateless predicate to apply to elements of this * stream * @return {@code true} if all elements of the stream match the provided * predicate otherwise {@code false} */ boolean allMatch(IntPredicate 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. * *

This is a short-circuiting * terminal operation. * * @param predicate a non-interfering, * stateless predicate to apply to elements of this * stream * @return {@code true} if no elements of the stream match the provided * predicate otherwise {@code false} */ boolean noneMatch(IntPredicate predicate); /** * Returns an {@link OptionalInt} describing the first element of this * stream (in the encounter order), or an empty {@code OptionalInt} if the * stream is empty. If the stream has no encounter order, then any element * may be returned. * *

This is a short-circuiting * terminal operation. * * @return an {@code OptionalInt} describing the first element of this stream, * or an empty {@code OptionalInt} if the stream is empty */ OptionalInt findFirst(); /** * Returns an {@link OptionalInt} describing some element of the stream, or * an empty {@code OptionalInt} if the stream is empty. * *

This is a short-circuiting * terminal operation. * *

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 the first element * in the encounter order is desired, use {@link #findFirst()} instead.) * * @return an {@code OptionalInt} describing some element of this stream, or * an empty {@code OptionalInt} if the stream is empty * @see #findFirst() */ OptionalInt findAny(); /** * Returns a {@code LongStream} consisting of the elements of this stream, * converted to {@code long}. * * @return a {@code LongStream} consisting of the elements of this stream, * converted to {@code long} */ LongStream asLongStream(); /** * Returns a {@code DoubleStream} consisting of the elements of this stream, * converted to {@code double}. * * @return a {@code DoubleStream} consisting of the elements of this stream, * converted to {@code double} */ DoubleStream asDoubleStream(); /** * Returns a {@code Stream} consisting of the elements of this stream, * each boxed to an {@code Integer}. * * @return a {@code Stream} consistent of the elements of this stream, * each boxed to an {@code Integer} */ Stream boxed(); @Override IntStream sequential(); @Override IntStream parallel(); @Override PrimitiveIterator.OfInt iterator(); @Override Spliterator.OfInt spliterator(); // Static factories /** * Returns a builder for an {@code IntStream}. * * @return a stream builder */ public static Builder builder() { return new Streams.IntStreamBuilderImpl(); } /** * Returns an empty sequential {@code IntStream}. * * @return an empty sequential stream */ public static IntStream empty() { return StreamSupport.intStream(Spliterators.emptyIntSpliterator(), false); } /** * Returns a sequential {@code IntStream} containing a single element. * * @param t the single element * @return a singleton sequential stream */ public static IntStream of(int t) { return StreamSupport.intStream(new Streams.IntStreamBuilderImpl(t), false); } /** * Returns a sequential stream whose elements are the specified values. * * @param values the elements of the new stream * @return the new stream */ public static IntStream of(int... values) { return Arrays.stream(values); } /** * Returns an infinite sequential {@code IntStream} 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. * *

The first element (position {@code 0}) in the {@code IntStream} 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}. * * @param seed the initial element * @param f a function to be applied to to the previous element to produce * a new element * @return A new sequential {@code IntStream} */ public static IntStream iterate(final int seed, final IntUnaryOperator f) { Objects.requireNonNull(f); final PrimitiveIterator.OfInt iterator = new PrimitiveIterator.OfInt() { int t = seed; @Override public boolean hasNext() { return true; } @Override public int nextInt() { int v = t; t = f.applyAsInt(t); return v; } }; return StreamSupport.intStream(Spliterators.spliteratorUnknownSize( iterator, Spliterator.ORDERED | Spliterator.IMMUTABLE | Spliterator.NONNULL), false); } /** * Returns a sequential {@code IntStream} where each element is * generated by an {@code IntSupplier}. This is suitable for generating * constant streams, streams of random elements, etc. * * @param s the {@code IntSupplier} for generated elements * @return a new sequential {@code IntStream} */ public static IntStream generate(IntSupplier s) { Objects.requireNonNull(s); return StreamSupport.intStream( new StreamSpliterators.InfiniteSupplyingSpliterator.OfInt(Long.MAX_VALUE, s), false); } /** * Returns a sequential {@code IntStream} from {@code startInclusive} * (inclusive) to {@code endExclusive} (exclusive) by an incremental step of * {@code 1}. * * @apiNote *

An equivalent sequence of increasing values can be produced * sequentially using a {@code for} loop as follows: *

{@code
     *     for (int i = startInclusive; i < endExclusive ; i++) { ... }
     * }
* * @param startInclusive the (inclusive) initial value * @param endExclusive the exclusive upper bound * @return a sequential {@code IntStream} for the range of {@code int} * elements */ public static IntStream range(int startInclusive, int endExclusive) { if (startInclusive >= endExclusive) { return empty(); } else { return StreamSupport.intStream( new Streams.RangeIntSpliterator(startInclusive, endExclusive, false), false); } } /** * Returns a sequential {@code IntStream} from {@code startInclusive} * (inclusive) to {@code endInclusive} (inclusive) by an incremental step of * {@code 1}. * * @apiNote *

An equivalent sequence of increasing values can be produced * sequentially using a {@code for} loop as follows: *

{@code
     *     for (int i = startInclusive; i <= endInclusive ; i++) { ... }
     * }
* * @param startInclusive the (inclusive) initial value * @param endInclusive the inclusive upper bound * @return a sequential {@code IntStream} for the range of {@code int} * elements */ public static IntStream rangeClosed(int startInclusive, int endInclusive) { if (startInclusive > endInclusive) { return empty(); } else { return StreamSupport.intStream( new Streams.RangeIntSpliterator(startInclusive, endInclusive, true), false); } } /** * Creates a lazy concatenated {@code IntStream} whose elements are all the * elements of a first {@code IntStream} succeeded by all the elements of the * second {@code IntStream}. The resulting stream is ordered if both * of the input streams are ordered, and parallel if either of the input * streams is parallel. * * @param a the first stream * @param b the second stream to concatenate on to end of the first stream * @return the concatenation of the two streams */ public static IntStream concat(IntStream a, IntStream b) { Objects.requireNonNull(a); Objects.requireNonNull(b); Spliterator.OfInt split = new Streams.ConcatSpliterator.OfInt( a.spliterator(), b.spliterator()); return StreamSupport.intStream(split, a.isParallel() || b.isParallel()); } /** * A mutable builder for an {@code IntStream}. * *

A stream builder has a lifecycle, where it 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 stream whose elements are the elements that were added to the * stream builder, in the order they were added. * * @see IntStream#builder() * @since 1.8 */ public interface Builder extends IntConsumer { /** * Adds an element to the stream being built. * * @throws IllegalStateException if the builder has already transitioned * to the built state */ @Override void accept(int t); /** * Adds an element to the stream being built. * * @implSpec * The default implementation behaves as if: *

{@code
         *     accept(t)
         *     return this;
         * }
* * @param t the element to add * @return {@code this} builder * @throws IllegalStateException if the builder has already transitioned * to the built state */ default Builder add(int 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 */ IntStream build(); } }