63

Sometimes I want to perform a set of operations on a stream, and then process the resulting stream two different ways with other operations.

Can I do this without having to specify the common initial operations twice?

For example, I am hoping a dup() method such as the following exists:

Stream [] desired_streams = IntStream.range(1, 100).filter(n -> n % 2 == 0).dup();
Stream stream14 = desired_streams[0].filter(n -> n % 7 == 0); // multiples of 14
Stream stream10 = desired_streams[1].filter(n -> n % 5 == 0); // multiples of 10
8
  • 2
    I do realize that there will be no performance gain because streams are evaluated lazily; I am just hoping to avoid duplicating code. – necromancer Jun 29 '14 at 9:39
  • Why not turn the streams into lists? – Elazar Jun 29 '14 at 9:39
  • 1
    Locate what varies in your code and extract this into variables. Then create a method to extract reusable piece of code and apply variables to it. – JMelnik Jun 29 '14 at 9:42
  • @Elazar doing so would not be memory efficient, and would not work for infinite streams! – necromancer Jun 29 '14 at 9:43
  • 2
    Nothing can duplicate general infinite streams, without further information. – Elazar Jun 29 '14 at 19:07
35

It is not possible in general.

If you want to duplicate an input stream, or input iterator, you have two options:

A. Keep everything in a collection, say a List<>

Suppose you duplicate a stream into two streams s1 and s2. If you have advanced n1 elements in s1 and n2 elements with s2, you must keep |n2 - n1| elements in memory, just to keep pace. If your stream is infinite, there may be no upper bound for the storage required.

Take a look at Python's tee() to see what it takes:

This itertool may require significant auxiliary storage (depending on how much temporary data needs to be stored). In general, if one iterator uses most or all of the data before another iterator starts, it is faster to use list() instead of tee().

B. When possible: Copy the state of the generator that creates the elements

For this option to work, you'll probably need access to the inner workings of the stream. In other words, the generator - the part that creates the elements - should support copying in the first place. [OP: See this great answer, as an example of how this can be done for the example in the question]

It will not work on input from the user, since you'll have to copy the state of the entire "outside world". Java's Stream do not support copying, since it is designed to be as general as possible; for example, to work with files, network, keyboard, sensors, randomness etc. [OP: Another example is a stream that reads a temperature sensor on demand. It cannot be duplicated without storing a copy of the readings]

This is not only the case in Java; this is a general rule. You can see that std::istream in C++ only supports move semantics, not copy semantics ("copy constructor (deleted)"), for this reason (and others).

4
  • +1 awesome answer; will likely accept and link to the currently accepted answer as a specific example of point "B." – necromancer Jun 30 '14 at 2:07
  • 2
    a blocking queue would be one solution that allows bounded storage problem where a reader to the first stream would be blocked until the second stream is consumed. naturally, not always applicable but might work for some use cases esp. with a large buffer. – necromancer Jun 30 '14 at 2:10
  • Note that you might be able to compress the n2 - n1 elements, although I don't believe it to be practical too often. – Elazar Sep 7 '17 at 13:56
  • When I have encountered this type of problem (not so often as I am relatively new to java.streams!) my initial instinct was to go for Option A. However I always felt uneasy about this, it seems like we are moving out of the streams world, then back in again ... just for the sake of duplication. I think I'm much in favour of option B. I'm using it in my project and it looks to be working as desired. On the face of it maybe processing has to be duplicated, I guess this is more a question for the authors of the Streams API?? – Bill Naylor Jul 13 '20 at 17:50
52

It is not possible to duplicate a stream in this way. However, you can avoid the code duplication by moving the common part into a method or lambda expression.

Supplier<IntStream> supplier = () ->
    IntStream.range(1, 100).filter(n -> n % 2 == 0);
supplier.get().filter(...);
supplier.get().filter(...);
2
  • 2
    i am considering switching the accepted answer to the one by Elazar and linking to yours as a great example of the second solution and to the solution of the specific example I used in my question. hope that's ok. thanks! – necromancer Jun 30 '14 at 2:12
  • 10
    @necromancer: Thanks for asking. Feel free to change the accepted answer. – nosid Jun 30 '14 at 6:57
8

It's possible if you're buffering elements that you've consumed in one duplicate, but not in the other yet.

We've implemented a duplicate() method for streams in jOOλ, an Open Source library that we created to improve integration testing for jOOQ. Essentially, you can just write:

Tuple2<Seq<Integer>, Seq<Integer>> desired_streams = Seq.seq(
    IntStream.range(1, 100).filter(n -> n % 2 == 0).boxed()
).duplicate();

(note: we currently need to box the stream, as we haven't implemented an IntSeq yet)

Internally, there is a LinkedList buffer storing all values that have been consumed from one stream but not from the other. That's probably as efficient as it gets if your two streams are consumed about at the same rate.

Here's how the algorithm works:

static <T> Tuple2<Seq<T>, Seq<T>> duplicate(Stream<T> stream) {
    final LinkedList<T> gap = new LinkedList<>();
    final Iterator<T> it = stream.iterator();

    @SuppressWarnings("unchecked")
    final Iterator<T>[] ahead = new Iterator[] { null };

    class Duplicate implements Iterator<T> {
        @Override
        public boolean hasNext() {
            if (ahead[0] == null || ahead[0] == this)
                return it.hasNext();

            return !gap.isEmpty();
        }

        @Override
        public T next() {
            if (ahead[0] == null)
                ahead[0] = this;

            if (ahead[0] == this) {
                T value = it.next();
                gap.offer(value);
                return value;
            }

            return gap.poll();
        }
    }

    return tuple(seq(new Duplicate()), seq(new Duplicate()));
}

More source code here

In fact, using jOOλ, you'll be able to write a complete one-liner like so:

Tuple2<Seq<Integer>, Seq<Integer>> desired_streams = Seq.seq(
    IntStream.range(1, 100).filter(n -> n % 2 == 0).boxed()
).duplicate()
 .map1(s -> s.filter(n -> n % 7 == 0))
 .map2(s -> s.filter(n -> n % 5 == 0));

// This will yield 14, 28, 42, 56...
desired_streams.v1.forEach(System.out::println)

// This will yield 10, 20, 30, 40...
desired_streams.v2.forEach(System.out::println);
1
  • 1
    Thanks but the currently accepted answer does state: "If you have advanced n1 elements in s1 and n2 elements with s2, you have to keep |n2 - n1| elements in memory, just to keep pace. If your stream is infinite, there will be no upper bound for the storage required." – necromancer Sep 23 '14 at 10:55
4

You can also move the stream generation into separate method/function that returns this stream and call it twice.

0
3

Either,

  • Move the initialisation into a method, and simply call the method again

This has the advantage of being explicit about what you are doing, and also works for infinite streams.

  • Collect the stream and then re-stream it

In your example:

final int[] arr = IntStream.range(1, 100).filter(n -> n % 2 == 0).toArray();

Then

final IntStream s = IntStream.of(arr);
2
  • Thanks, I realized there is a simpler answer (see my own answer); Collecting the stream is not quite memory efficient and simply wouldn't work for infinite streams. – necromancer Jun 29 '14 at 9:45
  • You answer doesn't involve processing the streams. From your question I understood that you wanted to take a single stream and say, collect it to a Map and also sum() it. You are just taking about setting up pipelines. – Boris the Spider Jun 29 '14 at 9:47
2

Update: This doesn't work. See explanation below, after the text of the original answer.

How silly of me. All that I need to do is:

Stream desired_stream = IntStream.range(1, 100).filter(n -> n % 2 == 0);
Stream stream14 = desired_stream.filter(n -> n % 7 == 0); // multiples of 14
Stream stream10 = desired_stream.filter(n -> n % 5 == 0); // multiples of 10

Explanation why this does not work:

If you code it up and try to collect both streams, the first one will collect fine, but trying to stream the second one will throw the exception: java.lang.IllegalStateException: stream has already been operated upon or closed.

To elaborate, streams are stateful objects (which by the way cannot be reset or rewound). You can think of them as iterators, which in turn are like pointers. So stream14 and stream10 can be thought of as references to the same pointer. Consuming the first stream all the way will cause the pointer to go "past the end." Trying to consume the second stream is like trying to access a pointer that is already "past the end," Which naturally is an illegal operation.

As the accepted answer shows, the code to create the stream must be executed twice but it can be compartmentalized into a Supplier lambda or a similar construct.

Full test code: save into Foo.java, then javac Foo.java, then java Foo

import java.util.stream.IntStream;

public class Foo {
  public static void main (String [] args) {
    IntStream s = IntStream.range(0, 100).filter(n -> n % 2 == 0);
    IntStream s1 = s.filter(n -> n % 5 == 0);
    s1.forEach(n -> System.out.println(n));
    IntStream s2 = s.filter(n -> n % 7 == 0);
    s2.forEach(n -> System.out.println(n));
  }
}

Output:

$ javac Foo.java
$ java Foo
0
10
20
30
40
50
60
70
80
90
Exception in thread "main" java.lang.IllegalStateException: stream has already been operated upon or closed
    at java.util.stream.AbstractPipeline.<init>(AbstractPipeline.java:203)
    at java.util.stream.IntPipeline.<init>(IntPipeline.java:91)
    at java.util.stream.IntPipeline$StatelessOp.<init>(IntPipeline.java:592)
    at java.util.stream.IntPipeline$9.<init>(IntPipeline.java:332)
    at java.util.stream.IntPipeline.filter(IntPipeline.java:331)
    at Foo.main(Foo.java:8)
3
  • Immutable state, well, here you go. ;D – JMelnik Jun 29 '14 at 9:44
  • 1
    instead of deleting you could add some explanation why this approach didn't work. So that others could learn from it. – mschenk74 Jun 29 '14 at 10:29
  • @mschenk74 here you go :) – necromancer Jun 29 '14 at 10:44
0

For non-infinite streams, if you have access to the source, its straight forward:

@Test
public void testName() throws Exception {
    List<Integer> integers = Arrays.asList(1, 2, 4, 5, 6, 7, 8, 9, 10);
    Stream<Integer> stream1 = integers.stream();
    Stream<Integer> stream2 = integers.stream();

    stream1.forEach(System.out::println);
    stream2.forEach(System.out::println);
}

prints

1 2 4 5 6 7 8 9 10

1 2 4 5 6 7 8 9 10

For your case:

Stream originalStream = IntStream.range(1, 100).filter(n -> n % 2 == 0)

List<Integer> listOf = originalStream.collect(Collectors.toList())

Stream stream14 = listOf.stream().filter(n -> n % 7 == 0);
Stream stream10 = listOf.stream().filter(n -> n % 5 == 0);

For performance etc, read someone else's answer ;)

1
  • Thanks, but the spirit of the question was to tee a stream for which the source is inaccessible, or indeterminate such as stdin. It is adequately clear to me now that the cost of such teeing stems primarily from differences in the rate of effective consumption. e. g. if one consumer runs far ahead of the other, the difference needs to be buffered separately and additionally. – necromancer Dec 7 '18 at 5:33
0

I used this great answer to write following class:

public class SplitStream<T> implements Stream<T> {
    private final Supplier<Stream<T>> streamSupplier;

    public SplitStream(Supplier<Stream<T>> t) {
        this.streamSupplier = t;
    }

    @Override
    public Stream<T> filter(Predicate<? super T> predicate) {
        return streamSupplier.get().filter(predicate);
    }

    @Override
    public <R> Stream<R> map(Function<? super T, ? extends R> mapper) {
        return streamSupplier.get().map(mapper);
    }

    @Override
    public IntStream mapToInt(ToIntFunction<? super T> mapper) {
        return streamSupplier.get().mapToInt(mapper);
    }

    @Override
    public LongStream mapToLong(ToLongFunction<? super T> mapper) {
        return streamSupplier.get().mapToLong(mapper);
    }

    @Override
    public DoubleStream mapToDouble(ToDoubleFunction<? super T> mapper) {
        return streamSupplier.get().mapToDouble(mapper);
    }

    @Override
    public <R> Stream<R> flatMap(Function<? super T, ? extends Stream<? extends R>> mapper) {
        return streamSupplier.get().flatMap(mapper);
    }

    @Override
    public IntStream flatMapToInt(Function<? super T, ? extends IntStream> mapper) {
        return streamSupplier.get().flatMapToInt(mapper);
    }

    @Override
    public LongStream flatMapToLong(Function<? super T, ? extends LongStream> mapper) {
        return streamSupplier.get().flatMapToLong(mapper);
    }

    @Override
    public DoubleStream flatMapToDouble(Function<? super T, ? extends DoubleStream> mapper) {
        return streamSupplier.get().flatMapToDouble(mapper);
    }

    @Override
    public Stream<T> distinct() {
        return streamSupplier.get().distinct();
    }

    @Override
    public Stream<T> sorted() {
        return streamSupplier.get().sorted();
    }

    @Override
    public Stream<T> sorted(Comparator<? super T> comparator) {
        return streamSupplier.get().sorted(comparator);
    }

    @Override
    public Stream<T> peek(Consumer<? super T> action) {
        return streamSupplier.get().peek(action);
    }

    @Override
    public Stream<T> limit(long maxSize) {
        return streamSupplier.get().limit(maxSize);
    }

    @Override
    public Stream<T> skip(long n) {
        return streamSupplier.get().skip(n);
    }

    @Override
    public void forEach(Consumer<? super T> action) {
        streamSupplier.get().forEach(action);
    }

    @Override
    public void forEachOrdered(Consumer<? super T> action) {
        streamSupplier.get().forEachOrdered(action);
    }

    @Override
    public Object[] toArray() {
        return streamSupplier.get().toArray();
    }

    @Override
    public <A> A[] toArray(IntFunction<A[]> generator) {
        return streamSupplier.get().toArray(generator);
    }

    @Override
    public T reduce(T identity, BinaryOperator<T> accumulator) {
        return streamSupplier.get().reduce(identity, accumulator);
    }

    @Override
    public Optional<T> reduce(BinaryOperator<T> accumulator) {
        return streamSupplier.get().reduce(accumulator);
    }

    @Override
    public <U> U reduce(U identity, BiFunction<U, ? super T, U> accumulator, BinaryOperator<U> combiner) {
        return streamSupplier.get().reduce(identity, accumulator, combiner);
    }

    @Override
    public <R> R collect(Supplier<R> supplier, BiConsumer<R, ? super T> accumulator, BiConsumer<R, R> combiner) {
        return streamSupplier.get().collect(supplier, accumulator, combiner);
    }

    @Override
    public <R, A> R collect(Collector<? super T, A, R> collector) {
        return streamSupplier.get().collect(collector);
    }

    @Override
    public Optional<T> min(Comparator<? super T> comparator) {
        return streamSupplier.get().min(comparator);
    }

    @Override
    public Optional<T> max(Comparator<? super T> comparator) {
        return streamSupplier.get().max(comparator);
    }

    @Override
    public long count() {
        return streamSupplier.get().count();
    }

    @Override
    public boolean anyMatch(Predicate<? super T> predicate) {
        return streamSupplier.get().anyMatch(predicate);
    }

    @Override
    public boolean allMatch(Predicate<? super T> predicate) {
        return streamSupplier.get().allMatch(predicate);
    }

    @Override
    public boolean noneMatch(Predicate<? super T> predicate) {
        return streamSupplier.get().noneMatch(predicate);
    }

    @Override
    public Optional<T> findFirst() {
        return streamSupplier.get().findFirst();
    }

    @Override
    public Optional<T> findAny() {
        return streamSupplier.get().findAny();
    }

    @Override
    public Iterator<T> iterator() {
        return streamSupplier.get().iterator();
    }

    @Override
    public Spliterator<T> spliterator() {
        return streamSupplier.get().spliterator();
    }

    @Override
    public boolean isParallel() {
        return streamSupplier.get().isParallel();
    }

    @Override
    public Stream<T> sequential() {
        return streamSupplier.get().sequential();
    }

    @Override
    public Stream<T> parallel() {
        return streamSupplier.get().parallel();
    }

    @Override
    public Stream<T> unordered() {
        return streamSupplier.get().unordered();
    }

    @Override
    public Stream<T> onClose(Runnable closeHandler) {
        return streamSupplier.get().onClose(closeHandler);
    }

    @Override
    public void close() {
        streamSupplier.get().close();
    }
}

When you call any method of it's class, it delegates call to

streamSupplier.get()

So, instead of:

Supplier<IntStream> supplier = () ->
    IntStream.range(1, 100).filter(n -> n % 2 == 0);
supplier.get().filter(...);
supplier.get().filter(...);

You can do:

SplitStream<Integer> stream = 
    new SplitStream<>(() -> IntStream.range(1, 100).filter(n -> n % 2 == 0).boxed());
stream.filter(...);
stream.filter(...);

You can expand it to work with IntStream, DoubleStream, etc...

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