132

In many other languages, eg. Haskell, it is easy to repeat a value or function multiple times, eg. to get a list of 8 copies of the value 1:

take 8 (repeat 1)

but I haven't found this yet in Java 8. Is there such a function in Java 8's JDK?

Or alternatively something equivalent to a range like

[1..8]

It would seem an obvious replacement for a verbose statement in Java like

for (int i = 1; i <= 8; i++) {
    System.out.println(i);
}

to have something like

Range.from(1, 8).forEach(i -> System.out.println(i))

though this particular example doesn't look much more concise actually... but hopefully it's more readable.

7
  • 2
    Have you studied the Streams API? That should be your best bet as far as the JDK is concerned. It's got a range function, that's what I have found so far. Aug 30 '13 at 12:06
  • 1
    @MarkoTopolnik The Streams class has been removed (more precisely it has been split among several other classes and some methods have been completely removed).
    – assylias
    Aug 30 '13 at 12:09
  • 4
    You call a for loop verbose! It's a good thing you weren't around in the Cobol days. It took over 10 declarative statements in Cobol to display ascending numbers. Young people these days don't appreciate how good they have it. Aug 30 '13 at 12:59
  • 1
    @GilbertLeBlanc verbosity has nothing to do with it. Loops are not composable, Streams are. Loops lead to unavoidable repetition, while Streams permit reuse. As such Streams are a quantitatively better abstraction than loops and should be preferred. Nov 11 '15 at 21:40
  • 2
    @GilbertLeBlanc and we had to code in bare feet, in the snow. Dec 15 '16 at 21:24
169

For this specific example, you could do:

IntStream.rangeClosed(1, 8)
         .forEach(System.out::println);

If you need a step different from 1, you can use a mapping function, for example, for a step of 2:

IntStream.rangeClosed(1, 8)
         .map(i -> 2 * i - 1)
         .forEach(System.out::println);

Or build a custom iteration and limit the size of the iteration:

IntStream.iterate(1, i -> i + 2)
         .limit(8)
         .forEach(System.out::println);
16
  • 4
    Closures will completely transform Java code, for the better. Looking forward to that day... Aug 30 '13 at 12:11
  • 1
    @jwenting It really depends - typically with GUI stuff (Swing or JavaFX), that removes a lot of boiler plate due to anonymous classes.
    – assylias
    Aug 30 '13 at 12:12
  • 8
    @jwenting To anyone with experience in FP, code which revolves around higher-order functions is a pure win. To anyone without that experience, it's time to upgrade your skills---or risk being left behind in the dust. Aug 30 '13 at 12:14
  • 2
    @MarkoTopolnik You might want to use a slightly newer version of the javadoc (you are pointing to build 78, latest is build 105: download.java.net/lambda/b105/docs/api/java/util/stream/… ) Aug 30 '13 at 12:22
  • 1
    @GraemeMoss You could still use the same pattern (IntStream.rangeClosed(1, 8).forEach(i -> methodNoArgs());) but it confuses thing IMO and in that case a loop seems indicated.
    – assylias
    Aug 30 '13 at 22:36
70

Here's another technique I ran across the other day:

Collections.nCopies(8, 1)
           .stream()
           .forEach(i -> System.out.println(i));

The Collections.nCopies call creates a List containing n copies of whatever value you provide. In this case it's the boxed Integer value 1. Of course it doesn't actually create a list with n elements; it creates a "virtualized" list that contains only the value and the length, and any call to get within range just returns the value. The nCopies method has been around since the Collections Framework was introduced way back in JDK 1.2. Of course, the ability to create a stream from its result was added in Java SE 8.

Big deal, another way to do the same thing in about the same number of lines.

However, this technique is faster than the IntStream.generate and IntStream.iterate approaches, and surprisingly, it's also faster than the IntStream.range approach.

For iterate and generate the result is perhaps not too surprising. The streams framework (really, the Spliterators for these streams) is built on the assumption that the lambdas will potentially generate different values each time, and that they will generate an unbounded number of results. This makes parallel splitting particularly difficult. The iterate method is also problematic for this case because each call requires the result of the previous one. So the streams using generate and iterate don't do very well for generating repeated constants.

The relatively poor performance of range is surprising. This too is virtualized, so the elements don't actually all exist in memory, and the size is known up front. This should make for a fast and easily parallelizable spliterator. But it surprisingly didn't do very well. Perhaps the reason is that range has to compute a value for each element of the range and then call a function on it. But this function just ignores its input and returns a constant, so I'm surprised this isn't inlined and killed.

The Collections.nCopies technique has to do boxing/unboxing in order to handle the values, since there are no primitive specializations of List. Since the value is the same every time, it's basically boxed once and that box is shared by all n copies. I suspect boxing/unboxing is highly optimized, even intrinsified, and it can be inlined well.

Here's the code:

    public static final int LIMIT = 500_000_000;
    public static final long VALUE = 3L;

    public long range() {
        return
            LongStream.range(0, LIMIT)
                .parallel()
                .map(i -> VALUE)
                .map(i -> i % 73 % 13)
                .sum();
}

    public long ncopies() {
        return
            Collections.nCopies(LIMIT, VALUE)
                .parallelStream()
                .mapToLong(i -> i)
                .map(i -> i % 73 % 13)
                .sum();
}

And here are the JMH results: (2.8GHz Core2Duo)

Benchmark                    Mode   Samples         Mean   Mean error    Units
c.s.q.SO18532488.ncopies    thrpt         5        7.547        2.904    ops/s
c.s.q.SO18532488.range      thrpt         5        0.317        0.064    ops/s

There is a fair amount of variance in the ncopies version, but overall it seems comfortably 20x faster than the range version. (I'd be quite willing to believe that I've done something wrong, though.)

I'm surprised at how well the nCopies technique works. Internally it doesn't do very much special, with the stream of the virtualized list simply being implemented using IntStream.range! I had expected that it would be necessary to create a specialized spliterator to get this to go fast, but it already seems to be pretty good.

8
  • 6
    Less seasoned developers might be confused or get into trouble when they learn that nCopies doesn't actually copy anything and the "copies" all point to that one single object. It's always safe if that object is immutable, such as a boxed primitive in this example. You allude to this in your "boxed once" statement, but it might be nice to explicitly call out the caveats here because that behavior is not specific to auto-boxing. Mar 4 '15 at 0:04
  • 1
    So that implies that LongStream.range is significantly slower than IntStream.range? So it’s a good thing that the idea of not offering an IntStream (but use LongStream for all integer types) has been dropped. Note that for the sequential use case, there isn’t a reason to use stream at all: Collections.nCopies(8, 1).forEach(i -> System.out.println(i)); does the same as Collections.nCopies(8, 1).stream().forEach(i -> System.out.println(i)); but even more efficient might be Collections.<Runnable>nCopies(8, () -> System.out.println(1)).forEach(Runnable::run);
    – Holger
    Jun 11 '15 at 14:44
  • 1
    @Holger, these tests were performed on clean type profile, so they are unrelated to real world. Probably LongStream.range performs worse, because it has two maps with LongFunction inside, while ncopies has three maps with IntFunction, ToLongFunction and LongFunction, thus all lambdas are monomorphic. Running this test on pre-polluted type profile (which is closer to the real-world case) shows that ncopies is 1.5x slower. Jul 16 '15 at 11:44
  • 1
    Premature Optimization FTW Apr 10 '16 at 21:53
  • 2
    For the sake of completeness, it would be nice to see a benchmark that compares both of these techniques with a plain old for loop. While your solution is faster than the Stream code, my guess is that a for loop would beat either of these by a significant margin.
    – typeracer
    Nov 1 '19 at 4:52
38

For completeness, and also because I couldn't help myself :)

Generating a limited sequence of constants is fairly close to what you would see in Haskell, only with Java level verboseness.

IntStream.generate(() -> 1)
         .limit(8)
         .forEach(System.out::println);
3
  • () -> 1 would only generate 1's, is this intended? So the output would be 1 1 1 1 1 1 1 1. Jan 13 '14 at 3:56
  • 4
    Yes, per the OP's first Haskell example take 8 (repeat 1). assylias pretty much covered all the other cases.
    – clstrfsck
    Jan 13 '14 at 12:20
  • 3
    Stream<T> also has a generic generate method for getting an infinite stream of some other type, which can be limited the same way.
    – zstewart
    Oct 16 '17 at 21:54
13

Once a repeat function is somewhere defined as

public static BiConsumer<Integer, Runnable> repeat = (n, f) -> {
    for (int i = 1; i <= n; i++)
        f.run();
};

You can use it now and then this way, e.g.:

repeat.accept(8, () -> System.out.println("Yes"));

To get and equivalent to Haskell's

take 8 (repeat 1)

You could write

StringBuilder s = new StringBuilder();
repeat.accept(8, () -> s.append("1"));
1
  • 2
    This one is awesome. However I modified it to provide the number of the iteration back, by changing the Runnable to Function<Integer, ?> and then using f.apply(i).
    – Fons
    Jul 6 '17 at 10:12
0

This is my solution to implementing the times function. I'm a junior so I admit it could be not ideal, I'd be glad to hear if this is not a good idea for whatever reason.

public static <T extends Object, R extends Void> R times(int count, Function<T, R> f, T t) {
    while (count > 0) {
        f.apply(t);
        count--;
    }
    return null;
}

Here's some example usage:

Function<String, Void> greet = greeting -> {
    System.out.println(greeting);
    return null;
};

times(3, greet, "Hello World!");

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