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Which of the following is better practice in Java 8?

Java8:

joins.forEach((join) -> mIrc.join(mSession, join));

Java7:

for (String join : joins) {
    mIrc.join(mSession, join);
}

I have lots of for loops that could be "simplified" with lambdas, but is there really any advantage of using them including performance and readability?

EDIT

I'll also extend this question to longer methods - I know that you cant return or break the parent function from a lambda and this should be mentioned to if they are compared, but is there anything else to be considered?

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I believe lamdas are intended to improve use of multi-core processors. If your target environment is multi-core, I believe lamdas will have improved performance over the java 7 for loop. –  DwB May 19 '13 at 14:04
4  
There is no real performance advantage of one over another. First option is something inspired by FP (whitch is commonly talked about like more "nice" and "clear" way to express your code). In reality - this is rather "style" question. –  Eugeny Loy May 19 '13 at 14:04
2  
@Dwb: in this case, that is not relevant. forEach is not defined as being parallel or anything like that, so these two things are semantically equivalent. Of course it is possible to implement a parallel version of forEach (and one might already be present in the standard library), and in such a case lambda expression syntax would be very useful. –  AardvarkSoup May 19 '13 at 14:05
1  
@AardvarkSoup The instance on which forEach is called is a Stream (lambdadoc.net/api/java/util/stream/Stream.html). To request a parallel execution one could write joins.parallel().forEach(...) –  mschenk74 May 19 '13 at 15:20
1  
Is joins.forEach((join) -> mIrc.join(mSession, join)); really a "simplification" of for (String join : joins) { mIrc.join(mSession, join); }? You've increased the punctuation count from 9 to 12, for the benefit of hiding the type of join. What you've really done is to put two statements onto one line. –  Tom Hawtin - tackline Jul 26 '13 at 16:55

6 Answers 6

up vote 20 down vote accepted

The advantage comes into account when the operations can be executed in parallel. (See http://java.dzone.com/articles/devoxx-2012-java-8-lambda-and - the section about internal and external iteration)

UPDATE: The main advantage from my point of view is that the implementation of what is to be done within the loop can be defined without having to decide if it will be executed in parallel or sequential.

UPDATE2: If you want your loop to be executed in parallel you could simply write

joins.parallelStream().forEach((join) -> mIrc.join(mSession, join));

in the first case. In the second case you will have to write some extra code for thread handling etc.

UPDATE3: for my answer I assumed joins implementing the java.util.Stream interface. If joins implements only the java.util.Iterable interface this is no longer true.

UPDATE4: now in the released version of Java 8, the method parallel() was renamed to parallelStream()

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1  
The slides of an oracle engineer he is referencing to (blogs.oracle.com/darcy/resource/Devoxx/…) don't mention the parallelism within those lambda expressions. The parallelism may occur within the bulk collection methods like map & fold that aren't really related to lambdas. –  Thomas Jungblut May 19 '13 at 14:12
    
It doesn't really seem that OP's code will benefit from automatic parallelism here (especially since there is no guarantee that there will be one). We don't really know what is "mIrc", but "join" doesn't really seem like something that can be exexuted out-of order. –  Eugeny Loy May 19 '13 at 14:18
    
@ThomasJungblut In the API (lambdadoc.net/api/java/util/stream/…) there is some documentation about parallel and forEach. –  mschenk74 May 19 '13 at 14:21
    
@leo I interpreted mIrc and join as an IRC client joining some channels within a chat session. But that might be also complete nonsense since the questions doesn't define it. –  mschenk74 May 19 '13 at 15:32
    
@mschenk74 That is correct, but it is only one of many one-line for loops in my code. I don't need parallel execution in my case but +1 for a valid reason why lambda is better than for loop. –  nebkat May 19 '13 at 15:55

The better practice is to use for-each. Besides violating the Keep It Simple, Stupid principle, the new-fangled forEach() has at least the following deficiencies:

  • Can't use non-final variables. So, code like the following can't be turned into a forEach lambda:

    Object prev = null;
    for(Object curr : list)
    {
        if( prev != null )
            foo(prev, curr);
        prev = curr;
    }
    
  • Can't handle checked exceptions. Lambdas aren't actually forbidden from throwing checked exceptions, but common functional interfaces like Consumer don't declare any. Therefore, any code that throws checked exceptions must wrap them in try-catch or Throwables.propagate(). But even if you do that, it's not always clear what happens to the thrown exception. It could get swallowed somewhere in the guts of forEach()

  • Limited flow-control. A return in a lambda equals a continue in a for-each, but there is no equivalent to a break. It's also difficult to do things like return values, short circuit, or set flags (which would have alieviated things a bit, if it wasn't a violation of the no non-final variables rule). "This is not just an optimization, but critical when you consider that some sequences (like reading the lines in a file) may have side-effects, or you may have an infinite sequence."

  • Might execute in parallel, which is a horrible, horrible thing for all but the 0.1% of your code that needs to be optimized. Any parallel code has to be thought through (even if it doesn't use locks, volatiles, and other particularly nasty aspects of traditional multi-threaded execution). Any bug will be tough to find.

  • Might hurt performance, because the JIT can't optimize forEach()+lambda to the same extent as plain loops, especially now that lambdas are new. By "optimization" I do not mean the overhead of calling lambdas (which is small), but to the sophisticated analysis that the modern JIT compiler performs on running code.

  • If you do need parallelism, it is probably much faster and not much more difficult to use an ExecutorService. Streams are both automagical (read: don't know much about your problem) and use a specialized (read: inefficient for the general case) parallelization strategy (fork-join recursive decomposition).

  • Makes debugging more confusing, because of the nested call heirarchy, and, god forbid, parallel execution.

  • Sticks out like a sore thumb. The Java language already has the for-each statetement. Why replace it with a function call? Why encourage hiding side-effects somewhere in expressions? Why encourage unwieldy one-liners? Mixing regular for-each and new forEach willy-nilly is bad style. Code should speak in idioms (patterns that are quick to comprehend due to their repetition), and the fewer idioms are used the clearer the code is and less time is spent deciding which idiom to use (a big time-drain for perfectionists like myself!).

As you can see, I'm not a big fan of the forEach() except in cases when it makes sense.

Particularly offensive to me is the fact that Stream does not implement Iterable and cannot be used in a for-each, only with a forEach(). It is not fathomable to me why this is so. (Certainly C#'s designers didn't think it was necessary.) I recommend forcing Streams into Iterables using stream.collect(Collectors.toList()) or stream.toArray( T[]::new ) and using them with a for-each Edit: It's also possible to force a stream into an Iterable with for(T element : (Iterable<T>)stream::iterator) (as bewildering as that might look).

That said, forEach() is useful for the following:

  • Atomically iterating over a synchronized list. Prior to this, a list generated with Collections.synchronizedList() was atomic with respect to things like get or set, but was not thread-safe when iterating.

  • Parallel execution (using an appropriate parallel stream). This saves you a few lines of code vs using an ExecutorService, if your problem matches the performance assumptions built into Streams and Spliterators.

  • Specific containers which, like the synchronized list, benefit from being in control of iteration (although this is largely theoretical unless people can bring up more examples)

Articles I used for reference:

EDIT: Looks like some of the original proposals for lambdas (such as http://www.javac.info/closures-v06a.html) solve a lot of the issues I mention. What woe it is that we've been given the crap we have now.

share|improve this answer
14  
“Why encourage hiding side-effects somewhere in expressions?” is the wrong question. The functional forEach is there to encourage the functional style, i.e. using expressions without side-effects. If you encounter the situation the the forEach does not work well with your side-effects you should get the feeling that your are not using the right tool for the job. Then the simple answer is, that’s because your feeling is right, so stay at the for-each loop for that. The classical for loop did not become deprecated… –  Holger Dec 3 '13 at 18:55
2  
@Holger How can forEach be used without side-effects? –  Aleksandr Dubinsky Dec 3 '13 at 20:56
3  
All right, I wasn’t precise enough, forEach is the only stream operation intended for side-effects, but it’s not for side-effects like your example code, counting is a typical reduce operation. I would suggest, as a rule of thump, to keep every operation which manipulates local variables or shall influence the control flow (incl exception handling) in a classical for loop. Regarding the original question I think, the problem stems from the fact that someone uses a stream where a simple for loop over the source of the stream would be sufficient. Use a stream where forEach() works only –  Holger Dec 4 '13 at 13:54
3  
@Holger What is an example of side-effects that forEach would be appropriate for? –  Aleksandr Dubinsky Dec 4 '13 at 15:03
7  
Something which processes each item individually and doesn’t try to mutate local variables. E.g. manipulating the items itself or printing them, writing/sending them to a file, network stream, etc. It’s no problem for me if you question these examples and don’t see any application for it; filtering, mapping, reducing, searching, and (to a lesser degree) collecting are the preferred operations of a stream. The forEach looks like a convenience to me for linking with existing APIs. And for parallel operations, of course. These won’t work with for loops. –  Holger Dec 4 '13 at 17:21

When reading this question and some of the answers, one can get the impression, that Iterable#forEach in combination with lambda expressions is a shortcut/replacement for writing a traditional for-each loop. This is simply not true. This code from the OP:

joins.forEach(join -> mIrc.join(mSession, join));

is not intended as a shortcut for writing

for (String join : joins) {
    mIrc.join(mSession, join);
}

and should certainly not be used in this way. Instead it is intended as a shortcut (although it is not exactly the same) for writing

joins.forEach(new Consumer<T>() {
    @Override
    public void accept(T join) {
        mIrc.join(mSession, join);
    }
});

And it is as a replacement for the following Java 7 code:

final Consumer<T> c = new Consumer<T>() {
    @Override
    public void accept(T join) {
        mIrc.join(mSession, join);
    }
};
for (T t : joins) {
    c.accept(t);
}

Replacing the body of a loop with a functional interface, as in the examples above, makes your code more explicit: You are saying that (1) the body of the loop does not affect the surrounding code and control flow, and (2) the body of the loop may be replaced with a different implementation of the function, without affecting the surrounding code. Not being able to access non final variables of the outer scope is not a deficit of functions/lambdas, it is a feature that distinguishes the semantics of Iterable#forEach from the semantics of a traditional for-each loop. Once one gets used to the syntax of Iterable#forEach, it makes the code more readable, because you immediately get this additional information about the code.

Traditional for-each loops will certainly stay good practice (to avoid the overused term "best practice") in Java. But this doesn't mean, that Iterable#forEach should be considered bad practice or bad style. It is always good practice, to use the right tool for doing the job, and this includes mixing traditional for-each loops with Iterable#forEach, where it makes sense.

Since the alleged downsides of Iterable#forEach have already been discussed in this thread, here are some reasons, why you might probably want to use Iterable#forEach:

  • To make your code more explicit: As described above, Iterable#forEach can make your code more explicit and readable in some situations.

  • To make your code more extensible and maintainable: Using a function as the body of a loop allows you to replace this function with different implementations (see Strategy Pattern). You could e.g. easily replace the lambda expression with a method call, that may be overwritten by sub-classes:

    joins.forEach(getJoinStrategy());
    

    Then you could provide default strategies using an enum, that implements the functional interface. This not only makes your code more extensible, it also increases maintainability because it decouples the loop implementation from the loop declaration.

  • To make your code more debuggable: Seperating the loop implementation from the declaration can also make debugging more easy, because you could have a specialized debug implementation, that prints out debug messages, without the need to clutter your main code with if(DEBUG)System.out.println(). The debug implementation could e.g. be a delegate, that decorates the actual function implementation.

  • To optimize performance-critical code: Contrary to some of the assertions in this thread, Iterable#forEach does already provide better performance than a traditional for-each loop, at least when using ArrayList and running Hotspot in "-client" mode. While this performance boost is small and negligible for most use cases, there are situations, where this extra performance can make a difference. E.g. library maintainers will certainly want to evaluate, if some of their existing loop implementations should be replaced with Iterable#forEach.

    To back this statement up with facts, I have done some micro-benchmarks with Caliper. Here is the test code (latest Caliper from git is needed):

    @VmOptions("-server")
    public class Java8IterationBenchmarks {
    
        public static class TestObject {
            public int result;
        }
    
        public @Param({"100", "10000"}) int elementCount;
    
        ArrayList<TestObject> list;
        TestObject[] array;
    
        @BeforeExperiment
        public void setup(){
            list = new ArrayList<>(elementCount);
            for (int i = 0; i < elementCount; i++) {
                list.add(new TestObject());
            }
            array = list.toArray(new TestObject[list.size()]);
        }
    
        @Benchmark
        public void timeTraditionalForEach(int reps){
            for (int i = 0; i < reps; i++) {
                for (TestObject t : list) {
                    t.result++;
                }
            }
            return;
        }
    
        @Benchmark
        public void timeForEachAnonymousClass(int reps){
            for (int i = 0; i < reps; i++) {
                list.forEach(new Consumer<TestObject>() {
                    @Override
                    public void accept(TestObject t) {
                        t.result++;
                    }
                });
            }
            return;
        }
    
        @Benchmark
        public void timeForEachLambda(int reps){
            for (int i = 0; i < reps; i++) {
                list.forEach(t -> t.result++);
            }
            return;
        }
    
        @Benchmark
        public void timeForEachOverArray(int reps){
            for (int i = 0; i < reps; i++) {
                for (TestObject t : array) {
                    t.result++;
                }
            }
        }
    }
    

    And here are the results:

    When running with "-client", Iterable#forEach outperforms the traditional for loop over an ArrayList, but is still slower than directly iterating over an array. When running with "-server", the performance of all approaches is about the same.

  • To provide optional support for parallel execution: It has already been said here, that the possibility to execute the functional interface of Iterable#forEach in parallel using streams, is certainly an important aspect. Since Collection#parallelStream() does not guarantee, that the loop is actually executed in parallel, one must consider this an optional feature. By iterating over your list with list.parallelStream().forEach(...);, you explicitly say: This loop supports parallel execution, but it does not depend on it. Again, this is a feature and not a deficit!

    By moving the decision for parallel execution away from your actual loop implementation, you allow optional optimization of your code, without affecting the code itself, which is a good thing. Also, if the default parallel stream implementation does not fit your needs, no one is preventing you from providing your own implementation. You could e.g. provide an optimized collection depending on the underlying operating system, on the size of the collection, on the number of cores, and on some preference settings:

    public abstract class MyOptimizedCollection<E> implements Collection<E>{
        private enum OperatingSystem{
            LINUX, WINDOWS, ANDROID
        }
        private OperatingSystem operatingSystem = OperatingSystem.WINDOWS;
        private int numberOfCores = Runtime.getRuntime().availableProcessors();
        private Collection<E> delegate;
    
        @Override
        public Stream<E> parallelStream() {
            if (!System.getProperty("parallelSupport").equals("true")) {
                return this.delegate.stream();
            }
            switch (operatingSystem) {
                case WINDOWS:
                    if (numberOfCores > 3 && delegate.size() > 10000) {
                        return this.delegate.parallelStream();
                    }else{
                        return this.delegate.stream();
                    }
                case LINUX:
                    return SomeVerySpecialStreamImplementation.stream(this.delegate.spliterator());
                case ANDROID:
                default:
                    return this.delegate.stream();
            }
        }
    }
    

    The nice thing here is, that your loop implementation doesn't need to know or care about these details.

share|improve this answer
    
You have an interesting view in this discussion and bring up a number of points. I'll try to address them. You propose to switch between forEach and for-each based on some criteria regarding the nature of the loop body. Wisdom and discipline to follow such rules are the hallmark of a good programmer. Such rules are also his bane, because the people around him either don't follow them or disagree. Eg, using checked vs unchecked Exceptions. This situation seems even more nuanced. But, if the body "does not affect surround code or flow control," isn't factoring it out as a function better? –  Aleksandr Dubinsky Apr 22 at 22:43
    
To make code more extensible, you argue factoring out member functions (which can be called from a for-each) and using function objects (which can also be called from a for-each). I am not opposed to either of those techniques, and use function objects too. I am just not sure why they encourage the use of forEach() (which, again, won't let them use checked exceptions). Yes, the syntax is a bit shorter. What other reasons? –  Aleksandr Dubinsky Apr 22 at 22:46
    
Arguing performance is a can of worms. The optimizations that the JVM can do to a for-each go beyond the cost of a list access. The JVM can move redundant expression evaluations, allocate objects on the stack instead of the heap, etc, etc. This is where lambdas fall behind. –  Aleksandr Dubinsky Apr 22 at 22:58
1  
My whole point is, that one should not compare the two loop approaches in the sense that one is generally preferable to the other. Both loops have their uses, and it is the responsibility of the programmer to know the ins and outs of both loops, so he can effectively use them. –  Balder Apr 23 at 5:07
4  
There is a sentence at the very end of my critique: "Code should speak in idioms, and the fewer idioms are used the clearer the code is and less time is spent deciding which idiom to use". I began to deeply appreciate this point when I switched from C# to Java. –  Aleksandr Dubinsky Apr 23 at 16:07

TL;DR: List.stream().forEach() was the fastest.

I felt I should add my results from benchmarking iteration. I took a very simple approach (no benchmarking frameworks) and benchmarked 5 different methods:

  1. classic for
  2. classic foreach
  3. List.forEach()
  4. List.stream().forEach()
  5. List.parallelStream().forEach

the testing procedure and parameters

private List<Integer> list;
private final int size = 1_000_000;

public MyClass(){
    list = new ArrayList<>();
    Random rand = new Random();
    for (int i = 0; i < size; ++i) {
        list.add(rand.nextInt(size * 50));
    }    
}
private void doIt(Integer i) {
    i *= 2; //so it won't get JITed out
}

The list in this class shall be iterated over and have some doIt(Integer i) applied to all it's members, each time via a different method. in the Main class I run the tested method three times to warm up the JVM. I then run the test method 1000 times summing the time it takes for each iteration method (using System.nanoTime()). After that's done i divide that sum by 1000 and that's the result, average time. example:

myClass.fored();
myClass.fored();
myClass.fored();
for (int i = 0; i < reps; ++i) {
    begin = System.nanoTime();
    myClass.fored();
    end = System.nanoTime();
    nanoSum += end - begin;
}
System.out.println(nanoSum / reps);

I ran this on a i5 4 core CPU, with java version 1.8.0_05

classic for

for(int i = 0, l = list.size(); i < l; ++i) {
    doIt(list.get(i));
}

execution time: 4.21 ms

classic foreach

for(Integer i : list) {
    doIt(i);
}

execution time: 5.95 ms

List.forEach()

list.forEach((i) -> doIt(i));

execution time: 3.11 ms

List.stream().forEach()

list.stream().forEach((i) -> doIt(i));

execution time: 2.79 ms

List.parallelStream().forEach

list.parallelStream().forEach((i) -> doIt(i));

execution time: 3.6 ms

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I feel that I need to extend my comment a bit...

About paradigm\style

That's probably the most notable aspect. FP became popular due to what you can get avoiding side-effects. I won't delve deep into what pros\cons you can get from this, since this is not related to the question.

However, I will say that the iteration using Iterable.forEach is inspired by FP and rather result of bringing more FP to Java (ironically, I'd say that there is no much use for forEach in pure FP, since it does nothing except introducing side-effects).

In the end I would say that it is rather a matter of taste\style\paradigm you are currently writing in.

About parallelism.

From performance point of view there is no promised notable benefits from using Iterable.forEach over foreach(...).

According to official docs on Iterable.forEach :

Performs the given action on the contents of the Iterable, in the order elements occur when iterating, until all elements have been processed or the action throws an exception.

... i.e. docs pretty much clear that there will be no implicit parallelism. Adding one would be LSP violation.

Now, there are "parallell collections" that are promised in Java 8, but to work with those you need to me more explicit and put some extra care to use them (see mschenk74's answer for example).

BTW: in this case Stream.forEach will be used, and it doesn't guarantee that actual work will be done in parallell (depends on underlying collection).

UPDATE: might be not that obvious and a little stretched at a glance but there is another facet of style and readability perspective.

First of all - plain old forloops are plain and old. Everybody already knows them.

Second, and more important - you probably want to use Iterable.forEach only with one-liner lambdas. If "body" gets heavier - they tend to be not-that readable. You have 2 options from here - use inner classes (yuck) or use plain old forloop. People often gets annoyed when they see the same things (iteratins over collections) being done various vays/styles in the same codebase, and this seems to be the case.

Again, this might or might not be an issue. Depends on people working on code.

share|improve this answer
1  
Parallelism doesn't need new "parallel collections". It just depends on whether you asked for a sequantial stream (using collection.stream()) or for a parallel one (using collection.parallelStream()). –  JB Nizet May 19 '13 at 17:17
    
@JBNizet According to docs Collection.parallelStream() does not guarantee that implementing collection will return parallell stream. I, am actually wondering myself, when this might happen, but, probably this do depend on collection. –  Eugeny Loy May 19 '13 at 17:52
    
agreed. It also depends on the collection. But my point was that parallel foreach loops were already available with all the standard collections (ArrayList, etc.). No need to wait for "parallel collections". –  JB Nizet May 19 '13 at 18:06
    
@JBNizet agree on on your point, but that's not really what I meant by "parallel collections" in the first place. I reference Collection.parallelStream() which was added in Java 8 as "parallel collections" by the analogy to Scala's concept that does pretty much the same. Also, not sure how is it called in JSR's bit I saw couple of papers that use the same terminology for this Java 8 feature. –  Eugeny Loy May 19 '13 at 18:21
1  
for the last paragraph you can use a function reference: collection.forEach(MyClass::loopBody); –  ratchet freak May 19 '13 at 19:16

forEach() can be implemented to be faster than for-each loop, because the iterable knows the best way to iterate its elements, as opposed to the standard iterator way. So the difference is loop internally or loop externally.

For example ArrayList.forEach(action) may be simply implemented as

for(int i=0; i<size; i++)
    action.accept(elements[i])

as opposed to the for-each loop which requires a lot of scaffolding

Iterator iter = list.iterator();
while(iter.hasNext())
    Object next = iter.next();
    do something with `next`

However, we also need to account for two overhead costs by using forEach(), one is making the lambda object, the other is invoking the lambda method. They are probably not significant.

see also http://journal.stuffwithstuff.com/2013/01/13/iteration-inside-and-out/ for comparing internal/external iterations for different use cases.

share|improve this answer
3  
why does the iterable know the best way but the iterator does not? –  mschenk74 May 19 '13 at 18:15
    
no essential difference, but extra code are needed to conform to the iterator interface, which may be more costly. –  bayou.io May 19 '13 at 18:20
    
@zhong.j.yu if you implement Collection you also implement Iterable anyway. So, there is no code overhead in terms of "adding more code to implement missing interface methods", if that's your point. As mschenk74 said there seems to be no no reasons why you cannot tweak your iterator to know how to iterate over your collection in the best possible way. I do agree that there might be overhead for iterator creation, but seriously, those things usually so cheap, that you can say that they have zero cost... –  Eugeny Loy May 19 '13 at 18:36
1  
for example iterating a tree: void forEach(Consumer<T> v){leftTree.forEach(v);v.accept(rootElem);rightTree.forEach(v);}, this is more elegant than the external iteration, and you can decide on how to best synchronize –  ratchet freak May 19 '13 at 19:03
    
@leo the authors of these collections are -extremely- concerned with performance. –  bayou.io May 19 '13 at 20:49

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