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What, if any, is the performance difference between the following two loops?

for(Object o: objectArrayList){
    o.DoSomthing();
}

and

for(int i=0; i<objectArrayList.size(); i++){
    objectArrayList.get(i).DoSomthing();
}
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@Keparo: It is a "for each" loop not a "for-in" loop –  Ande Nov 3 '08 at 12:22
    
in java its called "for each", but when it come to Objective C its called "for In" loop. –  damithH May 16 '14 at 12:50
    
    
The extended for loop performance is discussed here: stackoverflow.com/questions/12155987/… –  eckes May 20 at 5:08

11 Answers 11

up vote 123 down vote accepted

From Item 46 in Effective Java by Joshua Bloch :

The for-each loop, introduced in release 1.5, gets rid of the clutter and the opportunity for error by hiding the iterator or index variable completely. The resulting idiom applies equally to collections and arrays:

// The preferred idiom for iterating over collections and arrays
for (Element e : elements) {
    doSomething(e);
}

When you see the colon (:), read it as “in.” Thus, the loop above reads as “for each element e in elements.” Note that there is no performance penalty for using the for-each loop, even for arrays. In fact, it may offer a slight performance advantage over an ordinary for loop in some circumstances, as it computes the limit of the array index only once. While you can do this by hand (Item 45), programmers don’t always do so.

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23  
Worth mentioning that in a for-each loop there is no way to access an index counter (since it doesn't exist) –  basszero Feb 6 '09 at 11:42
    
basszero, except if you add a counter... –  Alexander Feb 10 '12 at 11:02
    
Yes, but that counter is now visible outside of the loop. Sure, it's a simple fix but so is for-each! –  Indolering Nov 4 '12 at 5:19
24  
There is the performance penalty of allocating the iterator. I had some highly parallel code in an Android live wallpaper. I saw that the garbage collector was going crazy. It was because for-each loops were allocating temporary iterators in many different (short-lived) threads, cause the garbage collector a lot of work. Switching to regular index based loops fixed the problem. –  gsingh2011 Sep 30 '13 at 17:44
    
@gsingh2011 But this also depends on if you're using a random access list or not. Using index based access to non-random access lists will be a lot worse than using for-each with random access lists, I guess. If you're working with the interface List and thus don't know the actual implementation type you can check if the list is an instance of (implements) RandomAccess, if you really care that much: docs.oracle.com/javase/8/docs/api/java/util/RandomAccess.html –  Puce Mar 18 at 16:54

All these loops do the exact same, I just want to show these before throwing in my two cents.

First, the classic way of looping through List:

for(int i=0;i<strings.size();i++) { /* do something using strings.get(i) */ }

Second, the preferred way since it's less error prone (how many times have YOU done the "oops, mixed the variables i and j in these loops within loops" thing?).

for(String s : strings) { /* do something using s */ }

Third, the micro-optimized for loop:

int size = strings.size();
for(int i=0;++i<=size;) { /* do something using strings.get(i) */ }

Now the actual two cents: At least when I was testing these, the third one was the fastest when counting milliseconds on how long it took for each type of loop with a simple operation in it repeated a few million times - this was using Java 5 with jre1.6u10 on Windows in case anyone is interested.

While it at least seems to be so that the third one is the fastest, you really should ask yourself if you want to take the risk of implementing this peephole optimization everywhere in your looping code since from what I've seen, actual looping isn't usually the most time consuming part of any real program (or maybe I'm just working on the wrong field, who knows). And also like I mentioned in the pretext for the Java for-each loop (some refer to it as Iterator loop and others as for-in loop) you are less likely to hit that one particular stupid bug when using it. And before debating how this even can even be faster than the other ones, remember that javac doesn't optimize bytecode at all (well, nearly at all anyway), it just compiles it.

If you're into micro-optimization though and/or your software uses lots of recursive loops and such then you may be interested in the third loop type. Just remember to benchmark your software well both before and after changing the for loops you have to this odd, micro-optimized one.

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3  
Please note that the for loop with ++i<=size is "1-based", e.g. the get-method inside the loop will be called for values 1, 2, 3, etc. –  volley Nov 3 '08 at 19:30
10  
A better way to write the micro-optimized loop is for(int i=0, size=strings.size();++i<=size;) {} This is preferable because it minimizes the scope of size –  Dónal Dec 18 '08 at 16:58

The for-each loop should generally be preferred. The "get" approach may be slower if the List implementation you are using does not support random access. For example, if a LinkedList is used, you would incur a traversal cost, whereas the for-each approach uses an iterator that keeps track of its position in the list. More information on the nuances of the for-each loop.

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It's always better to use the iterator instead of indexing. This is because iterator is most likely optimzied for the List implementation while indexed (calling get) might not be. For example LinkedList is a List but indexing through its elements will be slower than iterating using the iterator.

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Thank you for agreeing with me =) –  Zach Scrivena Nov 3 '08 at 4:58
1  
I think there is no such thing as "always" in performance optimizations .) –  eckes May 20 at 5:11

Well, performance impact is mostly insignificant, but isn't zero. If you look at javadoc of RandomAccess interface:

As a rule of thumb, a List implementation should implement this interface if, for typical instances of the class, this loop:

for (int i=0, n=list.size(); i < n; i++)
    list.get(i);

runs faster than this loop:

for (Iterator i=list.iterator(); i.hasNext();)
      i.next();

And for-each loop is using version with iterator, so for ArrayList for example, for-each loop isn't fastest.

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Even with something like an ArrayList or Vector, where "get" is a simple array lookup, the second loop still has additional overhead that the first one doesn't. I would expect it to be a tiny bit slower than the first.

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The first loop has to get each element too. It creates an iterator behind the scenes to do this. They're really equivalent. –  Bill the Lizard Nov 2 '08 at 12:57
    
Thinking in terms of C, an iterator can just increment a pointer, but a get would have to multiply the value of i by the width of a pointer each time. –  Paul Tomblin Nov 2 '08 at 13:05
    
It depends on what type of list you use. I think you're right though, using get would never be faster, and sometimes slower. –  Bill the Lizard Nov 2 '08 at 13:12

The only way to know for sure is to benchmark it, and even that is not as simple as it may sound. The JIT compiler can do very unexpected things to your code.

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foreach makes the intention of your code clearer and that is normally preferred over a very minor speed improvement - if any.

Whenever I see an indexed loop I have to parse it a little longer to make sure it does what I think it does E.g. Does it start from zero, does it include or exclude the end point etc.?

Most of my time seems to be spent reading code (that I wrote or someone else wrote) and clarity is almost always more important than performance. Its easy to dismiss performance these days because Hotspot does such an amazing job.

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The following code:

import java.lang.reflect.Array;
import java.util.ArrayList;
import java.util.List;

interface Function<T> {
    long perform(T parameter, long x);
}

class MyArray<T> {

    T[] array;
    long x;

    public MyArray(int size, Class<T> type, long x) {
        array = (T[]) Array.newInstance(type, size);
        this.x = x;
    }

    public void forEach(Function<T> function) {
        for (T element : array) {
            x = function.perform(element, x);
        }
    }
}

class Compute {
    int factor;
    final long constant;

    public Compute(int factor, long constant) {
        this.factor = factor;
        this.constant = constant;
    }

    public long compute(long parameter, long x) {
        return x * factor + parameter + constant;
    }
}

public class Main {

    public static void main(String[] args) {
        List<Long> numbers = new ArrayList<Long>(50000000);
        for (int i = 0; i < 50000000; i++) {
            numbers.add(i * i + 5L);
        }

        long x = 234553523525L;

        long time = System.currentTimeMillis();
        for (int i = 0; i < numbers.size(); i++) {
            x += x * 7 + numbers.get(i) + 3;
        }
        System.out.println(System.currentTimeMillis() - time);
        System.out.println(x);
        x = 0;
        time = System.currentTimeMillis();
        for (long i : numbers) {
            x += x * 7 + i + 3;
        }
        System.out.println(System.currentTimeMillis() - time);
        System.out.println(x);
        x = 0;
        numbers = null;
        MyArray<Long> myArray = new MyArray<Long>(50000000, Long.class, 234553523525L);
        for (int i = 0; i < 50000000; i++) {
            myArray.array[i] = i * i + 3L;
        }
        time = System.currentTimeMillis();
        myArray.forEach(new Function<Long>() {

            public long perform(Long parameter, long x) {
                return x * 8 + parameter + 5L;
            }
        });
        System.out.println(System.currentTimeMillis() - time);
        System.out.println(myArray.x);
        myArray = null;
        myArray = new MyArray<Long>(50000000, Long.class, 234553523525L);
        for (int i = 0; i < 50000000; i++) {
            myArray.array[i] = i * i + 3L;
        }
        time = System.currentTimeMillis();
        myArray.forEach(new Function<Long>() {

            public long perform(Long parameter, long x) {
                return new Compute(8, 5).compute(parameter, x);
            }
        });
        System.out.println(System.currentTimeMillis() - time);
        System.out.println(myArray.x);
    }
}

Gives following output on my system:

224
-699150247503735895
221
-699150247503735895
220
-699150247503735895
219
-699150247503735895

I'm running Ubuntu 12.10 alpha with OracleJDK 1.7 update 6.

In general HotSpot optimizes a lot of indirections and simple reduntant operations, so in general you shouldn't worry about them unless there are a lot of them in seqence or they are heavily nested.

On the other hand, indexed get on LinkedList is much slower than calling next on iterator for LinkedList so you can avoid that performance hit while retaining readability when you use iterators (explicitly or implicitly in for-each loop).

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There appears to be a difference unfortunately.

If you look at the generated bytes code for both kinds of loops, they are different.

Here is an example from the Log4j source code.

In /log4j-api/src/main/java/org/apache/logging/log4j/MarkerManager.java we have a static inner class called Log4jMarker which defines:

    /*
     * Called from add while synchronized.
     */
    private static boolean contains(final Marker parent, final Marker... localParents) {
        //noinspection ForLoopReplaceableByForEach
        for (final Marker marker : localParents) {
            if (marker == parent) {
                return true;
            }
        }
        return false;
    }

With standard loop:

  private static boolean contains(org.apache.logging.log4j.Marker, org.apache.logging.log4j.Marker...);
    Code:
       0: iconst_0
       1: istore_2
       2: aload_1
       3: arraylength
       4: istore_3
       5: iload_2
       6: iload_3
       7: if_icmpge     29
      10: aload_1
      11: iload_2
      12: aaload
      13: astore        4
      15: aload         4
      17: aload_0
      18: if_acmpne     23
      21: iconst_1
      22: ireturn
      23: iinc          2, 1
      26: goto          5
      29: iconst_0
      30: ireturn

With for-each:

  private static boolean contains(org.apache.logging.log4j.Marker, org.apache.logging.log4j.Marker...);
    Code:
       0: aload_1
       1: astore_2
       2: aload_2
       3: arraylength
       4: istore_3
       5: iconst_0
       6: istore        4
       8: iload         4
      10: iload_3
      11: if_icmpge     34
      14: aload_2
      15: iload         4
      17: aaload
      18: astore        5
      20: aload         5
      22: aload_0
      23: if_acmpne     28
      26: iconst_1
      27: ireturn
      28: iinc          4, 1
      31: goto          8
      34: iconst_0
      35: ireturn

What is up with THAT Oracle?

I've tried this with Java 7 and 8 on Windows 7.

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For those who are trying to read the disassembly, the net result is that the code generated inside the loop is identical, but the for-each setup seems to have created an extra temporary variable containing a reference to the second argument. If the extra hidden variable is enregistered, but the parameter itself is not during code generation, then the for-each would be faster; if the parameter is enregistered in the for(;;) example, execution time would be identical. Gotta benchmark? –  Robin Davies Jul 20 at 19:27

By the variable name objectArrayList, I assume that is an instance of java.util.ArrayList. In that case, the performance difference would be unnoticeable.

On the other hand, if it's an instance of java.util.LinkedList, the second approach will be much slower as the List#get(int) is an O(n) operation.

So the first approach is always preferred unless the index is needed by the logic in the loop.

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