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I hope this question is not considered too basic for this forum, but we'll see. I'm wondering how to refactor some code for better performance that is getting run a bunch of times.

Say I'm creating a word frequency list, using a Map (probably a HashMap), where each key is a String with the word that's being counted and the value is an Integer that's incremented each time a token of the word is found.

In Perl, incrementing such a value would be trivially easy:

$map{$word}++;

But in Java, it's much more complicated. Here the way I'm currently doing it:

int count = map.containsKey(word) ? map.get(word) : 0;
map.put(word, count + 1);

Which of course relies on the autoboxing feature in the newer Java versions. I wonder if you can suggest a more efficient way of incrementing such a value. Are there even good performance reasons for eschewing the Collections framework and using a something else instead?

Update: I've done a test of several of the answers. See below.

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I think it would be the same for java.util.Hashtable. –  jrudolph Sep 17 '08 at 9:19
    
Of course if would be same, because Hashtable is infact a Map. –  whiskeysierra Jan 10 '10 at 14:08
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19 Answers

I think your solution would be the standard way, but - as you noted yourself - it is probably not the fastest way possible.

You may look at GNU Trove. That is a library which contains all sorts of fast primitive Collections. Your example would use a TObjectIntHashMap which has a method adjustOrPutValue which does exactly what you want.

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The link to TObjectIntHashMap is broken. This is the correct link: trove4j.sourceforge.net/javadocs/gnu/trove/map/… –  Erel Segal Halevi Dec 6 '11 at 12:16
    
Thanks, Erel, I fixed the link. –  jrudolph Dec 7 '11 at 20:44
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The various primitive wrappers, e.g., Integer are immutable so there's really not a more concise way to do what you're asking unless you can do it with something like AtomicLong. I can give that a go in a minute and update. BTW, Hashtable is a part of the Collections Framework.

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There are a couple of approaches:

  1. Use a Bag alorithm like the sets contained in Google Collections.

  2. Create mutable container which you can use in the Map:


    class My{
        String word;
        int count;
    }

And use put("word", new My("Word") ); Then you can check if it exists and increment when adding.

Avoid rolling your own solution using lists, because if you get innerloop searching and sorting, your performance will stink. The first HashMap solution is actually quite fast, but a proper like that found in Google Collections is probably better.

Counting words using Google Collections, looks something like this:



    HashMultiset s = new HashMultiset();
    s.add("word");
    s.add("word");
    System.out.println(""+s.count("word") );


Using the HashMultiset is quite elegent, because a bag-algorithm is just what you need when counting words.

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@Hank Gay

As a follow-up to my own (rather useless) comment: Trove looks like the way to go. If, for whatever reason, you wanted to stick with the standard JDK, ConcurrentMap and AtomicLong can make the code a tiny bit nicer, though YMMV.

    final ConcurrentMap<String, AtomicLong> map = new ConcurrentHashMap<String, AtomicLong>();
    map.putIfAbsent("foo", new AtomicLong(0));
    map.get("foo").incrementAndGet();

will leave 1 as the value in the map for foo. Realistically, increased friendliness to threading is all that this approach has to recommend it.

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3  
The putIfAbsent() returns the value. It could be a big improvement to store the returned value in a local variable and use it to incrementAndGet() rather than call get again. –  smartnut007 Dec 19 '11 at 20:51
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Another way would be creating a mutable integer:

class MutableInt {
  int value = 0;
  public void inc () { ++value; }
  public int get () { return value; }
}
...
Map<String,MutableInt> map = new HashMap<String,MutableInt> ();
MutableInt value = map.get (key);
if (value == null) {
  value = new MutableInt ();
  map.put (key, value);
} else {
  value.inc ();
}

of course this implies creating an additional object but the overhead in comparison to creating an Integer (even with Integer.valueOf) should not be so much.

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4  
You don't want to start the MutableInt off at 1 the first time you put it in the map? –  Tom Hawtin - tackline Sep 17 '08 at 10:19
2  
Apache's commons-lang has a MutableInt already written for you. –  SingleShot Sep 17 '11 at 6:35
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Instead of calling containsKey() it is faster just to call map.get and check if the returned value is null or not.

	Integer count = map.get(word);
	if(count == null){
		count = 0;
	}
	map.put(word, count + 1);
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You should be aware of the fact that your original attempt

int count = map.containsKey(word) ? map.get(word) : 0;
contains two potentially expensive operations on a map, namely containsKey and get. The former performs an operation potentially pretty similar to the latter, so you're doing the same work *twice*! If you look at the API for Map, get operations usually return null when the map does not contain the requested element. Note that this will make a solution like
map.put( key, map.get(key) + 1 );
dangerous, since it might yield NullPointerExceptions. You should check for a null first.

Also note, and this is very important, that HashMaps *can* contain nulls by definition. So not every returned null says "there is no such element". In this respect, containsKey behaves *differently* from get in actually telling you *whether* there is such an element. Refer to the API for details.

For your case, however, you might not want to distinguish between a stored null and "noSuchElement". If you don't want to permit nulls you might prefer a Hashtable. Using a wrapper library as was already proposed in other answers might be a better solution to manual treatment, depending on the complexity of your application. To complete the answer (and I forgot to put that in at first, thanks to the edit function!), the best way of doing it natively, is to get into a final variable, check for null and put it back in with a 1. The variable should be final because it's immutable anyway. The compiler might not need this hint, but its clearer that way.

final HashMap map = generateRandomHashMap();
final Object key = fetchSomeKey();
final Integer i = map.get(key);
if (i != null) {
    map.put(i + 1);
} else {
    // do something
}

If you do not want to rely on autoboxing, you should say something like map.put(new Integer(1 + i.getValue())); instead.

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To avoid the problem of initial unmapped/null values in groovy I end up doing: counts.put(key, (counts.get(key) ?: 0) + 1) // overly complex version of ++ –  Joe Atzberger May 9 '13 at 16:03
    
Or, most simply: counts = [:].withDefault{0} // ++ away –  Joe Atzberger May 9 '13 at 16:08
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I'd use Apache Collections Lazy Map (to initialize values to 0) and use MutableIntegers from Apache Lang as values in that map.

Biggest cost is having to serach the map twice in your method. In mine you have to do it just once. Just get the value (it will get initialized if absent) and increment it.

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Are you sure that this is a bottleneck? Have you done any performance analysis?

Try using the NetBeans profiler (its free and built into NB 6.1) to look at hotspots.

Finally, a JVM upgrade (say from 1.5->1.6) is often a cheap performance booster. Even an upgrade in build number can provide good performance boosts. If you are running on Windows and this is a server class application, use -server on the command line to use the Server Hotspot JVM. On Linux and Solaris machines this is autodetected.

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@Vilmantas Baranauskas: Regarding this answer, I would comment if I had the rep points, but I don't. I wanted to note that the Counter class defined there is NOT thread-safe as it is not sufficient to just synchronize inc() without synchronizing value(). Other threads calling value() are not guaranteed to see the the value unless a happens-before relationship has been established with the update.

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If you want to reference someone's answer, use @[Username] at the top, e.g., @Vilmantas Baranauskas <Content goes here> –  Hank Gay Sep 22 '08 at 17:04
    
I made that modification to clean it up. –  Alex Miller Feb 1 '10 at 23:07
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Memory rotation may be an issue here, since every boxing of an int larger than or equal to 128 causes an object allocation (see Integer.valueOf(int)). Although the garbage collector very efficiently deals with short-lived objects, performance will suffer to some degree.

If you know that the number of increments made will largely outnumber the number of keys (=words in this case), consider using an int holder instead. Phax already presented code for this. Here it is again, with two changes (holder class made static and initial value set to 1):

static class MutableInt {
  int value = 1;
  void inc() { ++value; }
  int get() { return value; }
}
...
Map<String,MutableInt> map = new HashMap<String,MutableInt>();
MutableInt value = map.get(key);
if (value == null) {
  value = new MutableInt();
  map.put(key, value);
} else {
  value.inc();
}

If you need extreme performance, look for a Map implementation which is directly tailored towards primitive value types. jrudolph mentioned GNU Trove.

By the way, a good search term for this subject is "histogram".

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It's always a good idea to look at the Google Collections Library for this kind of thing. In this case a Multiset will do the trick:

Multiset bag = Multisets.newHashMultiset();
String word = "foo";
bag.add(word);
bag.add(word);
System.out.println(bag.count(word)); // Prints 2

There are Map-like methods for iterating over keys/entries, etc. Internally the implementation currently uses a HashMap<E, AtomicInteger>, so you will not incur boxing costs.

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If only Sets had a get method....sigh. –  Michael Deardeuff Jan 17 '09 at 8:46
    
The above answeer needs to reflect tovares response. The api has changed since its posting (3 years ago :)) –  steve Nov 4 '11 at 12:35
    
Does the count() method on a multiset run in O(1) or O(n) time (worstcase)? The docs are unclear on this point. –  Adam Parkin May 3 '13 at 18:30
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up vote 122 down vote accepted

Some test results

I've gotten a lot of good answers to this question--thanks folks--so I decided to run some tests and figure out which method is actually fastest. The five methods I tested are these:

  • the "ContainsKey" method that I presented in the question
  • the "TestForNull" method suggested by Aleksandar Dimitrov
  • the "AtomicLong" method suggested by Hank Gay
  • the "Trove" method suggested by jrudolph
  • the "MutableInt" method suggested by phax.myopenid.com

Method

Here's what I did...

  1. created five classes that were identical except for the differences shown below. Each class had to perform an operation typical of the scenario I presented: opening a 10MB file and reading it in, then performing a frequency count of all the word tokens in the file. Since this took an average of only 3 seconds, I had it perform the frequency count (not the I/O) 10 times.
  2. timed the loop of 10 iterations but not the I/O operation and recorded the total time taken (in clock seconds) essentially using Ian Darwin's method in the Java Cookbook.
  3. performed all five tests in series, and then did this another three times.
  4. averaged the four results for each method.

Results

I'll present the results first and the code below for those who are interested.

The ContainsKey method was, as expected, the slowest, so I'll give the speed of each method in comparison to the speed of that method.

  • ContainsKey: 30.654 seconds (baseline)
  • AtomicLong: 29.780 seconds (1.03 times as fast)
  • TestForNull: 28.804 seconds (1.06 times as fast)
  • Trove: 26.313 seconds (1.16 times as fast)
  • MutableInt: 25.747 seconds (1.19 times as fast)

Conclusions

It would appear that only the MutableInt method and the Trove method are significantly faster, in that only they give a performance boost of more than 10%. However, if threading is an issue, AtomicLong might be more attractive than the others (I'm not really sure). I also ran TestForNull with final variables, but the difference was negligible.

Note that I haven't profiled memory usage in the different scenarios. I'd be happy to hear from anybody who has good insights into how the MutableInt and Trove methods would be likely to affect memory usage.

Personally, I find the MutableInt method the most attractive, since it doesn't require loading any third-party classes. So unless I discover problems with it, that's the way I'm most likely to go.

The code

Here is the crucial code from each method.

ContainsKey

import java.util.HashMap;
import java.util.Map;
...
Map<String, Integer> freq = new HashMap<String, Integer>();
...
int count = freq.containsKey(word) ? freq.get(word) : 0;
freq.put(word, count + 1);

TestForNull

import java.util.HashMap;
import java.util.Map;
...
Map<String, Integer> freq = new HashMap<String, Integer>();
...
Integer count = freq.get(word);
if (count == null) {
    freq.put(word, 1);
}
else {
    freq.put(word, count + 1);
}

AtomicLong

import java.util.concurrent.ConcurrentHashMap;
import java.util.concurrent.ConcurrentMap;
import java.util.concurrent.atomic.AtomicLong;
...
final ConcurrentMap<String, AtomicLong> map = 
    new ConcurrentHashMap<String, AtomicLong>();
...
map.putIfAbsent(word, new AtomicLong(0));
map.get(word).incrementAndGet();

Trove

import gnu.trove.TObjectIntHashMap;
...
TObjectIntHashMap<String> freq = new TObjectIntHashMap<String>();
...
freq.adjustOrPutValue(word, 1, 1);

MutableInt

import java.util.HashMap;
import java.util.Map;
...
class MutableInt {
  int value = 1; // note that we start at 1 since we're counting
  public void increment () { ++value;      }
  public int  get ()       { return value; }
}
...
Map<String, MutableInt> freq = new HashMap<String, MutableInt>();
...
MutableInt count = freq.get(word);
if (count == null) {
    freq.put(word, new MutableInt());
}
else {
    count.increment();
}
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1  
Great work, well done. A minor comment - the putIfAbsent() call in the AtomicLong code will instantiate a new AtomicLong(0) even if one is already in the map. If you tweak this to use if (map.get(key) == null) instead, you will probably get an improvement in those test results. –  Leigh Caldwell Sep 20 '08 at 13:36
    
Thanks for pointing that out, Leigh! –  gregory Sep 20 '08 at 14:08
    
I did the same thing recently with an approach similar to MutableInt. I'm glad to hear it was the optimal solution (I just assumed it was, without doing any tests). –  Kip Sep 22 '08 at 18:50
    
Nice to hear that you're faster than me, Kip. ;-) Let me know if you discover any drawbacks to that approach. –  gregory Sep 22 '08 at 19:41
3  
In the Atomic Long case wouldn't it be more efficient to do it in one step ( so you have only 1 expensive get operation instead of 2 ) "map.putIfAbsent(word, new AtomicLong(0)).incrementAndGet();" –  smartnut007 Jul 19 '11 at 19:47
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The Functional Java library's TreeMap datastructure has an update method in the latest trunk head:

public TreeMap<K, V> update(final K k, final F<V, V> f)

Example usage:

import static fj.data.TreeMap.empty;
import static fj.function.Integers.add;
import static fj.pre.Ord.stringOrd;
import fj.data.TreeMap;

public class TreeMap_Update
  {public static void main(String[] a)
    {TreeMap<String, Integer> map = empty(stringOrd);
     map = map.set("foo", 1);
     map = map.update("foo", add.f(1));
     System.out.println(map.get("foo").some());}}

This program prints "2".

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"put" need "get" (to ensure no duplicate key).
So directly do a "put",
and if there was a previous value, then do an addition:

Map map = new HashMap ();

MutableInt newValue = new MutableInt (1); // default = inc
MutableInt oldValue = map.put (key, newValue);
if (oldValue != null) {
  newValue.add(oldValue); // old + inc
}

If count starts at 0, then add 1: (or any others values...)

Map map = new HashMap ();

MutableInt newValue = new MutableInt (0); // default
MutableInt oldValue = map.put (key, newValue);
if (oldValue != null) {
  newValue.setValue(oldValue + 1); // old + inc
}

Notice : This code is not thread safe. Use it to build then use the map, not to concurrently update it.

Optimization : In a loop, keep old value to become the new value of next loop.

Map map = new HashMap ();
final int defaut = 0;
final int inc = 1;

MutableInt oldValue = new MutableInt (default);
while(true) {
  MutableInt newValue = oldValue;

  oldValue = map.put (key, newValue); // insert or...
  if (oldValue != null) {
    newValue.setValue(oldValue + inc); // ...update

    oldValue.setValue(default); // reuse
  } else
    oldValue = new MutableInt (default); // renew
  }
}
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Google Collections HashMultiset :
- quite elegant to use
- but consume CPU and memory

Best would be to have a method like : Entry<K,V> getOrPut(K); (elegant, and low cost)

Such a method will compute hash and index only once, and then we could do what we want with the entry (either replace or update the value).

More elegant:
- take a HashSet<Entry>
- extend it so that get(K) put a new Entry if needed
- Entry could be your own object.
--> (new MyHashSet()).get(k).increment();

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A variation on the MutableInt approach that might be even faster, if a bit of a hack, is to use a single-element int array:

Map<String,int[]> map = new HashMap<String,int[]>();
...
int[] value = map.get(key);
if (value == null) 
  map.put(key, new int[]{1} );
else
  ++value[0];

It would be interesting if you could rerun your performance tests with this variation. It might be the fastest.


Edit: The above pattern worked fine for me, but eventually I changed to use Trove's collections to reduce memory size in some very large maps I was creating -- and as a bonus it was also faster.

One really nice feature is that the TObjectIntHashMap class has a single adjustOrPutValue call that, depending on whether there is already a value at that key, will either put an initial value or increment the existing value. This is perfect for incrementing:

TObjectIntHashMap<String> map = new TObjectIntHashMap<String>();
...
map.adjustOrPutValue(key, 1, 1);
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google guava is your friend...

...at least in some cases. They have this nice AtomicLongMap. Especially nice because you are dealing with long as value in your map.

e.g.

AtomicLongMap map = AtomicLongMap.create();
[...]
map.getAndIncrement(word);

also possible to add more then 1 to the value:

map.getAndAdd(word, new Long(112)); 
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If you're using GS Collections, you can use a HashBag. It will be the most efficient approach in terms of memory usage and it will also perform well in terms of execution speed.

As of version 4.0.0, the implementation of HashBag is similar to @gregory's MutableInt method. HashBag is backed by UnifiedMap<K, Counter> which is similar to HashMap<K, MutableInt>. UnifiedMap uses half the memory of a HashMap and is slightly faster as well, so HashBag has the same benefits. In a future version of GS Collections, we'll replace the UnifiedMap with an ObjectIntMap which stores primitive ints instead of Counter objects. This will further reduce the memory overhead while still maintaining execution speeds similar to the Trove method.

HashBag provides the API you'd need since it's a Collection that also allows you to query for the number of occurrences of an item.

Here's an example from the GS Collections Kata.

MutableBag<String> bag =
  HashBag.newBagWith("one", "two", "two", "three", "three", "three");

Assert.assertEquals(3, bag.occurrencesOf("three"));

bag.add("one");
Assert.assertEquals(2, bag.occurrencesOf("one"));

bag.addOccurrences("one", 4);
Assert.assertEquals(6, bag.occurrencesOf("one"));

Note: I am a developer on GS collections.

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