# Weighted randomness in Java

In Java, given n Items, each with weight w, how does one choose a random Item from the collection with a chance equal to w?

Assume each weight is a double from 0.0 to 1.0, and that the weights in the collection sum to 1. Item.getWeight() returns the Item's weight.

-
How would you do it with pseudocode? –  Marcelo Jul 18 '11 at 18:07

``````Item[] items = ...;

// Compute the total weight of all items together
double totalWeight = 0.0d;
for (Item i : items)
{
totalWeight += i.getWeight();
}
// Now choose a random item
int randomIndex = -1;
double random = Math.random() * totalWeight;
for (int i = 0; i < items.length; ++i)
{
random -= items[i].getWeight();
if (random <= 0.0d)
{
randomIndex = i;
break;
}
}
Item myRandomItem = items[randomIndex];
``````
-
This. FYI you can do a binary search if you need to. –  Garrett Hall Jul 18 '11 at 18:16
For a binary search the partial sums would have to be stored, too. –  Paŭlo Ebermann Jul 18 '11 at 20:46
1. Give some arbitrary ordering to items... (i1, i2, ..., in)... with weights w1, w2, ..., wn.
2. Choose a random number between 0 and 1 (with sufficient granularity, by using any randomization function and appropriate scaling). Call this r0.
3. Let j = 1
4. Subtract wj from your r(j-1) to get rj. If rj <= 0, then you select item ij. Otherwise, increment j and repeat.

I think I've done it like that before... but there are probably more efficient ways to do this.

-
wrji2wwjri, my poor eyes! –  NateS Dec 16 at 17:55

One elegant way would be to sample an exponential distribution http://en.wikipedia.org/wiki/Exponential_distribution where the weights will be the rate of the distribution (lambda). Finally, you simply select the smallest sampled value.

In Java this looks like this:

``````    public static <E> E getWeightedRandom(Map<E, Double> weights, Random random) {
E result = null;
double bestValue = Double.MAX_VALUE;

for (E element : weights.keySet()) {
double value = -Math.log(random.nextDouble()) / weights.get(element);

if (value < bestValue) {
bestValue = value;
result = element;
}
}

return result;
}
``````

I am not sure whether this is more efficient than the other approaches, but if execution time is not the issue, it is a nicely looking solution.

-

If you want runtime selection efficiency then taking a little more time on the setup would probably be best. Here is one possible solution. It has more code but guarantees log(n) selection.

WeightedItemSelector Implements selection of a random object from a collection of weighted objects. Selection is guaranteed to run in log(n) time.

``````public class WeightedItemSelector<T> {
private final Random rnd = new Random();
private final TreeMap<Object, Range<T>> ranges = new TreeMap<Object, Range<T>>();
private int rangeSize; // Lowest integer higher than the top of the highest range.

public WeightedItemSelector(List<WeightedItem<T>> weightedItems) {
int bottom = 0; // Increments by size of non zero range added as ranges grows.

for(WeightedItem<T> wi : weightedItems) {
int weight = wi.getWeight();
if(weight > 0) {
int top = bottom + weight - 1;
Range<T> r = new Range<T>(bottom, top, wi);
if(ranges.containsKey(r)) {
Range<T> other = ranges.get(r);
throw new IllegalArgumentException(String.format("Range %s conflicts with range %s", r, other));
}
ranges.put(r, r);
bottom = top + 1;
}
}
rangeSize = bottom;
}

public WeightedItem<T> select() {
Integer key = rnd.nextInt(rangeSize);
Range<T> r = ranges.get(key);
if(r == null)
return null;
return r.weightedItem;
}
}
``````

Range Implements range selection to leverage TreeMap selection.

``````class  Range<T> implements Comparable<Object>{
final int bottom;
final int top;
final WeightedItem<T> weightedItem;
public Range(int bottom, int top, WeightedItem<T> wi) {
this.bottom = bottom;
this.top = top;
this.weightedItem = wi;
}

public WeightedItem<T> getWeightedItem() {
return weightedItem;
}

@Override
public int compareTo(Object arg0) {
if(arg0 instanceof Range<?>) {
Range<?> other = (Range<?>) arg0;
if(this.bottom > other.top)
return 1;
if(this.top < other.bottom)
return -1;
return 0; // overlapping ranges are considered equal.
} else if (arg0 instanceof Integer) {
Integer other = (Integer) arg0;
if(this.bottom > other.intValue())
return 1;
if(this.top < other.intValue())
return -1;
return 0;
}
throw new IllegalArgumentException(String.format("Cannot compare Range objects to %s objects.", arg0.getClass().getName()));
}

* @see java.lang.Object#toString()
*/
@Override
public String toString() {
StringBuilder builder = new StringBuilder();
builder.append("{\"_class\": Range {\"bottom\":\"").append(bottom).append("\", \"top\":\"").append(top)
.append("\", \"weightedItem\":\"").append(weightedItem).append("}");
return builder.toString();
}
}
``````

WeightedItem simply encapsulates an item to be selected.

``````public class WeightedItem<T>{
private final int weight;
private final T item;
public WeightedItem(int weight, T item) {
this.item = item;
this.weight = weight;
}

public T getItem() {
return item;
}

public int getWeight() {
return weight;
}

* @see java.lang.Object#toString()
*/
@Override
public String toString() {
StringBuilder builder = new StringBuilder();
builder.append("{\"_class\": WeightedItem {\"weight\":\"").append(weight).append("\", \"item\":\"")
.append(item).append("}");
return builder.toString();
}
}
``````
-
the weight is int, it should be double. –  Yeti Nov 14 '13 at 14:26

TreeMap does already do all the work for you.

Create a TreeMap. Create weights based on your method of choice. Add the weights beginning with 0.0 while adding the weight of the last element to your running weight counter.

i.e. (Scala):

``````var count = 0.0
for { object <- MyObjectList } { //Just any iterator over all objects
map.insert(count, object)
count += object.weight
}
``````

Then you just have to generate `rand = new Random(); num = rand.nextDouble() * count` to get a valid number.

``````map.to(num).last  //Scala
map.lowerKey(num) //Java
``````

will give you the random weighted item.

For smaller amounts of buckets also possible: Create an array of i.e. 100,000 Int's and distribute the number of the bucket based on the weight across the fields. Then you create a random Integer between 0 and 100,000-1 and you immediately get the bucket-number back.

-
+1 for an alternative that might be useful in a system with non-numeric weights and custom Comparators. Also, a good pointer towards setting up the binary-search approach mentioned in the comments on the leading answer (which should probably only be used if the weights are constant). But I wonder if TreeMap has too much overhead to be useful in a simple numeric-weight situation. –  MandisaW Jul 25 at 14:42
Well there is always the compromise between saving a few CPU cycles or saving a few programmer hours. :) –  mmlac Jul 30 at 4:46
Nice solution! I think a small change is required at least in case of Java and int weights. `num` will never be equal to `count` (i.e. sum of weights), and `num = 0` will throw NullPointerException. Simple fix is to use `map.lowerKey(num + 1)`. –  arun Dec 8 at 20:12

Below is a randomizer that maintains precision in proportions as well:

``````public class WeightedRandomizer
{
private final Random randomizer;

public WeightedRandomizer(Random randomizer)
{
this.randomizer = randomizer;
}

public IWeighable getRandomWeighable(List<IWeighable> weighables)
{
double totalWeight = 0.0;
long totalSelections = 1;
List<IWeighable> openWeighables = new ArrayList<>();

for (IWeighable weighable : weighables)
{
totalWeight += weighable.getAllocation();
totalSelections += weighable.getNumSelections();
}

for(IWeighable weighable : weighables)
{
double allocation = weighable.getAllocation() / totalWeight;
long numSelections = weighable.getNumSelections();
double proportion = (double) numSelections / (double) totalSelections;

if(proportion < allocation)
{