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How can I take n random elements from an ArrayList<E>? Ideally, I'd like to be able to make successive calls to the take() method to get another x elements, without replacement.

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what's take() in ArrayList? – Nishant Jan 15 '11 at 20:46
    
what have you got so far? If you get another x elements, can you pick elements from the previous set again, or must be all different all the time until ALL elements are picked? (Then, what next?) – Yanick Rochon Jan 15 '11 at 20:56
    
Without replacement. When you have no more left, you should get nothing back. – user568866 Jan 16 '11 at 14:02
up vote 58 down vote accepted

Two main ways.

  1. Use Random#nextInt(int):

    List<Foo> list = createItSomehow();
    Random random = new Random();
    Foo foo = list.get(random.nextInt(list.size()));
    

    It's however not guaranteed that successive n calls returns unique elements.

  2. Use Collections#shuffle():

    List<Foo> list = createItSomehow();
    Collections.shuffle(list);
    Foo foo = list.get(0);
    

    It enables you to get n unique elements by an incremented index (assuming that the list itself contains unique elements).

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I have got a list of 4000 words and I have to get 5 words out of that list each time I press the refresh button, am using the 2nd option of your answer. How much does it guarantee that I will get unique values all the time i.e. what's the probability ? – Prateek Jun 18 '13 at 12:27
    
@Prateek: If you have a question, press "Ask Question" button. Do not press "Add comment" or "Post Answer" button. – BalusC Jun 18 '13 at 12:31
    
I know when to use which button, my comment is somewhat related to your already posted answer so I didn't want to create a new thread of if and was looking for a response inline, thanks anyways. – Prateek Jun 18 '13 at 13:04
1  
Keep in mind that Collections.shuffle() uses a version of the Fisher-Yates shuffle algorithm, with an internal instance of Random. The Random class uses a long for its seed value, meaning it can only offer you up to 2^32 possible permutations. This is insufficient for shuffling any more than 12 elements with uniform probability of all permutations (that is, some permutations will never come up). You'll want to use Collections.shuffle(list,random) instead, where random is either and instance of SecureRandom or your own custom Random extension, if you're up to that task. – Matunos May 28 '15 at 7:42
    
Matunos - for what it's worth, the effective seed size of java.util.Random is 2^48, but as you say, it's still worth bearing in mind that you may need to select a better generator. I would still advocate the method I mention of simply picking the items with the relevant probability (you still need the same number of random numbers as a shuffle, but you don't have to swap all the pointers, potentially better memory locality, and there's a chance of terminating the loop "early" once you have selected all of the required elements). – Neil Coffey Feb 8 at 22:26

If you want to successively pick n elements from the list and be able to do so without replacement over and over and over again, you are probably best of randomly permuting the elements, then taking chunks off in blocks of n. If you randomly permute the list you guarantee statistical randomness for each block you pick out. Perhaps the easiest way to do this would be to use Collections.shuffle.

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3  
And the easiest way to do this is to call java.util.Collections.shuffle() – biziclop Jan 15 '11 at 20:48

A fair way to do this is to go through the list, on the nth iteration calculating the probability of whether or not to pick the nth element, which is essentially the fraction of the number of items you still need to pick over the number of elements available in the rest of the list. For example:

public static <T> T[] pickSample(T[] population, int nSamplesNeeded, Random r) {
  T[] ret = (T[]) Array.newInstance(population.getClass().getComponentType(),
                                    nSamplesNeeded);
  int nPicked = 0, i = 0, nLeft = population.length;
  while (nSamplesNeeded > 0) {
    int rand = r.nextInt(nLeft);
    if (rand < nSamplesNeeded) {
      ret[nPicked++] = population[i];
      nSamplesNeeded--;
    }
    nLeft--;
    i++;
  }
  return ret;
}

(This code copied from a page I wrote a while ago on picking a random sample from a list.)

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Simple and clear

   // define ArrayList to hold Integer objects
    ArrayList<Integer> arrayList = new ArrayList<>();

    for (int i = 0; i < maxRange; i++) {
        arrayList.add(i + 1);
    }

    // shuffle list
    Collections.shuffle(arrayList);

    // adding defined amount of numbers to target list
    ArrayList<Integer> targetList = new ArrayList<>();
    for (int j = 0; j < amount; j++) {
        targetList.add(arrayList.get(j)); 
    }

    return targetList;
share|improve this answer
    
I did not see the correlation between arrayList and targetList. – David Aug 20 '14 at 8:35
    
It should've been targetList.add(arrayList.get(j)) – nomad Jun 24 '15 at 18:01

Most of the proposed solutions till now suggest either a full list shuffle or successive random picking by checking uniqueness and retry if required.

But, we can take advantage of the Durstenfeld's algorithm (the most popular Fisher-Yates variant in our days).

Durstenfeld's solution is to move the "struck" numbers to the end of the list by swapping them with the last unstruck number at each iteration.

Due to the above, we don't need to shuffle the whole list, but run the loop for as many steps as the number of elements required to return. The algorithm ensures that the last N elements at the end of the list are 100% random if we used a perfect random function.

Among the many real-world scenarios where we need to pick a predetermined (max) amount of random elements from arrays/lists, this optimized method is very useful for various card games, such as Texas Poker, where you a-priori know the number of cards to be used per game; only a limited number of cards is usually required from the deck.

public static <E> List<E> pickNRandomElements(List<E> list, int n, Random r) {
    int length = list.size();

    if (length < n) return null;

    //We don't need to shuffle the whole list
    for (int i = length - 1; i >= length - n; --i)
    {
        Collections.swap(list, i , r.nextInt(i + 1));
    }
    return list.subList(length - n, length);
}

public static <E> List<E> pickNRandomElements(List<E> list, int n) {
    return pickNRandomElements(list, n, new Random());
}
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Use the following class:

import java.util.Enumeration;
import java.util.Random;

public class RandomPermuteIterator implements Enumeration<Long> {
    int c = 1013904223, a = 1664525;
    long seed, N, m, next;
    boolean hasNext = true;

    public RandomPermuteIterator(long N) throws Exception {
        if (N <= 0 || N > Math.pow(2, 62)) throw new Exception("Unsupported size: " + N);
        this.N = N;
        m = (long) Math.pow(2, Math.ceil(Math.log(N) / Math.log(2)));
        next = seed = new Random().nextInt((int) Math.min(N, Integer.MAX_VALUE));
    }

    public static void main(String[] args) throws Exception {
        RandomPermuteIterator r = new RandomPermuteIterator(100);
        while (r.hasMoreElements()) System.out.print(r.nextElement() + " ");
    }

    @Override
    public boolean hasMoreElements() {
        return hasNext;
    }

    @Override
    public Long nextElement() {
        next = (a * next + c) % m;
        while (next >= N) next = (a * next + c) % m;
        if (next == seed) hasNext = false;
        return  next;
    }
}
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