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I want to shuffle a list of unique items, but not do an entirely random shuffle. I need to be sure that no element in the shuffled list is at the same position as in the original list. Thus, if the original list is (A, B, C, D, E), this result would be OK: (C, D, B, E, A), but this one would not: (C, E, A, D, B) because "D" is still the fourth item. The list will have at most seven items. Extreme efficiency is not a consideration. I think this modification to Fisher/Yates does the trick, but I can't prove it mathematically:

function shuffle(data) {
    for (var i = 0; i < data.length - 1; i++) {
        var j = i + 1 + Math.floor(Math.random() * (data.length - i - 1));

        var temp = data[j];
        data[j] = data[i];
        data[i] = temp;
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Put each item in another position randomly. There is a small chance that you can´t find a position for the last one but then just start over. –  adrianm Sep 2 '11 at 6:34
A finite recurrence would prove mathematically that your algorithm works : at the end of iteration i, the element at position i isn't the original element anymore. When at iteration n-2, data[n-2] is automatically shuffled with data[n-1]. Thus, if data[n-1] was still holding its original value, it gets swapped at the last iteration. The same goes for data[n-1]. –  Rerito Nov 25 '14 at 9:46

3 Answers 3

You are looking for a derangement of your entries.

First of all, your algorithm works in the sense that it outputs a random derangement, ie a permutation with no fixed point. However it has a enormous flaw (which you might not mind, but is worth keeping in mind): some derangements cannot be obtained with your algorithm. In other words, it gives probability zero to some possible derangements, so the resulting distribution is definitely not uniformly random.

One possible solution, as suggested in the comments, would be to use a rejection algorithm:

  • pick a permutation uniformly at random
  • if it hax no fixed points, return it
  • otherwise retry

Asymptotically, the probability of obtaining a derangement is close to 1/e = 0.3679 (as seen in the wikipedia article). Which means that to obtain a derangement you will need to generate an average of e = 2.718 permutations, which is quite costly.

A better way to do that would be to reject at each step of the algorithm. In pseudocode, something like this (assuming the original array contains i at position i, ie a[i]==i):

for (i = 1 to n-1) {
   do {
      j = rand(i, n)   // random integer from i to n inclusive
   } while a[j] != i   // rejection part
   swap a[i] a[j]

The main difference from your algorithm is that we allow j to be equal to i, but only if it does not produce a fixed point. It is slightly longer to execute (due to the rejection part), and demands that you be able to check if an entry is at its original place or not, but it has the advantage that it can produce every possible derangement (uniformly, for that matter).

I am guessing non-rejection algorithms should exist, but I would believe them to be less straight-forward.


My algorithm is actually bad: you still have a chance of ending with the last point unshuffled, and the distribution is not random at all, see the marginal distributions of a simulation: marginal distributions

An algorithm that produces uniformly distributed derangements can be found here, with some context on the problem, thorough explanations and analysis.

Second Edit:

Actually your algorithm is known as Sattolo's algorithm, and is known to produce all cycles with equal probability. So any derangement which is not a cycle but a product of several disjoint cycles cannot be obtained with the algorithm. For example, with four elements, the permutation that exchanges 1 and 2, and 3 and 4 is a derangement but not a cycle.

If you don't mind obtaining only cycles, then Sattolo's algorithm is the way to go, it's actually much faster than any uniform derangement algorithm, since no rejection is needed.

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Are you sure there are some derangements that the OP's algorithm can't generate? I don't see why. I don't know what language that is (Java?), but Math.random() looks like a commonly-seen function that returns uniformly distributed floats in the range [0, 1). Given that, each step through the loop should swap data[i] with one of the values after it, chosen without bias. This should produce an unbiased derangement, no? What does your graphical simulation say? –  Tom Zych Sep 2 '11 at 22:01
Thank you! I just love the word "derangement"; certainly one of the best. mathematical. terms. ever. The fact that I can't generate all the derangements doesn't make any difference to my application, though a nagging voice in my head says, "but you should do it correctly." –  jdeisenberg Sep 2 '11 at 22:33
@Tom: See my latest edit to see why some derangements cannot be obtained. The simulation shows, at position i,j, the probability of entry originally at index i to end up at index j. The first line is fairly uniform, meaning that the first entry has equal chance of ending anywhere besides the first position. But the last line shows that the last entry has a very high chance of ending at the penultimate position, and a slight chance of remaining in place. –  FelixCQ Sep 3 '11 at 15:37
Don't have time to delve into all this right now, but have you considered that when i reaches length - 2, data[i] must be switched with data[i+1], because it may still be the value that was originally there? And indeed, this is what the OP's program does. –  Tom Zych Sep 3 '11 at 16:04
@FelixCQ could you please tell me how you drew the distribution image? I am quite interested. –  peter Apr 27 '12 at 3:32

Your algorithm looks correct. To put it in pseudocode:

for i in [start] to [next-to-last]:
    choose random j in [positions after i]
    swap data[i] with data[j]

Thus, each cell gets data guaranteed to be from another cell.

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In C++:

template <class T> void shuffle(std::vector<T>&arr)
    int size = arr.size();

    for (auto i = 1; i < size; i++)
        int n = rand() % (size - i) + i;
        std::swap(arr[i-1], arr[n]);
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