# Generate multiple sequences of numbers with unique values at each index

I have a row with numbers `1:n`. I'm looking to add a second row also with the numbers `1:n` but these should be in a random order while satisfying the following:

1. No positions have the same number in both rows
2. No combination of numbers occurs twice

For example, in the following

``````Row 1:  1  2  3  4  5  6  7 ...
Row 2:  3  6  15 8  13 12 7 ...
``````

the number 7 occurs at the same position in both rows 1 and 2 (namely position 7; thereby not satisfying rule 1)

while in the following

``````Row 1:  1  2  3  4  5  6  7 ...
Row 2:  3  7  15 8  13 12 2 ...
``````

the combination of 2+7 appears twice (in positions 2 and 7; thereby not satisfying rule 2).

It would perhaps be possible – but unnecessarily time-consuming – to do this by hand (at least up until a reasonable number), but there must be quite an elegant solution for this in MATLAB.

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Given say, 10 people, would you be happy if three of them were in a cycle separate from the rest? e.g. `1->2` `2->3`, `3->1`. If you would prefer to ban any such divisions in the group, then I've described a simple solution in my answer. –  Aaron McDaid Jan 13 '12 at 0:24

This is fairly straightforward. Create a random permutation of the nodes, but interpret the list as follows: Interpret it as a random walk around the nodes, and if node 'b' appears after node 'a', it means that node 'b' appears below node 'a' in the lists:

So if your initial random permutation is

``````3 2 5 1 4
``````

Then the walk in this case is `3 -> 2 -> 5 -> 1 -> 4` and you creates the rows as follows:

``````Row 1:  1 2 3 4 5
Row 2:  4 5 2 3 1
``````

This random walk will satisfy both conditions.

But do you wish to allow more than one cycle in your network? I know you don't want two people to have each other's hat. But what about 7 people, where 3 of them have each other's hats and the other 4 have each other's hats? Is this acceptable and/or desirable?

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In hindsight: it took me a bit longer to understand what you meant but theoretically this seems to be the most elegant solution, as it doesn't require any looping ("trial and error")! –  user1092247 Jan 13 '12 at 18:38
@user1092247, No problem, I had to edit my answer a little to make it more readable. Feel free to suggest any rewording. –  Aaron McDaid Jan 13 '12 at 18:49

This problem is called a derangment of a permutation.
Use the function randperm, in order to find a random permutation of your data.

``````x = [1  2  3  4  5  6  7];
y = randperm(x);
``````

Then, you can check that the sequence is legal. If not, do it again and again..
You have a probability of about 0.3 each time to succeed, which means that you need roughly 10/3 times to try until you find it. Therefore you will find the answer really quickly.

Alternatively, you can use this algorithm to create a random derangment.

Edit

If you want to have only cycles of size > 2, this is a generalization of the problem. In it is written that the probability in that case is smaller, but big enough to find it in a fixed amount of steps. So the same approach is still valid.

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I think it's a partial derangement. To extend the analogy in the PDF document you linked to: while no gentleman should be getting back their own hat (derangement), there should also be no two gentleman that have each other's hat (rule 2, see my edit). Perhaps one can create in matlab a script that compares a randomly generated sequence of '1:n' for these two rules until it finds one that satisfies both? –  user1092247 Jan 12 '12 at 15:04
@user1092247, I have updated my answer. Welcome to SO. If you liked my answer, don't forget to upvote and accept. –  Andrey Jan 12 '12 at 15:17
Whoever downvoted, I would love to hear what is wrong. –  Andrey Jan 13 '12 at 16:47

Andrey has already pointed you to `randperm` and the rejection-sampling-like approach. After generating a permutation `p`, an easy way to check whether it has fixed point is `any(p==1:n)`. An easy way to check whether it contains cycles of length 2 is `any(p(p)==1:n)`.

So this gets permutations `p` of `1:n` fulfilling your requirements:

``````p=[];
while (isempty(p))
p=randperm(n);
if any(p==1:n), p=[];
elseif any(p(p)==1:n), p=[];
end
end
``````

Surrounding this with a `for` loop and for each counting the iterations of the `while` loop, it seems that one needs to generate on average `4.5` permutations for every "valid" one (and `6.2` if cycles of length three are not allowed, either). Very interesting.

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This is a great piece of code! The solution satisfying the second condition (using "p(p)") works well (even though it indeed requires "trial and error"-looping). Thanks! –  user1092247 Jan 13 '12 at 18:43