# Get X unique numbers from a set

What is the most elegant way to grab unique random numbers I ponder?

At the moment I need random unique numbers, I check to see if it's not unique by using a while loop to see if I've used the random number before.

So It looks like:

``````int n = getRandomNumber % [Array Size];

for each ( Previously used n in list)
Check if I've used n before, if I have...try again.
``````

There are many ways to solve this linear O(n/2) problem, I just wonder if there is a elegant way to solve it. Trying to think back to MATH115 Discrete mathematics and remember if the old lecturer covered anything to do with a seemingly trivial problem.

I can't think at the moment, so maybe once I have some caffeine my brain will suss it with the heightened IQ induced from the Coffee.

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possible duplicate of Five unique, random numbers from a subset –  Aryabhatta Jul 10 '10 at 14:09

grab unique random numbers I ponder?

1. Make an array of N unique elements (integers in range 0..N-1, for example), store N as arraySize and initialArraySize (arraySize = N; initialArraySize = N)
2. When random number is requested:
2.1 if arraySize is zero, then arraySize = initialArraySize
2.1 Generate index = getRandomNuber()%arraySize
2.3 result = array[index]. Do not return result yet.
2.2 swap array[index] with array[arraySize-1]. Swap means "exchange" c = array[index]; array[index] = array[arraySize-1]; array[arraySize-1] = c
2.3 decrease arraySize by 1.
2.4 return result.

You'll get a list of random numbers that won't repeat until you run out of unique values. O(1) complexity.

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If you want k random integers drawn without replacement (to get unique numbers) from the set {1, ..., n}, what you want is the first k elements in a random permutation of [n]. The most elegant way to generate such a random permutation is by using the Knuth shuffle. See here: http://en.wikipedia.org/wiki/Knuth_shuffle

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This will be practical only for a sufficiently small `n`. If `n` >= 2^32-1, for example, it would be impractical. –  codekaizen Jul 10 '10 at 6:54
@codekaizen: I surmise from the OPs post that n is the size of an array, so this should be practical in that case. –  GregS Jul 10 '10 at 17:53
@GregS: yes, in that case, it's true. The way I had read the question was that he wanted to generate sequences of arbitrary length. –  codekaizen Jul 10 '10 at 18:51

An n-bit Maximal Period Linear Shift Feedback Register (LFSR) will cycle through all of its (2^n -1) internal states before an internal state is repeated. A LFSR is a Maximal Period LFSR if and only if the polynomial formed from a tap sequence plus 1 is a primitive polynomial mod 2.

Thus, an n-bit Maximal Period LFSR will provide you with a sequence of (2^n - 1) unique random numbers, each one of them is n-bit long.

A LFSR is very elegant.

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The sequence won't, of course, be random... –  Aaron Jul 10 '10 at 4:04
It would be pseudo-random, of course, and completely pre-determined. Anything which is generated using an algorithm, and not involving a special kind of hardware, would be PRNG. For a TRNG you must utilize some physical phenomenon which is considered random. –  M.A. Hanin Jul 10 '10 at 9:45
It also won't solve the OPs problem, for which there is no reason to suspect an array length of 2^n - 1. –  GregS Jul 10 '10 at 17:50