# How to generate random permutations with CUDA

What parallel algorithms could I use to generate random permutations from a given set? Especially proposals or links to papers suitable for CUDA would be helpful.

A sequential version of this would be the Fisher-Yates shuffle.

Example:

Let S={1, 2, ..., 7} be the set of source indices. The goal is to generate n random permutations in parallel. Each of the n permutations contains each of the source indices exactly once, e.g. {7, 6, ..., 1}.

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Make X thread-local random generators and run Fisher-Yates on each...? –  Kos Sep 29 '12 at 15:41
This would definitely work, but also present a worst case for an implementation with CUDA due to the SIMD execution model. –  diver_182 Sep 29 '12 at 17:04
Can you explain how would that be worst case? Do you mean that different seeds would make all threads follow different control paths? Why do you think so? F-Y shuffle is a simple loop –  Kos Sep 29 '12 at 17:08
How about using a `thrust::permutation_iterator`? It does however, require you to write your own reindexing scheme. –  Recker Oct 6 '12 at 7:45

Fisher-Yates shuffle could be parallelized. For example, 4 concurrent workers need only 3 iterations to shuffle vector of 8 elements. On first iteration they swap 0<->1, 2<->3, 4<->5, 6<->7; on second iteration 0<->2, 1<->3, 4<->5, 6<->7; and on last iteration 0<->4, 1<->5, 2<->6, 3<->7.

This could be easily implemented as CUDA `__device__` code (inspired by standard min/max reduction):

``````const int id  = threadIdx.x;
__shared__ int perm_shared[2 * BLOCK_SIZE];
perm_shared[2 * id]     = 2 * id;
perm_shared[2 * id + 1] = 2 * id + 1;

unsigned int shift = 1;
unsigned int pos = id * 2;
while(shift <= BLOCK_SIZE)
{
if (curand(&curand_state) & 1) swap(perm_shared, pos, pos + shift);
shift = shift << 1;
pos = (pos & ~shift) | ((pos & shift) >> 1);
}
``````

Here the curand initialization code is omitted, and method `swap(int *p, int i, int j)` exchanges values `p[i]` and `p[j]`.

Note that the code above has the following assumptions:

1. The length of permutation is 2 * BLOCK_SIZE, where BLOCK_SIZE is a power of 2.
2. 2 * BLOCK_SIZE integers fit into `__shared__` memory of CUDA device
3. BLOCK_SIZE is a valid size of CUDA block (usually something between 32 and 512)

To generate more than one permutation I would suggest to utilize different CUDA blocks. If the goal is to make permutation of 7 elements (as it was mentioned in the original question) then I believe it will be faster to do it in single thread.

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If the length of s = s_L, a very crude way of doing this could be implemented in thrust:

First, create a vector val of length s_L x n that repeats s n times.

Create a vector val_keys associate n unique keys repeated s_L times with each element of val, e.g.,

``````  val = {1,2,...,7,1,2,...,7,....,1,2,...7}
val_keys = {0,0,0,0,0,0,0,1,1,1,1,1,1,2,2,2,...., n,n,n}
``````

Now the fun part. create a vector of length s_L x n uniformly distributed random variables

``````  U  = {0.24, 0.1, .... , 0.83}
``````

then you can do zip iterator over val,val_keys and sort them according to U:

http://choorucode.wordpress.com/2011/04/04/thrust-zip_iterator/

both val, val_keys will be all over the place, so you have to put them back together again using thrust::stable_sort_by_key() to make sure that if val[i] and val[j] both belong to key[k] and val[i] precedes val[j] following the random sort, then in the final version val[i] should still precede val[j]. If all goes according to plan, val_keys should look just as before, but val should reflect the shuffling.

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