# Julia sparse matrix with random 1's

So I have a size N in julia and I need an NxN sparse matrix with N ones in it, in random places. What would be the best way to go about this?

At first I thought about randomly generating indexes and then setting those numbers to 1 in a sparse matrix but I recently found the sprand functions however I don't understand how to use them correctly or apply them to my problem. I tried using it with my limited understanding and it keeps generating error messages. Help is of course always greatly appreciated :)

• `sprand`....... Jan 13 '18 at 19:15
• `sparse(rand(1:N, N), rand(1:N, N), ones(N), N, N)` will do it Jan 14 '18 at 14:55
• this does not always work as you can get some (i,j) repeated several times thus getting a matrix with less nonzero elements than expected. Jan 14 '18 at 18:14
• True. Added an answer which is more complex but fixes the problem. Jan 15 '18 at 10:36

Inspired by @DanGetz comment above, the following solution is a one-line function using `randperm`. I deleted the original answer as it was not very helpful.

``````sparseN(N) = sparse(randperm(N), randperm(N), ones(N), N, N)
``````

This is also incredibly fast:

``````@time sparseN(10_000);
0.000558 seconds (30 allocations: 782.563 KiB)
``````
• Does this guarantee no re-use of the same i,j tuple? Jan 17 '18 at 10:56
• Yes, it will never repeat any indices, since `randperm` permutes `1:N` unique values. Jan 17 '18 at 14:08

A sparse matrix of dimension (N rows)x(M columns) has at most NxM components that can be indexed using the K=[0,N*M) integer set. For any k in K you can retrieve element indices (i,j) thanks to a Euclidean division k = i + j*N (here column major layout).

To randomly sample n elements of K (without repetition), you can use Knuth algorithm "Algorithm S (Selection sampling technique)" 3.4.2, in its book Vol2., seminumerical-Algorithms

In Julia:

``````function random_select(n::Int64,K::Int64)
@assert 0<=n<=K

sample=Vector{Int64}(n)
t=Int64(0)
m=Int64(0)

while m<n
if (K-t)*rand()>=n-m
t+=1
else
m+=1
sample[m]=t
t+=1
end
end
sample
end
``````

The next part simply retrieves the I,J indices to create the sparse matrix from its coordinate form:

``````function create_sparseMatrix(n::Int64,N::Int64,M::Int64)
@assert (0<=N)&&(0<=M)
@assert 0<=n<=N*M

nonZero = random_select(n,N*M)

# column major: k=i+j*N
I = map(k->mod(k,N),nonZero)
J = map(k->div(k,N),nonZero)

sparse(I+1,J+1,ones(n),N,M)
end
``````

Usage example: a 4x5 sparse matrix with 3 nonzero (=1.0) at random positions:

``````julia> create_sparseMatrix(3,4,5)
4×5 SparseMatrixCSC{Float64,Int64} with 3 stored entries:
[4, 1]  =  1.0
[3, 2]  =  1.0
[3, 3]  =  1.0
``````

Border case tests:

``````julia> create_sparseMatrix(0,4,5)
4×5 SparseMatrixCSC{Float64,Int64} with 0 stored entries

julia> create_sparseMatrix(4*5,4,5)
4×5 SparseMatrixCSC{Float64,Int64} with 20 stored entries:
[1, 1]  =  1.0
[2, 1]  =  1.0
[3, 1]  =  1.0
[4, 1]  =  1.0
⋮
[4, 4]  =  1.0
[1, 5]  =  1.0
[2, 5]  =  1.0
[3, 5]  =  1.0
[4, 5]  =  1.0
``````

Insisting on a one-line-ish solution:

``````using StatsBase
sparseones(N,M,K) = sparse(
(x->(first.(x).+1,last.(x).+1))(divrem.(sample(0:N*M-1,K,replace=false),M))...,
ones(K),N,M
)
``````

Giving:

``````julia> sparseones(3,4,5)
3×4 SparseMatrixCSC{Float64,Int64} with 5 stored entries:
[1, 1]  =  1.0
[2, 1]  =  1.0
[3, 3]  =  1.0
[2, 4]  =  1.0
[3, 4]  =  1.0
``````

This method is essentially the same as the earlier answer with the advantage of re-using existing `sample` and being much shorter. It is even faster on larger matrices.