# undecomposability of a non-negative integer matrix

I am looking for an algorithm to test whether a non-negative dxd integer matrix is undecomposable. I call a matrix undecomposable if it can not be written as a product of two non-negative dxd integer matrices none of them being a permutation matrix (ie not invertible in the semiring of non-negative integer matrices SL_d(N)). I am mostly interested in the case of 3x3 matrices with determinant 1. Note that the case of 1x1 matrices correspond to ask wether a positive integer is prime. For the case of 2x2 matrices with determinant 1 it is well known that the only non-decomposable matrices are the permutation matrices and the elementary matrices (this is because the elementary matrices generate the whole SL_2(N)). There are infinitely many known examples of undecomposable matrices in SL_3(N) (J. Rivat "Undecomposable matrices in dimension 3" appendix in Pytheas Fogg "Substitutions in Dynamics, Arithmetics and Combinatorics", Springer LNM).

There is a naive algorithm which consists at looking at a more general factorisation of the form BC = A with B a d x k matrix and C a k x d matrix. That way we may start a recursive construction. We fill the first column of B by B0 and the first line of C by C0 in such way that B0 * C0 <= A (here I mean all coefficients are smaller). Then it is enough to find B' and C' of size respectively d x (k-1) and (k-1) x d such that B' * C' = A - B0*C0. This algorithm is relatively slow!

The equations associated to the problem are quadratic with 2 d^2 variables (d^2 for A and d^2 for B) and I want to solve them with non-negative integers. As the equations are of very special form, I guess that there might be some better way to solve them or at least to make the recursive construction more efficient.

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Can you formalize your question a bit more? For a given matrix M you want to know if there exist matrices A and B such that M = A x B ? There is always a trivial solution A = Identity, B = M, so NO matrix is indecomposable... –  catchmeifyoutry Jul 13 '13 at 12:08
@catchmeifyoutry Right! I mean non-trivial solution (as you would do for integer factorization). Thanks. –  V. Delecroix Jul 13 '13 at 12:12
How would you define non-trivial? Does that mean that neither A or B can be diagonal? –  Marc Claesen Jul 13 '13 at 12:14
For `d > 1`, you can always write `M = P*(P^(-1)*M)` where `P` is a nontrivial permutation matrix, a matrix with exactly one `1` in each row and each column, `0` everywhere else. The inverse of a permutation matrix is again a permutation matrix, so, if I didn't misunderstand your requirements, the only indecomposable ones would be 1×1 prime matrices. You might want to exclude permutation matrices too. –  Daniel Fischer Jul 13 '13 at 16:04
I recommend you post this on mathoverflow. Also, make it clear whether you want a factorization if it exists, or you just want a yes/no answer whether the matrix is indecomposable. For 1x1, primality testing can be done in polynomial time (using some somewhat heavy number theory, hence why yours is arguably a math question), but actually producing a factorization of a non-prime number is suspected to be hard (either NP-complete, or somewhere between NP-complete and P). Also if you are willing to assume a bound on the entries of your matrix (to make things faster), make that known too. –  user2566092 Jul 14 '13 at 1:10

ok i try to write the problem as i see it:

``````M = A x B
``````
• M known non negative integer input matrix NxN
• A,B unknown output decomposition of M, non unit, non negative integer

multiplication of matrixes:

``````M[i][j] = sum(k=0,1,...,N-1)A[i][k]*B[k][j]
``````

ok now let me write an 3x3 example for clarity:

``````M[3][3]=A*B

i  j    i  k    k  j    i  k    k  j    i  k    k  j
M[0][0]=A[0][0]*B[0][0]+A[0][1]*B[1][0]+A[0][2]*B[2][0]
M[0][1]=A[0][0]*B[0][1]+A[0][1]*B[1][1]+A[0][2]*B[2][1]
M[0][2]=A[0][0]*B[0][2]+A[0][1]*B[1][2]+A[0][2]*B[2][2]
M[1][0]=A[1][0]*B[0][0]+A[1][1]*B[1][0]+A[1][2]*B[2][0]
M[1][1]=A[1][0]*B[0][1]+A[1][1]*B[1][1]+A[1][2]*B[2][1]
M[1][2]=A[1][0]*B[0][2]+A[1][1]*B[1][2]+A[1][2]*B[2][2]
M[2][0]=A[2][0]*B[0][0]+A[2][1]*B[1][0]+A[2][2]*B[2][0]
M[2][1]=A[2][0]*B[0][1]+A[2][1]*B[1][1]+A[2][2]*B[2][1]
M[2][2]=A[2][0]*B[0][2]+A[2][1]*B[1][2]+A[2][2]*B[2][2]
// usage of B[i][j]
M[0][0]=A[0][0]*B[0][0]+...
M[1][0]=A[1][0]*B[0][0]+...
M[2][0]=A[2][0]*B[0][0]+...
M[?][j]=A[?][i]*B[i][j]+...
// usage of A[i][j]
M[0][0]=A[0][0]*B[0][0]+...
M[0][1]=A[0][0]*B[0][1]+...
M[0][2]=A[0][0]*B[0][2]+...
M[i][?]=A[i][j]*B[j][?]+...
``````

When you look closer then the solution is very simple. find all:

``````A[i][j]=GCD(M[i][0],...,M[i][N-1])
``````

then derive B either from M,A or as B=M*inverse(A)

M is decomposable if there is at least single A[i][j] > 1

also you can get B as GCD and derivate A from M,B,....

thats all , hope it helps...

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