A hackish way to do it for your purposes is to take the regular inverse, which is already implemented in numpy. Now find the determinant, which is implemented in numpy. Now multiply the regular inverse by the determinant, round to integers, and then multiply everything by the determinant's multiplicative inverse (modulo your modulus). Below, I have code for finding multiplicative inverses using the generalized euclidian algorithm. This is fine as long as rounding errors don't kill you....

A less hackish way is to actually implement gaussian elimination. Here's my code using Gaussian elimination, which I wrote for my own purposes (rounding errors were an issue for me). q is the modulus, which is not necessarily prime

```
def generalizedEuclidianAlgorithm(a, b):
if b > a:
#print a, b
return generalizedEuclidianAlgorithm(b,a);
elif b == 0:
return (1, 0);
else:
#print a,b
(x, y) = generalizedEuclidianAlgorithm(b, a % b);
return (y, x - (a / b) * y)
def inversemodp(a, p):
a = a % p
if (a == 0):
print "a is 0 mod p"
return 0
(x,y) = generalizedEuclidianAlgorithm(p, a % p);
return y % p
def identitymatrix(n):
return [[long(x == y) for x in range(0, n)] for y in range(0, n)]
def inversematrix(matrix, q):
n = len(matrix)
A = np.matrix([[ matrix[j, i] for i in range(0,n)] for j in range(0, n)], dtype = long)
Ainv = np.matrix(identitymatrix(n), dtype = long)
for i in range(0, n):
factor = inversemodp(A[i,i], q)
A[i] = A[i] * factor % q
Ainv[i] = Ainv[i] * factor % q
for j in range(0, n):
if (i != j):
factor = A[j, i]
A[j] = (A[j] - factor * A[i]) % q
Ainv[j] = (Ainv[j] - factor * Ainv[i]) % q
# print A, Ainv
# print i, j, factor
return Ainv
```