There are a number of ways to accomplish what I think you want here, but they depend on a few details.

There are a number of ways to invert a matrix (or, more generally, to solve linear systems). Some examples are Gaussian elimination, Gauss-Jordan elimination, and L/U decomposition. You can use any of these to solve a general linear system `A x = b`

for `x`

; to get the inverse of A, you need to solve `A X = I`

for matrix `X`

(where `I`

is the identity matrix).

The most important detail is: what do you mean by "multiplying bytes"? Your multiplication needs to be part of a finite field -- probably GF(256) in your case -- or you will not be able to invert it. In particular, this means that "multiplying" will not be regular processor-native multiplication; instead, you will either need to do some bit-fiddling, or table lookup (which tables are precomputed by said bit-fiddling). Also, GF(256) "addition" and "subtraction" are really bitwise xor (note, this means they are identical to each other).

Another thing: since you are using finite fields, I don't think you need to worry about pivoting. To explain: if you were using floating point, your linear system solver would need to choose which order to perform its basic steps, in order to keep floating point errors from accumulating exponentially (you would also want to avoid actually computing the inverse matrix, in favor of using the linear system solver for each vector). This choice of ordering is called "pivoting", and most references on linear solvers pay a lot of attention to it.

However, since finite field math is exact, you don't need to worry about that kind of instability -- you can perform the steps of your solver sequentially, and construct an exact inverse matrix. The only thing you need to check is if your matrix is singular: multiplying by a singular matrix loses information, so it can't be inverted, and it won't be a usable encryption matrix.