The answers so far are using/emulating mutable data-types, but what does a functional approach look like?

To see, let's decompose the problem into some functional components:

Gaussian elimination involves a sequence of row operations, so it is useful first to define a function taking 2 rows and scaling factors, and returning the resultant row operation result.

The row operations we want should eliminate a variable (column) from a particular row, so lets define a function which takes a pair of rows and a column index and uses the previously defined row operation to return the modified row with that column entry zero.

Then we define two functions, one to convert a matrix into triangular form, and another to back-substitute a triangular matrix to the diagonal form (using the previously defined functions) by eliminating each column in turn. We could iterate or recurse over the columns, and the matrix could be defined as a list, vector or array of lists, vectors or arrays. The input is not changed, but a modified matrix is returned, so we can finally do:

let out_matrix = to_diagonal (to_triangular in_matrix);

What makes it functional is not whether the data-types (array or list) are mutable, but how they they are used. This approach may not be particularly 'clever' or be the most efficient way to do Gaussian eliminations in OCaml, but using pure functions lets you express the algorithm cleanly.