Consider a matrix of real values forming base of a cartesian coordinate system. Each column represents a base vector. In the case of a isometric zoom, all base vectors have the same length. Let C(M,n) denote the n-th column vector of matrix M, i.e. C(M,n) = M_n,j, then for a isometric zoom it would be len(C(M,0)) = len(C(M,1)) = len(C(M,…)), where len(v) = sqrt(v·v)

In the case of anisometric scaling the length of the base vectors would differ, which is what you can use to detect this situation.

In computer graphics the matrices you encounter are *homogenous* to allow for a single matrix to represent all possible transformations within the space they represent. Homogenous matrices have N+1 rows and columns, where N is the number of dimensions of the coordinate space represented by them. By convention (at least in all popular computer graphics software) the upper left part (i.e. M_i,j where i and j in 1…N, 1-based index) form the base vectors, while the Nth column and row form the homogenous part.

So in case of OpenGL you'd look at the upper left 3×3 submatrix as coordinate base vectors. And since OpenGL indexes column major order you don't have to reorder what's retrieved from OpenGL.