I'm trying to find a wizard's vectorization for the following iterative computation (please look at the later edit):
% A is a logical matrix of size NxN B = false(size(A)); for k1 = 1:N, for k2 = 1:N, for k3 = 1:N B(k1,k2) = A(k1,k2) && ~A(k1,k3) && ~A(k3,k2); end; end; end;
I must stress out that solutions using
cellfun) are not feasible since they are slow, and I'm looking for performance improvement, not expressiveness enhancement.
Also, I'd like to avoid the obvious:
B = A & logical((1-A)^2)
because the memory footprint for computing this is 17 times the original's (and I work with big matrices in an eventually fragmented memory resource).
A positive answer (i.e. a solution) or a negative one (i.e. an explanation why this cannot work) are both greatly appreciated.
Thanks to H.Muster I became aware of a bug in my initial code. The iteration to be vectorized is actually:
% A is a logical matrix of size NxN B = A; for k1 = 1:N, for k2 = 1:N, for k3 = 1:N B(k1,k2) = B(k1,k2) && ~(A(k1,k3) && A(k3,k2)); end; end; end;
A faster iteration is welcome also (I'm studying this right now, if I find something I will post as comment/edit).
Even later edit
For those who are interested in the purpose of the code, it's supposed to compute the transitive reduction
B of a relationship graph
A(k1,k2)=true means that
k1 "relates to"
k2 (the reciprocal is not true).
k1 "relates to"
k2 and there is no other element
k3 "between" them, i.e.
k2 is the "next" after
k1. One must note that, if defined like this, an element may benefit of several "next" elements, not only one. The transitive reduction helps creating "non-deterministic iterators" (next is a set, not a single element) into set structures "induced" by a non-symmetric dyadic relation.