The following is the most basic way I know of to count transitions in a markov chain and use it to populate a transition matrix:
def increment_counts_in_matrix_from_chain(markov_chain, transition_counts_matrix): for i in xrange(1, len(markov_chain)): old_state = markov_chain[i - 1] new_state = markov_chain[i] transition_counts_matrix[old_state, new_state] += 1
I've tried speeding it up in 3 different ways:
1) Using a sparse matrix one-liner based on this Matlab code:
transition_matrix = full(sparse(markov_chain(1:end-1), markov_chain(2:end), 1))
Which in Numpy/SciPy, looks like this:
def get_sparse_counts_matrix(markov_chain, number_of_states): return coo_matrix((*(len(markov_chain) - 1), (markov_chain[0:-1], markov_chain[1:])), shape=(number_of_states, number_of_states))
And I've tried a couple more Python tweaks, like using zip():
for old_state, new_state in zip(markov_chain[0:-1], markov_chain[1:]): transition_counts_matrix[old_state, new_state] += 1
old_and_new_states_holder = Queue(maxsize=2) old_and_new_states_holder.put(markov_chain) for new_state in markov_chain[1:]: old_and_new_states_holder.put(new_state) old_state = old_and_new_states_holder.get() transition_counts_matrix[old_state, new_state] += 1
But none of these 3 methods sped things up. In fact, everything but the zip() solution was at least 10X slower than my original solution.
Are there any other solutions worth looking into?
Modified solution for building a transition matrix from lots of chains
The best answer to the above question specifically was DSM's. However, for anyone who wants to populate a transition matrix based on a list of millions of markov chains, the quickest way is this:
def fast_increment_transition_counts_from_chain(markov_chain, transition_counts_matrix): flat_coords = numpy.ravel_multi_index((markov_chain[:-1], markov_chain[1:]), transition_counts_matrix.shape) transition_counts_matrix.flat += numpy.bincount(flat_coords, minlength=transition_counts_matrix.size) def get_fake_transitions(markov_chains): fake_transitions =  for i in xrange(1,len(markov_chains)): old_chain = markov_chains[i - 1] new_chain = markov_chains[i] end_of_old = old_chain[-1] beginning_of_new = new_chain fake_transitions.append((end_of_old, beginning_of_new)) return fake_transitions def decrement_fake_transitions(fake_transitions, counts_matrix): for old_state, new_state in fake_transitions: counts_matrix[old_state, new_state] -= 1 def fast_get_transition_counts_matrix(markov_chains, number_of_states): """50% faster than original, but must store 2 additional slice copies of all markov chains in memory at once. You might need to break up the chains into manageable chunks that don't exceed your memory. """ transition_counts_matrix = numpy.zeros([number_of_states, number_of_states]) fake_transitions = get_fake_transitions(markov_chains) markov_chains = list(itertools.chain(*markov_chains)) fast_increment_transition_counts_from_chain(markov_chains, transition_counts_matrix) decrement_fake_transitions(fake_transitions, transition_counts_matrix) return transition_counts_matrix