I am looking to implement the Moran process in Python for a generalized number of individuals per time step. In other words, instead of just having one individual die, and one individual reproduce per time step, I want this to be generalized to N individuals.

The formula for the probability of a given type of individual dying / reproducing in a time step can be found here: http://en.wikipedia.org/wiki/Moran_process#Selection

Essentially, the probability is proportional to the number of individuals of that type and the fitness of that type, which can be arbitrarily large or small.

I want to be able to construct a probability distribution, from which I can sample, that captures the possible outcomes of how many of each types of individual will be chosen.

This process is very similar to sampling from the multivariate hypergeometric distribution (http://en.wikipedia.org/wiki/Hypergeometric_distribution#Multivariate_hypergeometric_distribution).

The reason that hypergeometric is used, instead of just the multinomial distribution, is to make sure that you don't "oversample" a specific type, so the distribution is not replacing things after they are sampled:

See:

This has the same relationship to the multinomial distribution that the hypergeometric distribution has to the binomial distributionâ€”the multinomial distribution is the "with-replacement" distribution and the multivariate hypergeometric is the "without-replacement" distribution.

Now my issue is that in the Moran process, the probabilities are proportional both to the number of individuals, and their respective fitnesses. If I were just sampling the distribution once, it would be easy to specify the probability by multiple the number of individuals by that type's fitness, and then summing over the total. However, with repeated sampling, is there a distribution that captures the "without-replacement" idea that I am looking for, but also can compute weighted probabilities where each k in the multivariate hypergeometric distribution counts is weighted (and then also that weight is subtracted after each sampling)?

If such a distribution doesn't exist, I am likely just to iterate the Moran process multiple times in each time step, as needed, but obviously this is a slightly different outcome than what I am looking for.