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Suppose that I have an n-sided loaded die where each side k has some probability pk of coming up when I roll it. I'm curious if there is good algorithm for storing this information statically (i.e. for a fixed set of probabilities) so that I can efficiently simulate a random roll of the die.

Currently, I have an O(lg n) solution for this problem. The idea is to store a table of the cumulative probability of the first k sides for all k, them to generate a random real number in the range [0, 1) and perform a binary search over the table to get the largest index whose cumulative value is no greater than the chosen value. I rather like this solution, but it seems odd that the runtime doesn't take the probabilities into account. In particular, in the extremal cases of one side always coming up or the values being uniformly distributed, it's possible to generate the result of the roll in O(1) using a naive approach, though my solution will still take logarithmicallh many steps.

Does anyone have any suggestions for how to solve this problem in a way that is somehow "adaptive" in it's runtime?

EDIT: Based on the answers to this question, I have written up an article describing many approaches to this problem, along with their analyses. It looks like Vose's implementation of the alias method gives Θ(n) preprocessing time and O(1) time per die roll, which is truly impressive. Hopefully this is a useful addition to the information contained in the answers!

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It's reasonable that there exists a O(1) solution for each specific case. – Tim Feb 17 '11 at 10:37
up vote 96 down vote accepted

You are looking for the alias method which provides a O(1) method for generating a fixed discrete probability distribution (assuming you can access entries in an array of length n in constant time) with a one-time O(n) set-up. You can find it documented in chapter 3 (PDF) of "Non-Uniform Random Variate Generation" by Luc Devroye.

The idea is to take your array of probabilities pk and produce three new n-element arrays, qk, ak, and bk. Each qk is a probability between 0 and 1, and each ak and bk is an integer between 1 and n.

We generate random numbers between 1 and n by generating two random numbers, r and s, between 0 and 1. Let i = floor(r*N)+1. If qi < s then return ai else return bi. The work in the alias method is in figuring out how to produce qk, ak and bk.

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+1: For a very nice list of methods (and actually pointing to an O(1) time method). – Aryabhatta Feb 17 '11 at 19:48
For such a useful algorithm, the Alias Method is surprisingly not very well-known. – mhum Feb 18 '11 at 3:21
For the record: I published a little C library for random sampling using the alias method apps.jcns.fz-juelich.de/ransampl. – Joachim Wuttke Aug 15 '13 at 16:52

Use a balanced binary search tree (or binary search in an array) and get O(log n) complexity. Have one node for each die result and have the keys be the interval that will trigger that result.

function get_result(node, seed):
    if seed < node.interval.start:
        return get_result(node.left_child, seed)
    else if seed < node.interval.end:
        // start <= seed < end
        return node.result
        return get_result(node.right_child, seed)

The good thing about this solution is that is very simple to implement but still has good complexity.

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I'm thinking of granulating your table.

Instead of having a table with the cumulative for each die value, you could create an integer array of length xN, where x is ideally a high number to increase accuracy of the probability.

Populate this array using the index (normalized by xN) as the cumulative value and, in each 'slot' in the array, store the would-be dice roll if this index comes up.

Maybe I could explain easier with an example:

Using three dice: P(1) = 0.2, P(2) = 0.5, P(3) = 0.3

Create an array, in this case I will choose a simple length, say 10. (that is, x = 3.33333)

arr[0] = 1,
arr[1] = 1,
arr[2] = 2,
arr[3] = 2,
arr[4] = 2,
arr[5] = 2,
arr[6] = 2,
arr[7] = 3,
arr[8] = 3,
arr[9] = 3

Then to get the probability, just randomize a number between 0 and 10 and simply access that index.

This method might loose accuracy, but increase x and accuracy will be sufficient.

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For full accuracy you can do the array lookup as a first step, and for array intervals that correspond to multiple sides do a search there. – aaz Feb 17 '11 at 17:06

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