How do I generate random numbers with a specified bias toward one number. For example, how would I pick between two numbers, 1 and 2, with a 90% bias toward 1. The best I can come up with is...

import random

print random.choice([1, 1, 1, 1, 1, 1, 1, 1, 1, 2])

Is there a better way to do this? The method I showed works in simple examples but eventually I'll have to do more complicated selections with biases that are very specific (such as 37.65% bias) which would require a very long list.

EDIT: I should have added that I'm stuck on numpy 1.6 so I can't use numpy.random.choice.


np.random.choice has a p parameter which you can use to specify the probability of the choices:

np.random.choice([1,2], p=[0.9, 0.1])
  • That is sooo simple and I'd love to use this but I'm stuck on numpy 1.6 (don't ask...) and random.choice is not available. Is there another method?
    – b10hazard
    Aug 26 '14 at 14:01
  • 1
    Okay, I got approval to update to numpy 1.8 so this answer works best. Thanks!
    – b10hazard
    Aug 27 '14 at 13:09

The algorithm used by np.random.choice() is relatively simple to replicate if you only need to draw one item at a time.

import numpy as np

def simple_weighted_choice(choices, weights, prng=np.random):
    running_sum = np.cumsum(weights)
    u = prng.uniform(0.0, running_sum[-1])
    i = np.searchsorted(running_sum, u, side='left')
    return choices[i]
  • I think the exact same approach works for vectorized generation of many items: if you add a size argument to your function and pass that to np.random.uniform, np.searchsorted can handle a multidimensional u array.
    – Jaime
    Aug 26 '14 at 15:45

For random sampling with replacement, the essential code in np.random.choice is

            cdf = p.cumsum()
            cdf /= cdf[-1]
            uniform_samples = self.random_sample(shape)
            idx = cdf.searchsorted(uniform_samples, side='right')

So we can use that in a new function the does the same thing (but without error checking and other niceties):

import numpy as np

def weighted_choice(values, p, size=1):
    values = np.asarray(values)

    cdf = np.asarray(p).cumsum()
    cdf /= cdf[-1]

    uniform_samples = np.random.random_sample(size)
    idx = cdf.searchsorted(uniform_samples, side='right')
    sample = values[idx]

    return sample


In [113]: weighted_choice([1, 2], [0.9, 0.1], 20)
Out[113]: array([1, 1, 1, 1, 1, 2, 1, 1, 1, 2, 1, 2, 1, 1, 1, 1, 1, 1, 1, 1])

In [114]: weighted_choice(['cat', 'dog', 'goldfish'], [0.3, 0.6, 0.1], 15)
array(['cat', 'dog', 'cat', 'dog', 'dog', 'dog', 'dog', 'dog', 'dog',
       'dog', 'dog', 'dog', 'goldfish', 'dog', 'dog'], 

Something like that should do the trick, and working with all floating point probability without creating a intermediate array.

import random
from itertools import accumulate  # for python 3.x

def accumulate(l):  # for python 2.x
    tmp = 0
    for n in l:
        tmp += n
        yield tmp

def random_choice(a, p):
    sums = sum(p)
    accum = accumulate(p)  # made a cumulative list of probability
    accum = [n / sums for n in accum]  # normalize
    rnd = random.random()
    for i, item in enumerate(accum):
        if rnd < item:
            return a[i]

Easy to get is the index in probability table. Make a table for as many weights as you need looking for example like this: prb = [0.5, 0.65, 0.8, 1]

Get index with something like this:

 def get_in_range(prb, pointer):
    """Returns index of matching range in table prb"""
    found = 0
    for p in prb:
        if nr>p:
            found += 1
    return found

Index returned by get_in_range may be used to point in corresponding table of values.

Example usage:

import random
values = [1, 2, 3]
weights = [0.9, 0.99, 1]
result = values[get_in_range(prb, random.random())]

There should be probability of choosing 1 with 95%; 2 with 4% and 3 with 1%

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