# How do I "randomly" select numbers with a specified bias toward a particular number

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? Aug 26 '14 at 14:01
• Okay, I got approval to update to numpy 1.8 so this answer works best. Thanks! 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. 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
``````

Examples:

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

In : weighted_choice(['cat', 'dog', 'goldfish'], [0.3, 0.6, 0.1], 15)
Out:
array(['cat', 'dog', 'cat', 'dog', 'dog', 'dog', 'dog', 'dog', 'dog',
'dog', 'dog', 'dog', 'goldfish', 'dog', 'dog'],
dtype='|S8')
``````

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%