# A weighted version of random.choice

I needed to write a weighted version of random.choice (each element in the list has a different probability for being selected). This is what I came up with:

``````def weightedChoice(choices):
"""Like random.choice, but each element can have a different chance of
being selected.

choices can be any iterable containing iterables with two items each.
Technically, they can have more than two items, the rest will just be
ignored.  The first item is the thing being chosen, the second item is
its weight.  The weights can be any numeric values, what matters is the
relative differences between them.
"""
space = {}
current = 0
for choice, weight in choices:
if weight > 0:
space[current] = choice
current += weight
rand = random.uniform(0, current)
for key in sorted(space.keys() + [current]):
if rand < key:
return choice
choice = space[key]
return None
``````

This function seems overly complex to me, and ugly. I'm hoping everyone here can offer some suggestions on improving it or alternate ways of doing this. Efficiency isn't as important to me as code cleanliness and readability.

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–  nmichaels Sep 9 '10 at 19:07
This question is different, since it's got explicit weights rather than based on the length of the dict keys. –  Ned Batchelder Sep 9 '10 at 19:09
I actually like your solution because it is quite readable and has a feature of traversing the input only once. –  liori Sep 9 '10 at 19:32
possible duplicate of Weighted choice short and simple –  jb. Mar 22 '14 at 13:28

``````def weighted_choice(choices):
total = sum(w for c, w in choices)
r = random.uniform(0, total)
upto = 0
for c, w in choices:
if upto + w > r:
return c
upto += w
assert False, "Shouldn't get here"
``````
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I don't know why I thought I had to sort the weights and go through them in order...this is better. –  Colin Sep 9 '10 at 19:22
You can drop an operation and save a sliver of time by reversing the statements inside the for loop: `upto +=w; if upto > r` –  knite Jul 31 '13 at 8:31
`random.uniform(0, total)` can return total (docs.python.org/2/library/random.html#random.uniform), in that case will be AssertionError –  rsk Oct 20 '13 at 4:43
@knite, Please don't suggest that. Did you even test that? It completely breaks the distribution. Running `weighted_choice([('a',1.0),('b',2.0),('c',3.0)])` with your modification causes b to never get picked... –  Cerin Dec 20 '13 at 22:25
@rsk, You're correct, although that's a very rare occurrence. Changing the `> r` to `>= r` fixes that problem for me. –  Cerin Dec 20 '13 at 22:27
1. Arrange the weights into a cumulative distribution.
2. Use random.random() to pick a random float `0.0 <= x < total`.
3. Search the distribution using bisect.bisect as shown in the example at http://docs.python.org/dev/library/bisect.html#other-examples.
``````from random import random
from bisect import bisect

def weighted_choice(choices):
values, weights = zip(*choices)
total = 0
cum_weights = []
for w in weights:
total += w
cum_weights.append(total)
x = random() * total
i = bisect(cum_weights, x)
return values[i]

>>> weighted_choice([("WHITE",90), ("RED",8), ("GREEN",2)])
'WHITE'
``````

If you need to make more than one choice, split this into two functions, one to build the cumulative weights and another to bisect to a random point.

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This is more efficient than Ned's answer. Basically, instead of doing a linear (O(n)) search through the choices, he's doing a binary search (O(log n)). +1! –  NHDaly Mar 14 '14 at 20:28
tuple index out of range if random() happens to return 1.0 –  Jon Vaughan Jul 17 '14 at 19:54
This still runs in `O(n)` because of the cumulative distribution calculation. –  Lev Levitsky Nov 16 '14 at 10:43

Crude, but may be sufficient:

``````import random
weighted_choice = lambda s : random.choice(sum(([v]*wt for v,wt in s),[]))
``````

Does it work?

``````# define choices and relative weights
choices = [("WHITE",90), ("RED",8), ("GREEN",2)]

# initialize tally dict
tally = dict.fromkeys(choices, 0)

# tally up 1000 weighted choices
for i in xrange(1000):
tally[weighted_choice(choices)] += 1

print tally.items()
``````

Prints:

``````[('WHITE', 904), ('GREEN', 22), ('RED', 74)]
``````

Assumes that all weights are integers. They don't have to add up to 100, I just did that to make the test results easier to interpret. (If weights are floating point numbers, multiply them all by 10 repeatedly until all weights >= 1.)

``````weights = [.6, .2, .001, .199]
while any(w < 1.0 for w in weights):
weights = [w*10 for w in weights]
weights = map(int, weights)
``````
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Nice, I'm not sure I can assume all weights are integers, though. –  Colin Sep 9 '10 at 19:21
Seems like your objects would be duplicated in this example. That'd be inefficient (and so is the function for converting weights to integers). Nevertheless, this solution is a good one-liner if the integer weights are small. –  wei2912 Dec 22 '13 at 7:36

If you have a weighted dictionary instead of a list you can write this

``````items = { "a": 10, "b": 5, "c": 1 }
random.choice([k for k in items for dummy in range(items[k])])
``````

Note that `[k for k in items for dummy in range(items[k])]` produces this list `['a', 'a', 'a', 'a', 'a', 'a', 'a', 'a', 'a', 'a', 'c', 'b', 'b', 'b', 'b', 'b']`

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This works for small total population values, but not for large datasets (e.g. US population by state would end up creating a working list with 300 million items in it). –  Ryan Jul 13 '12 at 0:31

If you don't mind using numpy, you can use numpy.random.choice.

For example:

``````import numpy

items  = [["item1", 0.2], ["item2", 0.3], ["item3", 0.45], ["item4", 0.05]
elems = [i[0] for i in items]
probs = [i[1] for i in items]

trials = 1000
results = [0] * len(items)
for i in range(trials):
res = numpy.random.choice(items, p=probs)  #This is where the item is selected!
results[items.index(res)] += 1
results = [r / float(trials) for r in results]
print "item\texpected\tactual"
for i in range(len(probs)):
print "%s\t%0.4f\t%0.4f" % (items[i], probs[i], results[i])
``````

If you know how many selections you need to make in advance, you can do it without a loop like this:

``````numpy.random.choice(items, trials, p=probs)
``````
-

I'd require the sum of choices is 1, but this works anyway

``````def weightedChoice(choices):
# Safety check, you can remove it
for c,w in choices:
assert w >= 0

tmp = random.uniform(0, sum(c for c,w in choices))
for choice,weight in choices:
if tmp < weight:
return choice
else:
tmp -= weight
raise ValueError('Negative values in input')
``````
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Out of curiosity, is there a reason you prefer random.random() * total instead of random.uniform(0, total)? –  Colin Sep 9 '10 at 19:23
@Colin No, not at all. Updated. –  phihag Sep 9 '10 at 19:27
You traverse three times over iterable. This might be not supported by iterable. –  liori Sep 9 '10 at 19:30
I think it is actually possible. utopia.duth.gr/~pefraimi/research/data/2007EncOfAlg.pdf It is actually pretty simple... But who cares... –  liori Sep 9 '10 at 20:56
@liori I do care, and you're right: weightedChoice can be computed with one iterator pass only. However, this seems to require more than 1 call to the pseudo random generator. –  phihag Sep 10 '10 at 14:04

Since version 1.7.0, NumPy has a `choice` function that supports probability distributions.

``````from numpy.random import choice
draw = choice(list_of_candidates, number_of_items_to_pick, p=probability_distribution)
``````

Note that `probability_distribution` is a sequence in the same order of `list_of_candidates`. You can also use the keyword `replace=False` to change the behavior so that drawn items are not replaced.

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``````import numpy as np
w=np.array([ 0.4,  0.8,  1.6,  0.8,  0.4])
np.random.choice(w, p=w/sum(w))
``````
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I looked the pointed other thread and came up with this variation in my coding style, this returns the index of choice for purpose of tallying, but it is simple to return the string ( commented return alternative):

``````import random
import bisect

try:
range = xrange
except:
pass

def weighted_choice(choices):
total, cumulative = 0, []
for c,w in choices:
total += w
cumulative.append((total, c))
r = random.uniform(0, total)
# return index
return bisect.bisect(cumulative, (r,))
# return item string
#return choices[bisect.bisect(cumulative, (r,))][0]

# define choices and relative weights
choices = [("WHITE",90), ("RED",8), ("GREEN",2)]

tally = [0 for item in choices]

n = 100000
# tally up n weighted choices
for i in range(n):
tally[weighted_choice(choices)] += 1

print([t/sum(tally)*100 for t in tally])
``````
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A general solution:

``````import random
def weighted_choice(choices, weights):
total = sum(weights)
treshold = random.uniform(0, total)
for k, weight in enumerate(weights):
total -= weight
if total < treshold:
return choices[k]
``````
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Here is another version of weighted_choice that uses numpy. Pass in the weights vector and it will return an array of 0's containing a 1 indicating which bin was chosen. The code defaults to just making a single draw but you can pass in the number of draws to be made and the counts per bin drawn will be returned.

If the weights vector does not sum to 1, it will be normalized so that it does.

``````import numpy as np

def weighted_choice(weights, n=1):
if np.sum(weights)!=1:
weights = weights/np.sum(weights)

draws = np.random.random_sample(size=n)

weights = np.cumsum(weights)
weights = np.insert(weights,0,0.0)

counts = np.histogram(draws, bins=weights)
return(counts[0])
``````
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I'm probably too late to contribute anything useful, but here's a simple, short, and very efficient snippet:

``````def choose_index(probabilies):
cmf = probabilies[0]
choice = random.random()
for k in xrange(len(probabilies)):
if choice <= cmf:
return k
else:
cmf += probabilies[k+1]
``````

No need to sort your probabilities or create a vector with your cmf, and it terminates once it finds its choice. Memory: O(1), time: O(N), with average running time ~ N/2.

If you have weights, simply add one line:

``````def choose_index(weights):
probabilities = weights / sum(weights)
cmf = probabilies[0]
choice = random.random()
for k in xrange(len(probabilies)):
if choice <= cmf:
return k
else:
cmf += probabilies[k+1]
``````
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