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I have a file with some probabilities for different values e.g.:

1 0.1
2 0.05
3 0.05
4 0.2
5 0.4
6 0.2

I would like to generate random numbers using this distribution. Does an existing module that handles this exist? It's fairly simple to code on your own (build the cumulative density function, generate a random value [0,1] and pick the corresponding value) but it seems like this should be a common problem and probably someone has created a function/module for it.

I need this because I want to generate a list of birthdays (which do not follow any distribution in the standard random module).

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2  
Other than random.choice()? You build the master list with the proper number of occurrences and choose one. This is a duplicate question, of course. – S.Lott Nov 24 '10 at 11:03
1  
@S.Lott isn't that very memory intensive for big differences in the distribution? – Lucas Moeskops Nov 24 '10 at 11:05
1  
@S.Lott: Your choice method would probably be fine for small numbers of occurrences but I'd rather avoid creating huge lists when it is not necessary. – pafcu Nov 24 '10 at 11:10
1  
@Lucasmus: define "big". @pafcu: define "huge". This will work delightfully well until you fill up all of memory with the distribution table. Will you really have billions of choices? Really? For any practical simulation, a few thousand values in a choice table essentially nothing. – S.Lott Nov 24 '10 at 11:18
3  
@S.Lott: OK, about 10000*365 = 3650000 = 3.6 million elements. I'm not sure about the memory usage in Python, but it's at least 3.6M*4B =14.4MB. Not a huge amount, but not something you should ignore either when there is an equally simple method that does not require the extra memory. – pafcu Nov 24 '10 at 11:25

11 Answers 11

up vote 25 down vote accepted

scipy.stats.rv_discrete might be what you want. You can supply your probabilities via the values parameter. You can then use the rvs() method of the distribution object to generate random numbers.

As pointed out by Eugene Pakhomov in the comments, you can also pass a p keyword parameter to numpy.random.choice(), e.g.

numpy.random.choice(numpy.arange(1, 7), p=[0.1, 0.05, 0.05, 0.2, 0.4, 0.2])
share|improve this answer
    
On my machine numpy.random.choice() is almost 20 times faster. – Eugene Pakhomov Jun 18 at 6:26
    
@EugenePakhomov I don't quite understand your comment. So a function doing something completely different is faster than the one I suggested. My recommendation would still be to use the function that does what you want rather than a function that does something else, even if the function that does something else is faster. – Sven Marnach Jun 19 at 10:58
1  
it does exactly the same w.r.t. to the original question. E.g.: numpy.random.choice(numpy.arange(1, 7), p=[0.1, 0.05, 0.05, 0.2, 0.4, 0.2]) – Eugene Pakhomov Jun 20 at 12:17
1  
@EugenePakhomov That's nice, I didn't know that. I can see there is an answer mentioning this further, but it doesn't contain any example code and hasn't a lot of upvotes. I'll add a comment to this answer for better visibility. – Sven Marnach Jun 20 at 15:40

An advantage to generating the list using CDF is that you can use binary search. While you need O(n) time and space for preprocessing, you can get k numbers in O(k log n). Since normal Python lists are inefficient, you can use array module.

If you insist on constant space, you can do the following; O(n) time, O(1) space.

def random_distr(l):
    r = random.uniform(0, 1)
    s = 0
    for item, prob in l:
        s += prob
        if s >= r:
            return item
    return item  # Might occur because of floating point inaccuracies
share|improve this answer
    
The order of the (item, prob) pairs in the list matters in your implementation, right? – stackoverflowuser2010 Jun 6 '13 at 22:37
1  
@stackoverflowuser2010: It shouldn't matter (modulo errors in floating point) – sdcvvc Jun 7 '13 at 12:52
    
Nice. I found this to be 30% faster than scipy.stats.rv_discrete. – Aspen May 3 '15 at 3:07
1  
Quite a few times this function will throw a KeyError because the last line. – Drunken Master Sep 9 '15 at 20:02
1  
@Vaibhav: thanks, fixed – sdcvvc Dec 29 '15 at 12:17

(OK, I know you are asking for shrink-wrap, but maybe those home-grown solutions just weren't succinct enough for your liking. :-)

pdf = [(1, 0.1), (2, 0.05), (3, 0.05), (4, 0.2), (5, 0.4), (6, 0.2)]
cdf = [(i, sum(p for j,p in pdf if j < i)) for i,_ in pdf]
R = max(i for r in [random.random()] for i,c in cdf if c <= r)

I pseudo-confirmed that this works by eyeballing the output of this expression:

sorted(max(i for r in [random.random()] for i,c in cdf if c <= r)
       for _ in range(1000))
share|improve this answer
    
This looks impressive. Just to put things in context, here are the results from 3 consecutive executions of the above code: ['Count of 1 with prob: 0.1 is: 113', 'Count of 2 with prob: 0.05 is: 55', 'Count of 3 with prob: 0.05 is: 50', 'Count of 4 with prob: 0.2 is: 201', 'Count of 5 with prob: 0.4 is: 388', 'Count of 6 with prob: 0.2 is: 193']..............['Count of 1 with prob: 0.1 is: 77', 'Count of 2 with prob: 0.05 is: 60', 'Count of 3 with prob: 0.05 is: 51', 'Count of 4 with prob: 0.2 is: 193', 'Count of 5 with prob: 0.4 is: 438', 'Count of 6 with prob: 0.2 is: 181'] ............. and – Vaibhav Dec 29 '15 at 10:10
    
['Count of 1 with prob: 0.1 is: 84', 'Count of 2 with prob: 0.05 is: 52', 'Count of 3 with prob: 0.05 is: 53', 'Count of 4 with prob: 0.2 is: 210', 'Count of 5 with prob: 0.4 is: 405', 'Count of 6 with prob: 0.2 is: 196'] – Vaibhav Dec 29 '15 at 10:11
    
Essentially, this appears to be an involved convolution of 'sdcvvc's' answer.. – Vaibhav Dec 29 '15 at 10:17
    
A question, how do I return max(i... , if 'i' is an object? – Vaibhav Dec 29 '15 at 11:33
    
@Vaibhav i isn't an object. – Marcelo Cantos Dec 31 '15 at 1:34

Maybe it is kind of late. But you can use:

numpy.random.choice()

http://docs.scipy.org/doc/numpy/reference/generated/numpy.random.choice.html#numpy.random.choice

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1  
The OP doesn't want to use random.choice() - see the comments. – pobrelkey Dec 1 '13 at 1:17
1  
numpy.random.choice() is completely different from random.choice() and supports probability distribution. – Eugene Pakhomov Jun 18 at 6:25

you might want to have a look at NumPy Random sampling distributions

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3  
The numpy functions also seem to only support a limited number of distributions with no support for specifying your own. – pafcu Nov 24 '10 at 11:20

Make a list of items, based on their weights:

items = [1, 2, 3, 4, 5, 6]
probabilities= [0.1, 0.05, 0.05, 0.2, 0.4, 0.2]
# if the list of probs is normalized (sum(probs) == 1), omit this part
prob = sum(probabilities) # find sum of probs, to normalize them
c = (1.0)/prob # a multiplier to make a list of normalized probs
probabilities = map(lambda x: c*x, probabilities)
print probabilities

ml = max(probabilities, key=lambda x: len(str(x)) - str(x).find('.'))
ml = len(str(ml)) - str(ml).find('.') -1
amounts = [ int(x*(10**ml)) for x in probabilities]
itemsList = list()
for i in range(0, len(items)): # iterate through original items
  itemsList += items[i:i+1]*amounts[i]

# choose from itemsList randomly
print itemsList

An optimization may be to normalize amounts by the greatest common divisor, to make the target list smaller.

Also, this might be interesting.

share|improve this answer
    
If the list of items is large this might use a lot of extra memory. – pafcu Nov 24 '10 at 11:39
    
@pafcu Agreed. Just a solution, the second which came to my mind (the first one was to search for something like "weight probability python" :) ). – khachik Nov 24 '10 at 11:46

Another answer, probably faster :)

distribution = [(1, 0.2), (2, 0.3), (3, 0.5)]  
# init distribution  
dlist = []  
sumchance = 0  
for value, chance in distribution:  
    sumchance += chance  
    dlist.append((value, sumchance))  
assert sumchance == 1.0 # not good assert because of float equality  

# get random value  
r = random.random()  
# for small distributions use lineair search  
if len(distribution) < 64: # don't know exact speed limit  
    for value, sumchance in dlist:  
        if r < sumchance:  
            return value  
else:  
    # else (not implemented) binary search algorithm  
share|improve this answer

based on other solutions, you generate accumulative distribution (as integer or float whatever you like), then you can use bisect to make it fast

this is a simple example (I used integers here)

l=[(20, 'foo'), (60, 'banana'), (10, 'monkey'), (10, 'monkey2')]
def get_cdf(l):
    ret=[]
    c=0
    for i in l: c+=i[0]; ret.append((c, i[1]))
    return ret

def get_random_item(cdf):
    return cdf[bisect.bisect_left(cdf, (random.randint(0, cdf[-1][0]),))][1]

cdf=get_cdf(l)
for i in range(100): print get_random_item(cdf),

the get_cdf function would convert it from 20, 60, 10, 10 into 20, 20+60, 20+60+10, 20+60+10+10

now we pick a random number up to 20+60+10+10 using random.randint then we use bisect to get the actual value in a fast way

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None of these answers is particularly clear or simple.

Here is a clear, simple method that is guaranteed to work.

accumulate_normalize_probabilities takes a dictionary p that maps symbols to probabilities OR frequencies. It outputs usable list of tuples from which to do selection.

def accumulate_normalize_values(p):
        pi = p.items() if isinstance(p,dict) else p
        accum_pi = []
        accum = 0
        for i in pi:
                accum_pi.append((i[0],i[1]+accum))
                accum += i[1]
        if accum == 0:
                raise Exception( "You are about to explode the universe. Continue ? Y/N " )
        normed_a = []
        for a in accum_pi:
                normed_a.append((a[0],a[1]*1.0/accum))
        return normed_a

Yields:

>>> accumulate_normalize_values( { 'a': 100, 'b' : 300, 'c' : 400, 'd' : 200  } )
[('a', 0.1), ('c', 0.5), ('b', 0.8), ('d', 1.0)]

Why it works

The accumulation step turns each symbol into an interval between itself and the previous symbols probability or frequency (or 0 in the case of the first symbol). These intervals can be used to select from (and thus sample the provided distribution) by simply stepping through the list until the random number in interval 0.0 -> 1.0 (prepared earlier) is less or equal to the current symbol's interval end-point.

The normalization releases us from the need to make sure everything sums to some value. After normalization the "vector" of probabilities sums to 1.0.

The rest of the code for selection and generating a arbitrarily long sample from the distribution is below :

def select(symbol_intervals,random):
        print symbol_intervals,random
        i = 0
        while random > symbol_intervals[i][1]:
                i += 1
                if i >= len(symbol_intervals):
                        raise Exception( "What did you DO to that poor list?" )
        return symbol_intervals[i][0]


def gen_random(alphabet,length,probabilities=None):
        from random import random
        from itertools import repeat
        if probabilities is None:
                probabilities = dict(zip(alphabet,repeat(1.0)))
        elif len(probabilities) > 0 and isinstance(probabilities[0],(int,long,float)):
                probabilities = dict(zip(alphabet,probabilities)) #ordered
        usable_probabilities = accumulate_normalize_values(probabilities)
        gen = []
        while len(gen) < length:
                gen.append(select(usable_probabilities,random()))
        return gen

Usage :

>>> gen_random (['a','b','c','d'],10,[100,300,400,200])
['d', 'b', 'b', 'a', 'c', 'c', 'b', 'c', 'c', 'c']   #<--- some of the time
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from __future__ import division
import random
from collections import Counter


def num_gen(num_probs):
    # calculate minimum probability to normalize
    min_prob = min(prob for num, prob in num_probs)
    lst = []
    for num, prob in num_probs:
        # keep appending num to lst, proportional to its probability in the distribution
        for _ in range(int(prob/min_prob)):
            lst.append(num)
    # all elems in lst occur proportional to their distribution probablities
    while True:
        # pick a random index from lst
        ind = random.randint(0, len(lst)-1)
        yield lst[ind]

Verification:

gen = num_gen([(1, 0.1),
               (2, 0.05),
               (3, 0.05),
               (4, 0.2),
               (5, 0.4),
               (6, 0.2)])
lst = []
times = 10000
for _ in range(times):
    lst.append(next(gen))
# Verify the created distribution:
for item, count in Counter(lst).iteritems():
    print '%d has %f probability' % (item, count/times)

1 has 0.099737 probability
2 has 0.050022 probability
3 has 0.049996 probability 
4 has 0.200154 probability
5 has 0.399791 probability
6 has 0.200300 probability
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Here is a more effective way of doing this:

Just call the following function with your 'weights' array (assuming the indices as the corresponding items) and the no. of samples needed. This function can be easily modified to handle ordered pair.

Returns indexes (or items) sampled/picked (with replacement) using their respective probabilities:

def resample(weights, n):
    beta = 0

    # Caveat: Assign max weight to max*2 for best results
    max_w = max(weights)*2

    # Pick an item uniformly at random, to start with
    current_item = random.randint(0,n-1)
    result = []

    for i in range(n):
        beta += random.uniform(0,max_w)

        while weights[current_item] < beta:
            beta -= weights[current_item]
            current_item = (current_item + 1) % n   # cyclic
        else:
            result.append(current_item)
    return result

A short note on the concept used in the while loop. We reduce the current item's weight from cumulative beta, which is a cumulative value constructed uniformly at random, and increment current index in order to find the item, the weight of which matches the value of beta.

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