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algorithm - Probability distribution in Python

I have a bunch of keys that each have an unlikeliness variable. I want to randomly choose one of these keys, yet I want it to be more unlikely for unlikely (key, values) to be chosen than a less unlikely (a more likely) object. I am wondering if you would have any suggestions, preferably an existing python module that I could use, else I will need to make it myself.

I have checked out the random module; it does not seem to provide this.

I have to make such choices many millions of times for 1000 different sets of objects each containing 2,455 objects. Each set will exchange objects among each other so the random chooser needs to be dynamic. With 1000 sets of 2,433 objects, that is 2,433 million objects; low memory consumption is crucial. And since these choices are not the bulk of the algorithm, I need this process to be quite fast; CPU-time is limited.

Thx

Update:

Ok, I tried to consider your suggestions wisely, but time is so limited...

I looked at the binary search tree approach and it seems too risky (complex and complicated). The other suggestions all resemble the ActiveState recipe. I took it and modified it a little in the hope of making more efficient:

def windex(dict, sum, max):
    '''an attempt to make a random.choose() function that makes
    weighted choices accepts a dictionary with the item_key and
    certainty_value as a pair like:
    >>> x = [('one', 20), ('two', 2), ('three', 50)], the
    maximum certainty value (max) and the sum of all certainties.'''
    n = random.uniform(0, 1)
    sum = max*len(list)-sum 
    for key, certainty in dict.iteritems():
        weight = float(max-certainty)/sum
        if n < weight:
            break
        n = n - weight
    return key

I am hoping to get an efficiency gain from dynamically maintaining the sum of certainties and the maximum certainty. Any further suggestions are welcome. You guys saves me so much time and effort, while increasing my effectiveness, it is crazy. Thx! Thx! Thx!

Update2:

I decided to make it more efficient by letting it choose more choices at once. This will result in an acceptable loss in precision in my algo for it is dynamic in nature. Anyway, here is what I have now:

def weightedChoices(dict, sum, max, choices=10):
    '''an attempt to make a random.choose() function that makes
    weighted choices accepts a dictionary with the item_key and
    certainty_value as a pair like:
    >>> x = [('one', 20), ('two', 2), ('three', 50)], the
    maximum certainty value (max) and the sum of all certainties.'''
    list = [random.uniform(0, 1) for i in range(choices)]
    (n, list) = relavate(list.sort())
    keys = []
    sum = max*len(list)-sum 
    for key, certainty in dict.iteritems():
        weight = float(max-certainty)/sum
        if n < weight:
            keys.append(key)
            if list: (n, list) = relavate(list)
            else: break
        n = n - weight
    return keys
def relavate(list):
    min = list[0]
    new = [l - min for l in list[1:]]
    return (min, new)

I haven't tried it out yet. If you have any comments/suggestions, please do not hesitate. Thx!

Update3:

I have been working all day on a task-tailored version of Rex Logan's answer. Instead of a 2 arrays of objects and weights, it is actually a special dictionary class; which makes things quite complex since Rex's code generates a random index... I also coded a test case that kind of resembles what will happen in my algo (but I can't really know until I try!). The basic principle is: the more a key is randomly generated often, the more unlikely it will be generated again:

import random, time
import psyco
psyco.full()

class ProbDict():
    """
    Modified version of Rex Logans RandomObject class. The more a key is randomly
    chosen, the more unlikely it will further be randomly chosen. 
    """
    def __init__(self,keys_weights_values={}):
        self._kw=keys_weights_values
        self._keys=self._kw.keys()
        self._len=len(self._keys)
        self._findSeniors()
        self._effort = 0.15
        self._fails = 0
    def __iter__(self):
        return self.next()
    def __getitem__(self, key):
        return self._kw[key]
    def __setitem__(self, key, value):
        self.append(key, value)
    def __len__(self):
        return self._len
    def next(self):
        key=self._key()
        while key:
            yield key
            key = self._key()
    def __contains__(self, key):
        return key in self._kw
    def items(self):
        return self._kw.items()
    def pop(self, key):  
        try:
            (w, value) = self._kw.pop(key)
            self._len -=1
            if w == self._seniorW:
                self._seniors -= 1
                if not self._seniors:
                    #costly but unlikely:
                    self._findSeniors()
            return [w, value]
        except KeyError:
            return None
    def popitem(self):
        return self.pop(self._key())
    def values(self):
        values = []
        for key in self._keys:
            try:
                values.append(self._kw[key][1])
            except KeyError:
                pass
        return values
    def weights(self):
        weights = []
        for key in self._keys:
            try:
                weights.append(self._kw[key][0])
            except KeyError:
                pass
        return weights
    def keys(self, imperfect=False):
        if imperfect: return self._keys
        return self._kw.keys()
    def append(self, key, value=None):
        if key not in self._kw:
            self._len +=1
            self._kw[key] = [0, value]
            self._keys.append(key)
        else:
            self._kw[key][1]=value
    def _key(self):
        for i in range(int(self._effort*self._len)):
            ri=random.randint(0,self._len-1) #choose a random object
            rx=random.uniform(0,self._seniorW)
            rkey = self._keys[ri]
            try:
                w = self._kw[rkey][0]
                if rx >= w: # test to see if that is the value we want
                    w += 1
                    self._warnSeniors(w)
                    self._kw[rkey][0] = w
                    return rkey
            except KeyError:
                self._keys.pop(ri)
        # if you do not find one after 100 tries then just get a random one
        self._fails += 1 #for confirming effectiveness only
        for key in self._keys:
            if key in self._kw:
                w = self._kw[key][0] + 1
                self._warnSeniors(w)
                self._kw[key][0] = w
                return key
        return None
    def _findSeniors(self):
        '''this function finds the seniors, counts them and assess their age. It
        is costly but unlikely.'''
        seniorW = 0
        seniors = 0
        for w in self._kw.itervalues():
            if w >= seniorW:
                if w == seniorW:
                    seniors += 1
                else:
                    seniorsW = w
                    seniors = 1
        self._seniors = seniors
        self._seniorW = seniorW
    def _warnSeniors(self, w):
        #a weight can only be incremented...good
        if w >= self._seniorW:
            if w == self._seniorW:
                self._seniors+=1
            else:
                self._seniors = 1
                self._seniorW = w
def test():
    #test code
    iterations = 200000
    size = 2500
    nextkey = size 


    pd = ProbDict(dict([(i,[0,i]) for i in xrange(size)]))
    start = time.clock()
    for i in xrange(iterations):
        key=pd._key()
        w=pd[key][0]
        if random.randint(0,1+pd._seniorW-w):
            #the heavier the object, the more unlikely it will be removed
            pd.pop(key)
        probAppend = float(500+(size-len(pd)))/1000
        if random.uniform(0,1) < probAppend:
            nextkey+=1
            pd.append(nextkey)
    print (time.clock()-start)*1000/iterations, "msecs / iteration with", pd._fails, "failures /", iterations, "iterations"
    weights = pd.weights()
    weights.sort()
    print "avg weight:", float(sum(weights))/pd._len, max(weights), pd._seniorW, pd._seniors, len(pd), len(weights)
    print weights
test()

Any comments are still welcome. @Darius: your binary trees are too complex and complicated for me; and I do not think its leafs can be removed efficiently... Thx all

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1 Answer

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This activestate recipe gives an easy-to-follow approach, specifically the version in the comments that doesn't require you to pre-normalize your weights:

import random

def weighted_choice(items):
    """items is a list of tuples in the form (item, weight)"""
    weight_total = sum((item[1] for item in items))
    n = random.uniform(0, weight_total)
    for item, weight in items:
        if n < weight:
            return item
        n = n - weight
    return item

This will be slow if you have a large list of items. A binary search would probably be better in that case... but would also be more complicated to write, for little gain if you have a small sample size. Here's an example of the binary search approach in python if you want to follow that route.

(I'd recommend doing some quick performance testing of both methods on your dataset. The performance of different approaches to this sort of algorithm is often a bit unintuitive.)


Edit: I took my own advice, since I was curious, and did a few tests.

I compared four approaches:

The weighted_choice function above.

A binary-search choice function like so:

def weighted_choice_bisect(items):
    added_weights = []
    last_sum = 0

    for item, weight in items:
        last_sum += weight
        added_weights.append(last_sum)

    return items[bisect.bisect(added_weights, random.random() * last_sum)][0]

A compiling version of 1:

def weighted_choice_compile(items):
    """returns a function that fetches a random item from items

    items is a list of tuples in the form (item, weight)"""
    weight_total = sum((item[1] for item in items))
    def choice(uniform = random.uniform):
        n = uniform(0, weight_total)
        for item, weight in items:
            if n < weight:
                return item
            n = n - weight
        return item
    return choice

A compiling version of 2:

def weighted_choice_bisect_compile(items):
    """Returns a function that makes a weighted random choice from items."""
    added_weights = []
    last_sum = 0

    for item, weight in items:
        last_sum += weight
        added_weights.append(last_sum)

    def choice(rnd=random.random, bis=bisect.bisect):
        return items[bis(added_weights, rnd() * last_sum)][0]
    return choice

I then built a big list of choices like so:

choices = [(random.choice("abcdefg"), random.uniform(0,50)) for i in xrange(2500)]

And an excessively simple profiling function:

def profiler(f, n, *args, **kwargs):
    start = time.time()
    for i in xrange(n):
        f(*args, **kwargs)
    return time.time() - start

The results:

(Seconds taken for 1,000 calls to the function.)

  • Simple uncompiled: 0.918624162674
  • Binary uncompiled: 1.01497793198
  • Simple compiled: 0.287325024605
  • Binary compiled: 0.00327413797379

The "compiled" results include the average time taken to compile the choice function once. (I timed 1,000 compiles, then divided that time by 1,000, and added the result to the choice function time.)

So: if you have a list of items+weights which change very rarely, the binary compiled method is by far the fastest.


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