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I'm trying to implement a weighted random numbers. I'm currently just banging my head against the wall and cannot figure this out.

In my project (Hold'em hand-ranges, subjective all-in equity analysis), I'm using Boost's random -functions. So, let's say I want to pick a random number between 1 and 3 (so either 1, 2 or 3). Boost's mersenne twister generator works like a charm for this. However, I want the pick to be weighted for example like this:

1 (90% chance to be picked up)
2 (56% chance to be picked up)
3 ( 4% chance to be picked up)

Does Boost have some sort of functionality for this?

share|improve this question
Doesn't add up to 100% :) – Artelius Nov 19 '09 at 8:00
Doesn't need to add up to 100. They're individual probabilities, not in pool of 0-100%. – nhaa123 Nov 19 '09 at 8:12
Yea, those have to add up. What happens when 1 doesn't get picked, 2 doesn't either, and same with 3? – GManNickG Nov 19 '09 at 9:07
@nhaa122: Then they're just weights, not percentage-chances. – Artelius Nov 19 '09 at 10:12
@Artelius: You're absolutely right. – nhaa123 Nov 19 '09 at 10:37
up vote 88 down vote accepted

There is a straightforward algorithm for picking an item at random, where items have individual weights:

1) calculate the sum of all the weights

2) pick a random number that is 0 or greater and is less than the sum of the weights

3) go through the items one at a time, subtracting their weight from your random number, until you get the item where the random number is less than that item's weight

Pseudo-code illustrating this:

int sum_of_weight = 0;
for(int i=0; i<num_choices; i++) {
   sum_of_weight += choice_weight[i];
int rnd = random(sum_of_weight);
for(int i=0; i<num_choices; i++) {
  if(rnd < choice_weight[i])
    return i;
  rnd -= choice_weight[i];
assert(!"should never get here");

This should be straightforward to adapt to your boost containers and such.

If your weights are rarely changed but you often pick one at random, and as long as your container is storing pointers to the objects or is more than a few dozen items long (basically, you have to profile to know if this helps or hinders), then there is an optimisation:

By storing the cumulative weight sum in each item you can use a binary search to pick the item corresponding to the pick weight.

If you do not know the number of items in the list, then there's a very neat algorithm called reservoir sampling that can be adapted to be weighted.

share|improve this answer
As an optimization you could use cumulative weights and use a binary search. But for only three different values this is probably overkill. – sellibitze Nov 19 '09 at 10:02
I assume when you say "in order" you are purposely omitting a pre-sort step on the choice_weight array, yes? – SilentDirge Oct 31 '11 at 19:17
@Aureis, there is no need to sort the array. I have tried to clarify my language. – Will Nov 1 '11 at 6:19
this is an awesome answer, i used the algorithm in a game to define the appearance frequencies of different types of characters – Emmett J. Butler Aug 4 '12 at 19:04
Several years late to the party, but in the above pseudo-code shouldn't "if(rnd < choice_weight[i])" be "if(rnd < CUMULATIVE_choice_weight[i])" ? – Wouter Aug 6 '13 at 18:37

Updated answer to an old question. You can easily do this in C++11 with just the std::lib:

#include <iostream>
#include <random>
#include <iterator>
#include <ctime>
#include <type_traits>
#include <cassert>

int main()
    // Set up distribution
    double interval[] = {1,   2,   3,   4};
    double weights[] =  {  .90, .56, .04};
    std::piecewise_constant_distribution<> dist(std::begin(interval),
    // Choose generator
    std::mt19937 gen(std::time(0));  // seed as wanted
    // Demonstrate with N randomly generated numbers
    const unsigned N = 1000000;
    // Collect number of times each random number is generated
    double avg[std::extent<decltype(weights)>::value] = {0};
    for (unsigned i = 0; i < N; ++i)
        // Generate random number using gen, distributed according to dist
        unsigned r = static_cast<unsigned>(dist(gen));
        // Sanity check
        assert(interval[0] <= r && r <= *(std::end(interval)-2));
        // Save r for statistical test of distribution
        avg[r - 1]++;
    // Compute averages for distribution
    for (double* i = std::begin(avg); i < std::end(avg); ++i)
        *i /= N;
    // Display distribution
    for (unsigned i = 1; i <= std::extent<decltype(avg)>::value; ++i)
        std::cout << "avg[" << i << "] = " << avg[i-1] << '\n';

Output on my system:

avg[1] = 0.600115
avg[2] = 0.373341
avg[3] = 0.026544

Note that most of the code above is devoted to just displaying and analyzing the output. The actual generation is just a few lines of code. The output demonstrates that the requested "probabilities" have been obtained. You have to divide the requested output by 1.5 since that is what the requests add up to.

share|improve this answer
Just a reminder note on compilation of this example: requires C++ 11 ie. use -std=c++0x compiler flag, available from gcc 4.6 onwards. – Pete855217 May 20 '12 at 9:59
Care to just pick out the necessary parts that solve the problem? – Jonny May 27 '15 at 4:42

What I do when I need to weight numbers is using a random number for the weight.

For example: I need that generate random numbers from 1 to 3 with the following weights:

  • 10% of a random number could be 1
  • 30% of a random number could be 2
  • 60% of a random number could be 3

Then I use:

weight = rand() % 10;

switch( weight ) {

    case 0:
        randomNumber = 1;
    case 1:
    case 2:
    case 3:
        randomNumber = 2;
    case 4:
    case 5:
    case 6:
    case 7:
    case 8:
    case 9:
        randomNumber = 3;

With this, randomly it has 10% of the probabilities to be 1, 30% to be 2 and 60% to be 3.

You can play with it as your needs.

Hope I could help you, Good Luck!

share|improve this answer
This rules out dynamically adjusting the distribution. – Josh C Aug 2 '14 at 19:38
Hacky but I like it. Nice for a quick prototype where you want some rough weighting. – drewish Mar 14 '15 at 18:54

Build a bag (or std::vector) of all the items that can be picked.
Make sure that the number of each items is proportional to your weighting.


  • 1 60%
  • 2 35%
  • 3 5%

So have a bag with 100 items with 60 1's, 35 2's and 5 3's.
Now randomly sort the bag (std::random_shuffle)

Pick elements from the bag sequentially until it is empty.
Once empty re-randomize the bag and start again.

share|improve this answer
if you have a bag of red and blue marbles and you select a red marble from it and don't replace it is the probability of selecting another red marble still the same? In the same way, your statement "Pick elements from the bag sequentially until it is empty" produces a totally different distribution than intended. – ldog Sep 23 '10 at 18:14
@ldog: I understand your argument but we are not looking for true randomness we are looking for a particular distribution. This technique guarantees the correct distribution. – Loki Astari Sep 23 '10 at 19:32
my point exactly is that you do not correctly produce distribution, by my previous argument. consider the simple counter example, say you put you have an array of 3 as 1,2,2 producing 1 1/3 of the time and 2 2/3. Randomize the array, pick the first, lets say a 2, now the next element you pick follows the distribution of 1 1/2 the time and 2 1/2 the time. Savvy? – ldog Sep 23 '10 at 22:55

Choose a random number on [0,1), which should be the default operator() for a boost RNG. Choose the item with cumulative probability density function >= that number:

template <class It,class P>
It choose_p(It begin,It end,P const& p)
    if (begin==end) return end;
    double sum=0.;
    for (It i=begin;i!=end;++i)
    double choice=sum*random01();
    for (It i=begin;;) {
        choice -= p(*i);
        It r=i;
        if (choice<0 || i==end) return r;
    return begin; //unreachable

Where random01() returns a double >=0 and <1. Note that the above doesn't require the probabilities to sum to 1; it normalizes them for you.

p is just a function assigning a probability to an item in the collection [begin,end). You can omit it (or use an identity) if you just have a sequence of probabilities.

share|improve this answer

I've implemented several simple weighted random algorithms.

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