# Random numbers based on a probability

I'm having trouble generating random numbers that do not follow a discrete uniform distribution.

So for example, say I have 5 numbers (to keep it simple), a probability of number k being generated would be k/15. (k = 1 to 5)

My idea is to generate a random number j using rand(), and if this number j is:

1 => then number 1 is generated

2 or 3 => num 2

4 or 5 or 6 => num 3

7 or 8 or 9 or 10 => num 4

11 or 12 or 13 or 14 or 15 => num 5

Now scale this to generating 1-10, 1-100, 1-1000. Does this work the way I intend it to? I've constructed a loop that pretty much does this every time a number needs to be generated, I think it's probably inefficient since it goes up until it finds the j number generated in one of the ranges... What could be a better way to do this?

EDIT: or maybe create an array once with the proper numbers and then pull out with rand() better solution?

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there are many similar questions on SO..... –  Mitch Wheat Jun 8 '12 at 2:31

Consider that the sum `s` of integers from 1 to `n` is `s = n * (n + 1) / 2`. Solve for `n` to get `n = (± sqrt(8*s + 1) - 1) / 2`. We can ignore the negative square root, as we know `n` is positive. Thus `n = (sqrt(8*s + 1) - 1) / 2`.

So, plugging in integers for `s` between 1 and 15:

``````s  n
01 1.000000
02 1.561553
03 2.000000
04 2.372281
05 2.701562
06 3.000000
07 3.274917
08 3.531129
09 3.772002
10 4.000000
11 4.216991
12 4.424429
13 4.623475
14 4.815073
15 5.000000
``````

If we take the ceiling of each computed `n` (the smallest integer not less than `n`), we get this:

``````s  n
01 1
02 2
03 2
04 3
05 3
06 3
07 4
08 4
09 4
10 4
11 5
12 5
13 5
14 5
15 5
``````

Thus you can go from the uniform distribution to your distribution in constant space and constant time (no iteration and no precomputed tables):

``````double my_distribution_from_uniform_distribution(double s) {
return ceil((sqrt(8*s + 1) - 1) / 2);
}
``````

N.B. This relies on `sqrt` giving an exact result for a perfect square (e.g. returning exactly 7 given exactly 49). This is normally a safe assumption, because IEEE 754 requires exact rounding of square roots.

IEEE 754 doubles can represent all integers from 1 through 2^53 (and many larger integers, but not contiguously after 2^53). So this function should work correctly for all `s` from 1 to `floor((2^53 - 1) / 8) = 1125899906842623`.

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You seem to be on the right track, but C++ already has a specialized random number distribution for that, `std::discrete_distribution`

``````#include <iostream>
#include <vector>
#include <map>
#include <random>

int main()
{
std::random_device rd;
std::mt19937 gen(rd());

// list of probabilities
std::vector<double> p = {0, 1.0/15, 2.0/15, 3.0/15, 4.0/15, 5.0/15};
// could also be min, max, and a generating function (n/15 in your case?)
std::discrete_distribution<> d(p.begin(), p.end());

// some statistics
std::map<int, int> m;
for(int n=0; n<10000; ++n) {
++m[d(gen)];
}
for(auto p : m) {
std::cout << p.first << " generated " << p.second << " times\n";
}
}
``````

online demo: http://ideone.com/jU1ll

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The other answers assume the intended distribution follows along with the sequence of triangular numbers but the question also refers to ranges from 1-100 and 1-1000, neither of which are triangular. So the general answer does appear to be more appropriate. –  shawnt00 Jul 22 '12 at 22:24

You can take advantage of the curious arithmetical fact that:

``````S(n) = 1 + 2 + 3 + ... + (n - 1) + n
``````

or simplified:

``````S(n) = n * (n + 1) / 2
``````

This lets you avoid storing the array.

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