# Generate random numbers that sum up to n

How to generate between 1 and n random numbers (positive integers greater than 0) which sum up to exactly n?

Example results if n=10:

``````10
2,5,3
1,1,1,1,1,1,1,1,1,1
1,1,5,1,1,1
``````

Each of the permutations should have the same probability of occurring, however, I don't need it to be mathematically precise. So if the probabilities are not the same due to some modulo error, I don't care.

Is there a go-to algorithm for this? I only found algorithms where the number of values is fixed (i.e., give me exactly m random numbers which sum up to n).

• @ceejayoz: I thought of this algorithm too, however, it looks like it's way off the "same probability for each permutation", isn't it? There are easily more than 10 permutations, but "10" has a probability of 1/10th. (I know, I said it doesn't have to be mathematically precise, but it shouldn't be way off)
– D.R.
Nov 15, 2018 at 20:16
• Just to clarify - you say "numbers" but your examples are all integer. Are you excluding floating point solutions? Are negative values allowed? How about zeros?
– pjs
Nov 15, 2018 at 20:34
– D.R.
Nov 16, 2018 at 10:51
• No attempt and no tag to indicate what language you're writing this in. To me, this looks more like a Mathematics question than a programming one. Nov 16, 2018 at 11:24
• @TobySpeight: In the end I want to have C# code, but I've omitted the C# tag as I'm interested in the algorithm and not a specific implementation. Are algorithm questions not part of StackOverflow? As for the attempt, if I can't find an approach myself, I'm not entitled to post here?
– D.R.
Nov 16, 2018 at 11:26

Imagine the number n as a line built of n equal, indivisible sections. Your numbers are lengths of those sections that sum up to the whole. You can cut the original length between any two sections, or none.

This means there are n-1 potential cut points.

Choose a random n-1-bit number, that is a number between 0 and 2^(n-1); its binary representation tells you where to cut.

``````0 : 000 : [-|-|-|-] : 1,1,1,1
1 : 001 : [-|-|- -] :  1,1,2
3 : 011 : [-|- - -] :   1,3
5 : 101 : [- -|- -] :   2,2
7 : 111 : [- - - -] :    4
``````

etc.

Implementation in python-3

``````import random

def perm(n, np):
p = []
d = 1
for i in range(n):
if np % 2 == 0:
p.append(d)
d = 1
else:
d += 1
np //= 2
return p

def test(ex_n):
for ex_p in range(2 ** (ex_n - 1)):
p = perm(ex_n, ex_p)
print(len(p), p)

def randperm(n):
np = random.randint(0, 2 ** (n - 1))
return perm(n, np)

print(randperm(10))
``````

you can verify it by generating all possible solutions for small n

``````test(4)
``````

output:

``````4 [1, 1, 1, 1]
3 [2, 1, 1]
3 [1, 2, 1]
2 [3, 1]
3 [1, 1, 2]
2 [2, 2]
2 [1, 3]
1 [4]
``````
• Thanks for adding the explanation - that's a really good answer now. And we don't need to generate all n bits of the decision tree at once - if we have a source of random bits, we can just take them as we need them. That can avoid the overhead of huge arithmetic numbers which we won't be using for arithmetic. Nov 16, 2018 at 15:10
• I love the way you have solved it and I really like how you illustrated the example. Nov 16, 2018 at 15:16
• honestly, for dumb people like me, I wish you had actually named your variables so I could better reason about the code. I want to make modifications but I have no idea what d is, or np vs p, etc. I'd like to set a cap on the number of values in p. So like, "find 5 numbers that add up to 10". Jul 10, 2022 at 19:08

# Generate Random Integers With Fixed Sum

## Method One: Multinomial Distribution

Deviation cannot be controlled strictly within the desired range.

``````# Python
import numpy as np
_sum = 800
n = 16
rnd_array = np.random.multinomial(_sum, np.ones(n)/n, size=1)[0]
print('Array:', rnd_array, ', Sum:', sum(rnd_array))
# returns Array: [64 41 57 49 48 44 46 44 40 55 58 54 54 54 39 53] , Sum: 800
``````

## Method Two: Random Integer Generator Within Lower and Upper Bounds

To control the deviation

``````# Python
import random
def generate_random_integers(_sum, n):
mean = _sum / n
variance = int(5 * mean)

min_v = mean - variance
max_v = mean + variance
array = [min_v] * n

diff = _sum - min_v * n
while diff > 0:
a = random.randint(0, n - 1)
if array[a] >= max_v:
continue
array[a] += 1
diff -= 1
return np.array([int(number) for number in array])
_sum = 800
n = 16
rnd_array = generate_random_integers(_sum, n)
print('Array:', rnd_array, ', Sum:', sum(rnd_array))
# Returns Array: [45 46 46 58 53 77 33 53 39 38 44 51 33 60 75 49] , Sum: 800
``````

Use a modulo.

``````#include <stdio.h>
#include <stdlib.h>
#include <time.h>

int main()
{
srand(time(0));
int n=10;
int x=0; /* sum of previous random number */
while (x<n) {
int r = rand() % (n-x) + 1;
printf("%d ", r);
x += r;
}
/* done */
printf("\n");
}
``````

Example output:

``````10
1 1 8
3 4 1 1 1
6 3 1
9 1
6 1 1 1 1
5 4 1
``````
• This seems biased towards the shorter sequences; only one of the example outputs begins with `1`, but we'd expect about half of them to begin with `1` if it selected fairly from all possibilities. Nov 16, 2018 at 15:14