To generate N positive numbers that sum to a positive number M at random, where each possible combination is equally likely:

Generate N exponentially-distributed random variates. One way to generate such a number can be written as—

```
number = -ln(1.0 - RNDU())
```

where `ln(x)`

is the natural logarithm of `x`

and `RNDU()`

is a method that returns a uniform random variate greater than 0 and less than 1. Note that generating the N variates with a uniform distribution is not ideal because a biased distribution of random variate combinations will result. However, the implementation given above has several problems, such as being ill-conditioned at large values because of the distribution's right-sided tail, especially when the implementation involves floating-point arithmetic. Another implementation is given in another answer.

Divide the numbers generated this way by their sum.

Multiply each number by M.

The result is N numbers whose sum is approximately equal to M (I say "approximately" because of rounding error). See also the Wikipedia article Dirichlet distribution.

This problem is also equivalent to the problem of generating random variates uniformly from an N-dimensional unit simplex.

However, for better accuracy (compared to the alternative of using floating-point numbers, which often occurs in practice), you should consider generating `n`

random *integers* that sum to an *integer* `m * x`

, and treating those integers as the numerators to `n`

rational numbers with denominator `x`

(and will thus sum to `m`

assuming `m`

is an integer). You can choose `x`

to be a large number such as 2^{32} or 2^{64} or some other number with the desired precision. If `x`

is 1 and `m`

is an integer, this solves the problem of generating random *integers* that sum to `m`

.

The following pseudocode shows two methods for generating `n`

uniform random integers with a given positive sum, in random order. (The algorithm for this was presented in Smith and Tromble, "Sampling Uniformly from the Unit Simplex", 2004.) In the pseudocode below—

- the method
`PositiveIntegersWithSum`

returns `n`

integers **greater than 0** that sum to `m`

, in random order,
- the method
`IntegersWithSum`

returns `n`

integers **0 or greater** that sum to `m`

, in random order, and
`Sort(list)`

sorts the items in `list`

in ascending order (note that sort algorithms are outside the scope of this answer).

```
METHOD PositiveIntegersWithSum(n, m)
if n <= 0 or m <=0: return error
ls = [0]
ret = NewList()
while size(ls) < n
c = RNDINTEXCRANGE(1, m)
found = false
for j in 1...size(ls)
if ls[j] == c
found = true
break
end
end
if found == false: AddItem(ls, c)
end
Sort(ls)
AddItem(ls, m)
for i in 1...size(ls): AddItem(ret,
ls[i] - ls[i - 1])
return ret
END METHOD
METHOD IntegersWithSum(n, m)
if n <= 0 or m <=0: return error
ret = PositiveIntegersWithSum(n, m + n)
for i in 0...size(ret): ret[i] = ret[i] - 1
return ret
END METHOD
```

Here, `RNDINTEXCRANGE(a, b)`

returns a uniform random integer in the interval [a, b).