The function assumes that `rand()`

is uniformly distributed; whether or not that is a valid assumption depends on the implementation of `rand()`

.

Given a uniform `rand()`

, we can get a random number in the range `[0,n)`

by calculating `rand()%n`

. However, in general, this won't be quite uniform. For example, suppose `n`

is 3 and `RAND_MAX`

is 7:

```
rand() 0 1 2 3 4 5 6 7
rand() % n 0 1 2 0 1 2 0 1
```

We can see that 0 and 1 come up with a probability of 3/8, while 2 only comes up with a probability of 2/8: the distribution is not uniform.

Your code discards any value of `rand()`

greater or equal to the largest multiple of `n`

that it can generate. Now each value has an equal probability:

```
rand() 0 1 2 3 4 5 6 7
rand() % n 0 1 2 0 1 2 X X
```

So 0,1 and 2 all come up with a probability of 1/3, as long as we are not so unlucky that the loop never terminates.

Regarding your update:

I think a simple top = RAND_MAX / n * n would do.

If `RAND_MAX`

were an exclusive bound (one more than the actual maximum), then that would be correct. Since it's an inclusive bound, we need to add one to get the exclusive bound; and since the following logic compares with `>`

against an inclusive bound, then subtract one again after the calculation:

```
int top = ((RAND_MAX + 1) / n) * n - 1;
```

However, if `RAND_MAX`

were equal to `INT_MAX`

, then the calculation would overflow; to avoid that, subtract `n`

at the beginning of the calculation, and add it again at the end:

```
int top = (((RAND_MAX - n) + 1) / n) * n - 1 + n;
```