The simplest way to get uniformly distributed results from `rand`

is something like this:

```
int limited_rand(int limit)
{
int r, d = RAND_MAX / limit;
limit *= d;
do { r = rand(); } while (r >= limit);
return r / d;
}
```

The result will be in the range `0`

to `limit-1`

, and each will occur with equal probability as long as the values `0`

through `RAND_MAX`

all had equal probability with the original `rand`

function.

Other methods such as modular arithmetic or dividing without the loop I used introduce **bias**. Methods that go through floating point intermediates do not avoid this problem. Getting good random floating point numbers from `rand`

is at least as difficult. Using my function for integers (or an improvement of it) is a good place to start if you want random floats.

**Edit**: Here's an explanation of what I mean by bias. Suppose `RAND_MAX`

is 7 and `limit`

is 5. Suppose (if this is a good `rand`

function) that the outputs 0, 1, 2, ..., 7 are all equally likely. Taking `rand()%5`

would map 0, 1, 2, 3, and 4 to themselves, but map 5, 6, and 7 to 0, 1, and 2. This means the values 0, 1, and 2 are twice as likely to pop up as the values 3 and 4. A similar phenomenon happens if you try to rescale and divide, for instance using `rand()*(double)limit/(RAND_MAX+1)`

Here, 0 and 1 map to 0, 2 and 3 map to 1, 4 maps to 2, 5 and 6 map to 3, and 7 maps to 4.

These effects are somewhat mitigated by the magnitude of `RAND_MAX`

, but they can come back if `limit`

is large. By the way, as others have said, with linear congruence PRNGs (the typical implementation of `rand`

), the low bits tend to behave very badly, so using modular arithmetic when `limit`

is a power of 2 may avoid the bias problem I described (since `limit`

usually divides `RAND_MAX+1`

evenly in this case), but you run into a different problem in its place.