A somewhat late answer, but it should provide some additional
information **if** the quality of the generation is important. (Not all
applications need this—a slight bias is often not a problem.)

First, of course, the problem in the original code is the fact that
`range * rand()`

has precedence over the following division, and is done
using integer arithmetic. Depending on `RAND_MAX`

, this can easily
result in overflow, with implementation defined results; on all
implementations that I know, if it does result in overflow (because
`RAND_MAX > INT_MAX / range`

, the actual results will almost certainly
be smaller than `RAND_MAX + 1.0`

, and the division will result in a
value less than `1.0`

. There are several ways of avoiding this: the
simplest and most reliable is simply `rand() % range + lowest`

.

Note that this supposes that `rand()`

is of reasonable quality. Many
earlier implementations weren't, and I've seen at least one where
`rand() % 6 + 1`

to simulate a dice throw alternated odd and even. The
only correct solution here is to get a better implementation of
`rand()`

; it has lead to people trying alternative solutions, such as
`(range * (rand() / (RAND_MAX + 1.0))) + lowest`

. This masks the
problem, but it won't change a bad generator into a good one.

A second issue, **if** the quality of the generation is important, is
that when generating random integers, you're discretizing: if you're
simulating the throw of a die, for example, you have six possible
values, which you want to occur with equal probability. The random
generator will generate `RAND_MAX + 1`

different values, with equal
probability. If `RAND_MAX + 1`

is not a multiple of 6, there's no
possible way of distributing the values equaly amont the 6 desired
values. Imagine the simple case where `RAND_MAX + 1`

is 10. Using the
`%`

method above, the values 1–4 are twice as likely as the the
values 5 and 6. If you use the more complicated formula ```
1 + int(6 *
(rand() / (RAND_MAX + 1.0)))
```

(in the case where `RAND_MAX + 1 == 10`

,
it turns out that 3 and 6 are only half as likely as the other values.
Mathematically, there's simply no way of distributing 10 different
values into 6 slots with an equal number of elements in each slot.

Of course, `RAND_MAX`

will always be considerably larger than 10, and
the bias introduced will be considerably less; if the range is
significantly less than `RAND_MAX`

, it could be acceptable. If it's
not, however, the usual procedure is something like:

```
int limit = (RAND_MAX + 1LL) - (RAND_MAX + 1LL) % range;
// 1LL will prevent overflow on most machines.
int result = rand();
while ( result >= limit ) {
result = rand();
}
return result % range + lowest;
```

(There are several ways of determining the values to throw out. This
happens to be the one I use, but I remember Andy Koenig using something
completely different—but which resulted in the same values being
thrown out in the end.)

Note that most of the time, you won't enter the loop; the worst case is
when `range`

is `(RAND_MAX + 1) / 2 + 1`

, in which case, you'll still
average just under one time through the loop.

Note that these comments only apply when you need a fixed number of
discrete results. For the (other) common case of generating a random
floating point number in the range of `[0,1)`

, ```
rand() / (RAND_MAX +
1.0)
```

is about as good as you're going to get.

`(rand() % range) + lowest`

instead? – Joachim Pileborg Feb 28 '12 at 15:28