arc4random() returns an unsigned 32-bit integer, meaning the values are between
0 and 2^32-1 = 4 294 967 295.

Now, the bias results from the fact that the multiple subintervals created with
modulo are not fitting exactly into the random output range.
Lets imagine for clarity a random generator that creates numbers from 0 to 198
inclusive. You want numbers from 0 to 99, therefore you calculate random() % 100,
yielding 0 to 99:

0 % 100 = 0

99 % 100 = 99

100 % 100 = 0

198 % 100 = 98

You see that 99 is the only number which can occur only *once* while all
others can occur *twice* in a run. That means that the probability for 99
is exactly halved which is also the worst case in a bias where at least
2 subintervals are involved.

As all powers of two smaller than the range interval fits nicely into the
2^32 interval, the bias disappears in this case.

The implications are that the smaller the result set with modulo and the higher
the random output range, the smaller the bias. In your example, 6 is your upper
bound (I assume 0 is the lower bound), so you use % 7, resulting that 0-3
occurs 613 566 757 times while 4-6 occurs 613 566 756 times.

So 0-3 is 613 566 757 / 613 566 756 = 1.0000000016298 times more probable
than 4-6.

While it seems easy to dismiss, some experiments (especially Monte-Carlo
experiments) were flawed exactly because these seemingly incredible small
differences were pretty important.

Even worse is the bias if the desired output range is *bigger* than
the random target range. Please read the Fisher-Yates shuffle entry
because many poker sites learned the hard way that normal linear
congruential random generators and bad shuffling algorithms resulted in
impossible or very probable decks or worse, *predictable* decks.