Your friend's code is making use of the fact that for N > 3, all prime numbers take the form (6×M±1) for M = 1, 2, ... (so for M = 1, the prime candidates are N = 5 and N = 7, and both those are primes). Also, all prime pairs are like 5 and 7. This only checks 2 out of every 3 odd numbers, whereas your solution checks 3 out of 3 odd numbers.
Your friend's code is using division to achieve something akin to the square root. That is, the condition
divisor <= n / divisor is more or less equivalent to, but slower and safer from overflow than,
divisor * divisor <= n. It might be better to use
unsigned long long max = sqrt(n); outside the loop. This reduces the amount of checking considerably compared with your proposed solution which searches through many more possible values. The square root check relies on the fact that if N is composite, then for a given pair of factors F and G (such that F×G = N), one of them will be less than or equal to the square root of N and the other will be greater than or equal to the square root of N.
As Michael Burr points out, the friend's prime function identifies 25 (5×5) and 35 (5×7) as prime, and generates 177 numbers under 1000 as prime whereas, I believe, there are just 168 primes in that range. Other misidentified composites are 121 (11×11), 143 (13×11), 289 (17×17), 323 (17×19), 841 (29×29), 899 (29×31).
unsigned long long c;
for (c = 5; c < 1000; c += 2)
The trouble with the original code is that it stops checking too soon because
divisor is set to the larger, rather than the smaller, of the two numbers to be checked.
static int prime(unsigned long long n)
unsigned long long val = 1;
unsigned long long divisor = 5;
if (n == 2 || n == 3)
if (n < 2 || n%2 == 0 || n%3 == 0)
for ( ; divisor<=n/divisor; val++, divisor=6*val-1)
if (n%divisor == 0 || n%(divisor+2) == 0)
Note that the revision is simpler to understand because it doesn't need to explain the shorthand negated conditions in tail comments. Note also the
+2 instead of
-2 in the body of the loop.