Marc B's link shows a nice and simple algorithm which is correct, written by NSLogan. I wrote a slight modification to it to show some size/speed tradeoffs. I thought I'd share for interest's sake.

First, the code:

```
#include <stdio.h>
#include <stdlib.h>
#include <math.h>
#include <assert.h>
#include <time.h>
#define USE_BITS
#ifdef USE_BITS
#define alloc_prime char *prime = calloc(i/8,sizeof(*prime));
#define set_not_prime(x) prime[x/8]|= (1<<(x%8))
#define is_prime(x) (!(prime[x/8]&(1<<(x%8))))
#endif
#ifdef USE_CHAR
#define alloc_prime char *prime = calloc(i,sizeof(*prime));
#define set_not_prime(x) prime[x] = 1
#define is_prime(x) (prime[x] == 0)
#endif
#ifdef USE_SIZE_TYPE
#define alloc_prime size_t *prime = calloc(i,sizeof(*prime));
#define set_not_prime(x) prime[x] = 1
#define is_prime(x) (prime[x] == 0)
#endif
int main(){
int i;
printf("Find primes up to: ");
scanf("%i",&i);
clock_t start, stop;
double t = 0.0;
assert((start = clock())!=-1);
//create prime list
alloc_prime;
int c1, c2, c3;
if(!prime){
printf("Can't allocate %zu bytes!\n",i*sizeof(*prime));
exit(1);
}
//set 0 and 1 as not prime
set_not_prime(0);
set_not_prime(1);
//find primes then eliminate their multiples (0 = prime, 1 = composite)
for(c2 = 2;c2 <= (int)sqrt(i)+1;c2++){
if(is_prime(c2)){
c1=c2;
for(c3 = 2*c1;c3 <= i+1; c3 += c1){
set_not_prime(c3);
}
}
}
stop = clock();
t = (double) (stop-start)/CLOCKS_PER_SEC;
//print primes
for(c1 = 0; c1 < i+1; c1++){
if(is_prime(c1))printf("%i\n",c1);
// if(prime[c1] == 0) printf("%i\n",c1);
}
printf("Run time: %f\n", t); //print time to find primes
return 0;
}
```

(Forgive the error message for not being accurate when USE_BITS is defined...)

I've compared three different ways of storing the boolean variables that peoro suggested. One method actually uses bits, the second takes an entire byte, and the last uses an entire machine word. A naive guess about which is fastest might be the machine word method, since each flag/boolean is dealt with more 'naturally' by your machine. The timings to calculate the primes up to 100,000,000 on my machine were as follows:

Bits: 3.8s
Chars: 5.8s
M-words: 10.8s

It is interesting to note that even all the ugly bit-shifting necessary to represent a boolean with only one bit is still faster overall. My conjecture is that caching and locality-of-reference seem to outweigh the extra ~3 instructions. Plus, you end up using 1/nth the memory of the n-bit-machine-word method!