Some time ago I used the (blazing fast) primesieve in python that I found here: Fastest way to list all primes below N in python

To be precise, this implementation:

```
def primes2(n):
""" Input n>=6, Returns a list of primes, 2 <= p < n """
n, correction = n-n%6+6, 2-(n%6>1)
sieve = [True] * (n/3)
for i in xrange(1,int(n**0.5)/3+1):
if sieve[i]:
k=3*i+1|1
sieve[ k*k/3 ::2*k] = [False] * ((n/6-k*k/6-1)/k+1)
sieve[k*(k-2*(i&1)+4)/3::2*k] = [False] * ((n/6-k*(k-2*(i&1)+4)/6-1)/k+1)
return [2,3] + [3*i+1|1 for i in xrange(1,n/3-correction) if sieve[i]]
```

Now I can slightly grasp the idea of the optimizing by automaticly skipping multiples of 2, 3 and so on, but when it comes to porting this algorithm to C++ I get stuck (I have a good understanding of python and a reasonable/bad understanding of C++, but good enough for rock 'n roll).

What I currently have rolled myself is this (`isqrt()`

is just a simple integer square root function):

```
template <class T>
void primesbelow(T N, std::vector<T> &primes) {
T sievemax = (N-3 + (1-(N % 2))) / 2;
T i;
T sievemaxroot = isqrt(sievemax) + 1;
boost::dynamic_bitset<> sieve(sievemax);
sieve.set();
primes.push_back(2);
for (i = 0; i <= sievemaxroot; i++) {
if (sieve[i]) {
primes.push_back(2*i+3);
for (T j = 3*i+3; j <= sievemax; j += 2*i+3) sieve[j] = 0; // filter multiples
}
}
for (; i <= sievemax; i++) {
if (sieve[i]) primes.push_back(2*i+3);
}
}
```

This implementation is decent and automatically skips multiples of 2, but if I could port the Python implementation I think it could be much faster (50%-30% or so).

To compare the results (in the hope this question will be successfully answered), the current execution time with `N=100000000`

, `g++ -O3`

on a Q6600 Ubuntu 10.10 is 1230ms.

Now I would love some help with either understanding what the above Python implementation does or that you would port it for me (not as helpful though).

**EDIT**

Some extra information about what I find difficult.

I have trouble with the techniques used like the correction variable and in general how it comes together. A link to a site explaining different Eratosthenes optimizations (apart from the simple sites that say "well you just skip multiples of 2, 3 and 5" and then get slam you with a 1000 line C file) would be awesome.

I don't think I would have issues with a 100% direct and literal port, but since after all this is for learning that would be utterly useless.

**EDIT**

After looking at the code in the original numpy version, it actually is pretty easy to implement and with some thinking not too hard to understand. This is the C++ version I came up with. I'm posting it here in full version to help further readers in case they need a pretty efficient primesieve that is not two million lines of code. This primesieve does all primes under 100000000 in about 415 ms on the same machine as above. That's a 3x speedup, better then I expected!

```
#include <vector>
#include <boost/dynamic_bitset.hpp>
// http://vault.embedded.com/98/9802fe2.htm - integer square root
unsigned short isqrt(unsigned long a) {
unsigned long rem = 0;
unsigned long root = 0;
for (short i = 0; i < 16; i++) {
root <<= 1;
rem = ((rem << 2) + (a >> 30));
a <<= 2;
root++;
if (root <= rem) {
rem -= root;
root++;
} else root--;
}
return static_cast<unsigned short> (root >> 1);
}
// http://stackoverflow.com/questions/2068372/fastest-way-to-list-all-primes-below-n-in-python/3035188#3035188
// http://stackoverflow.com/questions/5293238/porting-optimized-sieve-of-eratosthenes-from-python-to-c/5293492
template <class T>
void primesbelow(T N, std::vector<T> &primes) {
T i, j, k, l, sievemax, sievemaxroot;
sievemax = N/3;
if ((N % 6) == 2) sievemax++;
sievemaxroot = isqrt(N)/3;
boost::dynamic_bitset<> sieve(sievemax);
sieve.set();
primes.push_back(2);
primes.push_back(3);
for (i = 1; i <= sievemaxroot; i++) {
if (sieve[i]) {
k = (3*i + 1) | 1;
l = (4*k-2*k*(i&1)) / 3;
for (j = k*k/3; j < sievemax; j += 2*k) {
sieve[j] = 0;
sieve[j+l] = 0;
}
primes.push_back(k);
}
}
for (i = sievemaxroot + 1; i < sievemax; i++) {
if (sieve[i]) primes.push_back((3*i+1)|1);
}
}
```

`dynamic_bitset`

like you have, just fill that in, and then write out the sieve in a single loop. That will probably make your version run much faster, even without trying to copy the techniques from the Python version. – Jeremiah Willcock Mar 13 '11 at 23:34`return [2,3] + [3*i+1|1 for i in xrange(1,n/3-correction) if sieve[i]]`

. And that's pretty much what I'm doing too. The first loop is sieving in place and already pushing the primes that we know and the second loop is to push the primes that come after the root of the sievelimit. – orlp Mar 13 '11 at 23:38`sieve`

itself change its length, although I can't tell for sure. They do add elements while returning, as you demonstrate, however. – Jeremiah Willcock Mar 14 '11 at 0:04