It is the number of times the sieve will be run to eliminate all non-primes from the list.

```
result.RemoveAll(i => i > result[index] && i % result[index] == 0);
```

Each time you run the sieve, this line of code takes the smallest number in the list (the smallest prime that the `result`

hasn't had all its multiples removed of yet) and then removes all the multiples. This is run 168 times, and on the 168th time the smallest number the list hasn't been screened of yet is 997, which naturally is the 168th prime.

This only needs to be run 168 times because all numbers can be expressed as the product of a list of primes, and there is no number less than 1000000 that is a multiple of the 169th primes number (1,009) that is NOT a multiple of a prime lower than 1009. The lowest number that this would removed by sieving out 1009 that has NOT been removed already is `1009 * 1013 = 1,022,117`

, or the 169th primes multiplied by the 170th prime, which is clearly greater than 100000 and thus doesn't need to be checked for this set of numbers.

Hence, all the multiples of 1009 have already been removed from the list when you get to that point, so there's no point in continuing as you already have removed all the non-primes from the list. :D

not a Sieve of Eratosthenes, which would only use additions to cull composite numbers from an array;it is a Trial Division Prime Sieveas it eliminates composite numbers over a range by trial division and testing for non zero remainders. It is a kind of optimized version because it only divides by found primes. It isn't an exact optimization because it requires an estimate of at least the number of primes up to the square root of the range (as 168 is the number of primes to 1000 for range 1000000). A better version is here. – GordonBGood Apr 30 '14 at 7:41