Hmm, very interesting. Your code is actual honest to goodness *genuine sieve of Eratosthenes* IMHO, counting its way along the ascending natural numbers by decrementing each counter that it sets up for each prime encountered, by 1 on each step.

And it is very inefficient. Tested on Ideone it runs at the same empirical order of growth `~ n^2.2`

(at the tested range of few thousand primes produced) as the famously inefficient Turner's trial division sieve (in Haskell).

Why? Several reasons. *First*, no **early bailout** in your test: when you detect it's a composite, you continue processing the array of counters, `sieve`

. You have to, because of the *second reason*: you **count** the difference **by decrementing** each counter by 1 on each step, with 0 representing your current position. This is the most faithful expression of the original sieve IMHO, and it is very inefficient: today our CPUs know how to add numbers in O(1) time (if those numbers belong to a certain range, 0 .. 2^32, or 0 .. 2^64, of course).

Moreover, our computers also have direct access memory now, and having calculated the far-off number we can mark it in a random access array. Which is the foundation of the efficiency of the sieve of Eratosthenes on modern computers - both the direct calculation, and the direct marking of multiples.

And *third*, perhaps the most immediate reason for inefficiency, is the *premature* handling of the multiples: when you encounter 5 as a prime, you add its first multiple (not yet encountered) i.e. 25, *right away* into the array of counters, `sieve`

(i.e. the distance between the current point and the multiple, `i*i-i`

). That is much too soon. The addition of 25 must be *postponed* until ... well, until we encounter 25 among the ascending natural numbers. Starting to handle the multiples of each prime prematurely (at `p`

instead of `p*p`

) leads to having way too many counters to maintain - `O(n)`

of them (where `n`

is the number of primes produced), instead of just `O(π(sqrt(n log n))) = O(sqrt(n / log n))`

.

The *postponement* optimization when applied on a similar "counting" sieve in Haskell brought its empirical orders of growth from `~ n^2.3 .. 2.6`

for `n = 1000 .. 6000`

primes down to just above `~ n^1.5`

(with obviously enormous gains in speed). When counting was further replaced by direct addition, the resulting measured empirical orders of growth were `~ n^1.2 .. 1.3`

in producing up to hlaf a million primes (although in all probability it would gain on `~ n^1.5`

for bigger ranges).