# Why is my implementation of Atkin sieve is slower than Eratosthenes?

I'm doing problems from Project Euler in Ruby and implemented Atkin's sieve for finding prime numbers but it runs slower than sieve of Eratosthenes. What is the problem?

``````def atkin_sieve(n)
primes = [2,3,5]

sieve = Array.new(n+1, false)

y_upper = n-4 > 0 ? Math.sqrt(n-4).truncate : 1
for x in (1..Math.sqrt(n/4).truncate)
for y in (1..y_upper)
k = 4*x**2 + y**2
sieve[k] = !sieve[k] if k%12 == 1 or k%12 == 5
end
end

y_upper = n-3 > 0 ? Math.sqrt(n-3).truncate : 1
for x in (1..Math.sqrt(n/3).truncate)
for y in (1..y_upper)
k = 3*x**2 + y**2
sieve[k] = !sieve[k] if k%12 == 7
end
end

for x in (1..Math.sqrt(n).truncate)
for y in (1..x)
k = 3*x**2 - y**2
if k < n and k%12 == 11
sieve[k] = !sieve[k]
end
end
end

for j in (5...n)
if sieve[j]
prime = true
for i in (0...primes.length)
if j % (primes[i]**2) == 0
prime = false
break
end
end
primes << j if prime
end
end
primes
end

def erato_sieve(n)
primes = []
for i in (2..n)
if primes.all?{|x| i % x != 0}
primes << i
end
end
primes
end
``````
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Your "erato_sieve" is not even remotely related to the Sieve of Eratosthenes ... it is, rather, an inefficient version of en.wikipedia.org/wiki/Trial_division –  Jim Balter May 3 '13 at 4:40

As Wikipedia says, "The modern sieve of Atkin is more complicated, but faster when properly optimized" (my emphasis).

The first obvious place to save some time in the first set of loops would be to stop iterating over `y` when `4*x**2 + y**2` is greater than `n`. For example, if `n` is 1,000,000 and `x` is 450, then you should stop iterating when `y` is greater than 435 (instead of continuing to 999 as you do at the moment). So you could rewrite the first loop as:

``````for x in (1..Math.sqrt(n/4).truncate)
X = 4 * x ** 2
for y in (1..Math.sqrt(n - X).truncate)
k = X + y ** 2
sieve[k] = !sieve[k] if k%12 == 1 or k%12 == 5
end
end
``````

(This also avoids re-computing `4*x**2` each time round the loop, though that is probably a very small improvement, if any.)

Similar remarks apply, of course, to the other loops over `y`.

A second place where you could speed things up is in the strategy for looping over `y`. You loop over all values of `y` in the range, and then check to see which ones lead to values of `k` with the correct remainders modulo 12. Instead, you could just loop over the right values of `y` only, and avoid testing the remainders altogether.

If `4*x**2` is 4 modulo 12, then `y**2` must be 1 or 9 modulo 12, and so `y` must be 1, 3, 5, 7, or 11 modulo 12. If `4*x**2` is 8 modulo 12, then `y**2` must be 5 or 9 modulo 12, so `y` must be 3 or 9 modulo 12. And finally, if `4*x**2` is 0 modulo 12, then `y**2` must be 1 or 5 modulo 12, so `y` must be 1, 5, 7, 9, or 11 modulo 12.

I also note that your sieve of Eratosthenes is doing useless work by testing divisibility by all primes below `i`. You can halt the iteration once you've test for divisibility by all primes less than or equal to the square root of `i`.

-

It would help a lot if you actually implemented the Sieve of Eratosthenes properly in the first place.

The critical feature of that sieve is that you only do one operation per time a prime divides a number. By contrast you are doing work for every prime less than the number. The difference is subtle, but the performance implications are huge.

Here is the actual sieve that you failed to implement:

``````def eratosthenes_primes(n)
primes = []
could_be_prime = (0..n).map{|i| true}
could_be_prime[0] = false
could_be_prime[1] = false
i = 0
while i*i <= n
if could_be_prime[i]
j = i*i
while j <= n
could_be_prime[j] = false
j += i
end
end
i += 1
end
return (2..n).find_all{|i| could_be_prime[i]}
end
``````

Compare this with your code for finding all of the primes up to 50,000. Also note that this can easily be sped up by a factor of 2 by special casing the logic for even numbers. With that tweak, this algorithm should be fast enough for every Project Euler problem that needs you to compute a lot of primes.

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Rather than `X=4 * x ** 2`, you could rely on the fact that `X` already has the value of `4 * (x-1) ** 2`. Since 4x^2 = 4(x-1)^2 + 4(2x - 1), all you need to do is add `8 * x - 4` to `X`. You can use this same trick for `k`, and the other places where you have repeated calculations (like 3x^2 + y^2).