# Fast algorithm for finding prime numbers? [duplicate]

First of all - I checked a lot in this forum and I haven't found something fast enough. I try to make a function that returns me the prime numbers in a specified range. For example I did this function (in C#) using the sieve of Eratosthenes. I tried also Atkin's sieve but the Eratosthenes one runs faster (in my implementation):

``````public static void SetPrimesSieve(int Range)
{
Primes = new List<uint>();
int Half = (Range - 1) >> 1;
BitArray Nums = new BitArray(Half, false);
int Sqrt = (int)Math.Sqrt(Range);
for (int i = 3, j; i <= Sqrt; )
{
for (j = ((i * i) >> 1) - 1; j < Half; j += i)
Nums[j] = true;
do
i += 2;
while (i <= Sqrt && Nums[(i >> 1) - 1]);
}
for (int i = 0; i < Half; ++i)
if (!Nums[i])
}
``````

It runs about twice faster than codes & algorithms I found... There's should be a faster way to find prime numbers, could you help me?

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## marked as duplicate by George Stocker♦Jun 3 '13 at 12:24

In what range are you looking for primes? Just between 0 and max int? Also how wide is the range? –  Gleno Sep 27 '10 at 21:52
let's say something like billion/2 –  Ohad Sep 27 '10 at 21:56
There are 50M primes less than 10^9, so precomputing them would give you a 200MB table. It would actually be smaller to just store the sieve (10^9 bits is 125MB, and you don't need to store the even bits, so you could fit it all in under 64MB). –  Gabe Sep 27 '10 at 22:07
BTW, I just ran `SetPrimesSieve(1e9)` on my computer and it computed a million primes per second. I doubt many algorithms can compute more than a million anything per second! –  Gabe Sep 27 '10 at 22:22
You can try a multi-threaded version of the algorithm: google.com/search?q=parallel+sieve+of+eratosthenes –  Sheldon L. Cooper Sep 28 '10 at 0:11
show 1 more comment

When searching around for algorithms on this topic (for project Euler) I don't remember finding anything faster. If speed is really the concern, have you thought about just storing the primes so you simply need to look it up?

EDIT: quick google search found this, confirming that the fastest method would be just to page the results and look them up as needed.

One more edit - you may find more information here, essentially a duplicate of this topic. Top post there states that atkin's sieve was faster than eras' as far as generating on the fly.

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no, those aren't fast, even my code is faster. I really saw something that says it's very fast(somewhy I don't trust it...) I'll check it tommorow, I have to go. thanks anyway. (it's not duplicate of the other topic, there were slow answers) –  Ohad Sep 27 '10 at 22:27
That is an awesome article, +1 –  NickLarsen Oct 28 '10 at 13:22
there are algorithms very very faster than this simple one, see my answer –  Saeed Amiri Oct 28 '10 at 20:09

The fastest algorithm in my experience so far is the Sieve of Erathostenes with wheel factorization for 2, 3 and 5, where the primes among the remaining numbers are represented as bits in a byte array. In Java on one core of my 3 year old Laptop it takes 23 seconds to compute the primes up to 1 billion.

With wheel factorization the Sieve of Atkin was about a factor of two slower, while with an ordinary `BitSet` it was about 30% faster.

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I did an algorithm that can find prime numbers from range 2-90 000 000 for 0.65 sec on I 350M-notebook, written in C .... you have to use bitwise operations and have "code" for recalculating index of your array to index of concrete bit you want. for example If you want folds of number 2, concrete bits will be for example ....10101000 ... so if you read from left ... you get index 4,6,8 ... thats it

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1. For speed, precompute then load from disk. It's super fast. I did it in Java long ago.

2. Don't store as an array, store as a bitsequence for odd numbers. Way more efficient on memory

3. If your speed question is that you want this particular computation to run fast (you need to justify why you can't precompute and load it from disk) you need to code a better Atkin's sieve. It is faster. But only slightly.

4. You haven't indicated the end use for these primes. We may be missing something completely because you've not told us the application. Tell us a sketch of the application and the answers will be targetted better for your context.

5. Why on earth do you think something faster exists? You haven't justified your hunch. This is a very hard problem. (that is to find something faster)

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