# C#: Implementation of the Sieve of Atkin

I was wondering if someone here have a good implementation of the Sieve of Atkin that they would like to share.

I am trying to implement it, but can't quite wrap my head around it. Here is what I have so far.

``````public class Atkin : IEnumerable<ulong>
{

public Atkin(ulong limit)
{
this.limit = limit;
primes = new List<ulong>();
}

private void FindPrimes()
{
var isPrime = new bool[limit + 1];
var sqrt = Math.Sqrt(limit);

for (ulong x = 1; x <= sqrt; x++)
for (ulong y = 1; y <= sqrt; y++)
{
var n = 4*x*x + y*y;
if (n <= limit && (n % 12 == 1 || n % 12 == 5))
isPrime[n] ^= true;

n = 3*x*x + y*y;
if (n <= limit && n % 12 == 7)
isPrime[n] ^= true;

n = 3*x*x - y*y;
if (x > y && n <= limit && n % 12 == 11)
isPrime[n] ^= true;
}

for (ulong n = 5; n <= sqrt; n++)
if (isPrime[n])
for (ulong k = n*n; k <= limit; k *= k)
isPrime[k] = false;

for (ulong n = 5; n <= limit; n++)
if (isPrime[n])
}

public IEnumerator<ulong> GetEnumerator()
{
if (!primes.Any())
FindPrimes();

foreach (var p in primes)
yield return p;
}

IEnumerator IEnumerable.GetEnumerator()
{
return GetEnumerator();
}
}
``````

I have pretty much just tried to "translate" the pseudocode listed at Wikipedia, but it isn't working correctly. So either I have misunderstood something or just done something wrong. Or most likely both...

Have a list of the first 500 primes which I use as a test and my implementation fails at number 40(or 41?).

Values differ at index [40]
Expected: 179
But was: 175

Are you able to find my mistake, do you have an implementation laying around that you could share, or both?

The exact test I am using looks like this:

``````public abstract class AtkinTests
{
[Test]
public void GetEnumerator_FirstFiveHundredNumbers_AreCorrect()
{
var sequence = new Atkin(2000000);
var actual = sequence.Take(500).ToArray();
var expected = First500;

CollectionAssert.AreEqual(expected, actual);
}

private static readonly ulong[] First500 = new ulong[]
{
2, 3, 5, 7, 11, 13, 17, ...
};
}
``````
-
I've made an implementation that is a little faster than yours and a lot faster on a multi-core, see alicebobandmallory.com/articles/2010/01/14/… –  Jonas Elfström Jan 15 '10 at 9:31

This code:

``````for (ulong k = n*n; k <= limit; k *= k)
isPrime[k] = false;
``````

doesn't seem to be a faithful translation of this pseudocode:

``````is_prime(k) ← false, k ∈ {n², 2n², 3n², ..., limit}
``````

Your code looks like it will run for n * n, n ^ 4, n ^ 8, etc. i.e. squaring each time instead of adding n-squared each time. Try this:

``````ulong nSquared = n * n;
for (ulong k = nSquared; k <= limit; k += nSquared)
isPrime[k] = false;
``````
-
Awesome! That seems to have been it actually... and I was in fact a bit unsure about that exact part, just didn't know how to write it correctly :P –  Svish Oct 14 '09 at 21:43

Here's another implementation. It uses BitArray to save memory. The Parallel.For needs .NET Framework 4.

``````static List<int> FindPrimesBySieveOfAtkins(int max)
{
//  var isPrime = new BitArray((int)max+1, false);
//  Can't use BitArray because of threading issues.
var isPrime = new bool[max + 1];
var sqrt = (int)Math.Sqrt(max);

Parallel.For(1, sqrt, x =>
{
var xx = x * x;
for (int y = 1; y <= sqrt; y++)
{
var yy = y * y;
var n = 4 * xx + yy;
if (n <= max && (n % 12 == 1 || n % 12 == 5))
isPrime[n] ^= true;

n = 3 * xx + yy;
if (n <= max && n % 12 == 7)
isPrime[n] ^= true;

n = 3 * xx - yy;
if (x > y && n <= max && n % 12 == 11)
isPrime[n] ^= true;
}
});

var primes = new List<int>() { 2, 3 };
for (int n = 5; n <= sqrt; n++)
{
if (isPrime[n])
{
int nn = n * n;
for (int k = nn; k <= max; k += nn)
isPrime[k] = false;
}
}

for (int n = sqrt + 1; n <= max; n++)
if (isPrime[n])

return primes;
}
``````
-
At first glance this looks really cool and it is indeed quite fast, but it seems as though it doesn't work properly. Try FindPrimesBySieveOfAtkins(1000000).Count and you will get different values around the 78500 mark. Presumably this is due to the parallelism, as I'm sure you can see. –  Dommer Dec 14 '10 at 2:54
You are absolutely right. I had my worries about the non thread safe characteristics of BitArray but I thought that the `isPrime[n] ^= true;` was an atomic operation and that it didn't matter in what order bit bits was flipped would make it possible to use anyway. Not so. Changed it to a boolean array and that seems to rock the boat but of course at a much bigger memory cost. –  Jonas Elfström Dec 14 '10 at 8:46
Would it be possible to use the bit array if you used the msdn.microsoft.com/en-us/library/… class or something? –  Svish Nov 17 '11 at 9:10
Can't say I see how. –  Jonas Elfström Nov 17 '11 at 21:57

Here is a faster implementation of the Sieve of Atkin, I stole the algorithm from this Python script here (I take no credit for the algorithm):

http://programmingpraxis.com/2010/02/19/sieve-of-atkin-improved/

``````using System;
using System.Collections;
using System.Collections.Generic;

namespace PrimeGenerator
{
// The block element type for the bit array,
// use any unsigned value. WARNING: UInt64 is
// slower even on x64 architectures.
using BitArrayType = System.UInt32;

// This should never be any bigger than 256 bits - leave as is.
using BitsPerBlockType = System.Byte;

// The prime data type, this can be any unsigned value, the limit
// of this type determines the limit of Prime value that can be
// found. WARNING: UInt64 is slower even on x64 architectures.
using PrimeType = System.Int32;

/// <summary>
/// Calculates prime number using the Sieve of Eratosthenes method.
/// </summary>
/// <example>
/// <code>
///     var lpPrimes = new Eratosthenes(1e7);
///     foreach (UInt32 luiPrime in lpPrimes)
///         Console.WriteLine(luiPrime);
/// </example>
public class Atkin : IEnumerable<PrimeType>
{
#region Constants

/// <summary>
/// Constant for number of bits per block, calculated based on size of BitArrayType.
/// </summary>
const BitsPerBlockType cbBitsPerBlock = sizeof(BitArrayType) * 8;

#endregion

#region Protected Locals

/// <summary>
/// The limit for the maximum prime value to find.
/// </summary>

/// <summary>
/// The number of primes calculated or null if not calculated yet.
/// </summary>
protected PrimeType? mpCount = null;

/// <summary>
/// The current bit array where a set bit means
/// the odd value at that location has been determined
/// to not be prime.
/// </summary>
protected BitArrayType[] mbaOddPrime;

#endregion

#region Initialisation

/// <summary>
/// Create Sieve of Atkin generator.
/// </summary>
/// <param name="limit">The limit for the maximum prime value to find.</param>
public Atkin(PrimeType limit)
{
// Check limit range
if (limit > PrimeType.MaxValue - (PrimeType)Math.Sqrt(PrimeType.MaxValue))
throw new ArgumentOutOfRangeException();

mpLimit = limit;

FindPrimes();
}

#endregion

#region Private Methods

/// <summary>
/// Finds the prime number within range.
/// </summary>
private unsafe void FindPrimes()
{
// Allocate bit array.
mbaOddPrime = new BitArrayType[(((mpLimit >> 1) + 1) / cbBitsPerBlock) + 1];

PrimeType lpYLimit, lpN, lpXX3, lpXX4, lpDXX, lpDN, lpDXX4, lpXX, lpX, lpYY, lpMinY, lpS, lpK;

fixed (BitArrayType* lpbOddPrime = &mbaOddPrime[0])
{
// n = 3x^2 + y^2 section
lpXX3 = 3;
for (lpDXX = 0; lpDXX < 12 * SQRT((mpLimit - 1) / 3); lpDXX += 24)
{
lpXX3 += lpDXX;
lpYLimit = (12 * SQRT(mpLimit - lpXX3)) - 36;
lpN = lpXX3 + 16;

for (lpDN = -12; lpDN < lpYLimit + 1; lpDN += 72)
{
lpN += lpDN;
lpbOddPrime[(lpN >> 1) / cbBitsPerBlock] ^=
(BitArrayType)((BitArrayType)1 << (int)((lpN >> 1) % cbBitsPerBlock));
}

lpN = lpXX3 + 4;
for (lpDN = 12; lpDN < lpYLimit + 1; lpDN += 72)
{
lpN += lpDN;
lpbOddPrime[(lpN >> 1) / cbBitsPerBlock] ^=
(BitArrayType)((BitArrayType)1 << (int)((lpN >> 1) % cbBitsPerBlock));
}
}

//    # n = 4x^2 + y^2 section
lpXX4 = 0;
for (lpDXX4 = 4; lpDXX4 < 8 * SQRT((mpLimit - 1) / 4) + 4; lpDXX4 += 8)
{
lpXX4 += lpDXX4;
lpN = lpXX4 + 1;

if ((lpXX4 % 3) != 0)
{
for (lpDN = 0; lpDN < (4 * SQRT(mpLimit - lpXX4)) - 3; lpDN += 8)
{
lpN += lpDN;
lpbOddPrime[(lpN >> 1) / cbBitsPerBlock] ^=
(BitArrayType)((BitArrayType)1 << (int)((lpN >> 1) % cbBitsPerBlock));
}
}
else
{
lpYLimit = (12 * SQRT(mpLimit - lpXX4)) - 36;
lpN = lpXX4 + 25;

for (lpDN = -24; lpDN < lpYLimit + 1; lpDN += 72)
{
lpN += lpDN;
lpbOddPrime[(lpN >> 1) / cbBitsPerBlock] ^=
(BitArrayType)((BitArrayType)1 << (int)((lpN >> 1) % cbBitsPerBlock));
}

lpN = lpXX4 + 1;
for (lpDN = 24; lpDN < lpYLimit + 1; lpDN += 72)
{
lpN += lpDN;
lpbOddPrime[(lpN >> 1) / cbBitsPerBlock] ^=
(BitArrayType)((BitArrayType)1 << (int)((lpN >> 1) % cbBitsPerBlock));
}
}
}

//    # n = 3x^2 - y^2 section
lpXX = 1;
for (lpX = 3; lpX < SQRT(mpLimit / 2) + 1; lpX += 2)
{
lpXX += 4 * lpX - 4;
lpN = 3 * lpXX;

if (lpN > mpLimit)
{
lpMinY = ((SQRT(lpN - mpLimit) >> 2) << 2);
lpYY = lpMinY * lpMinY;
lpN -= lpYY;
lpS = 4 * lpMinY + 4;
}
else
lpS = 4;

for (lpDN = lpS; lpDN < 4 * lpX; lpDN += 8)
{
lpN -= lpDN;
if (lpN <= mpLimit && lpN % 12 == 11)
lpbOddPrime[(lpN >> 1) / cbBitsPerBlock] ^=
(BitArrayType)((BitArrayType)1 << (int)((lpN >> 1) % cbBitsPerBlock));
}
}

// xx = 0
lpXX = 0;
for (lpX = 2; lpX < SQRT(mpLimit / 2) + 1; lpX += 2)
{
lpXX += 4*lpX - 4;
lpN = 3*lpXX;

if (lpN > mpLimit)
{
lpMinY = ((SQRT(lpN - mpLimit) >> 2) << 2) - 1;
lpYY = lpMinY * lpMinY;
lpN -= lpYY;
lpS = 4*lpMinY + 4;
}
else
{
lpN -= 1;
lpS = 0;
}

for (lpDN = lpS; lpDN < 4 * lpX; lpDN += 8)
{
lpN -= lpDN;
if (lpN <= mpLimit && lpN % 12 == 11)
lpbOddPrime[(lpN>>1) / cbBitsPerBlock] ^=
(BitArrayType)((BitArrayType)1 << (int)((lpN>>1) % cbBitsPerBlock));
}
}

// # eliminate squares
for (lpN = 5; lpN < SQRT(mpLimit) + 1; lpN += 2)
if ((lpbOddPrime[(lpN >> 1) / cbBitsPerBlock] & ((BitArrayType)1 << (int)((lpN >> 1) % cbBitsPerBlock))) != 0)
for (lpK = lpN * lpN; lpK < mpLimit; lpK += lpN * lpN)
if ((lpK & 1) == 1)
lpbOddPrime[(lpK >> 1) / cbBitsPerBlock] &=
(BitArrayType)~((BitArrayType)1 << (int)((lpK >> 1) % cbBitsPerBlock));
}
}

/// <summary>
/// Calculates the truncated square root for a number.
/// </summary>
/// <param name="value">The value to get the square root for.</param>
/// <returns>The truncated sqrt of the value.</returns>
private unsafe PrimeType SQRT(PrimeType value)
{
return (PrimeType)Math.Sqrt(value);
}

/// <summary>
/// Gets a bit value by index.
/// </summary>
/// <param name="bits">The blocks containing the bits.</param>
/// <param name="index">The index of the bit.</param>
/// <returns>True if bit is set, false if cleared.</returns>
private bool GetBitSafe(BitArrayType[] bits, PrimeType index)
{
if ((index & 1) == 1)
return (bits[(index >> 1) / cbBitsPerBlock] & ((BitArrayType)1 << (int)((index >> 1) % cbBitsPerBlock))) != 0;
else
return false;
}

#endregion

#region Public Properties

/// <summary>
/// Get the limit for the maximum prime value to find.
/// </summary>
public PrimeType Limit
{
get
{
return mpLimit;
}
}

/// <summary>
/// Returns the number of primes found in the range.
/// </summary>
public PrimeType Count
{
get
{
if (!mpCount.HasValue)
{
PrimeType lpCount = 0;
foreach (PrimeType liPrime in this) lpCount++;
mpCount = lpCount;
}

return mpCount.Value;
}
}

/// <summary>
/// Determines if a value in range is prime or not.
/// </summary>
/// <param name="test">The value to test for primality.</param>
/// <returns>True if the value is prime, false otherwise.</returns>
public bool this[PrimeType test]
{
get
{
if (test > mpLimit) throw new ArgumentOutOfRangeException();
if (test <= 1) return false;
if (test == 2) return true;
if ((test & 1) == 0) return false;
return !GetBitSafe(mbaOddPrime, test >> 1);
}
}

#endregion

#region Public Methods

/// <summary>
/// Gets the enumerator for the primes.
/// </summary>
/// <returns>The enumerator of the primes.</returns>
public IEnumerator<PrimeType> GetEnumerator()
{
//    return [2,3] + filter(primes.__getitem__, xrange(5,limit,2))

// Two & Three always prime.
yield return 2;
yield return 3;

// Start at first block, third MSB (5).
int liBlock = 0;
byte lbBit = 2;
BitArrayType lbaCurrent = mbaOddPrime[0] >> lbBit;

// For each value in range stepping in incrments of two for odd values.
for (PrimeType lpN = 5; lpN <= mpLimit; lpN += 2)
{
// If current bit not set then value is prime.
if ((lbaCurrent & 1) == 1)
yield return lpN;

// Move to NSB.
lbaCurrent >>= 1;

// Increment bit value.
lbBit++;

// If block is finished.
if (lbBit == cbBitsPerBlock)
{
lbBit = 0;
lbaCurrent = mbaOddPrime[++liBlock];

//// Move to first bit of next block skipping full blocks.
while (lbaCurrent == 0)
{
lpN += ((PrimeType)cbBitsPerBlock) << 1;
if (lpN <= mpLimit)
lbaCurrent = mbaOddPrime[++liBlock];
else
break;
}
}
}
}

#endregion

#region IEnumerable<PrimeType> Implementation

/// <summary>
/// Gets the enumerator for the primes.
/// </summary>
/// <returns></returns>
IEnumerator IEnumerable.GetEnumerator()
{
return GetEnumerator();
}

#endregion
}
}
``````

Its close in speed to my most optimised version of the Sieve of Eratosthenes, but its still slower by about 20%, it can be found here:

http://stackoverflow.com/a/9700790/738380

-
processing the large array in chunks as you do for the multi-threaded version of the SoE will likely make this run faster than the equivalent version of your implementation of the SoE as it will reduce cache thrashing of memory access. However, if fairly high factors are eliminated using wheel factorization is applied to your SoE, the SoE will again outrun the SoA for any number range where we would care to wait (ie. less than days) because the number of composite culls of SoE will then be less than the number of toggles by this SoA. –  GordonBGood Oct 11 '13 at 4:36
Berstein and Atkin's reference implementation of the SoA as compared to an equivalent implementation of the SoE only used 2,3,5 wheel factorization for the SoE because that is equivalent to the native wheel factorization of SoA but much larger factors such as 2,3,5,7,11,13 are possible for the SoE whereas the SoA does not respond to further wheel factorization. In this way, the number of composite culls by SoE can be reduced to about two thirds of the number of toggles by SoA to likely put the SoE slightly ahead of an even further optimized SoA in spite of the extra complexity. –  GordonBGood Oct 11 '13 at 4:42
The question that should be asked is "Why use the Sieve of Atkin rather than the Sieve of Eratosthenes when both are maximally ooptimized?" and the answer is "There is likely no reason at all.", as I develop in this answer. This isn't why your SoA code here is 20% slower, which is more likely to be that this algorithm still hasn't completely removed the need for the modulo for one of the quadratic cases, nor is your implementation of the SoE maximally optimized as I develop in my multi-threading answer. –  GordonBGood Jan 1 at 2:28

Heres mine, it uses a class called CompartmentalisedParallel which allows you to perform parallel for loops but control the number of threads so that the indexes are grouped up. However, due to the threading issues you need to either lock the BitArray each time it is altered or create a separate BitArray for each thread and then XOR them together at the end, the first option was pretty slow because the amount of locks, the second option seemed faster for me!

``````using System;
using System.Collections;
using System.Collections.Generic;

namespace PrimeGenerator
{
public class Atkin : Primes
{
protected BitArray mbaPrimes;

public Atkin(int limit)
: this(limit, true)
{
}

: base(limit)
{
if (mbaPrimes == null) FindPrimes();
}

{
get
{
}
}

public override IEnumerator<int> GetEnumerator()
{
yield return 2;
yield return 3;
for (int lsN = 5; lsN <= msLimit; lsN += 2)
if (mbaPrimes[lsN]) yield return lsN;
}

private void FindPrimes()
{
mbaPrimes = new BitArray(msLimit + 1, false);

int lsSQRT = (int)Math.Sqrt(msLimit);

int[] lsSquares = new int[lsSQRT + 1];
for (int lsN = 0; lsN <= lsSQRT; lsN++)
lsSquares[lsN] = lsN * lsN;

{
CompartmentalisedParallel.For<BitArray>(
1, lsSQRT + 1, new ParallelOptions(),
(start, finish) => { return new BitArray(msLimit + 1, false); },
(lsX, lsState, lbaLocal) =>
{
int lsX2 = lsSquares[lsX];

for (int lsY = 1; lsY <= lsSQRT; lsY++)
{
int lsY2 = lsSquares[lsY];

int lsN = 4 * lsX2 + lsY2;
if (lsN <= msLimit && (lsN % 12 == 1 || lsN % 12 == 5))
lbaLocal[lsN] ^= true;

lsN -= lsX2;
if (lsN <= msLimit && lsN % 12 == 7)
lbaLocal[lsN] ^= true;

if (lsX > lsY)
{
lsN -= lsY2 * 2;
if (lsN <= msLimit && lsN % 12 == 11)
lbaLocal[lsN] ^= true;
}
}

return lbaLocal;
},
(lbaResult, start, finish) =>
{
lock (mbaPrimes)
mbaPrimes.Xor(lbaResult);
},
-1
);
}
else
{
for (int lsX = 1; lsX <= lsSQRT; lsX++)
{
int lsX2 = lsSquares[lsX];

for (int lsY = 1; lsY <= lsSQRT; lsY++)
{
int lsY2 = lsSquares[lsY];

int lsN = 4 * lsX2 + lsY2;
if (lsN <= msLimit && (lsN % 12 == 1 || lsN % 12 == 5))
mbaPrimes[lsN] ^= true;

lsN -= lsX2;
if (lsN <= msLimit && lsN % 12 == 7)
mbaPrimes[lsN] ^= true;

if (lsX > lsY)
{
lsN -= lsY2 * 2;
if (lsN <= msLimit && lsN % 12 == 11)
mbaPrimes[lsN] ^= true;
}
}
}
}

for (int lsN = 5; lsN < lsSQRT; lsN += 2)
if (mbaPrimes[lsN])
{
var lsS = lsSquares[lsN];
for (int lsK = lsS; lsK <= msLimit; lsK += lsS)
mbaPrimes[lsK] = false;
}
}
}
}
``````

And the CompartmentalisedParallel class:

``````using System;

namespace PrimeGenerator
{
public static class CompartmentalisedParallel
{
#region Int

private static int[] CalculateCompartments(int startInclusive, int endExclusive, ref int threads)
{

for (int liCount = 0; liCount < threads; liCount++)

}

public static void For<TLocal>(
int startInclusive, int endExclusive,
ParallelOptions parallelOptions,
Func<int, int, TLocal> localInit,
Func<int, ParallelLoopState, TLocal, TLocal> body,
Action<TLocal, int, int> localFinally,
{

Parallel.For(
{

body(liCounter, lsState, llLocal);

}
);
else
{
TLocal llLocal = localInit(startInclusive, endExclusive);
for (int liCounter = startInclusive; liCounter < endExclusive; liCounter++)
body(liCounter, null, llLocal);
localFinally(llLocal, startInclusive, endExclusive);
}
}

public static void For(
int startInclusive, int endExclusive,
ParallelOptions parallelOptions,
Action<int, ParallelLoopState> body,
{

Parallel.For(
{
body(liCounter, lsState);
}
);
else
for (int liCounter = startInclusive; liCounter < endExclusive; liCounter++)
body(liCounter, null);
}

public static void For(
int startInclusive, int endExclusive,
ParallelOptions parallelOptions,
Action<int> body,
{

Parallel.For(
{
body(liCounter);
}
);
else
for (int liCounter = startInclusive; liCounter < endExclusive; liCounter++)
body(liCounter);
}

public static void For(
int startInclusive, int endExclusive,
Action<int, ParallelLoopState> body,
{
For(startInclusive, endExclusive, new ParallelOptions(), body, threads);
}

public static void For(
int startInclusive, int endExclusive,
Action<int> body,
{
For(startInclusive, endExclusive, new ParallelOptions(), body, threads);
}

public static void For<TLocal>(
int startInclusive, int endExclusive,
Func<int, int, TLocal> localInit,
Func<int, ParallelLoopState, TLocal, TLocal> body,
Action<TLocal, int, int> localFinally,
{
For<TLocal>(startInclusive, endExclusive, new ParallelOptions(), localInit, body, localFinally, threads);
}

#endregion

#region Long

private static long[] CalculateCompartments(long startInclusive, long endExclusive, ref long threads)
{

for (long liCount = 0; liCount < threads; liCount++)

}

public static void For<TLocal>(
long startInclusive, long endExclusive,
ParallelOptions parallelOptions,
Func<long, long, TLocal> localInit,
Func<long, ParallelLoopState, TLocal, TLocal> body,
Action<TLocal, long, long> localFinally,
{

Parallel.For(
{

body(liCounter, lsState, llLocal);

}
);
else
{
TLocal llLocal = localInit(startInclusive, endExclusive);
for (long liCounter = startInclusive; liCounter < endExclusive; liCounter++)
body(liCounter, null, llLocal);
localFinally(llLocal, startInclusive, endExclusive);
}
}

public static void For(
long startInclusive, long endExclusive,
ParallelOptions parallelOptions,
Action<long, ParallelLoopState> body,
{

Parallel.For(
{
body(liCounter, lsState);
}
);
else
for (long liCounter = startInclusive; liCounter < endExclusive; liCounter++)
body(liCounter, null);
}

public static void For(
long startInclusive, long endExclusive,
ParallelOptions parallelOptions,
Action<long> body,
{

Parallel.For(
{
body(liCounter);
}
);
else
for (long liCounter = startInclusive; liCounter < endExclusive; liCounter++)
body(liCounter);
}

public static void For(
long startInclusive, long endExclusive,
Action<long, ParallelLoopState> body,
{
For(startInclusive, endExclusive, new ParallelOptions(), body, threads);
}

public static void For(
long startInclusive, long endExclusive,
Action<long> body,
{
For(startInclusive, endExclusive, new ParallelOptions(), body, threads);
}

public static void For<TLocal>(
long startInclusive, long endExclusive,
Func<long, long, TLocal> localInit,
Func<long, ParallelLoopState, TLocal, TLocal> body,
Action<TLocal, long, long> localFinally,
{
For<TLocal>(startInclusive, endExclusive, new ParallelOptions(), localInit, body, localFinally, threads);
}

#endregion
}
}
``````

Primes base class:

``````using System.Collections;
using System.Collections.Generic;

namespace PrimeGenerator
{
public abstract class Primes : IEnumerable<int>
{

public Primes(int limit)
{
msLimit = limit;
}

public int Limit
{
get
{
return msLimit;
}
}

public int Count
{
get
{
int liCount = 0;
foreach (int liPrime in this)
liCount++;
return liCount;
}
}

public abstract IEnumerator<int> GetEnumerator();

IEnumerator IEnumerable.GetEnumerator()
{
return GetEnumerator();
}
}
}
``````

Use it by doing the following:

``````    var lpPrimes = new Atkin(count, true);
Console.WriteLine(lpPrimes.Count);
Console.WriteLine(s.ElapsedMilliseconds);
``````

However, i found the Eratosthenes to be quicker in all cases, even with a four core CPU running in multithreaded mode for the Atkin:

``````using System;
using System.Collections;
using System.Collections.Generic;

namespace PrimeGenerator
{
public class Eratosthenes : Primes
{
protected BitArray mbaOddEliminated;

public Eratosthenes(int limit)
: base(limit)
{
if (mbaOddEliminated == null) FindPrimes();
}

public override IEnumerator<int> GetEnumerator()
{
yield return 2;
for (int lsN = 3; lsN <= msLimit; lsN+=2)
if (!mbaOddEliminated[lsN>>1]) yield return lsN;
}

private void FindPrimes()
{
mbaOddEliminated = new BitArray((msLimit>>1) + 1);
int lsSQRT = (int)Math.Sqrt(msLimit);
for (int lsN = 3; lsN < lsSQRT + 1; lsN += 2)
if (!mbaOddEliminated[lsN>>1])
for (int lsM = lsN*lsN; lsM <= msLimit; lsM += lsN<<1)
mbaOddEliminated[lsM>>1] = true;
}
}
}
``````

If you get the Atkin to run faster, please let me know!

-
You can get the Sieve of Atkin (SoA) to run faster in several ways: 1) Avoid all need for the (expensive) modulo operations by recognizing that each of the quadratic sequences "4*x^2+y^2", "3*x^2+y^2", and "3*x^2-y^2" follow a modulo 15 pattern so as to only generate the appropriate modulo numbers for each following that pattern to be faster by over a factor of 2, 2) you can segment the culling arrays so that there aren't concurrency issues as each thread has one (preferably bit based) array. Of course, the SoE can also be segmented and have wheel factorization applied for an addition gain. –  GordonBGood Oct 10 '13 at 5:00
cont'd: In the end, the SoA only runs faster when the SoE is restricted to a wheel factorization of the same elimination of the factors of 2, 3, and 5 upon which the SoA is based; a maximally optimized SoE is still faster than a maximally optimized SoA for any ranges of primes we are likely to want to wait. This is even more true when written using a native compiling language such as C++ in that the simpler operations of the SoE are more conducive to compiler optimizations such that it can take as little as three CPU clock cycles per composite cull. I don't think SoA can be that efficient. –  GordonBGood Oct 10 '13 at 7:35
cont'd: I have written a C# version which enumerates all the 203,280,221 primes to (four billion plus) in about 7.5 seconds on an i7-2700K processor (3.5 GHz) another answer here which uses seqmentation, multi-threading, and wheel factorization. Over 2/3's of this time is enumerating the found primes, so the algorithm (SoE/SoA) doesn't matter much if both are optimized. That answer only uses 2,3,5 wheel factorization so an optimized SoA should be slightly faster, but if I used say 2,3,5,7,11,13 factorization then the SoE will be faster again. –  GordonBGood Oct 10 '13 at 10:24
it seems your later answer in the code translated from Python has improved the optimization issues I raise in my first comment, but you still haven't applied segmentation and multi-threading to the SoA... –  GordonBGood Oct 11 '13 at 4:16

Heres an improvement of the Sieve of Eratosthenes using custom FixBitArrays and unsafe code for speed results, this is about 225% faster than my previous Eratosthenes algorithm, and the class is standalone (this is not multithreaded - Eratosthenes is not compatible with multi threading), On an AMD Phenom II X4 965 Processor I can calculate Primes to 1,000,000,000 limit in 9,261 ms:

``````using System;
using System.Collections;
using System.Collections.Generic;

namespace PrimeGenerator
{
// The block element type for the bit array,
// use any unsigned value. WARNING: UInt64 is
// slower even on x64 architectures.
using BitArrayType = System.UInt32;

// This should never be any bigger than 256 bits - leave as is.
using BitsPerBlockType = System.Byte;

// The prime data type, this can be any unsigned value, the limit
// of this type determines the limit of Prime value that can be
// found. WARNING: UInt64 is slower even on x64 architectures.
using PrimeType = System.UInt32;

/// <summary>
/// Calculates prime number using the Sieve of Eratosthenes method.
/// </summary>
/// <example>
/// <code>
///     var lpPrimes = new Eratosthenes(1e7);
///     foreach (UInt32 luiPrime in lpPrimes)
///         Console.WriteLine(luiPrime);
/// </example>
public class Eratosthenes : IEnumerable<PrimeType>
{
#region Constants

/// <summary>
/// Constant for number of bits per block, calculated based on size of BitArrayType.
/// </summary>
const BitsPerBlockType cbBitsPerBlock = sizeof(BitArrayType) * 8;

#endregion

#region Protected Locals

/// <summary>
/// The limit for the maximum prime value to find.
/// </summary>

/// <summary>
/// The current bit array where a set bit means
/// the odd value at that location has been determined
/// to not be prime.
/// </summary>
protected BitArrayType[] mbaOddNotPrime;

#endregion

#region Initialisation

/// <summary>
/// Create Sieve of Eratosthenes generator.
/// </summary>
/// <param name="limit">The limit for the maximum prime value to find.</param>
public Eratosthenes(PrimeType limit)
{
// Check limit range
if (limit > PrimeType.MaxValue - (PrimeType)Math.Sqrt(PrimeType.MaxValue))
throw new ArgumentOutOfRangeException();

mpLimit = limit;

FindPrimes();
}

#endregion

#region Private Methods

/// <summary>
/// Finds the prime number within range.
/// </summary>
private unsafe void FindPrimes()
{
// Allocate bit array.
mbaOddNotPrime = new BitArrayType[(((mpLimit >> 1) + 1) / cbBitsPerBlock) + 1];

// Cache Sqrt of limit.
PrimeType lpSQRT = (PrimeType)Math.Sqrt(mpLimit);

// Fix the bit array for pointer access
fixed (BitArrayType* lpbOddNotPrime = &mbaOddNotPrime[0])
// Scan primes up to lpSQRT
for (PrimeType lpN = 3; lpN <= lpSQRT; lpN += 2)
// If the current bit value for index lpN is cleared (prime)
if (
(
lpbOddNotPrime[(lpN >> 1) / cbBitsPerBlock] &
((BitArrayType)1 << (BitsPerBlockType)((lpN >> 1) % cbBitsPerBlock))
) == 0
)
// Leave it cleared (prime) and mark all multiples of lpN*2 from lpN*lpN as not prime
for (PrimeType lpM = lpN * lpN; lpM <= mpLimit; lpM += lpN << 1)
// Set as not prime
lpbOddNotPrime[(lpM >> 1) / cbBitsPerBlock] |=
(BitArrayType)((BitArrayType)1 << (BitsPerBlockType)((lpM >> 1) % cbBitsPerBlock));
}

/// <summary>
/// Gets a bit value by index.
/// </summary>
/// <param name="bits">The blocks containing the bits.</param>
/// <param name="index">The index of the bit.</param>
/// <returns>True if bit is set, false if cleared.</returns>
private bool GetBitSafe(BitArrayType[] bits, PrimeType index)
{
return (bits[index / cbBitsPerBlock] & ((BitArrayType)1 << (BitsPerBlockType)(index % cbBitsPerBlock))) != 0;
}

#endregion

#region Public Properties

/// <summary>
/// Get the limit for the maximum prime value to find.
/// </summary>
public PrimeType Limit
{
get
{
return mpLimit;
}
}

/// <summary>
/// Returns the number of primes found in the range.
/// </summary>
public PrimeType Count
{
get
{
PrimeType lptCount = 0;
foreach (PrimeType liPrime in this)
lptCount++;
return lptCount;
}
}

/// <summary>
/// Determines if a value in range is prime or not.
/// </summary>
/// <param name="test">The value to test for primality.</param>
/// <returns>True if the value is prime, false otherwise.</returns>
public bool this[PrimeType test]
{
get
{
if (test > mpLimit) throw new ArgumentOutOfRangeException();
if (test <= 1) return false;
if (test == 2) return true;
if ((test & 1) == 0) return false;
return !GetBitSafe(mbaOddNotPrime, test >> 1);
}
}

#endregion

#region Public Methods

/// <summary>
/// Gets the enumerator for the primes.
/// </summary>
/// <returns>The enumerator of the primes.</returns>
public IEnumerator<PrimeType> GetEnumerator()
{
// Two always prime.
yield return 2;

// Start at first block, second MSB.
int liBlock = 0;
byte lbBit = 1;
BitArrayType lbaCurrent = mbaOddNotPrime[0] >> 1;

// For each value in range stepping in incrments of two for odd values.
for (PrimeType lpN = 3; lpN <= mpLimit; lpN += 2)
{
// If current bit not set then value is prime.
if ((lbaCurrent & 1) == 0)
yield return lpN;

// Move to NSB.
lbaCurrent >>= 1;

// Increment bit value.
lbBit++;

// If block is finished.
if (lbBit == cbBitsPerBlock)
{
// Move to first bit of next block.
lbBit = 0;
liBlock++;
lbaCurrent = mbaOddNotPrime[liBlock];
}
}
}

#endregion

#region IEnumerable<PrimeType> Implementation

/// <summary>
/// Gets the enumerator for the primes.
/// </summary>
/// <returns>The enumerator for the prime numbers.</returns>
IEnumerator IEnumerable.GetEnumerator()
{
return GetEnumerator();
}

#endregion
}
}
``````

Primes found in 1,000,000,000: 50,847,534 in 9,261 ms

-
Quite fast but "Eratosthenes is not compatible with multi threading" is incorrect; it is if you take the right algorithmic approach: segment your large array into sub portions to cull each segment, which should be the size of the processor caches for better memory access efficiency, then use a number of threads equal to the number of processors to handle each successive segment page, with one extra segment for the foreground counter/enumerator to process. Your AMD X4 CPU's run time should by divided by 4 except for the time to count/enumerate the primes so about 2.5 seconds for 1 billion. –  GordonBGood Aug 20 '13 at 19:16