Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

I was curious about prime numbers and would like to know the most efficient way to find relatively small prime numbers for a range up to say, 10 million. I read that the sieve of erastosthenes (SOE) is the most efficient way to find smaller prime numbers. I implemented SOE using python but had a few questions:

  1. The worst case running time of my algorithm seems to be O(n^2). I'm still learning, so I know this algorithm can be made more efficient.

  2. Is there a difference in the most efficient mathematical way and most efficient programming way to find prime numbers? Mathematically, SOE is one of the fastest, but programming-wise is SOE all that fast?

    def FindPrime(n):
        primes = [2, 3]
        for num in range(4, n):
            notprime = False
            for p in primes:
                if num % p == 0:
                    notprime = True
            if notprime == False:
                primes.append(num)
    
        print primes
    
    print FindPrime(100)
    
share|improve this question
    
For algo answer: stackoverflow.com/questions/453793/… –  Jason S Aug 6 at 1:42
    
But vanilla Python is not efficient at anything big & mathy, period. –  Jason S Aug 6 at 1:42
4  
@Jason S - Using Python is completely irrelevant to the asymptotic complexity/efficiency of algorithms, except maybe in that it provides a particular set of convenient ready-made building blocks. Assuming you use the same algorithm (with same-algorithm building blocks), Python may well be slower than C or C++, but only by constant factors. A key point about asymptotic analysis (big O etc) is that constant factors are irrelevant. –  Steve314 Aug 6 at 2:00
1  
The question asked about the difference between math & programming efficiency. If it's really just about the algo it is a dupe. –  Jason S Aug 6 at 2:03
2  
People have already answered your question, but I will just point out that the running time of your algorithm is n^2/log n as a consequence of the prime number theorem (the inner loop is order n/log n). –  TheGreatContini Aug 6 at 3:19

3 Answers 3

First of all, you should know that your algorithm isn't the sieve of Eratosthenes. You're using trial division.

There are a number of improvements that can be made to your implementation.

  1. Use xrange(), which is O(1) memory-wise, not range(), which is O(n).

  2. Skip even numbers in your search: xrange(4, n, 2) steps 2 at a time.

  3. Don't test if a prime p divides n when p > sqrt(n). It is not possible.

As you predicted, these changes don't affect the order of complexity, but you'll see a solid performance improvement.

As for a faster algorithm, first implement a real sieve of Eratosthenes, then try the much faster sieve of Atkin.

share|improve this answer
    
Great to know. Could you implement the sieve of erastosthenes here in python? Would love to see how it is coded in this language. –  MNRC Aug 6 at 3:34
    
Sieve of Atkins is only much faster than Erasthones version when you are using the optimized code. See cr.yp.to/primegen/primegen-0.97.tar.gz for the current version of the source code from the original authors of the improved sieve. –  Gary Walker Aug 6 at 4:01
    
Read the source that I referenced and you will see optimized code. It is algorithmiically opaque and hard to get right. But it does run fast. Suggesting writing the Atkin version is a waste of time for a newbie question; esp. in python. Python is great for a lot of things, all-purpose speed is not one of those things, even with PyPy, Psyco and Pyrex, etc. –  Gary Walker Aug 6 at 13:21
    
Sending a newbie to write C++ is wasting his time. This is learning. –  uʍop ǝpısdn Aug 6 at 22:02
  1. uʍop ǝpısdn is right your code is not SOE

  2. you can find mine SOE implementation here

    • which makes the prime finding more efficient then yours solution
  3. complexity of mine implementation of SOE

    • time: T(0.5·n·DIGAMMA(CEIL(SQRT(n))+0.3511·n) if the sqrt(N) is used like suggested in comment inside code
    • time(n= 1M): T(3.80*n)
    • time(n= 10M): T(4.38*n)
    • time(n= 100M): T(4.95*n)
    • time(n=1000M): T(5.53*n)
    • so approximately the run time is: T((0.3516+0.5756*log10(n))*n)
    • so the complexity is O(n.log(n))
  4. difference between speed (runtime) and complexity O()

    • the actual runtime is t=T(f(n))*c
    • for big enough n it converges to t=O(f(n))*c
    • where O() is the time complexity of algorithm
    • and T() is actual run time equation for any n (not O() !!!)
    • the c is some constant time which is needed to process single pass in all fors together etc...
    • better O() does not mean faster solution
    • for any n only after treshold where
    • O1(f1(n))*c1 < O2(f2(n))*c2
    • so if you well optimize the c constant then you can beat better complexity algorithms up to a treshold
    • for example your code is around T(n.n/2) -> O(n^2)
    • but for low n can be faster then mine SOE O(n.log(n))
    • because mine needs to prepare tables which takes more time then your divison up to a point
    • but after that yours get much much slower ...

So for the question if there is difference between most efficient math and programing solution

  • the answer is YES it can be on defined N-range
share|improve this answer

You can use fast inverse root algorithm which includes a little bit bithacking and find square root of a number in O(c) then can find it is prime or not ,in O(n^(1/2)) then at your problem you can find primes at interval in O(n*(n^(1/2))) and it is better than O(n^2) and if we look the algorithm you mention it is best way for lists(has bounds 0-something) because it does not check twice any value and its time complexity can be reduced to O((n^(1/2))*log(log(n))/log(n)) and it can use for creating look up tables and your implementation is partly wrong for idea , I write sample in c++ you can use it :

float root( float number )
{
    long i;
    float x2, y;
    const float threehalfs = 1.5F;

    x2 = number * 0.5F;
    y  = number;
    i  = * ( long * ) &y;                       // evil floating point bit level hacking
    i  = 0x5f3759df - ( i >> 1 );               // what the fuck?
    y  = * ( float * ) &i;
    y  = y * ( threehalfs - ( x2 * y * y ) );   // 1st iteration
    y  = y * ( threehalfs - ( x2 * y * y ) );   // 2nd iteration, this can be removed
    y  = y * ( threehalfs - ( x2 * y * y ) );   // 3rd iteration, this can be removed

    return 1/y;
}


void seo(int ub){//ub->upper bound should be at least 2
    if(ub<2)
        return;
    int size=ub-1;
    int *arr=new int[size];
    for(int i=0;i<size;i++){
        arr[i]=i+2;
    }
    int outer_ub=((int)root((float)ub))-1;
    for(int j=0;j<outer_ub;j++){
        if(arr[j]>0){
            int inc=arr[j];
            for(int i=inc+j;i<size;i+=inc){
                arr[i]=0;
            }
        }
    }
    for(int i=0;i<size;i++){
        if(arr[i]!=0)
            cout<<arr[i]<<endl;
    }
}
share|improve this answer
    
sqrt(n) is O(1) in practice, whether fast or slow. –  Will Ness Sep 4 at 10:34

Your Answer

 
discard

By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.