# Time complexity of an algorithm to find prime numbers

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)
``````
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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
@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
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
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

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.

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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 `for`s 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
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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;
}
}
``````
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sqrt(n) is O(1) in practice, whether fast or slow. –  Will Ness Sep 4 at 10:34