How to find a number of prime numbers?

I need to find a certain amount of prime numbers. I have a working algorithm which takes a number-limit as a parameter - it finds all primes that are less than the limit.

For example - for param `20` it would return `2,3,5,7,11,13,17,19`, but I need to input `5` and get `2,3,5,7,11`. What is the best way? I am using the Sieve of Eratosthenes and there is no way to limit the number-deleting part, since I don't know how big the 195th prime number is and I therefore don't know if I should delete all multiples of 2 up to 1568 or 1268426. I hope the question is clear, thanks for help

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Can you provide your code or at least some pseudo-code? – jbranchaud Jan 29 '12 at 20:21
Is this a homework question? – Korhan Ozturk Jan 29 '12 at 20:22
See also: projecteuler.net/problem=7 - if you solve it, you will get access to some useful resources. – Tomasz Nurkiewicz Jan 29 '12 at 20:23
@KorhanÖztürk nope, it's a part of a older competition in programming, specifically in algorithms and this was bugging me off – Martin Melka Jan 29 '12 at 20:32
I see.. So, did the algorithm below worked for you? @Magicmaster – Korhan Ozturk Jan 29 '12 at 21:08

There are several ways to do what you want.

The prime number theorem says that the number of primes less than n is asymptotically equal to n/log(n). You could add a small buffer, then do the Sieve of Eratosthenes, and throw out any primes beyond your limit.

Rather than an approximation, there are formulas that compute the exact number of primes less than n without listing the primes. You could use one of those formulas to find the n th prime, then use a Sieve to make the list of primes. Google for "Legendre sum" and "Lehmer's formula" if you want to take this approach.

You could use a segmented Sieve of Eratosthenes. Sieve up to some convenient limit. If you've got the answer, stop. Otherwise, pick the next segment, and then the next, and so on until you've found the number of primes that you want.

There is a very clever method of generating an infinite list of primes that replaces the bit-array of the Sieve of Eratosthenes with a priority queue. Google for Melissa O'Neill's paper The Genuine Sieve of Eratosthenes.

You can see complete explanations and implementations of all of these algorithms here.

By the way, the 195th prime is 1187. There are 247 primes less than 1568, and 97790 primes less than 1268426.

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The best options are, in my opinion, the segmented sieve and a monolithic sieve with upper bound derived from the prime number theorem plus a small buffer. The priority queue method is slow. – Daniel Fischer Jan 30 '12 at 5:33
Agreed. There is actually an exact formula for the upper bound of the number of primes not exceeding n, which you can look up in any number theory textbook. But it misses the mark by quite a bit, and you're probably better off with the n / log(n) approximation. PS to Fischer: thanks for the edit. – user448810 Jan 30 '12 at 13:49

Sometime ago, I wrote a small module that deals with prime numbers (which served my needs when working on Project Euler stuff). This is decently quick in that it keeps track of a list of prime numbers it has seen. This greatly reduces the computation time.

This is the major routine you will need (written in python). The documentation is mediocre, but I hope this helps.

``````def primes(num, l=[]):

# l is the list of prime numbers you already have
# This is reused to check for primality of a number

if len(l) == 0: l = get_list() # Read from disk

# Check to see if a sublist can be created
e = l[-1]
if (num < e):
res = search.binary_low(l, num)
return l[:res[0]+1]

e = 6*(ceil(e/6))

lim = num + 1
# Extend the current list
for n in range(e, lim, 6):
m = n - 1
if isprime(m, l): l.append(m)
m = n + 1
if isprime(m, l): l.append(m)

# Save to pickle
set_list(l) # Write to disk

return l
``````

You can find related routines over here

https://github.com/pavanky/expo/blob/master/python/prime.py

https://github.com/pavanky/expo/blob/master/python/search.py

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You can take the same idea behind the original Sieve of Eratosthenes, but do it iteratively.

``````find_n_primes(num_primes):
primes = [2]
i = 3
while primes.size < num_primes:
is_prime = true
for p in primes:
if p > sqrt(i):
break
if i % p == 0:
is_prime = false
break
if is_prime: