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I came across this (really) simple program a while ago. It just outputs the first x primes. I'm embarrassed to ask, is there any way to make it more "pythonic" ie condense it while making it (more) readable? Switching functions is fine; I'm only interested in readability.

Thanks

from math import sqrt


def isprime(n):
  if n ==2:
    return True
  if n % 2 ==0 : # evens
    return False

  max = int(sqrt(n))+1 #only need to search up to sqrt n 
  i=3
  while i <= max: # range starts with 3 and for odd i
    if n % i == 0:
      return False
    i+=2

  return True



reqprimes = int(input('how many primes: '))
primessofar = 0
currentnumber = 2
while primessofar < reqprimes:

  result = isprime(currentnumber)

  if result:
     primessofar+=1
     print currentnumber
     #print '\n'

  currentnumber += 1
share|improve this question

8 Answers 8

up vote 7 down vote accepted

Your algorithm itself may be implemented pythonically, but it's often useful to re-write algorithms in a functional way - You might end up with a completely different but more readable solution at all (which is even more pythonic).

def primes(upper):
    n = 2; found = []
    while n < upper:
        # If a number is not divisble through all preceding primes, it's prime
        if all(n % div != 0 for div in found):
            yield n
            found.append( n )
        n += 1

Usage:

for pr in primes(1000):
    print pr

Or, with Alasdair's comment taken into account, a more efficient version:

from math import sqrt
from itertools import takewhile

def primes(upper):
    n = 2; foundPrimes = []
    while n < upper:
        sqrtN = int(sqrt(n))
        # If a number n is not divisble through all preceding primes up to sqrt(n), it's prime
        if all(n % div != 0 for div in takewhile(lambda div: div <= sqrtN, foundPrimes)):
            yield n
            foundPrimes.append(n)
        n += 1
share|improve this answer
    
But please use set() for found instead of a list. This way it will be as slow as O(n*log) instead of as O(n^2). –  isagalaev Nov 21 '09 at 18:59
1  
@isagalaev: Er, no - you're wrong. You'll need to traverse any of the primes, not lookup one. In fact the list if more efficient since adding an element is O(1) instead of O(log n), –  Dario Nov 21 '09 at 19:30
    
The all statement is inefficient - you only need to check for div<=sqrt(n) –  Alasdair Nov 21 '09 at 19:38
    
@Alasdair: You're right - fixed it –  Dario Nov 21 '09 at 20:24

The given code is not very efficient. Alternative solution (just as inefficient):

>>> from math import sqrt
>>> def is_prime(n):
...     return all(n % d for d in range(2, int(sqrt(n)) + 1))
... 
>>> def primes_up_to(n):
...     return filter(is_prime, range(2, n))
... 
>>> list(primes_up_to(20))
[2, 3, 5, 7, 11, 13, 17, 19]

This code uses all, range, int, math.sqrt, filter and list. It is not completely identical to your code, as it prints primes up to a certain number, not exactly n primes. For that, you can do:

>>> from itertools import count, islice
>>> def n_primes(n):
...     return islice(filter(is_prime, count(2)), n)
... 
>>> list(n_primes(10))
[2, 3, 5, 7, 11, 13, 17, 19, 23, 29]

That introduces another two functions, namely itertools.count and itertools.islice. (That last piece of code works only in Python 3.x; in Python 2.x, use itertools.ifilter instead of filter.)


  : A more efficient method is to use the Sieve of Eratosthenes.

share|improve this answer

A few minor things from the style guide.

  • Uses four spaces, not two. (Personally I prefer tabs, but that's not the Pythonic way.)
  • Fewer blank lines.
  • Consistent whitespace: n ==2: => n == 2:
  • Use underscores in your variables names: currentnumber => current_number

  • share|improve this answer
    1  
    Also, using 'max' as a variable name is discouraged as it covers up the builtin max function. –  Paul Osborne Nov 21 '09 at 19:22

    Firstly, you should not assign max to a variable as it is an inbuilt function used to find the maximum value from an iterable. Also, that entire section of code can instead be written as

    for i in xrange(3, int(sqrt(n))+1, 2):
        if n%i==0: return False
    

    Also, instead of defining a new variable result and putting the value returned by isprime into it, you can just directly do

    if isprime(currentnumber):
    
    share|improve this answer

    I recently found Project Euler solutions in functional python and it has some really nice examples of working with primes like this. Number 7 is pretty close to your problem:

    def isprime(n):
        """Return True if n is a prime number"""
        if n < 3:
            return (n == 2)
        elif n % 2 == 0:
            return False
        elif any(((n % x) == 0) for x in xrange(3, int(sqrt(n))+1, 2)):
            return False
        return True
    
    def primes(start=2):
        """Generate prime numbers from 'start'"""
        return ifilter(isprime, count(start))
    
    share|improve this answer

    Usually you don't use while loops for simple things like this. You rather create a range object and get the elements from there. So you could rewrite the first loop to this for example:

    for i in range( 3, int( sqrt( n ) ) + 1, 2 ):
        if n % i == 0:
            return False
    

    And it would be a lot better if you would cache your prime numbers and only check the previous prime numbers when checking a new number. You can save a lot time by that (and easily calculate larger prime numbers this way). Here is some code I wrote before to get all prime numbers up to n easily:

    def primeNumbers ( end ):
        primes = []
        primes.append( 2 )
    
        for i in range( 3, end, 2 ):
        	isPrime = True
    
        	for j in primes:
        		if i % j == 0:
        			isPrime = False
        			break
    
        	if isPrime:
        		primes.append( i )
    
        return primes
    
    print primeNumbers( 20 )
    
    share|improve this answer

    Translated from the brilliant guys at stacktrace.it (Daniele Varrazzo, specifically), this version takes advantage of a binary min-heap to solve this problem:

    from heapq import heappush, heapreplace
    
    def yield_primes():
        """Endless prime number generator."""
    
        # Yield 2, so we don't have to handle the empty heap special case
        yield 2
    
        # Heap of (non-prime, prime factor) tuples.
        todel = [ (4, 2) ]
    
        n = 3
        while True:
            if todel[0][0] != n:
                # This number is not on the head of the heap: prime!
                yield n
                heappush(todel, (n*n, n))   # add to heap
    
            else:
                # Not prime: add to heap
                while todel[0][0] == n:
                    p = todel[0][1]
                    heapreplace(todel, (n+p, p))
                    # heapreplace pops the minimum value then pushes: 
                    # heap size is unchanged
    
            n += 1
    

    This code isn't mine and I don't understand it fully (but the explaination is here :) ), so I'm marking this answer as community wiki.

    share|improve this answer

    You can make it more pythonic with sieve algorithm (all primes small than 100):

    def primes(n):
        sieved = set()
        for i in range(2, n):
            if not(i in sieved):
                for j in range(i + i, n, i):
                    sieved.add(j)
        return set(range(2, n)) - sieved
    
    print primes(100)
    

    A very small trick will turn it to your goal.

    share|improve this answer
        
    What trick? Do you mean count & like double the number if #primes is too low? I can't think of a better way. –  MercerKernel Nov 21 '09 at 21:59

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