Prime number check Python [closed]

I've written this very simple prime number check:

``````prime = int(input())
if prime % prime == 0 and prime % 2 != 0 and prime % 3 != 0 or prime == 2 or prime == 3:
print("true")
else:
print("false")
``````

... which seems to work somehow, but i'm not certain if its the correct way, can someone please confirm?

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closed as not a real question by casperOneMay 22 '12 at 14:01

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I don't understand this part: `prime % prime == 0` ? Isn't that the modulo operator, which would return 0 every time – keyser May 19 '12 at 14:47
If this is homework you should tag it as such. – Edwin Dalorzo May 19 '12 at 14:48
@Keyser You mean `0` every time? – jamylak May 19 '12 at 14:48
prime & prime always returns 0, which is always equal to 0. – Marlin Pierce May 19 '12 at 14:48
@jamylak of course :p – keyser May 19 '12 at 14:48

i'm not certain if its the correct way

It isn't. To give one counterexample, it thinks that `25` is a prime number. To make matters worse, there are infinitely many such counterexamples.

Wikipedia is worth of a read for various (correct) methods of doing this.

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As simple as it gets:

``````def isprime(n):
"""check if integer n is a prime"""
# range starts with 2 and only needs to go up the squareroot of n
for x in xrange(2, int(n**0.5)+1):
if n % x == 0:
return False
return True
``````

For an impressive prime-number generator, see here

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I think this fails whith n = 1 – enrmarc Jul 30 '13 at 22:35

The Wikipedia article on primality can help you design a better algorithm. There are many of them, but the basic ones are not that complicated.

• First, depart from the fact that a prime number must be a positive integer bigger than 1. This invariant implies that if n < 2 you could return false immediatelly. In your code, n=0 fails.
• In a naive approach, you can then move to check all divisors of n from 1 to n. If you just find two, then you know it's a prime.
• A more intuitive approach could be to conclude that every number is divisible by 1 and itself, and so, you could check for divisors only between 2 and n-1. And in the moment that you find a divisor of n, you can conclude n is not a prime.
• A improved approach recognizes that all even numbers are divisible by 2, and so, if n is not divisible by 2 then, from there on you can only check for odd divisors.
• Finally, you do not need to check for all the divisors up to n. It should suffice to check divisor up to the square root of n. If you haven't found a divisor when you reach that threshold, than you can conclude n is a prime.
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