# Checking if a number is a prime number in Python [duplicate]

I have written the following code, which should check if the entered number is a prime number or not, but there is an issue i couldn't get through:

``````def main():
n = input("Please enter a number:")
is_prime(n)

def is_prime(a):
x = True
for i in (2, a):
while x:
if a%i == 0:
x = False
else:
x = True

if x:
print "prime"
else:
print "not prime"

main()
``````

If the entered number is not a prime number, it displays "not prime", as it is supposed to, but if the number is a prime number, it doesn't display anything. Could you please help me with it?

• Note: `for i in (2, a)` runs the loop exactly twice: once with i == 2, and once with i == a. You probably wanted to use `for i in range(2, a)`. – Marius Gedminas Nov 6 '10 at 17:46

Here is my take on the problem:

``````from math import sqrt; from itertools import count, islice

def isPrime(n):
return n > 1 and all(n%i for i in islice(count(2), int(sqrt(n)-1)))
``````

This is a really simple and concise algorithm, and therefore it is not meant to be anything near the fastest or the most optimal primality check algorithm. It has a time complexity of `O(sqrt(n))`. Head over here to learn more about primality tests done right and their history.

## Explanation

I'm gonna give you some insides about that almost esoteric single line of code that will check for prime numbers:

• First of all, using `range()` is really a bad idea, because it will create a list of numbers, which uses a lot of memory. Using `xrange()` is better, because it creates a generator, which only needs to memorize the initial arguments you provide, and generates every number on-the-fly. If you're using Python 3 or higher `range()` has been converted to a generator by default. By the way, this is not the best solution at all: trying to call `xrange(n)` for some `n` such that `n > 231-1` (which is the maximum value for a C `long`) raises `OverflowError`. Therefore the best way to create a range generator is to use `itertools`:

``````xrange(2147483647+1) # OverflowError

from itertools import count, islice

count(1)                        # Count from 1 to infinity with step=+1
islice(count(1), 2147483648)    # Count from 1 to 2^31 with step=+1
islice(count(1, 3), 2147483648) # Count from 1 to 3*2^31 with step=+3
``````
• You do not actually need to go all the way up to `n` if you want to check if `n` is a prime number. You can dramatically reduce the tests and only check from 2 to `√(n)` (square root of `n`). Here's an example:

Let's find all the divisors of `n = 100`, and list them in a table:

`````` 2  x  50 = 100
4  x  25 = 100
5  x  20 = 100
10  x  10 = 100 <-- sqrt(100)
20  x  5  = 100
25  x  4  = 100
50  x  2  = 100
``````

You will easily notice that, after the square root of `n`, all the divisors we find were actually already found. For example `20` was already found doing `100/5`. The square root of a number is the exact mid-point where the divisors we found begin being duplicated. Therefore, to check if a number is prime, you'll only need to check from 2 to `sqrt(n)`.

• Why `sqrt(n)-1` then, and not just `sqrt(n)`? That's because the second argument provided to `itertools.islice` object is the number of iterations to execute. `islice(count(a), b)` stops after `b` iterations. That's the reason why:

``````for number in islice(count(10), 2):
print number,

# Will print: 10 11

for number in islice(count(1, 3), 10):
print number,

# Will print: 1 4 7 10 13 16 19 22 25 28
``````
• The function `all(...)` is the same of the following:

``````def all(iterable):
for element in iterable:
if not element:
return False
return True
``````

It literally checks for all the numbers in the `iterable`, returning `False` when a number evaluates to `False` (which means only if the number is zero). Why do we use it then? First of all, we don't need to use an additional index variable (like we would do using a loop), other than that: just for concision, there's no real need of it, but it looks way less bulky to work with only a single line of code instead of several nested lines.

## Extended version

I'm including an "unpacked" version of the `isPrime()` function, to make it easier to understand and read it:

``````from math import sqrt
from itertools import count, islice

def isPrime(n):
if n < 2:
return False

for number in islice(count(2), int(sqrt(n) - 1)):
if n % number == 0:
return False

return True
``````
• Doesn't work :# – Confuse Aug 16 '15 at 6:32
• It is wrong to say that "1 is proved not to be a prime number". It isn't prime because, for example, it would break the "fundamental theorem of arithmetic". 1 would be a prime number, because it is only divisible by itself and by 1 (itself). It isn't a prime number just for convenience. In the past, (at least some) mathematicians considered 1 to be prime. – nbro Jan 18 '16 at 19:09
• I am pretty sure that your version of calculating if a number is prime is not the most efficient. The fact that you are already importing modules unnecessarily is already a reason. – nbro Jan 18 '16 at 19:32
• The actual definition of a prime number is an integer greater than one is called a prime number if its only positive divisors (factors) are one and itself. – Coombes Apr 11 '16 at 14:41
• @nbro these "unnecessary" modules are actually necessary if you want compute big numbers, which is the primary purpose of any primality check algorithm. Also, if you consider 1 a prime number you can easily edit the code. – Marco Bonelli Apr 11 '16 at 14:58

There are many efficient ways to test primality (and this isn't one of them), but the loop you wrote can be concisely rewritten in Python:

``````def is_prime(a):
return all(a % i for i in xrange(2, a))
``````

That is, a is prime if all numbers between 2 and a (not inclusive) give non-zero remainder when divided into a.

• note that `is_prime` returns `True` for 0 and 1. However, Wikipedia defines a prime number as "a natural number greater than 1 that has no positive divisors other than 1 and itself." so i changed it to `return a > 1 and all(a % i for i in xrange(2, a))` – Michael Osl Mar 5 '14 at 21:30
• just add `if x<2: return False` – Cat H Jun 11 '14 at 7:11
• I must also add that testing integers over sqrt(a) rounded up is useless, as all factor pairs cross at the square root. – user3074620 Jun 19 '14 at 19:46
• Actually this is going to make a lot of useless comparisons: checking in `xrange(2, math.sqrt(a))` is enough. Plus, `xrange()` will raise `OverflowError` for numbers bigger than C longs, so it's better to use `itertools.count` and `itertools.islice`. – Marco Bonelli Jan 14 '15 at 14:38
• DO NOT USE THIS FUNCTION! Here are the reasons. 1) Returns true if a == 1, but 1 is not considered a prime. 2) It checks if a number is prime until a - 1, but a decent programmer knows that it is necessary only up to sqrt(a). 3) It doesn't skip even numbers: except 2, all primes are odd numbers. 4) It doesn't show the algorithmic thinking behind how to find a prime number, because it uses Python's commodities. 5) xrange doesn't exist in Python 3, so some people will not be able to run it. – nbro Jan 18 '16 at 19:36

This is the most efficient way to see if a number is prime, if you only have a few query. If you ask a lot of numbers if they are prime try Sieve of Eratosthenes.

``````import math

def is_prime(n):
if n == 2:
return True
if n % 2 == 0 or n <= 1:
return False

sqr = int(math.sqrt(n)) + 1

for divisor in range(3, sqr, 2):
if n % divisor == 0:
return False
return True
``````
• Why stop the range at the (`sqrt` + 1) of the number you are checking? I don't understand why, although I see it works. – pyrocumulus Sep 10 '13 at 18:10
• Never mind, found it at en.wikipedia.org/wiki/Primality_test :) – pyrocumulus Sep 10 '13 at 22:04
• Note that you can probably gain in efficiency if instead of importing `math` you just simply raise to the `0.5` power, which is an equivalent calculation. – nbro Jan 18 '16 at 19:15
• sqrt, maybe because if 10 is not a prime number, it's a product of 2*5 and 5*2 as well, the max would happen when it get multiplied by itself, and +1 for the tackling the round-off error, in this way we do not need to go through the whole range to check the if it is a prime number ( I really liked this algorithm) – Hootan Jan 7 '18 at 18:08

If `a` is a prime then the `while x:` in your code will run forever, since `x` will remain `True`.

So why is that `while` there?

I think you wanted to end the for loop when you found a factor, but didn't know how, so you added that while since it has a condition. So here is how you do it:

``````def is_prime(a):
x = True
for i in range(2, a):
if a%i == 0:
x = False
break # ends the for loop
# no else block because it does nothing ...

if x:
print "prime"
else:
print "not prime"
``````
• this doesn't work either: a%a==0. Using tighter bounds on i (like, say, (2, sqrt(a)) fixes this. – rtpg Nov 6 '10 at 17:38
• @Dasuraga: `a` is not in `range(a)` so that wouldn't happen ... of course sqrt is a better bound but i didnt want to change too much since its a beginner question. – Jochen Ritzel Nov 6 '10 at 18:42
• whoops, there wasn't actually a `range` there. Makes me wonder how the original code was supposed to work ... – Jochen Ritzel Nov 6 '10 at 18:47
• +1 for actually explaining why OPs code doesn't work (i.e. answering the actual question!) rather than just providing a better algorithm like everyone else. – OJFord Jun 12 '14 at 0:19
``````def prime(x):
# check that number is greater that 1
if x > 1:
for i in range(2, x + 1):
# check that only x and 1 can evenly divide x
if x % i == 0 and i != x and i != 1:
return False
else:
return True
else:
return False # if number is negative
``````
``````def is_prime(x):
n = 2
if x < n:
return False
else:
while n < x:
print n
if x % n == 0:
return False
break
n = n + 1
else:
return True
``````
• That's not even a good answer - for example, you only need to loop whilst `n * n <= x`. – Toby Speight Jan 18 '16 at 19:28
``````a = input('inter a number: ')
s = 0
if a == 1:
print a, 'is a prime'

else :

for i in range (2, a ):

if a%i == 0:
print a,' is not a prime number'
s = 'true'
break

if s == 0 : print a,' is a prime number'
``````

it worked with me just fine :D

• 1 is not a prime number and 2 is a prime number. Your program does not say so. – Mark Jun 29 '13 at 7:44
• looks like it's been fixed – Matt O'Brien Aug 18 '14 at 4:26
• @MattO'Brien The post was never edited. – EKons Sep 1 '16 at 23:34
``````def isPrime(x):
if x<2:
return False
for i in range(2,x):
if not x%i:
return False
return True
``````

print isPrime(2)
True
print isPrime(3)
True
print isPrime(9)
False

• This doesn't answer the question at all. And 10 is not a prime so it's incorrect code as well. – interjay Jul 12 '13 at 22:32
• The code is correct,it was a typo mistake that. – Mesut014 Jul 13 '13 at 13:25
• No, the code isn't correct. It will report 9 and many other numbers as being prime. – interjay Jul 13 '13 at 13:30