Of many primality tests floating around the Internet, consider the following prime test:
if n == 2 or n == 3: return True
if n < 2 or n%2 == 0: return False
if n < 9: return True
if n%3 == 0: return False
r = int(n**0.5)
f = 5
while f <= r:
if n%f == 0: return False
if n%(f+2) == 0: return False
Consider the prime number 5003:
r = int(n**0.5) evaluates to 70 (the square root of 5003 is 70.7318881411 and
int() truncates this value)
Because of the first few tests, and the tests in the middle of loop, the loop only needs to be evaluated every 6th number.
Consider the next odd number (since all even numbers other than 2 are not prime) of 5005, same thing prints:
The limit is the square root since
x*y == y*x The function only has to go 1 loop to find that 5005 is divisible by 5 and therefore not prime. Since
5 X 1001 == 1001 X 5 (and both are 5005), we do not need to go all the way to 1001 in the loop to know what we know at 5!
Now, let's look at the algorithm you have:
for i in range(2,int(n**0.5)+1):
There are two issues:
- It does not test if
n is less than 2, and there are no primes less than 2;
- It tests every number between 2 and n**0.5 including all even and all odd numbers. Since every number greater than 2 that is divisible by 2 is not prime, we can speed it up a little by only testing odd numbers greater than 2.
if n==2 or n==3: return True
if n%2==0 or n<2: return False
for i in range(3,int(n**0.5)+1,2): # only odd numbers
OK -- that speeds it up by about 30% (I benchmarked it...)
The algorithm I used
is_prime is about 2x times faster still, since only every 6th integer is looping through the loop. (Once again, I benchmarked it.)
Side note: x**0.5 is the square root:
>>> import math
Side note 2: primality testing is an interesting problem in computer science.