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 > 2`^{31}-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
```

`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