Imagine what happens if the *last* number in `range(3, int(n**0.5), 2)`

is not an integer divisor of `n`

:

```
if n % x ==0:
prime = False # not this
else:
prime = True # this
```

So *even if all previous checks evaluated *`False`

, you call `n`

a prime. The *minimal* change to your code to fix this is:

```
prime = prime and True # or 'prime &= True'
```

So if `prime`

is *already* `False`

, it remains `False`

.

However, bear in mind that, for primality, if *any* of those checks is `False`

`n`

is not prime. You can use this and Python's `and`

and `all`

(which are evaluated lazily, i.e. don't keep checking once finding a `False`

) to implement much more efficiently:

```
def rand_prime():
while True:
p = randint(10000, 100000)
if (r % 2 != 0 and
all(p % n != 0 for n in range(3, int(((p ** 0.5) + 1), 2))):
return p
```

For even better performance, note that `randrange`

incorporates a `step`

argument, just like `range`

, so you can skip all of the even numbers (which definitely aren't prime!):

```
def rand_prime():
while True:
p = randrange(10001, 100000, 2)
if all(p % n != 0 for n in range(3, int((p ** 0.5) + 1), 2)):
return p
```

*Note: *`sqrt(n)`

(from `math`

) is, in my opinion, a little clearer to other, less-technical readers than `n ** 0.5`

(although it may or may not be more efficient).

`for`

loop, you're ignoring what the earlier iterations told you by setting`prime = False`

or`prime = True`

without considering what`prime`

used to be. – user2357112 Jan 10 '14 at 11:29