The problem with relying on any floating point computation (`math.sqrt(x)`

, or `x**0.5`

) is that you can't really be sure it's exact (for sufficiently large integers `x`

, it won't be, and might even overflow). Fortunately (if one's in no hurry;-) there are many pure integer approaches, such as the following...:

```
def is_square(apositiveint):
x = apositiveint // 2
seen = set([x])
while x * x != apositiveint:
x = (x + (apositiveint // x)) // 2
if x in seen: return False
seen.add(x)
return True
for i in range(110, 130):
print i, is_square(i)
```

Hint: it's based on the "Babylonian algorithm" for square root, see wikipedia. It *does* work for any positive number for which you have enough memory for the computation to proceed to completion;-).

**Edit**: let's see an example...

```
x = 12345678987654321234567 ** 2
for i in range(x, x+2):
print i, is_square(i)
```

this prints, as desired (and in a reasonable amount of time, too;-):

```
152415789666209426002111556165263283035677489 True
152415789666209426002111556165263283035677490 False
```

Please, before you propose solutions based on floating point intermediate results, make sure they work correctly on this simple example -- it's not **that** hard (you just need a few extra checks in case the sqrt computed is a little off), just takes a bit of care.

And then try with `x**7`

and find clever way to work around the problem you'll get,

```
OverflowError: long int too large to convert to float
```

you'll have to get more and more clever as the numbers keep growing, of course.

If I *was* in a hurry, of course, I'd use gmpy -- but then, I'm clearly biased;-).

```
>>> import gmpy
>>> gmpy.is_square(x**7)
1
>>> gmpy.is_square(x**7 + 1)
0
```

Yeah, I know, that's just so easy it feels like cheating (a bit the way I feel towards Python in general;-) -- no cleverness at all, just perfect directness and simplicity (and, in the case of gmpy, sheer speed;-)...

`int`

then looks for the decimal place, which will never be there. – Mike Graham Mar 22 '10 at 1:28