How about:

```
def nth_root(val, n):
ret = int(val**(1./n))
return ret + 1 if (ret + 1) ** n == val else ret
print nth_root(124, 3)
print nth_root(125, 3)
print nth_root(126, 3)
print nth_root(1, 100)
```

Here, both `val`

and `n`

are expected to be integer and positive. This makes the `return`

expression rely exclusively on integer arithmetic, eliminating any possibility of rounding errors.

Note that accuracy is only guaranteed when `val**(1./n)`

is fairly small. Once the result of that expression deviates from the true answer by more than `1`

, the method will no longer give the correct answer (it'll give the same approximate answer as your original version).

Still I am wondering why `int(125**(1/3))`

is `4`

```
In [1]: '%.20f' % 125**(1./3)
Out[1]: '4.99999999999999911182'
```

`int()`

truncates that to `4`

.

`125**(1/3)`

->`4.999999999999999`