Your initial attempt, as well as the good correction of user2989737, tries every number from n down to the solution. It is very slow for large numbers, complexity is O(n). It will be better to start from 0 up to the solution, which improves complexity to O(sqrt n):

```
intSquareRoot :: Int -> Int
intSquareRoot n = try 0 where
try i | i*i <= n = try (i + 1)
| True = i - 1
```

But here is a much more efficient code using Babylonian method (Newton's method applied to square roots):

```
squareRoot :: Integral t => t -> t
squareRoot n
| n > 0 = babylon n
| n == 0 = 0
| n < 0 = error "Negative input"
where
babylon a | a > b = babylon b
| True = a
where b = quot (a + quot n a) 2
```

It is not as fast as Pedro Rodrigues solution (GNU's multiprecision library algorithm), but it is much simpler and easier to understand. It also needs to use an internal recursion in order to keep the original n.

To make it complete, I generalized it to any Integral type, checked for negative input, and checked for n == 0 to avoid division by 0.

r(for root) and started comparing`r*r`

and`n`

, what value would you try forr? And how would you let Haskell know about it? – JB. Nov 13 '13 at 22:00