Your issue is that, although you've tried to fix it in a variety of ways, you haven't tried to do something `x`

, which is exactly where your problem lies. Let's look at the type of `sqrt`

:

```
Prelude> :t sqrt
sqrt :: (Floating a) => a -> a
```

On the other hand, `x`

is an `Int`

, and if we ask GHCi for information about `Floating`

, it tells us:

```
Prelude> :info Floating
class (Fractional a) => Floating a where
pi :: a
<...snip...>
acosh :: a -> a
-- Defined in GHC.Float
instance Floating Float -- Defined in GHC.Float
instance Floating Double -- Defined in GHC.Float
```

So the only types which are `Floating`

are `Float`

s and `Double`

s. We need a way to convert an `Int`

to a `Double`

, much as `floor :: (RealFrac a, Integral b) => a -> b`

goes the other direction. Whenever you have a type question like this, you can ask Hoogle, a Haskell search engine which searches types. Unfortunately, if you search for `Int -> Double`

, you get lousy results. But what if we relax what we're looking for? If we search for `Integer -> Double`

, we find that there's a function `fromInteger :: Num a => Integer -> a`

, which is almost exactly what you want. And if we relax our type all the way to `(Integral a, Num b) => a -> b`

, you find that there is a function `fromIntegral :: (Integral a, Num b) => a -> b`

.

Thus, to compute the square root of an integer, use `floor . sqrt $ fromIntegral x`

, or use

```
isqrt :: Integral i => i -> i
isqrt = floor . sqrt . fromIntegral
```

You were thinking about the problem in the right direction for the output of `sqrt`

; it returned a floating-point number, but you wanted an integer. In Haskell, however, there's no notion of subtyping or implicit casts, so you need to alter the *input* to `sqrt`

as well.

To address some of your other concerns:

```
intSqrt :: Int -> Int
intSqrt x = floor (sqrt (x + 0.0))
```

You call this "nonsense", so it's clear you don't expect it to work, but why doesn't it? Well, the problem is that `(+)`

has type `Num a => a -> a -> a`

—you can only add two things of the same type. This is generally good, since it means you can't add a complex number to a 5×5 real matrix; however, since `0.0`

must be an instance of `Fractional`

, you won't be able to add it to `x :: Int`

.

It seems that (sqrt 500) works fine…

This works because the type of `500`

isn't what you expect. Let's ask our trusty companion GHCi:

```
Prelude> :t 500
500 :: (Num t) => t
```

In fact, all integer literals have this type; they can be *any* sort of number, which works because the `Num`

class contains the function `fromInteger :: Integer -> a`

. So when you wrote `sqrt 500`

, GHC realized that `500`

needed to satisfy `500 :: (Num t, Floating t) => t`

(and it will implicitly pick `Double`

for numeric types like that thank to the defaulting rules). Similarly, the `0.0`

above has type `Fractional t => t`

, thanks to `Fractional`

's `fromRational :: Rational -> a`

function.

… but (sqrt x) insists on x being a Floating …

See above, where we look at the type of `sqrt`

.

… and there is no function I can find to convert an Int to a real ….

Well, you have one now: `fromIntegral`

. I don't know why you couldn't find it; apparently Hoogle gives much worse results than I was expecting, thanks to the generic type of the function.

Why is this so hard?

I hope it isn't anymore, now that you have `fromIntegral`

.

`sqrt 500`

is valid because 500 is a valid literal for a floating point number. However`sqrt (500 :: Int)`

would be invalid. – sepp2k Aug 9 '11 at 20:12`Float`

,`Double`

,`floor`

?:`squares = map (\x -> x * x) [0 ..]`

`squareRoot n = last $ takeWhile (<= n) squares`

– applicative Aug 9 '11 at 22:54