You're getting the errors because of type mismatches. The type of `sqrt`

is `sqrt :: Floating a => a -> a`

, and the type of `truncate`

is `truncate :: (RealFrac a, Integral b) => a -> b`

. The former says that `sqrt`

takes as input any floating-point number, and returns one of the same type as output; the latter says it can truncate any real fractional number^{1} into any integral number. However, you assert that `x`

is an `Int`

, and an `Int`

isn't a floating-point number. Thus, the second error: "No instance for `(Floating Int)`

arising from a use of ``sqrt`

'". This says that because of `sqrt x`

, it wanted `Int`

to be a floating-point number, but there's no definition for that. Your first error is similar: since `sqrt :: Floating a => a -> a`

, its output is the same as its input, so you're trying to call `truncate`

on an integer. This of course makes no sense, since `Int`

is not a `RealFrac`

, and that's why you get the first error. Fixing this is easy:

```
isSquare :: Int -> Bool
isSquare x = let x' = truncate $ sqrt (fromIntegral x :: Double) in x'*x' == x
```

The `fromIntegral`

function has the type `fromIntegral :: (Integral a, Num b) => a -> b`

; it can convert any integral number into *any* number at all. This is why we need to tell Haskell that we want it to produce a `Double`

; it'd default to that anyway, but it's nice to be clear (though not necessary). `Double`

is an instance both of `Floating`

and `RealFrac`

, so you can `sqrt`

and `truncate`

it. I also rearranged your code a little; the way it is up there is how I'd write it, since this way we only compute the `truncation`

and `sqrt`

once. Also, note that if you remove the type signature, Haskell will infer the more general type `isSquare :: Integral a => a -> Bool`

, since you never assume that `x`

is precisely an `Int`

.

The reason that `truncate(sqrt(9))*truncate(sqrt(9))==9`

successfully returned `True`

is because of the type of `9`

. You can ask GHCi to tell you this:

```
Prelude> :t 9
9 :: (Num t) => t
```

In Haskell, all integral numeric literals have the type `Num t => t`

(`9.0`

, or any number with a decimal point, has the type `Fractional t => t`

). This means that they can be *any* kind of number at all, which is a good thing. Otherwise, `9`

would have to just be an `Int`

or `Integer`

, and defining new number types—or even using both `Int`

and `Integer`

!^{2}—would be a royal pain. Thus, when you write `truncate(sqrt(9))`

, GHCi determines that `9`

must be an instance of `Floating`

(from `sqrt`

) and `RealFrac`

(from `truncate`

), which it defaults to `Double`

, making everything work. This defaulting is standard behavior for numeric types (it's why you could leave out the `:: Double`

in my definition of `isSquare`

), though not for anything else (except in GHCi, which extends it for convenience). Since `9`

isn't just an `Int`

, but `x`

is, you don't need to convert `9`

, but you do need to convert `x`

.

**1:** The difference between `Floating`

and `RealFrac`

is that, for instance, `Complex Double`

is an instance of `Floating`

but not `RealFrac`

, and `Rational`

is an instance of `RealFrac`

but not `Floating`

. `Float`

and `Double`

are instances of both.

**2:** In case you haven't come across this, the difference is that `Int`

is finite-precision, and `Integer`

is arbitrary-precision.