Numeric literals (i.e. just typing a number in Haskell code) are not some fixed type. They are polymorphic. They need to be evaluated in some context that requires them to have a concrete type.

So the expression `5.0 * (3 - 1)`

is *not* multiplying an `Int`

by a `Float`

. `5.0`

has to be some `Fractional`

type, `3`

and `1`

are each some `Num`

type. `3 - 1`

means that the 3 and the 1 both have to be the *same* `Num`

type, but we still don't (yet) have any more constraints about which particular one it is; the result of the subtraction is the same type.

The `*`

means both arguments have to be the same type, and the result will be the same type too. Since `5.0`

is some `Fractional`

type, the `(3 - 1)`

must be too. We already knew that `3`

, `1`

, and `(3 - 1)`

had to be some `Num`

type but all `Fractional`

types are also `Num`

types, so this requirements are not in conflict.

The end result is that the whole expression `5.0 * (3 - 1)`

is some type that is `Fractional`

, and the `5.0`

, `3`

, and `1`

are all the same type. You can use the `:t`

command in GHCi to see this:

```
Prelude> :t 5.0 * (3 - 1)
5.0 * (3 - 1) :: Fractional a => a
```

But to actually *evaluate* that expression, we need to do so for some concrete type. If we were evaluating this and passing it to some function that required `Float`

, `Double`

, or some other particular `Fractional`

type then Haskell would pick that one. If we just evaluate the expression with no other context requiring it to be a particular type, Haskell has some defaulting rules to automatically choose one for you (if the defaulting rules don't apply it will instead give you a type error about ambiguous type variables).

```
Prelude> 5.0 * (3 - 1)
10.0
Prelude> :t it
it :: Double
```

Above I've evaluated `5.0 * (3 - 1)`

, then asked for the type of the magic `it`

variable which GHCi always binds to the last value it evaluated. This tells me that GHCi has defaulted my `Fractional a => a`

type to just `Double`

, in order to compute that the value of the expression was `10.0`

. In doing that evaluation, it only ever multipled (and subtracted) `Double`

s, it never multiplied a `Double`

by an `Int`

.

Now, that's what's going on when you attempt to multiple numeric *literals* that look like they might be of different types. But your `test`

function isn't multiplying literals, it's multiplying variables of particular known types. In Haskell you can't multiply an `Int`

by a `Float`

because the `*`

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

- it takes two values of the same numeric type and gives you a result that is that type. You can multiply an `Int`

by an `Int`

to get an `Int`

, or a `Float`

by a `Float`

to get a `Float`

. You can't multiply an `Int`

by a `Float`

to get a `???`

.

Other languages support this sort of operation only by implicitly inserting calls to conversion functions under some circumstances. Haskell *never* implicitly converts between types, but it has the conversion functions. You just need to call them explicitly if you want them to be called. This would do the trick:

```
test :: Float -> Int -> Int -> Float
test a b c = a * fromIntegral (b - c)
```