The definition of `curry`

is:

```
curry :: ((a, b) -> c) -> a -> b -> c
curry f = \x y -> f (x, y)
```

If we substitute that in:

```
\x y z -> (curry (==) x y) z
\x y z -> ((==) (x, y)) z -- Function application
\x y z -> (==) (x, y) z -- Remove parentheses (function application is left associative in Haskell, so they are unnecessary here)
\x y z -> (x, y) == z -- Convert to infix
```

We can tell right away that `z`

must be some kind of tuple as well, or else this last line wouldn't type check since both arguments of `==`

must have the same type.

When we look at the definition of the tuple instance for `Eq`

, we find

```
instance (Eq a, Eq b) => Eq (a, b) where
(x, y) == (x', y') = (x == x') && (y == y')
```

(This isn't spelled out in the source code of the standard library, it actually uses the "standalone deriving" mechanism to automatically derive the instance for the `(Eq a, Eq b) => (a, b)`

type. This code is equivalent to what gets derived though.)

So, in this case, we can treat `==`

as though it has the type

```
(==) :: (Eq a, Eq b) => (a, b) -> (a, b) -> Bool
```

Both `x`

and `y`

must have types that are instances of `Eq`

, but they don't need to be the *same* instance of `Eq`

. For example, what if we have `12`

and `"abc"`

? Those are two different types but we can still use our function, since they are both instances of `Eq`

: `(\x y z -> (x, y) == z) (12, "abc") (30, "cd")`

(this expression type checks and evaluates to `False`

).