Let's say you want to implement a generic algorithm or data structure, "generic" meaning polymorphic: it should work for any data type. For example, let's say you want to write a function that determines whether three input values are equal.

Taking a specific (monomorphic) case, you can do this for integers:

```
eq3 :: Int -> Int -> Int -> Bool
eq3 x y z = x == y && y == z
```

We'd expect the above definition to work for other types as well, of course, but if we simply tell the compiler that the function should apply to *any* type:

```
eq3 :: a -> a -> a -> Bool
eq3 x y z = x == y && y == z
```

... the compiler complains that the `==`

function doesn't apply to our generic `a`

:

```
<interactive>:12:49:
No instance for (Eq a)
arising from a use of `=='
In the first argument of `(&&)', namely `x == y'
In the expression: x == y && y == z
In an equation for `eq3': eq3 x y z = x == y && y == z
```

We have to tell the compiler that our type `a`

is an *instance* of the `Eq`

type class, which you already noticed is where the `==`

function is declared. See the difference here:

```
eq3 :: Eq a => a -> a -> a -> Bool
eq3 x y z = x == y && y == z
```

Now we have a function that can operate uniformly on any type `a`

belonging to the `Eq`

type class.