The trick is to use type classes. In the case of `printf`

, the key is the `PrintfType`

type class. It does not expose any methods, but the important part is in the types anyway.

```
class PrintfType r
printf :: PrintfType r => String -> r
```

So `printf`

has an overloaded return type. In the trivial case, we have no extra arguments, so we need to be able to instantiate `r`

to `IO ()`

. For this, we have the instance

```
instance PrintfType (IO ())
```

Next, in order to support a variable number of arguments, we need to use recursion at the instance level. In particular we need an instance so that if `r`

is a `PrintfType`

, a function type `x -> r`

is also a `PrintfType`

.

```
-- instance PrintfType r => PrintfType (x -> r)
```

Of course, we only want to support arguments which can actually be formatted. That's where the second type class `PrintfArg`

comes in. So the actual instance is

```
instance (PrintfArg x, PrintfType r) => PrintfType (x -> r)
```

Here's a simplified version which takes any number of arguments in the `Show`

class and just prints them:

```
{-# LANGUAGE FlexibleInstances #-}
foo :: FooType a => a
foo = bar (return ())
class FooType a where
bar :: IO () -> a
instance FooType (IO ()) where
bar = id
instance (Show x, FooType r) => FooType (x -> r) where
bar s x = bar (s >> print x)
```

Here, `bar`

takes an IO action which is built up recursively until there are no more arguments, at which point we simply execute it.

```
*Main> foo 3 :: IO ()
3
*Main> foo 3 "hello" :: IO ()
3
"hello"
*Main> foo 3 "hello" True :: IO ()
3
"hello"
True
```

QuickCheck also uses the same technique, where the `Testable`

class has an instance for the base case `Bool`

, and a recursive one for functions which take arguments in the `Arbitrary`

class.

```
class Testable a
instance Testable Bool
instance (Arbitrary x, Testable r) => Testable (x -> r)
```