You're really asking two things here: "How do I write the function
twice?", and "how do I write an
f with two different types?"
Let's think about the first question. Letting Haskell infer types for the moment, let's think about what it should look like. It needs to take one argument:
twice f = undefined.
twice then returns a function which takes an argument and applies
f to it twice:
twice f = \x -> f (f x).
But what's the type of this function? Well,
x must be of some type
α. Since we evaluate
(f x), this means that
f must be a function that takes in an
α and returns a
f :: α -> β. However, we also evaluate
f (f x), so
f must take a
β as input as well, returning a
f :: β -> γ. Any single variable can only have one type, so this tells us that
α -> β = β -> γ, and so
α = β and
β = γ. Thus,
f :: α -> α, and so
\x -> f (f x) :: α -> α; this means that
twice :: (α -> α) -> α -> α.
This answers your first question. And you'll notice that I said above that
f must be a function from one type to the same type. This answers your second question: it is impossible to write an
f with two different types. This is because, as I said, any single variable may only have one (possibly polymorphic) type. Why? Well, among other reasons, suppose we have a variable
impossible with two type signatures,
impossible :: Int and
impossible :: String, and two bindings,
impossible = 24 and
impossible = "absz". Then what does
show impossible return? The
show function is of type
show :: Show α => α -> String; since both
String are instances of the
Show typeclass, we can't tell if this would return
"\"absz\"". Inconsistencies like this are why we allow only one type.
All hope is not lost, however! You also mentioned using union types to implement
f. In this context, you probably mean the
Either type (although all datatypes in Haskell are a form of union types called discriminated unions).
Either is a type which takes two type parameters (just like
, the list type, takes one); we say that it has kind [the type of a type]
Either :: * -> * -> *).
Either is the union type:
Either A B consists of all the elements of
A and all the elements of
B, lifted into
Either. As Michael Steele said, you can write your function with two type signatures as a function which returns an
f :: Either δ ε -> Either δ ε. Note that this is a perfectly valid value to pass as a parameter to
Either δ ε is a perfectly legal type. We define functions on
Either via pattern matching; the two constructors of
Left :: δ -> Either δ ε and
Right :: ε -> Either δ ε, for lifting the two types of values. A sample function, then, would look like
f :: Either Int String -> Either Int String
f (Left n) = Right $ "The number " ++ show n
f (Right s) = Left $ length s
-- f (Left 3) == Right "The number 3"
-- f (Right "The number 3") == Left 12
-- twice f (Left 3) == Left 12
If you really want to mimic your example and go through three types, from
γ, you can either use nested
Eithers or define your own data type. With nested
Eithers, you get
f :: Either Int (Either String Char) -> Either Int (Either String Char)
f (Left n) = Right $ Left $ "The number " ++ show n
f (Right (Left s)) = Right $ Right $ head $ drop 11 s
f (Right (Right c)) = Left $ fromEnum c
-- f (Left 42) == Right (Left "The number 42")
-- f (Right (Left "The number 42")) == Right (Right '4')
-- f (Right (Right '4')) == Left 52
-- twice f (Left 42) == Right (Right '4')
With a new type, you get:
data Either3 a b c = Left3 a | Mid3 b | Right3 c deriving (Eq, Ord, Read, Show)
f :: Either3 Int String Char -> Either3 Int String Char
f (Left3 n) = Mid3 $ "The number " ++ show n
f (Mid3 s) = Right3 $ head $ drop 11 s
f (Right3 c) = Left3 $ fromEnum c
-- f (Left3 42) == Mid3 "The number 42"
-- f (Mid3 "The number 42") == Right3 '4'
-- f (Right3 '4') == Left3 52
-- twice f (Left3 42) == Right3 '4'
You could also define a specific
data MyType = MyInt Int | MyStr String | MyChar Char, and replace every
Either3 Int String Char with
MyStr, and every
MyChar; this is effectively the same thing, but less general.
Note that, thanks to Haskell's currying, we can rewrite our original
twice f x = f (f x). And in fact, even more simply, we can write this as
twice f = f (.) f, or
twice = join (.), if we import
Control.Monad. This is irrelevant for the purposes of answering this question, but is interesting for other reasons (especially the
(->) α instance for
Monad, which I don't fully understand); you might want to take a look if you haven't seen it before.