# Haskell: Functions that sometimes return a function

How do you write a function that can either return a value or another function?

For example:

``````Function Foo (x)
If X = 0 Return "Done"
Else Return a Function that calls Foo(x-1)
``````
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I'm not familiar with haskell, but how do you use a function if you don't know what it will return? –  Stephen Jul 4 '10 at 1:05
In Haskell, you'd normally specify in advance which types a function might feel like returning using an algebraic data type, then use pattern matching to examine it. `Either`, as in sepp2k's answer, is a general purpose way of doing that for two possible results. –  C. A. McCann Jul 4 '10 at 2:04
Are you sure you are not just looking for a recursive call "foo (x-1)"? The classic Factorial function would be the ur-example of this. Also your pseudo-code isn't even close to Haskell (spurious brackets, capital letters etc). I think you need to spend time with a tutorial rather than asking here. –  Paul Johnson Jul 4 '10 at 9:05
That's a stupid comment. Of course the pseudo-code isn't close to Haskell, that's why it's called pseudo-code. –  Jonathan Allen Jul 5 '10 at 1:25
I don't think it's a stupid comment - if you're looking for help with Haskell it would make sense to make the minor changes to your code that would make it look like Haskell...it's not like your notation saves any space over the corresponding Haskell code... –  Bill Jul 6 '10 at 1:25
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In haskell the return type of a function can only depend on the type of its arguments and, in case of functions with polymorphic return types, how the return value is used. In particular the return type of the function can not depend on the value of the argument.

In other words: you can't do what you want directly. In cases where you want to return one of two types, you can usually the type `Either a b` which is defined as `data Either a b = Left a | Right b`, which allows you to return a value of type `a` wrapped in a `Left` or a value of type `b` wrapped in a `Right`. You could then use pattern matching to retrieve the value in a type safe manner.

However since in this case the type for `b` would have to be infinite this does not work and you have to define your own wrapper type for this. Like so:

``````data MyResult = Str String | Fun ( () -> MyResult)
foo 0 = Str "done"
foo x = Fun (\ () -> foo (x-1))
``````

`foo` now has type `Num a => a -> MyResult`. However every time you call `foo` you have to pattern match to see whether you got back a Str with a string inside or a Fun with a function inside.

Also note that if you want to return a function rather than a value in order to delay execution, this doesn't make sense in haskell because it is lazy and things generally don't get evaluated before they are used.

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So there's no unified base type like we have in .NET or almost have in Java? –  Jonathan Allen Jul 4 '10 at 1:41
@JonathanAllen: There's not only no common base type, there is no subtyping at all. –  sepp2k Jul 4 '10 at 1:52
Though I should add that in many cases where you'd rely on subtyping in OO languages, haskell's parametric polymorphism allows you to achieve the same effect in a different way. –  sepp2k Jul 4 '10 at 1:55
More importantly, there's no general means of inspecting a value to determine its type. Which is a good thing, because it means we can be confident that polymorphic functions will behave consistently for all arguments. –  C. A. McCann Jul 4 '10 at 2:13
@camccann: `foo instanceof Bar` in java makes sense if and only if the static type of foo is a supertype of Bar. Otherwise it would always be false. In haskell `foo instanceof Bar` would always return true (in case where the static type of foo is Bar) or always return false (in case it's not). Neither of which would be useful. The point is in java you don't know whether a variable of type Object really contains a String or an ArrayList (as an example). In haskell you always know the type, so you don't need to check it. –  sepp2k Jul 4 '10 at 2:38

From the looks of your pseudo code, I'm guessing you're expecting to return a "nullary" function, that is one that takes no arguments, and will call 'Foo(x-1)' when invoked.

If this is so, then as pointed out at the end of sepp2k's answer, there is such need in Haskell - that is what happens by default. Specifically:

``````foo x = if x == 0 then "Done"
else foo(x-1)
``````

does exactly this: The value returned by calling, say, `foo(7)` is a thing that when the program needs it's value will evaluate `foo(6)`. The recursive call won't be evaluated inside the evaluation of the `if` expression.

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Except, of course, that the `if` expression wouldn't be evaluated if the result wasn't being demanded... –  SamB May 3 '11 at 3:30

You need to think about the types of your function: if Foo is of type (Int -> t), what is t? It needs to return something of type t in both cases. I think this is a little hard, because I don't think t can be String type or a function type (->) in the same function.

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Of course it can - that's the point of the `Either` type suggestion many folks have suggested. –  BMeph Jul 8 '10 at 22:00

I know this doesn't answer your question directly, but I think you need to expand your idea about what it means to "return a function". For example the function:

``````mean3 :: Float -> Float -> Float -> Float
mean3 x y z = (x + y + z) / 3
``````

Can be thought of as "taking 3 numbers and returning a number". Or it can be thought of as "a function taking two numbers, and returning a function from a number to a number":

``````mean3 :: Float -> Float -> (Float -> Float)

mean1 :: (Float -> Float)
mean1 = mean3 1 2
``````
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That seems rather limiting. What if I don't know how many numbers it should take ahead of time? –  Jonathan Allen Jul 4 '10 at 9:06
@Jonathan Allen: make a function taking a list. –  sdcvvc Jul 4 '10 at 11:13

Just following up from sepp2k's great answer. I think you're missing a fundamental concept in Haskell - you're always returning a function. Even a "value" of sorts is a function.

For example, bust open ghci and try:

``````> :t 5
:: (Num t) => t
``````

Just a function that takes no input, return value is a Num.

``````> :t "What  is this?"
:: [Char]
``````

Likewise, just a function that takes no value, returns [Char]

"But these are all just values! I'm not convinced!"

What's main then? (Supposing you've got it defined):

``````> :t main
:: IO ()
``````

Just a function that returns an IO () instance.

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I don't agree with this. A function is something that can be applied. You can't apply a string. Anything that does not match the type `a -> b` (for some a and b) is not a function. –  sepp2k Jul 4 '10 at 13:37
So this isn't a function? void foo () { printf("Hello"); } –  Dan Jul 4 '10 at 19:00
In Haskell, it would either have the type `() -> IO ()`, in which case it would be a function; or it would have the type `IO ()`, in which case it would be a value which is, roughly speaking, an "IO action". In C, too, you do have to apply it, by writing `foo()`. –  Antal S-Z Jul 4 '10 at 20:04
@sepp2k: I'm 99% sure it's just semantics. I can't see any inconsistencies arising from defining a string as a function taking 0 arguments, which, when applied to 0 arguments, evaluates to itself -- and if so then it's a valid definition. (Just as your definition, in which a function can only be applied to 1 argument, is also valid since it doesn't lead to inconsistencies either.) –  j_random_hacker Jul 5 '10 at 10:51
@j_random_hacker: Sure it's a matter of definition. The definition of Haskell (i.e. the Haskell 98 report) says the following: "A function type has the form t1 -> t2". If you use a definition that differs from that, you're going to run into trouble communicating with people who use the official definition. For example the statement that the argument to map can be any function is false if you define a string to be a function, too, while any haskeller would tell you it's true (unless you first tell him that you're operating under a different definition of the word "function"). –  sepp2k Jul 5 '10 at 11:04
``````{-# LANGUAGE ExistentialQuantification #-}

data MyResult = Str String | forall a. Fun a -- deriving Show

foo 0 = Str "done"
foo x = Fun (\ () -> foo (x-1))
``````

that sort of works, but you can't derive an existential type (methinks) so you need to call foo like that: `(\(Main.Str x) -> x) (Main.foo 0)`.

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Normally, we write this as

``````foo _ = "Done"
``````

or, pointlessly,

``````foo = const "Done"
``````

(Unless, of course, we really wanted to get `_|_` for negative numbers ;-)

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``````foo x =