Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free.

I am trying to compose a function of type (Floating a) => a -> a -> a with a function of type (Floating a) => a -> a to obtain a function of type (Floating a) => a -> a -> a. I have the following code:

test1 :: (Floating a) => a -> a -> a
test1 x y = x

test2 :: (Floating a) => a -> a
test2 x = x

testBoth :: (Floating a) => a -> a -> a
testBoth = test2 . test1
--testBoth x y = test2 (test1 x y)

However, when I compile it in GHCI, I get the following error:

    Could not deduce (Floating (a -> a)) from the context (Floating a)
      arising from a use of `test2'
                   at /path/test.hs:8:11-15
    Possible fix:
      add (Floating (a -> a)) to the context of
        the type signature for `testBoth'
      or add an instance declaration for (Floating (a -> a))
    In the first argument of `(.)', namely `test2'
    In the expression: test2 . test1
    In the definition of `testBoth': testBoth = test2 . test1
Failed, modules loaded: none.

Note that the commented-out version of testBoth compiles. The strange thing is that if I remove the (Floating a)s from all type signatures or if I change test1 to just take x instead of x and y, testBoth compiles.

I've searched StackOverflow, Haskell wikis, Google, etc. and not found anything about a restriction on function composition relevant to this particular situation. Does anyone know why this is happening?

share|improve this question

2 Answers 2

up vote 9 down vote accepted
   \x y -> test2 (test1 x y)
== \x y -> test2 ((test1 x) y)
== \x y -> (test2 . (test1 x)) y
== \x -> test2 . (test1 x)
== \x -> (test2 .) (test1 x)
== \x -> ((test2 .) . test1) x
== (test2 .) . test1

These two things are not like each other.

   test2 . test1
== \x -> (test2 . test1) x
== \x -> test2 (test1 x)
== \x y -> (test2 (test1 x)) y
== \x y -> test2 (test1 x) y
share|improve this answer
Thank you. Clear and concise. I haven't seen the (test2 .) notation before but it must mean f |-> test2.f. –  gdj Dec 3 '10 at 1:08
@gdj: In Haskell, a binary operator can be partially applied to form a section. –  ephemient Dec 3 '10 at 4:07
Yes, I'm aware of that; just never seen it used with "." but it makes perfect sense. Thanks! –  gdj Dec 3 '10 at 4:24

You're problem doesn't have anything to do with Floating, though the typeclass does make your error harder to understand. Take the below code as an example:

test1 :: Int -> Char -> Int
test1 = undefined

test2 :: Int -> Int
test2 x = undefined

testBoth = test2 . test1

What is the type of testBoth? Well, we take the type of (.) :: (b -> c) -> (a -> b) -> a -> c and turn the crank to get:

  1. b ~ Int (the argument of test2 unified with the first argument of (.))
  2. c ~ Int (the result of test2 unified with the result of the first argument of (.))
  3. a ~ Int (test1 argument 1 unified with argument 2 of (.))
  4. b ~ Char -> Int (result of test1 unified with argument 2 of (.))

but wait! that type variable, 'b' (#4, Char -> Int), has to unify with the argument type of test2 (#1, Int). Oh No!

How should you do this? A correct solution is:

testBoth x = test2 . test1 x

There are other ways, but I consider this the most readable.

Edit: So what was the error trying to tell you? It was saying that unifying Floating a => a -> a with Floating b => b requires an instance Floating (a -> a) ... while that's true, you really didn't want GHC to try and treat a function as a floating point number.

share|improve this answer
Thanks, this is an intuitive explanation. When I left out the typeclass, that must have meant that testBoth would take x and pass it to test1, then take the resulting function f : y |-> x and pass it to test2, which would then return f. That's clearly not what I wanted. –  gdj Dec 3 '10 at 1:11

Your Answer


By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.