Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

I'm working through the examples in "Beginning Haskell: A project based approach" and in Chapter 6 you write kMeans during which I pass in a [(Double,Double)] and convert them to vectors and life is good. It all works.

However, I'd like to create a vector in ghci after importing the Vector module and it all blows up.

Prelude Chapter6.TimeMachine> import Chapter6.Vector
Prelude Chapter6.Vector Chapter6.TimeMachine> toVector ((0,0) :: (Double, Double))

    No instance for (Vectorizable (Double, Double) v0)
      arising from a use of `toVector'
    The type variable `v0' is ambiguous
    Possible fix: add a type signature that fixes these type variable(s)
    Note: there is a potential instance available:
      instance Vectorizable (Double, Double) (Double, Double)
        -- Defined in `Chapter6.Vector'
    Possible fix:
      add an instance declaration for (Vectorizable (Double, Double) v0)
    In the expression: toVector ((0, 0) :: (Double, Double))
    In an equation for `it': it = toVector ((0, 0) :: (Double, Double))

I imagine this is all caused by the way Vector is defined, but I don't understand why. There is an instance instance Vectorizable (Double,Double) (Double,Double) already so I would expect toVector to handle input of (Double, Double). I'm certainly creating lists of (Double, Double) as the data I pass into kMeans and it calls toVector without problems, however the kMeans function has the following type signature which somehow resolves this issue:

-- kMeans takes input data and computes the centroids based off 
kMeans :: (Vector v, Vectorizable e v) => Int -> [e] -> [v]
kMeans numCentroids dataPoints = ...

I'm not sure how to resolve this. I've tried various incantations and not gotten anywhere.

{-# LANGUAGE MultiParamTypeClasses, FlexibleInstances, BangPatterns #-}

module Chapter6.Vector where
import Data.List

class (Ord v) => Vector v where
  distance :: v -> v -> Double
  centroid :: [v] -> v
  isUndefined :: v -> Bool    

instance Vector (Double, Double) where
  isUndefined (a,b) = isNaN a || isNaN b
  distance (a,b) (c,d) = sqrt $ (c-a)*(c-a) + (d-b)*(d-b)
  centroid vs = let baseVal = (0,0,0) :: (Int, Double, Double)
                    (n',x',y') = foldl' (\(!n,!x,!y) (x2,y2) -> (n+1,x+x2,y+y2)) baseVal vs
                in toVector (x' / fromIntegral n', y' / fromIntegral n')    

class Vector v => Vectorizable e v where
  toVector :: e -> v    

instance Vectorizable (Double,Double) (Double,Double) where
  toVector = id

What do I do?

share|improve this question

1 Answer 1

up vote 4 down vote accepted

Let's look at your error:

No instance for (Vectorizable (Double, Double) v0)
  arising from a use of `toVector'
The type variable `v0' is ambiguous

GHCi knows that you're trying to convert a (Double, Double) to an instance of Vector, but it's not sure which one.

You could clear this up a couple ways.

Like the error says (Possible fix: add a type signature that fixes these type variable(s) - "fixes" as in "fixes in place" not "repairs"), the simplest way is to tell it which one:

λ toVector ((0,0) :: (Double, Double)) :: (Double, Double)

The reason why this is ambiguous is that you've set up your Vectorizable type class to support many different instances, like:

instance Vector () where
  isUndefined () = True
  distance () () = 0.0
  centroid _ = ()

instance Vector Double where
  isUndefined = isNaN
  distance = (abs .) . subtract
  centroid = uncurry (/) . foldl' (\(!x,!n) y -> (x+y,n+1)) (0,0)

instance Vectorizable (Double,Double) () where
  toVector = const ()

instance Vectorizable (Double,Double) Double where
  toVector = fst

None of these are defined yet, but they could be, and the compiler doesn't want to guess for you in an ambiguous situation.

A solution to get rid of the ambiguity would to use either FunctionalDependencies (aka FunDeps) or TypeFamilies to make the output type dependent on the input type for Vectorizable:


{-# LANGUAGE FunctionalDependencies #-}
-- ...
class Vector v => Vectorizable e v | e -> v where
  toVector :: e -> v


{-# LANGUAGE TypeFamilies, FlexibleContexts #-}
-- ...
class Vector (Output e) => Vectorizable e where
  type Output e
  toVector :: e -> Output e

instance Vectorizable (Double,Double) where
  type Output (Double, Double) = (Double, Double)
  toVector = id

Now it suffices to specify your input type, since the other instances of Vectorizable given above are no longer legal:

λ toVector ((0,0) :: (Double, Double))

If you use TypeFamilies, you can make the relationship between the input and output bijective, so you could specify either the output type OR the input type

class (Output e ~ v, Input v ~ e, Vector v) => Vectorizable e v where
  type Input  v
  type Output e
  toVector :: e -> Output e

instance Vectorizable (Double,Double) (Double,Double) where
  type Input (Double, Double) = (Double, Double)
  type Output (Double, Double) = (Double, Double)
  toVector = id


λ (toVector (0,0)) :: (Double, Double)
λ toVector ((0,0) :: (Double, Double))

(thanks to this thread for the idea)

share|improve this answer
Doh! It never occurred to me to constrain the input to (Double, Double) and the result to (Double, Double). Thanks! –  Tim Perry Aug 13 at 0:36
Ah, this is all making sense now. In my larger program, where I never explicitly declare Vectors or Vectorizables as (Double, Double), it selects the only currently existing type when I pass in the data of type (Double, Double) and the instances exist so it works. But then when I try "let infinity = toVector (1/0,1/0)" inside a function it correctly gets worried that it may not be a valid Vector if the code is called where the data is a different type even though it would be valid with the current data set.... –  Tim Perry Aug 13 at 16:18

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.