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I am using Haskell and have declared a Vector as

data Vector = Vector [Double]

Now, I want to declare the dot product of two vectors as

dot :: Vector -> Vector -> Double
dot a b = sum $ a * b -- I already wrote Vector as an instance of Num for *.

But, the problem is, I receive the error

Couldn't match expected type [a0] with actual type Vector

I assume this means that sum doesn't know how to operate on a Vector. What is the best way to approach this issue?

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The product a * b gives a Vector, but sum takes a list. You need a converting function, like the toList that jozefg defines. –  md2perpe Oct 30 '13 at 22:22

5 Answers 5

up vote 6 down vote accepted

So I've noticed you're not using standard vectors. I'd suggest switching to them, but if you really don't want to,

 toList :: Vector -> [Double]
 toList (Vector a) = a

and use

dot a b = sum . toList $ a * b

If you switch to standard vectors you have 3 choices

  1. Turn your Vector to a list,

    import Data.Vector as V
    dot a b = sum . V.toList $ a * b
    

    Simple, but needlessly slow.

  2. Use a more general sum

    import Data.Foldable as F
    dot a b = F.sum $ a * b
    

    Flexible, can lead to weird type errors since we're relying on another typeclass.

  3. Use a different, specific (the fancy word is monomorphic) sum

     import Data.Vector as V
     dot a b = V.sum $ a * b
    

    Simplest, but of course, if you stop using vectors this will break.

I'd recommend option 3, no need to be overly general yet.

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Also I believe that the foldable method just goes through V.toList, so (3) may be much faster as well. –  J. Abrahamson Oct 30 '13 at 23:04
    
@J.Abrahamson Actually it appears to rely on Data.Vector.Fusion.Stream –  jozefg Oct 30 '13 at 23:28
    
Oh, nice! I hadn't looked at it in a while and had always worried about the Foldable instance wrecking fusion. –  J. Abrahamson Oct 31 '13 at 0:17

You are using sum from Prelude with type:

sum :: Num a => [a] -> a

sum for vectors is defined in Data.Vector (usually imported qualified)

edit: I missed the fact that you are using your own datatype, not the one from Data.Vector

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Wrong vector, he's using a wrapper around [Double] –  jozefg Oct 30 '13 at 20:22
    
I guess i missed that =) –  Arjan Oct 30 '13 at 20:23
    
No worries so did I :) –  jozefg Oct 30 '13 at 20:24

Since you aren't using Data.Vector vectors, you can't actually make sum work directly on your data type, since it's type is

sum :: Num a => [a] -> a

and you're giving it Vector [Double] instead of a Num a => [a]. You'll have to extract list inside the vector first:

toList :: Vector -> [Double]
toList (Vector vals) = vals

dot :: Vector -> Vector -> Double
dot a b = sum . toList $ a * b

That being said, you should probably just use the vectors provided by Data.Vector, or at the very least you should define your Vector type as

{-# LANGUAGE DeriveFunctor #-}

import Control.Applicative

data Vector a = Vector [a] deriving (Eq, Ord, Show, Functor)

instance Applicative Vector where
    pure a = Vector [a]
    (Vector fs) <*> (Vector xs) = Vector $ zipWith ($) fs xs

instance Num a => Num (Vector a) where
    a + b = (+) <$> a <*> b
    a * b = (*) <$> a <*> b
    -- etc.

Then you can have Vector Int, Vector Double, even Vector (Int -> Double), and since it's now a Functor and an Applicative, you can do a lot more with it, as this example suggests.

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Generally, yes. Oftentimes this is desirable since it allows you to prune away functions that you don't want people to have access to. For instance, giving a user [Double] lets them compute the length and examine it as a linked-list, while newtype Vector = Vector [Double] would let you expose vectorLength if and only if you feel it a good idea.

But that's not the problem at hand. Immediately you want to be able to operate on your Vector type without redefining every useful function you can think of. Fortunately, there are many ways to get past this.

You could define Vector as a type synonym instead of a new concrete type. This lets Haskell transparently interpret Vector as [Double] and use the full complement of list functions automatically

type Vector = [Double]

vectorSum :: Vector -> Double
vectorSum = sum

You could, though you were trying to avoid it, also just write your own vectorSum directly.

vectorSum :: Vector -> Double
vectorSum (Vector list) = sum list

Generally, it looks a little different in real code as people tend to abuse record syntax to make an easy "escape hatch" for Vector

data Vector = Vector { unVector :: [Double] }

vectorSum :: Vector -> Double
vectorSum = sum . unVector

manySums :: [Double]
manySums = map (\v -> sum (unVector v)) makeLotsOfVectors

You could define Vector as an instance of Foldable. Foldable is a typeclass and is the primary mechanism by which Haskell achieves polymorphism. In particular, you say that a type t is an instance of Foldable if you can think of it as containing elements in a particular order that can be "smashed" together. That pretty much describes a Vector and a sum, so

import Prelude hiding (foldl)
import Data.Foldable (Foldable, foldl, foldMap)

data Vector a = Vector [a]        -- note that the type is parametric, this is
                                  -- required for Foldable

foldableSum :: (Foldable t) => t Double -> Double
foldableSum = foldl (+) 0

instance Foldable Vector where
  foldMap f (Vector list) = foldMap f list   -- it just inherits from the 
                                             -- Foldable [] instance

vectorSum :: Vector Double -> Double
vectorSum = foldableSum

You can also use a very convenient mechanism of GHC Haskell called GeneralizedNewtypeDeriving to make these tedious instances happen automatically. To do this, we have to take note that Vector is very similar to []---it's actually just a new name for it. That means we can use newtype instead of data.

{-# LANGUAGE GeneralizedNewtypeDeriving #-}

newtype Vector a = Vector [a] deriving ( Foldable )

vectorSum :: Vector Double -> Double
vectorSum = foldl (+) 0

Funnily enough, there's also an extension to GHC Haskell that lets you derive Foldable even if you don't have a newtype. GeneralizedNewtypeDeriving is more powerful, but for Foldable specifically we don't need to use it.

{-# LANGUAGE DeriveFoldable #-}

data Vector a = Vector [a]

vectorSum :: Vector Double -> Double
vectorSum = foldl (+) 0

There's also the very powerful vector library that others have mentioned which can do all of this and MUCH much more.

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To a create a dot function you could do

data Vector = Vector [Double]

dot :: Vector -> Vector -> Double
dot (Vector a) (Vector b) = sum $ zipWith (*) a b

This way 'a' and 'b' are now the [Double] inside of the Vector and not the Vector its self.

Step-by-step:

dot (Vector [1,2]) (Vector [3,4]) = sum $ zipWith (*) [1,2] [3,4]

= sum $ zipWith (*) [1,2] [3,4]
= sum $ [1*3, 2*4]
= 1*3 + 2*4
= 3 + 8
= 11
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