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Is there any way to make a class instance return a value which is not of the instance's type? An example is wanting to return a value of type Double for the the scalar product of two vectors:

--  data structure to contain a 3D point in space
data Point3D = Point3D !Double !Double !Double
    deriving (Eq, Ord)

instance Num Point3D where
    -- Multiplication, scalar == Dot product
    Point3D x1 y1 z1 * Point3D x2 y2 z2 = x1*x2 + y1*y2 + z1*z2 :: Double

Furthermore, is there any way to define how operators work between functions of different types? For example, I would like to define Point3D x y z + Double a = Point3D (x + a) (y + a) (z + a)

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The main endeavour to overcome the problems of the Num class is the Numeric Prelude. –  leftaroundabout Feb 22 '12 at 15:30

3 Answers 3

up vote 5 down vote accepted

The numeric operations in the Num typeclass are all defined with the type :: Num n => n -> n -> n, so both operands and the return value must have the same type. There's no way to alter an existing typeclass, so your options are either to define new operators or hide the existing Num class and replace it completely with your own implementation.

In order to implement operators that can have different operand types, you are going to need a couple of language extensions.

{-# LANGUAGE MultiParamTypeClasses #-}
{-# LANGUAGE FunctionalDependencies #-}

Instead of a Num-like class that encompasses +, - and *, it's more flexible to define different typeclasses for different operands, because while Point3D * Double makes sense, Point3D + Double usually does not. Let's start with Mul.

class Mul a b c | a b -> c where
    (|*|) :: a -> b -> c

Without extensions, typeclasses only ever contain a single type parameter, but with MultiParamTypeClasses, we can declare a typeclass like Mul for the combination of types a, b and c. The part after the parameters, | a b -> c is a "functional dependecy" which in this case states that the type c is dependent on a and b. This means that if we have an instance like Mul Double Point3D Point3D the functional dependency states that we can't have any other instances Mul Double Point3D c, where c something other than Point3D, i.e. the return type of the multiplication is always unambiguously determined by the type of the operands.

Here's how we implement instances for Mul:

instance Mul Double Double Double where
    (|*|) = (*)

instance Mul Point3D Double Point3D where
    Point3D x y z |*| a = Point3D (x*a) (y*a) (z*a)

instance Mul Double Point3D Point3D where
    a |*| Point3D x y z = Point3D (x*a) (y*a) (z*a)

This flexibility does not come without its caveats, though, because it will make type inference a lot more difficult for the compiler. For example, you can't simply write

p = Point3D 1 2 3 |*| 5

Because the literal 5 isn't necessarily of type Double. It can be any Num n => n, and it's entirely possible that someone declares new instances like Mul Point3D Int Int which behaves completely differently. So what this means is that we need to specify the types of numerical literals explicitly.

p = Point3D 1 2 3 |*| (5 :: Double)

Now, if instead of defining new operands we wish to override the default Num class from Prelude, we can do it like this

import Prelude hiding (Num(..))
import qualified Prelude as P

class Mul a b c | a b -> c where
    (*) :: a -> b -> c

instance Mul Double Double Double where
    (*) = (P.*)

instance Mul Point3D Double Point3D where
    Point3D x y z * a = Point3D (x*a) (y*a) (z*a)
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An excellent response. Thank you. –  thoughtadvances Feb 22 '12 at 20:47

There is no way to get the standard Num functions (including the operators) to return a different type. * has the type Num n => n -> n -> n which means the n has to be the same type throughout.

There is also no way to have a standard Num function (like +) work with arguments of two different types.

The usual solution to this problem is to create a new operator. So you could create a scalar addition operator like |+| and use that to add doubles to your points.

If you aren't against unicode, you could use · for your dot product :). Haskell supports this, but other programs may have difficulty typing unicode.

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Ah, yes, I created a custom class, but I did not think of doing a -> Double -> a. –  thoughtadvances Feb 22 '12 at 2:39
I think this fixes both situations, it just requires that I come up with a different operator for every single different situation I have. Very annoying. –  thoughtadvances Feb 22 '12 at 2:44
Why could Haskell not simply have conditional operators? If Double Point3D, then do this. If Point3D Point3D, then do this. –  thoughtadvances Feb 22 '12 at 2:49
Not so fast. Take a look, for example, at the hmatrix package. Namely, look at the <> operator, which is the matrix multiplication operator. You can see the documentation here: hackage.haskell.org/packages/archive/hmatrix/…. You can see the code at the bottom here: hackage.haskell.org/packages/archive/hmatrix/… . He has jerry-rigged it such that <> works: Matrix <> Matrix, Vector <> Matrix, and Matrix <> Vector. He must have abstracted away in some way that makes this look possible. –  thoughtadvances Feb 22 '12 at 7:24
Hmm, yes he did. However, he used some extensions I am not familiar with, so I can't help you much here. Also, you'd still have to define your own operator (as opposed to using + or *). –  Tikhon Jelvis Feb 22 '12 at 7:33

You can create your custom class with a multiplication that can take different types.

import Prelude hiding ((*))
import qualified Prelude

class Mul a b c | a b -> c where (*) :: a -> b -> c
instance Mul Double Double Double where (*) = (Prelude.*)
instance Mul Double Int Double where a * b = a Prelude.* fromIntegral b

You need to turn on multi-parameter type classes and functional dependencies for this to work.

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