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After the longwinded discussion at Write this Scala Matrix multiplication in Haskell, I was left wondering...what would a type-safe matrix multiplication look like? So here's your challenge: either link to a Haskell implementation, or implement yourself, the following:

data Matrix ... = ...

matrixMult :: Matrix ... -> Matrix ... -> Matrix ...
matrixMult ... = ...

Where matrixMult produces a type error at compile time if you try to multiply two matricies with incompatible dimensions. Brownie points if you link to papers or books that discuss this precise topic, and/or discuss yourself how useful/useless this functionality is.

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3 Answers 3

up vote 11 down vote accepted

There are a number of packages that implement this:

The Repa papers in particular have a really nice discussion of the design space and choices made: http://repa.ouroborus.net/

Of historical interest is McBride's "Faking It" from 2001 which describes strongly typed vectors. The techniques he employs are fairly similar to those used in the above packages. They were obviously known in circles doing dependently typed programming, but my impression is that the "Faking It" paper is one of the earlier instances where these were used in Haskell. Oleg's 2005 Monad Reader article on number-parameterized types has some good discussion on the history of these techniques as well.

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You could use type-level natural numbers to encode the dimensions. Your matrix type becomes

-- x, y: Dimensions
data Matrix x y n = ...

and you have to define two additonal ADTs and a class TLN (Type Level Naturals):

data Zero
data Succ a
class    TLN a                 where fromTLN :: a -> Int
instance TLN Zero              where fromTLN = const Zero
instance TLN a => TLN (Succ a) where fromTLN = 1 + fromTLN (undefined :: a)

Your function's type is quite easy:

matrixMult :: (TLN x, TLN y, TLN t, Num a) =>
  Matrix x t a -> Matrix t y a -> Matrix x y a

You can extract the arrays dimension by generating an undefined of appropriate type together with the ScopedTypeVariables extension.

This code is completely untested and GHC may barf on compilation. It is just a sketch about how it could be done.


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Sorry, can't resist pasting something I whipped up ages ago. This was before type families so I used fundeps for the arithmetic. I verified that this still works on GHC 7.

{-# LANGUAGE EmptyDataDecls,
  UndecidableInstances #-}

import System.IO

-- Peano type numerals

data Z
data S a

type One = S Z
type Two = S One
type Three = S Two

class Nat a
instance Nat Z
instance Nat a => Nat (S a)

class Positive a
instance Nat a => Positive (S a)

class Pred a b | a -> b
instance Pred (S a) a

-- Vector type

newtype Vector n k = Vector {unVector :: [k]}
    deriving (Read, Show, Eq)

empty :: Vector Z k
empty = Vector []

vtail :: Pred s' s => Vector s' k -> Vector s k
vtail (Vector (a:as)) = Vector as
vhead :: Positive s => Vector s k -> k
vhead (Vector (a:as)) = a

liftV :: (a->b) -> Vector s a -> Vector s b
liftV f = Vector . map f . unVector

type Matrix m n k = Vector m (Vector n k)

infixr 6 |>
(|>) :: k -> Vector s k -> Vector (S s) k
k |> v = Vector . (k:) . unVector $ v

-- Arithmetic

instance (Num k) => Num (Vector n k) where
    (+) (Vector v) (Vector u) = Vector $ zipWith (+) v u
    (*) (Vector v) (Vector u) = Vector $ zipWith (*) v u
    abs = liftV abs
    signum = liftV signum

dot :: Num k => Vector n k -> Vector n k -> k
dot u v = sum . unVector $ v*u

class Transpose n m where
    transpose :: Matrix n m k -> Matrix m n k

instance (Transpose m a, Nat a, Nat m) => Transpose m (S a) where
    transpose v = liftV vhead v |>
                  transpose (liftV vtail v)

instance Transpose m Z where
    transpose v = empty

multiply :: (Nat n, Nat m, Nat n', Num k, Transpose m n) =>
            Matrix m n k -> Matrix n' m k -> Matrix n n' k
multiply a (Vector bs) = Vector [Vector [a `dot` b | a <- as] | b <- bs]
    where (Vector as) = transpose a

printMatrix :: Show k => Matrix m n k -> IO ()
printMatrix = mapM_ (putStrLn) . map (show.unVector) . unVector

-- Examples

m :: Matrix Three Three Integer
m =    (1 |> 2 |> 3 |> empty)
    |> (2 |> 3 |> 4 |> empty) 
    |> (3 |> 4 |> 5 |> empty) |> empty
n :: Matrix Three Two Integer
n =    (1 |> 0 |> empty)
    |> (0 |> 1 |> empty) 
    |> (1 |> 1 |> empty) |> empty
o = multiply n m
p = multiply n (transpose n)
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