If you inspect the type of your `add`

and `sub`

, you will see the issue.

```
ghci> :t add
add :: Num a => [[a]] -> [[a]] -> [[a]]
ghci> :t sub
sub :: Num a => [[a]] -> [[a]] -> [[a]]
```

Mikhail's suggestion was to essentially unwrap the 2D list and rewrap it in the Num instance methods. Another way to do this is to modify your `add`

and `sub`

methods to work on Matrices instead. Here I use a "lifting" approach, where I write combinators to "lift" a function from one type to another.

```
-- unwraps the 2d list from a matrix
unMatrix :: Matrix a -> [[a]]
unMatrix (Matrix m) = m
-- lifts a 2d list operation to be a Matrix operation
liftMatrixOp :: ([[a]] -> [[a]] -> [[a]]) -> Matrix a -> Matrix a -> Matrix a
liftMatrixOp f x y = Matrix $ f (unMatrix x) (unMatrix y)
-- lifts a regular operation to be a 2d list operation
lift2dOp :: (a -> a -> a) -> [[a]] -> [[a]] -> [[a]]
lift2dOp f = zipWith (zipWith f)
```

With these combinators, defining `add`

and `sub`

is simply a matter of lifting appropriately.

```
add, sub :: Num a => Matrix a -> Matrix a -> Matrix a
add = liftMatrixOp add2D
sub = liftMatrixOp sub2D
add2D, sub2D :: Num a => [[a]] -> [[a]] -> [[a]]
add2D = lift2dOp (+)
sub2D = lift2dOp (-)
```

Now that we have functions that work on Matrices, the Num instance is simple

```
instance (Num a) => Num (Matrix a) where
(+) = add
(-) = sub
..etc..
```

Of course we could have combined `lift2dOp`

and `liftMatrixOp`

into one convenience function:

```
-- lifts a regular operation to be a Matrix operation
liftMatrixOp' :: (a -> a -> a) -> Matrix a -> Matrix a -> Matrix a
liftMatrixOp' = liftMatrixOp . lift2dOp
instance (Num a) => Num (Matrix a) where
(+) = liftMatrixOp' (+)
(-) = liftMatrixOp' (-)
(*) = liftMatrixOp' (*)
..etc..
```

Now you try: define `liftMatrix :: (a -> a) -> Matrix a -> Matrix a`

, a lifting function for unary functions. Now use that to define `negate`

, `abs`

, and `signum`

. The docs suggest that `abs x * signum x`

should always be equivalent to `x`

. See if this is true for our implementation.

```
ghci> quickCheck (\xs -> let m = Matrix xs in abs m * signum m == m)
+++ OK, passed 100 tests.
```

In fact, if you write `liftMatrix`

with the more lenient type signature, it can be used to define a `Functor`

instance for Matrices.

```
liftMatrix :: (a -> b) -> Matrix a -> Matrix b
instance Functor (Matrix a) where
fmap = liftMatrix
```

Now think about how you could implement `fromInteger`

. Implementing this allows you to do stuff like this in ghci:

```
ghci> Matrix [[1,2],[3,4]] + 1
Matrix [[2,3],[4,5]]
```

That's how it works the way I implemented it, anyways. Remember that any numeric literal `n`

in Haskell code is actually transformed into `fromInteger n`

, which is why this works.

I think that's enough fun for now, but if you need more exercises, try getting comfortable with this `Arbitrary`

instance of Matrices:

```
instance Arbitrary a => Arbitrary (Matrix a) where
arbitrary = liftM Matrix arbitrary
```

`(+) x y`

with`(+) (Matrix x) (Matrix y)`

. The error message tells you that`sub`

expects a`[[a]]`

, but you're giving it`Matrix a`

. – Mikhail Glushenkov Oct 5 '11 at 7:00`Show`

instance that you requested. – Mikhail Glushenkov Oct 5 '11 at 7:10