It will be easier if you use `[[Rational]]`

instead of `[[Int]]`

since you get nice division.

You probably want to start by implementing the elementary row operations.

```
swap :: Int -> Int -> [[Rational]] -> [[Rational]
swap r1 r2 m = --a matrix with r1 and r2 swapped
scale :: Int -> Rational -> [[Rational]] -> [[Rational]]
scale r c m = --a matrix with row r multiplied by c
addrow :: Int -> Int -> Rational -> [[Rational]] -> [[Rational]]
addrow r1 r2 c m = --a matrix with (c * r1) added to r2
```

In order to actually do guassian elimination, you need a way to decide what multiple of one row to add to another to get a zero. So given two rows..

```
5 4 3 2 1
7 6 5 4 3
```

We want to add c times row 1 to row 2 so that the 7 becomes a zero. So `7 + c * 5 = 0`

and `c = -7/5`

. So in order to solve for c all we need are the first elements of each row. Here's a function that finds c:

```
whatc :: Rational -> Rational -> Rational
whatc _ 0 = 0
whatc a b = - a / b
```

Also, as others have said, using lists to represent your matrix will give you worse performance. But if you're just trying to understand the algorithm, lists should be fine.

`[[Int]]`

is generally bad idea for matrix, because I doubt whether you want O(n) complexity access. Consider`Data.Array`

(low level) or even`hmatrix`

(as Jan suggests) hackages. – Matvey Aksenov Dec 11 '11 at 11:57