# Implement Gauss-Jordan elimination in Haskell

We want to program the gauss-elimination to calculate a basis (linear algebra) as exercise for ourselves. It is not homework.

I thought first of `[[Int]]` as structure for our matrix. I thought then that we can sort the lists lexicographically. But then we must calculate with the matrix. And there is the problem. Can someone give us some hints.

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This is a bit vague: "But then we must calculate with the matrix. And there is the problem." What calculations are you having a problem with? –  dave4420 Dec 11 '11 at 11:42
I must add a line a to line b: add (x:xs) (y:ys) = (x + y) : add xs ys. But how can I make it that the first element of the 2 line will be 0. –  Alexei Dec 11 '11 at 11:45
`[[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

## 2 Answers

Consider using matrices from the hmatrix package. Among its modules you can find both a fast implementation of a matrix and a lot of linear algebra algorithms. Browsing their sources might help you with your doubts.

Here's a simple example of adding one row to another by splitting the matrix into rows.

``````import Numeric.Container
import Data.Packed.Matrix

addRow :: Container Vector t => Int -> Int -> Matrix t -> Matrix t
addRow from to m = let rows = toRows m in
fromRows \$ take to rows ++
[(rows !! from) `add` (rows !! to)] ++
drop (to + 1) rows
``````

Another example, this time by using matrix multiplication.

``````addRow :: (Product e, Container Vector e) =>
Int -> Int -> Matrix e -> Matrix e
addRow from to m = m `add` (e <> m)
where
nrows = rows m
e = buildMatrix nrows nrows
(\(r,c) -> if (r,c) /= (to,from) then 0 else 1)
``````

Cf. Container, Vector, Product.

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Could you add types? I believe they would help understanding the examples considerably –  Masse Dec 14 '11 at 6:26
@Masse, thanks, I've added them. HTH. –  Jan Dec 14 '11 at 19:19

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.

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Actually, you only need euclidean division to perform Gaussian elimination (it is more complex though). –  Alexandre C. Dec 11 '11 at 15:11