# Newtons Method Type Class Haskell

Trying a couple different ways of implementing Newtons Method, but I cant seem to get it working. It's most likely a very simple fix, but I just need someone to point out what I'm doing wrong. Yeah I know my code is ugly, just messing around right now.

In this example, I just try to make an equation for xn+1, which isn't working.

``````function :: (Num a) => a ->  a
function x = 98 - x^98
function' :: (Num a) => a -> a
function' x = (-98)*(x^97)
xi = 1.04
iterations = 20

newtons :: (Integral a) => a -> a

newtons x = x - fromIntegral ( div (function x) (function' x) )
``````

When I type 'newtons xi' in ghci I get an error that says "no instance for Integral Double arising from a use of newtons". What type class should I be using to make this work?

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Why would you implement an archetypical calculus, i.e. real number based algorithm with integer arithmetic? This is obviously a case for floating-point numbers. –  leftaroundabout Nov 20 '13 at 1:25
The problem is that `xi` is a `Double`, but you're passing it in to `newtons`, which expects an `Integral a` type. `Double` is not an `Integral` type. Why are you converting to `Integral` anyway? It has no relevance in the context of Newton's method. –  bheklilr Nov 20 '13 at 1:29
Forgot I had that there. But when I made my type class for Newtons (Num a) it told me "Could not deduce (Integral a) arising from a use of div from the context of (Num a) bound by the type signature for newtons" So I assumed that div must only work on integers. –  caleborp Nov 20 '13 at 1:39
That's because of the type signature of `div`. You probably need to use `Fractional` rather than `Num`, since then you can use `/`. –  bheklilr Nov 20 '13 at 1:41

Just needed more general types. Didn't see the iteration function which is the core of the algorithm so I tried to adapt it around your existing code:

``````function :: Num a => a -> a
function x = 98 - x^98

function' :: Num a => a -> a
function' x = (-98)*(x^97)

xi :: Double
xi = 1.04

newton :: (Fractional a, Ord a) => (a -> a) -> (a -> a) -> a -> a
newton f f' x
| (abs (f x)) < epsilon = x
| otherwise = newton f f' (x - (f x / f' x))
where
epsilon = 1e-4

main :: IO ()
main = do
-- Prints out the two extrema
print \$ newton function function' xi    --  1.0478970878235732
print \$ newton function function' (-xi) -- -1.0478970878235732
``````

This is a naive implementation, if you need performance and numeric stability then the ad package is best suited for this.

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