For cultural and intellectual enrichment, I've decided to learn a bit of Haskell. I've been reading Hughes' "Why Functional Programming Matters" and am trying to translate its code into true Haskell. I've attached some of my attempt below (for the numerical parts of the paper; the alpha-beta algorithm is even more interesting but I'd also have to write a game evaluator from scratch!).
At this point it's been more of an exercise in Haskell syntax than anything else. I've already done simple things like translate
repeat into the native Haskell
iterate, translate a few functions that used a lot of parentheses to function composition (making them more point-free in the process), etc.
But my code certainly works, and I wonder if it's sufficiently "Haskell-ish". Can any experts out there give me some hints?
-- 4.1 Newton-Raphson square roots next n x = (x + n/x)/2.0 -- -- this is "iterate::(a->a)->a->[a]" -- repeat f a = a : iterate f (f a) within eps (a:b:rest) = if abs(a-b) <= eps then b else within eps (b:rest) sqroot a0 eps n = within eps (iterate (next n) a0) relative eps (a:b:rest) = if abs(a-b) <= eps*abs(b) then b else relative eps (b:rest) relativesqrt a0 eps n = relative eps (iterate (next n) a0) -- 4.2 numerical differentiation easydiff f x h = (f (x+h) - f x) / h differentiate h0 f x = map (easydiff f x) (iterate (/2) h0) -- diff1a h0 eps f x = within eps (differentiate h0 f x) diff1 h0 eps f = within eps . differentiate h0 f elimerror n (a:b:rest) = (b*(2**n)-a)/(2**n-1) : elimerror n (b:rest) -- need fromIntegral to make a non-integer out of the Int which comes out of round order (a:b:c:rest) = fromIntegral (round (logBase 2 ((a-c)/(b-c)-1))) improve s = elimerror (order s) s --diff2a h0 eps f x = within eps (improve (differentiate h0 f x)) diff2 h0 eps f = within eps . improve . differentiate h0 f --super s = map second (iterate improve s) -- how can we make this point-free? super :: (RealFrac t, Floating t) => [t] -> [t] -- w/o this it wants to be [double]->[double] super = map second . iterate improve -- second (a:b:rest) = b second = head . tail diff3 h0 eps f = within eps . super . differentiate h0 f -- 4.3 integration easyintegrate f a b = (f a + f b)*(b-a)/2 -- addpair becomes (uncurry (+)) integrate f a b = integ f a b (f a) (f b) integ f a b fa fb = (fa+fb)*(b-a)/2 : map (uncurry (+)) (zip (integ f a m fa fm) (integ f m b fm fb)) where m = (a+b)/2 fm = f m -- test: following should be about pi approxpi eps = within eps (improve (integrate (\x -> 4/(1+x*x)) 0 1)) superpi eps = within eps (super (integrate (\x -> 4/(1+x*x)) 0 1)) -- is there any way to keep track of the number of iterations? state monad, but seems like a lot of work...\