When solving system of linear equations by Tridiagonal matrix algorithm in Haskell I met following problem.
We have three vectors:
c, and we want to make a third vector
c' which is a combination of them:
c'[i] = c[i] / b[i], i = 0 c'[i] = c[i] / (b[i] - a[i] * c'[i-1]), 0 < i < n - 1 c'[i] = undefined, i = n - 1
Naive implementation of the formula above in Haskell is as follows:
calcC' a b c = Data.Vector.generate n f where n = Data.Vector.length a f i = | i == 0 = c!0 / b!0 | i == n - 1 = 0 | otherwise = c!i / (b!i - a!i * f (i - 1))
It looks like this function
calcC' has complexity O(n2) due to recurrence. But all we actualy need is to pass to inner function
f one more parameter with previously generated value.
I wrote my own version of
generate with complexity O(n) and helper function
mapP f xs = mapP' xs Nothing where mapP'  _ =  mapP' (x:xs) xp = xn : mapP' xs (Just xn) where xn = f x xp generateP n f = Data.Vector.fromList $ mapP f [0 .. n-1]
As one can see,
mapP acts like a standard
map, but also passes to mapping function previously generated value or
Nothing for first call.
My question: is there any pretty standard ways to do this in Haskell? Don't I reinvent the weel?