To solve some problem I need to compute a variant of the pascal's triangle which is defined like this:
f(1,1) = 1, f(n,k) = f(n-1,k-1) + f(n-1,k) + 1 for 1 <= k < n, f(n,0) = 0, f(n,n) = 2*f(n-1,n-1) + 1.
For n given I want to efficiently get the n-th line (f(n,1) .. f(n,n)). One further restriction: f(n,k) should be -1 if it would be >= 2^32.
next :: [Int64] -> [Int64] next list@(x:_) = x+1 : takeWhile (/= -1) (nextRec list) nextRec (a:rest@(b:_)) = boundAdd a b : nextRec rest nextRec [a] = [boundAdd a a] boundAdd x y | x < 0 || y < 0 = -1 | x + y + 1 >= limit = -1 | otherwise = (x+y+1) -- start shoud be  fLine d start = until ((== d) . head) next start
The problem: for very large numbers I get a stack overflow. Is there a way to force haskell to evaluate the whole list? It's clear that each line can't contain more elements than an upper bound, because they eventually become -1 and don't get stored and each line only depends on the previous one. Due to the lazy evaluation only the head of each line is computed until the last line needs it's second element and all the trunks along the way are stored... I have a very efficient implementation in c++ but I am really wondering if there is a way to get it done in haskell, too.