I wrote code for solving the local alignment problem with Smith–Waterman algorithm.
I want to do this with input of strings with length 10000, with reasonable memory(under 2GB ram) and reasonable time (under 5 minutes).
At first I was using bio library's built in function for this, and it runs way too slow and eat up 4GB of ram before I killed it.
Note the java program jAligner, which implements the same algorithm, can solve this problem with less than 1GB of memory and less than 20 seconds.
When I wrote an unboxed version of this, the program gives me
<<loop>>. I think it's because the array need to access items in the array before the array gets built entirely.
So I wonder is it even possible to write Haskell code with similar performance for this kind of larger dynamic programming problems.
module LocalAlign where --import Data.Array.Unboxed import Data.Tuple import Data.Array localAffineAlignment :: (Char -> Char -> Int) -> Int -> Int -> String -> String -> (Int, (String, String, String, String)) localAffineAlignment f g e s' t' = (score, best) where n = length s' m = length t' s= array (0,n-1) $ zip [0..n-1] s' t= array (0,m-1) $ zip [0..m-1] t' table :: (Array (Int,Int) Int,Array (Int,Int) Int) table = (c,d) where --a :: UArray (Int,Int) Int a = array ((0,0),(n,m)) [((x,y),a' x y)|x<-[0..n],y<-[0..m]] --s end with gap b = array ((0,0),(n,m)) [((x,y),b' x y)|x<-[0..n],y<-[0..m]] --t end with gap c = array ((0,0),(n,m)) [((x,y),fst (c' x y))|x<-[0..n],y<-[0..m]] -- best d = array ((0,0),(n,m)) [((x,y),snd (c' x y))|x<-[0..n],y<-[0..m]] -- direction a' i j | i==0 || j==0 = inf | otherwise = max (a!(i-1,j)-e) (c!(i-1,j)-g-e) b' i j | i==0 || j==0 = inf | otherwise = max (b!(i,j-1)-e) (c!(i,j-1)-g-e) c' i j | min i j == 0 = (0,0) | otherwise = maximum [(b!(i,j),3),(a!(i,j),2),(c!(i-1,j-1) + f u v,1),(0,0)] where u = s!(i-1) v = t!(j-1) inf = -1073741824 score :: Int score = maximum $ elems $ fst table best :: (String, String, String, String) best = (drop si $ take ei s',drop sj $ take ej t',b1,b2) where (a,d') = table (si,sj,b1,b2) = build ei ej   (ei,ej) = snd $ maximum $ map swap $ assocs a build x y ss tt | o == 0 = (x,y,ss,tt) | d == 1 = build (x-1) (y-1) (u:ss) (v:tt) | d == 2 = build (x-1) y (u:ss) ('-':tt) | otherwise = build x (y-1) ('-':ss) (v:tt) where o = a!(x,y) d = d'!(x,y) u = s!(x-1) v = t!(y-1)