# Is it possible to use Haskell to reasonably solve large DP problems

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)

-

You might be interested in the MemoCombinators library, which makes doing dynamic programming much easier. You can basically write the algorithm without memoization, then just annotate which variables you want memoized, and the compiler takes it from there.

-
thx, I will look into this one. The problem is not memorization, but the memory cost spend on storing thunks, which lead to running out of memory and start using swap space. –  Chao Xu Dec 13 '12 at 9:41
@ChaoXu add some strictness annotations? –  jberryman Dec 13 '12 at 20:10
With strictness, the code would have to access the array before the array is frozen, which causes <<loop>>. –  Chao Xu Dec 13 '12 at 21:55
pretty sure there is no better way except write it in mutable arrays. I will post an update when I get it ready –  Chao Xu Dec 13 '12 at 21:56

is it even possible to write Haskell code with similar performance for this kind of larger dynamic programming problems.

Yes, of course. Use the same data structures and the same algorithms, and you will get same (or better, or worse, by constant factors) performance.

You are using (intermediate) lists and boxed arrays heavily. Consider using the vector package instead.

-
unboxed vector still give me <<loop>>. I think what I'm looking for are things that really allow me to access the array while building it, and fast. Say b = generate 10 a with a i = if i==0 then 0 else (b ! (i-1)) and compiles and really fast. –  Chao Xu Dec 12 '12 at 23:18
@ChaoXu: mutable vectors from the vector package allow it. The functions create and constructN both let you access a vector while it's under construction. –  John L Dec 12 '12 at 23:49
I see, I did some thinking and realize there is no way to not using mutation. I am enforcing some cells must store a integer before evaluation of something else, and we get to use a monad. Oh well, in the end I still have to write imperative code. –  Chao Xu Dec 13 '12 at 9:43