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I made a implementation of the KMP algorithm's fail table.

kmp s = b
    where a = listArray (0,length s-1) s
          b = 0:list 0 (tail s)
          list _ [] = [] 
          list n (x:xs) 
            | x==a!n    = (n+1):list (n+1) xs
            | n > 0     = list (b!!(n-1)) (x:xs)
            | otherwise = 0:list 0 xs

b is a list, and b!!(n-1) in the last line is slow, therefore I wish to speed it up and did the following.

kmp s = b
    where a = listArray (0,length s-1) s
          t = listArray (0,length s-1) b
          b = 0:list 0 (tail s)
          list _ [] = [] 
          list n (x:xs) 
            | x==a!n    = (n+1):list (n+1) xs
            | n > 0     = list (t!(n-1)) (x:xs)
            | otherwise = 0:list 0 xs

Note the only difference is to replace b!! by t! and declares t to be the array generated from b.

For the same input, the original code have the correct output, but the new one just outputs <<loop>>.

How can one fix this problem?

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up vote 3 down vote accepted

Your problem is that the list b needs the array t to determine its structure (length). But the array t needs the length of the list before it exists:

listArray :: Ix i => (i,i) -> [e] -> Array i e
listArray (l,u) es = runST (ST $ \s1# ->
    case safeRangeSize (l,u)            of { n@(I# n#) ->
    case newArray# n# arrEleBottom s1#  of { (# s2#, marr# #) ->
    let fillFromList i# xs s3# | i# ==# n# = s3#
                               | otherwise = case xs of
            []   -> s3#
            y:ys -> case writeArray# marr# i# y s3# of { s4# ->
                    fillFromList (i# +# 1#) ys s4# } in
    case fillFromList 0# es s2#         of { s3# ->
    done l u n marr# s3# }}})

As you can see, first a raw array of appropriate size is allocated, then it is filled with arrEleBottom (which is an error call with message undefined array element), then the list is traversed and the list elements are written to the array (the list elements can refer to array values without problem). Then, finally, the array is frozen. Before the array is frozen, it cannot be accessed from outside the filling code (it's basically an ST s computation).

The simplest way to fix it is IMO to use a mutable array in an ST s monad,

kmp s = elems b
    l = length s - 1
    a = listArray (0, l) s
    b = runSTArray $ do
           t <- newArray_ (0,l)
           writeArray t 0 0
           let fill _ _ [] = return t
               fill i n (x:xs)
                 | x == a!n = do
                        writeArray t i (n+1)
                        fill (i+1) (n+1) xs
                 | n > 0    = do
                        k <- readArray t (n-1)
                        fill i k (x:xs)
                 | otherwise = do
                        writeArray t i 0
                        fill (i+1) 0 xs
           fill 1 0 (tail s)

is a very direct (and a bit inefficient) translation of the code.

share|improve this answer
The textbook imperative version of the algorithm (see, e.g., CLRS) translates directly into a fast version (no O(n^2) lookups) using only lazy construction of the array. Also, Bird's book "Pearls of Functional Algorithm Design" has a derivation of KMP which doesn't use arrays, but that would certainly look very different from the OP's algorithm. – Fixnum Dec 3 '12 at 6:56
@Fixnum There's no O(n²) in the STArray version, it's an unoptimised version of the textbook algorithm as I know it, perfectly linear. Of course converting the array to a list afterwards is not very efficient, one should use the array [actually, one should use an unboxed array from the start]. – Daniel Fischer Dec 3 '12 at 7:02
Sorry! I was referring to the OP's complaint about list indexing, which I mistakenly assumed lead to asymptotic slowdown. I was just trying to point out that you can eliminate (!!) without mutable arrays and with less invasive changes to the OP's code). – Fixnum Dec 3 '12 at 7:51
I see. Sorry for the misunderstanding. But I don't see invasive changes to the OP's algorithm, it's a very direct port, I didn't want to change the structure. – Daniel Fischer Dec 3 '12 at 8:00

This doesn't directly answer your question, but gives a simpler fix than the proposed version using STArrays.

The imperative version of the algorithm translates directly into a version that doesn't use repeated list indexing or state, just lazy array construction:

import Data.Array.IArray

kmp :: String -> Array Int Int
kmp s = b
    a :: Array Int Char
    a = listArray (0,l-1) s
    b = listArray (1,l) (0:map (\q -> f (b!(q-1)) q) [2..l])
    f k q
      | k > 0 && (a ! k) /= (a ! (q-1)) =
        f (b ! k) q
      | a ! k == a ! (q-1) = k + 1
      | otherwise = k
    l = length s

However, I haven't benchmarked this.

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