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So, here is my clumsy code implementing chained HashTable in Haskell.

{-# LANGUAGE FlexibleInstances #-}

import Data.Array(Array(..), array, bounds, elems, (//), (!))
import Data.List(foldl')
import Data.Char
import Control.Monad.State

class HashTranform a where
    hashPrepare :: a -> Integer

instance HashTranform Integer where
    hashPrepare = id 

instance HashTranform String where
    hashPrepare cs = fromIntegral (foldl' (flip ((+) . ord)) 0 cs)

divHashForSize :: (HashTranform a) => Integer -> a -> Integer
divHashForSize sz k = 1 + (hashPrepare k) `mod` sz 

type Chain k v = [(k, v)]

chainWith :: (Eq k) => Chain k v -> (k, v) -> Chain k v
chainWith cs p@(k, v) = if (null after) then p:cs else before ++ p:(tail after)
  where (before, after) = break ((== k) . fst) cs

chainWithout :: (Eq k) => Chain k v -> k -> Chain k v
chainWithout cs k = filter ((/= k) . fst) cs 

data Hash k v = Hash {
    hashFunc   :: (k -> Integer)
  , chainTable :: Array Integer (Chain k v) 

--type HState k v = State (Hash k v)

instance (Show k, Show v) => Show (Hash k v) where
    show = show . concat . elems . chainTable

type HashFuncForSize k = Integer -> k -> Integer

createHash :: HashFuncForSize k -> Integer -> Hash k v
createHash hs sz = Hash (hs sz) (array (1, sz) [(i, []) | i <- []])

withSlot :: Hash k v -> k -> (Chain k v -> Chain k v) -> Hash k v
withSlot h k op
    | rows < hashed = h
    | otherwise     = Hash hf (ht // [(hashed, op (ht!hashed))])
  where hf     = hashFunc h
        ht     = chainTable h
        rows   = snd (bounds ht) 
        hashed = hf k

insert' :: (Eq k) => Hash k v -> (k, v) -> Hash k v
insert' h p@(k, v) = withSlot h k (flip chainWith p)

delete' :: (Eq k) => Hash k v -> k -> Hash k v
delete' h k = withSlot h k (flip chainWithout k)

insert :: (Eq k) => Hash k v -> Chain k v -> Hash k v
insert src pairs = foldl' insert' src pairs

delete :: (Eq k) => Hash k v -> [k] -> Hash k v
delete src keys = foldl' delete' src keys

search :: (Eq k) => k -> Hash k v -> Maybe v
search k h
    | rows < hashed = Nothing
    | otherwise     = k `lookup` (ht!hashed) 
  where hf     = hashFunc h
        ht     = chainTable h
        rows   = snd (bounds ht)
        hashed = hf k

The problem is I don't want to have to code like this:

new = intHash `insert` [(1112, "uygfd"), (211, "catdied")]
new' = new `delete` [(1112, "uygfd")]

I believe it's modified with State Monad somehow, but having read online tutorials I couldn't quite grasp how exactly it's done.

So could you show me how to implement at least insert, delete, search or any one of them to give exposition.

share|improve this question

1 Answer 1

up vote 4 down vote accepted

At the end of the day your "state" will be a Hash k v. Let's break the interface functions into two groups. First are "state dependent" functions like search k which has a type like Hash k v -> _ (where _ just means "something"). Second are the "state updating" functions like flip insert (k, v) and flip delete ks which have types like Hash k v -> Hash k v.

As you've noted, you can already simulate "state" by manually passing around the Hash k v argument. The State monad is nothing more than type magic to make that easier.

If you look at Control.Monad.State you'll see modify :: (s -> s) -> State s () and gets :: (s -> a) -> State s a. These functions transform your "state updating" and "state dependent" functions into "State monad actions". So now we can write a combined State monad action like so

deleteIf :: (v -> Bool) -> k -> State (Hash k v) ()
deleteIf predicate k = do
  v <- gets $ search k
  case fmap predicate v of
    Nothing    -> return ()
    Just False -> return ()
    Just True  -> modify $ flip delete [k]

and then we can sequence together larger computations

computation = deleteIf (>0) 'a' >> deleteIf (>0) 'b'

and then execute them by "running" the State monad

runState computation (createHash f 100)
share|improve this answer
Thank you! It was a great help! – esengie May 23 '13 at 9:36
You're welcome! :) – J. Abrahamson May 27 '13 at 0:27

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