I'm relearning Haskell after a 10 year hiatus, partly to see what's changed and partly as an antidote to days spent in C#, SQL and JavaScript and partly as it's cool all of a sudden ;-)

I decided to set myself the Towers of Hanoi as a coding kata, simple enough stuff but I already feel that my code is non-idiomatic and would love to hear what hints and tips any Haskell old hands might have.

To make the kata slightly more interesting I split the problem into two parts, the first part, the function `moves`, generates the sequence of moves required to solve the puzzle. The remainder of the code is designed to model the towers and execute the moves.

One part I definitely feel unhappy with is the `moveDisc` function, this would be tedious to extend to 4 towers.

Hanoi.hs

``````module Hanoi
where

import Data.Maybe

type Disc = Integer
type Towers = [[Disc]]
data Column = A | B | C deriving (Eq,Show)

getDisc :: Towers -> Column -> Maybe Disc
getDisc t A = listToMaybe \$ t !! 0
getDisc t B = listToMaybe \$ t !! 1
getDisc t C = listToMaybe \$ t !! 2

validMove :: Towers -> Column -> Column -> Bool
validMove tower from to
| srcDisc == Nothing = False
| destDisc == Nothing = True
| otherwise = srcDisc < destDisc
where srcDisc = getDisc tower from
destDisc = getDisc tower to

moveDisc :: Towers -> Column -> Column -> Towers
moveDisc [a:as, b, c] A B = [as, a:b, c]
moveDisc [a:as, b, c] A C = [as, b, a:c]
moveDisc [a, b:bs, c] B A = [b:a, bs, c]
moveDisc [a, b:bs, c] B C = [a, bs, b:c]
moveDisc [a, b, c:cs] C A = [c:a, b, cs]
moveDisc [a, b, c:cs] C B = [a, c:b, cs]

moves :: Integer -> Column -> Column -> Column -> [(Column,Column)]
moves 1 a _ c = [(a,c)]
moves n a b c = moves (n-1) a c b ++ [(a,c)] ++ moves (n-1) b a c

solve :: Towers -> Towers
solve towers = foldl (\t (from,to) -> moveDisc t from to) towers (moves len A B C)
where len = height towers

height :: Towers -> Integer
height (t:_) = toInteger \$ length t

newGame :: Integer -> Towers
newGame n = [[1..n],[],[]]
``````

TestHanoi.hs

``````module TestHanoi
where

import Test.HUnit
import Hanoi

main = runTestTT \$ "Hanoi Tests" ~: TestList [

getDisc [[1],[2],[2]] A ~?= Just 1 ,
getDisc [[1],[2],[3]] B ~?= Just 2 ,
getDisc [[1],[2],[3]] C ~?= Just 3 ,
getDisc [[],[2],[3]] A ~?= Nothing ,
getDisc [[1,2,3],[],[]] A ~?= Just 1 ,

validMove [[1,2,3],[],[]] A B ~?= True ,
validMove [[2,3],[1],[]] A B ~?= False ,
validMove [[3],[],[1,2]] A C ~?= False ,
validMove [[],[],[1,2,3]] A C ~?= False ,

moveDisc [[1],[],[]] A B ~?= [[],[1],[]] ,
moveDisc [[],[1],[]] B C ~?= [[],[],[1]] ,
moveDisc [[1,2],[],[]] A B ~?= [[2],[1],[]] ,
moveDisc [[],[2],[1]] C B ~?= [[],[1,2],[]] ,
moveDisc [[1,2],[],[]] A C ~?= [[2],[],[1]] ,
moveDisc [[3],[2],[1]] B A ~?= [[2,3],[],[1]] ,

moves 1 A B C ~?= [(A,C)] ,
moves 2 A B C ~?= [(A,B),(A,C),(B,C)] ,

"acceptance test" ~:
solve [[1,2,3,4,5,6], [], []] ~?= [[],[],[1,2,3,4,5,6]] ,

"is optimal" ~:
length (moves 3 A B C) ~?= 7
]
``````

I look forward to hearing any comments or suggestions for improvement.

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Here's an implementation using an alternative representation. Instead of storing three lists of peg sizes, I store a list of columns, where the first element corresponds to the position of the smallest disc, and so on. This has the benefit that it is now impossible to represent illegal states like missing discs, larger disks stacked on top of smaller ones, etc. It also makes many of the functions trivial to implement.

Hanoi.hs

``````module Hanoi where

import Control.Applicative
import Data.List
import Data.Maybe

type Disc = Integer
type Towers = [Column]
data Column = A | B | C deriving (Eq, Show)

getDisc :: Column -> Towers -> Maybe Disc
getDisc c t = (+1) . toInteger <\$> elemIndex c t

validMove :: Column -> Column -> Towers -> Bool
validMove from to = isJust . moveDisc from to

moveDisc :: Column -> Column -> Towers -> Maybe Towers
moveDisc from to = foldr check Nothing . tails
where check (c:cs)
| c == from   = const . Just \$ to : cs
| c == to     = const Nothing
| otherwise   = fmap (c:)

moves :: Integer -> Column -> Column -> Column -> [(Column,Column)]
moves 1 a _ c = [(a,c)]
moves n a b c = moves (n-1) a c b ++ [(a,c)] ++ moves (n-1) b a c

solve :: Towers -> Towers
solve towers = fromJust \$ foldM (\t (from,to) -> moveDisc from to t) towers (moves len A B C)
where len = height towers

height :: Towers -> Integer
height = genericLength

newGame :: Integer -> Towers
newGame n = genericReplicate n A
``````

HanoiTest.hs

``````module HanoiTest where

import Test.HUnit
import Hanoi

main = runTestTT \$ "Hanoi Tests" ~: TestList [

getDisc A [A, B, C] ~?= Just 1 ,
getDisc B [A, B, C] ~?= Just 2 ,
getDisc C [A, B, C] ~?= Just 3 ,
getDisc A [B, B, C] ~?= Nothing ,
getDisc A [A, A, A] ~?= Just 1 ,

validMove A B [A, A, A] ~?= True ,
validMove A B [B, A, A] ~?= False ,
validMove A C [C, C, A] ~?= False ,
validMove A C [C, C, C] ~?= False ,

moveDisc A B [A] ~?= Just [B] ,
moveDisc B C [B] ~?= Just [C] ,
moveDisc A B [A, A] ~?= Just [B, A] ,
moveDisc C B [C, B] ~?= Just [B, B] ,
moveDisc A C [A, A] ~?= Just [C, A] ,
moveDisc B A [C, B, A] ~?= Just [C, A, A] ,

moves 1 A B C ~?= [(A,C)] ,
moves 2 A B C ~?= [(A,B),(A,C),(B,C)] ,

"acceptance test" ~:
solve [A, A, A, A, A, A] ~?= [C, C, C, C, C, C] ,

"is optimal" ~:
length (moves 3 A B C) ~?= 7
]
``````

Apart from the representation change, I also made `moveDisc` total by having it return `Nothing` in case of an invalid move. That way I could trivially implement `validMove` in terms of it. I do feel like there's a more elegant way to implement `moveDisc` though.

Note that `solve` only works if the argument is an initial position. This is also the case for your code (it fails due to incomplete patterns in `moveDisc`). I return `Nothing` in this case.

Edit: Added rampion's improved `moveDisc` and changed the argument ordering to have the data structure last.

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very interesting, I like how you flipped (transposed?) the representation. I find it slightly harder to visualize but the code is improved in my opinion. `getDisc` is no longer required and `height` no longer depends on the towers being in initial state. –  chillitom May 5 '11 at 10:03
@chillitom: I finally remembered where I got the idea from: This talk from ICFP 2009: Functional Pearl: La Tour D’Hanoï. –  hammar May 5 '11 at 10:18
I think you're missing a `<\$>` in `otherwise = (c:) moveDisc cs from to` –  rampion May 5 '11 at 14:26
@rampion: Ah, yes, the joys of HTML escaping :) I should learn to pre-indent my code before pasting it into the browser so I don't have to use `<code>` and friends. –  hammar May 5 '11 at 14:30
here's a possibly more elegant `moveDisc`. It's non-recursive –  rampion May 5 '11 at 14:44

If you derive Enum in Column then it is easy to rewrite moveDisk to take arbitrary length lists.

Take the case of `(toInt a) < (toInt b)` your new tower after the switch is the first `(toInt a) - 1` of your initial tower then the bottom part of the second then the distance between a and b of the first, the head of the first cons the second, then the remainder.

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