# Euler 43 - is there a monad to help write this list comprehension?

Here is a way to solve Euler problem 43 (please let me know if this doesn't give the correct answer). Is there a monad or some other syntatic sugar which could assist with keeping track of the `notElem` conditions?

``````toNum xs = foldl (\s d -> s*10+d) 0 xs

numTest xs m = (toNum xs) `mod` m == 0

pandigitals = [ [d0,d1,d2,d3,d4,d5,d6,d7,d8,d9] |
d7 <- [0..9],
d8 <- [0..9], d8 `notElem` [d7],
d9 <- [0..9], d9 `notElem` [d8,d7],
numTest [d7,d8,d9] 17,
d5 <- [0,5],  d5 `notElem` [d9,d8,d7],
d3 <- [0,2,4,6,8], d3 `notElem` [d5,d9,d8,d7],
d6 <- [0..9], d6 `notElem` [d3,d5,d9,d8,d7],
numTest [d6,d7,d8] 13,
numTest [d5,d6,d7] 11,
d4 <- [0..9], d4 `notElem` [d6,d3,d5,d9,d8,d7],
numTest [d4,d5,d6] 7,
d2 <- [0..9], d2 `notElem` [d4,d6,d3,d5,d9,d8,d7],
numTest [d2,d3,d4] 3,
d1 <- [0..9], d1 `notElem` [d2,d4,d6,d3,d5,d9,d8,d7],
d0 <- [1..9], d0 `notElem` [d1,d2,d4,d6,d3,d5,d9,d8,d7]
]

main = do
let nums = map toNum pandigitals
print \$ nums
putStrLn ""
print \$ sum nums
``````

For instance, in this case the assignment to `d3` is not optimal - it really should be moved to just before the `numTest [d2,d3,d4] 3` test. Doing that, however, would mean changing some of the `notElem` tests to remove `d3` from the list being checked. Since the successive `notElem` lists are obtained by just consing the last chosen value to the previous list, it seems like this should be doable - somehow.

UPDATE: Here is the above program re-written with Louis' `UniqueSel` monad below:

``````toNum xs = foldl (\s d -> s*10+d) 0 xs
numTest xs m = (toNum xs) `mod` m == 0

pandigitalUS =
do d7 <- choose
d8 <- choose
d9 <- choose
guard \$ numTest [d7,d8,d9] 17
d6 <- choose
guard \$ numTest [d6,d7,d8] 13
d5 <- choose
guard \$ d5 == 0 || d5 == 5
guard \$ numTest [d5,d6,d7] 11
d4 <- choose
guard \$ numTest [d4,d5,d6] 7
d3 <- choose
d2 <- choose
guard \$ numTest [d2,d3,d4] 3
d1 <- choose
guard \$ numTest [d1,d2,d3] 2
d0 <- choose
guard \$ d0 /= 0
return [d0,d1,d2,d3,d4,d5,d6,d7,d8,d9]

pandigitals = map snd \$ runUS pandigitalUS [0..9]

main = do print \$ pandigitals
``````
-

Sure.

``````newtype UniqueSel a = UniqueSel {runUS :: [Int] -> [([Int], a)]}
return a = UniqueSel (\ choices -> [(choices, a)])
m >>= k = UniqueSel (\ choices ->
concatMap (\ (choices', a) -> runUS (k a) choices')
(runUS m choices))

mzero = UniqueSel \$ \ _ -> []
UniqueSel m `mplus` UniqueSel k = UniqueSel \$ \ choices ->
m choices ++ k choices

-- choose something that hasn't been chosen before
choose :: UniqueSel Int
choose = UniqueSel \$ \ choices ->
[(pre ++ suc, x) | (pre, x:suc) <- zip (inits choices) (tails choices)]
``````

and then you treat it like the List monad, with `guard` to enforce choices, except that it won't choose an item more than once. Once you have a `UniqueSel [Int]` computation, just do `map snd (runUS computation [0..9])` to give it `[0..9]` as the choices to select from.

-
I'm getting a type error: `runUS choices` is a function `[Int] -> [([Int], a0)]`, but the compiler is expecting just `[([Int], a)]` –  user5402 Mar 23 '12 at 1:25
The `(runUS choices)` should have been `(runUS m choices)` –  pat Mar 23 '12 at 4:42
Also, is `guard` from `Control.Monad`? If so, what would `mzero` be for `UniqueSel`? –  user5402 Mar 23 '12 at 8:01
Looks like `StateT [Int] []`. –  luqui Mar 23 '12 at 9:25
@luqui, I'm not 100% sure it's the same -- I'm not 100% sure which is `StateT [Int] []` and which is `ListT (State [Int])`. –  Louis Wasserman Mar 23 '12 at 13:46

Before jumping to monads, let's consider guided unique selection from finite domains first:

``````-- all possibilities:
pick_any []     = []
pick_any (x:xs) = (xs,x) : [ (x:dom,y) | (dom,y) <- pick_any xs ]

-- guided selection (assume there's no repetitions in the domain):
one_of ns xs = [ (dom,y) | let choices = pick_any xs, n <- ns,
(dom,y) <- take 1 \$ filter ((==n).snd) choices ]
``````

With this a list comprehension can be written without the use of `elem` calls:

``````p43 = sum [ fromDigits [d0,d1,d2,d3,d4,d5,d6,d7,d8,d9]
| (dom5,d5) <- one_of [0,5] [0..9]
, (dom6,d6) <- pick_any dom5
, (dom7,d7) <- pick_any dom6
, rem (100*d5+10*d6+d7) 11 == 0
....

fromDigits    :: (Integral a) => [a] -> Integer
fromDigits ds = foldl' (\s d-> s*10 + fromIntegral d) 0 ds
``````

The monad from Louis Wasserman's answer can be further augmented with additional operations based on the functions above:

``````import Control.Monad

newtype UniqueSel a = UniqueSel { runUS :: [Int] -> [([Int], a)] }

choose             = UniqueSel pick_any
choose_one_of xs   = UniqueSel \$ one_of xs
choose_n n         = replicateM n choose
set_choices cs     = UniqueSel (\ _ -> [(cs, ())])
get_choices        = UniqueSel (\cs -> [(cs, cs)])
``````

So that we can write

``````numTest xs m = fromDigits xs `rem` m == 0

pandigitalUS :: UniqueSel [Int]
pandigitalUS = do
set_choices [0..9]
[d7,d8,d9] <- choose_n 3
guard \$ numTest [d7,d8,d9] 17
d6 <- choose
guard \$ numTest [d6,d7,d8] 13
d5 <- choose_one_of [0,5]
guard \$ numTest [d5,d6,d7] 11
d4 <- choose
guard \$ numTest [d4,d5,d6] 7
d3 <- choose_one_of [0,2..8]
d2 <- choose
guard \$ rem (d2+d3+d4) 3 == 0
[d1,d0] <- choose_n 2
guard \$ d0 /= 0
return [d0,d1,d2,d3,d4,d5,d6,d7,d8,d9]

pandigitals = map (fromDigits.snd) \$ runUS pandigitalUS []

main = do print \$ sum pandigitals
``````
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if you write `fromDigits` to have type `Num a => [a] -> Integer`, you can keep `d0`, ... `d9` as Ints since no overflow will occur in the `rem` calls. –  user5402 Mar 27 '12 at 22:37
thanks for showing the `set_choices`, `choose_one`, `choose_n` and `select` functions –  user5402 Mar 27 '12 at 22:42
@user5402 thanks for the suggestion. :) It worked, with `Integral` context though. Will edit. –  Will Ness Mar 28 '12 at 8:41

The `UniqueSel` monad suggested by Louis Wasserman is exactly `StateT [Integer] []` (I'm using `Integer` everywhere for simplicity).

The state keeps the available digits and every computation is nondeterministic - from a given state we can select different digits to continue with. Now the `choose` function can be implemented as

``````import Control.Monad
import Data.List

choose :: PanM Integer
choose = do
xs <- get
x <- lift xs -- pick one of `xs`
let xs' = x `delete` xs
put xs'
return x
``````

And then the monad is run by `evalStateT` as

``````main = do
let nums = evalStateT pandigitals [0..9]
-- ...
``````
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