# Print all possible world configurations

Just starting out with Haskell! As an exercise, the current problem I'm trying to implement is as follows:

We have n squares, print all possible world configurations where :

• (1) Each square could have a "P" (pit) or not (2^n possibilities).
• (2) There can be at most one "W" (wumpus) in all n squares (n+1 possibilities).

Representing two squares as two strings, here is an output example for n=2. We have (2^n)·(n+1) = (2^2)·(2+1) = 12 configurations.

``````[[" W"," "],[" "," W"],[" "," "],
[" W","P"],[" ","PW"],[" ","P"],
["PW"," "],["P"," W"],["P"," "],
["PW","P"],["P","PW"],["P","P"]]
``````

Condition (1) is easily implemented. Looking around, I've found a few ways to express it :

``````p 0 = [[]]
p n = [x:xs | x <- [" ","P"], xs <- p (n-1)]
``````

or

``````p n = mapM (\x -> [" ","P"]) [1..n]
``````

or

``````p n = replicateM n [" ","P"]
``````

I cannot claim to understand the last two yet, but here they are for completeness.

Question : How can I add condition (2)? Can it be done with list comprehension? My not-so-good-looking novice solution involved these functions:

``````insertw :: Int -> [String] -> [String]
insertw n xs
| n < 0     = xs
| n >= lgth = xs
| otherwise = (take (n) xs) ++ [xs!!n++"W"] ++ (drop (n+1) xs)
where lgth  = length xs

duplicate :: Int -> [String] -> [[String]]
duplicate i squares
| i > lgth   = []
| otherwise  = (insertw i squares) : duplicate (i+1) squares
where lgth   = length squares

worlds :: Int -> [[String]]
worlds n = concat . map (duplicate 0) . p \$ n
``````
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You don't seem to make it clear what a "square" is. Either that or your solution for (1) doesn't do what you seem to think it does. –  Anon. Feb 9 '11 at 20:59
agree w/ Anon (+1). if i understand the problem correctly then your (1) is not correct. have you run your code for condition (1) alone to see what it produces? –  trh178 Feb 9 '11 at 21:03
Yes a square can hold P or can be empty. If we have 2 squares, here are the possible configurations: [[" "," "],[" ","P"],["P"," "],["P","P"]] –  num3ric Feb 9 '11 at 21:06
Are the two strings meant to be the two squares? –  Tim Perry Feb 9 '11 at 21:24
@Tim Perry Yes sorry, this must be causing the confusion. –  num3ric Feb 9 '11 at 21:27
show 1 more comment

Seems obvious to me :). In list comprehensions, the later lists can depend on the values generated in the earlier ones. The second function generates your set by calling the first when it adds a wumpus..

``````p 0 = [[]]
p n = [[x,' ']:xs | x <- [' ','P'], xs <- p (n-1)]

pw 0 = [[]]
pw n = [[x,w]:xs | w <- [' ','W'], x <- [' ','P'], xs <- if w == 'W' then p (n-1) else pw (n-1)]
``````

it isn't as clean as possible, but I always find list comprehensions bring an elegance to the problem :). Totally worth it.

-

Condition 2 isn't an obvious candidate for a list comprehension, but the working code you have already written can be cleaned up.

The iteration from `0` to `lgth` in `duplicate` can be done with a `map` instead of explicit recursion:

``````duplicate squares = map (\i -> insertw i squares) [0 .. length squares]
``````

`duplicate` no longer takes an index parameter, and `concat . map` is the same as `concatMap`:

``````worlds = concatMap duplicate . p
``````

If you do both a `drop` and a `take`, then `splitAt` is often the better operation.

``````insertw n xs =
case splitAt n xs of
(as, []) -> as
(as, b : bs) -> as ++ ((b ++ "W") : bs)
``````

Note that we got rid of the `length xs` and `xs !! n` operations too.

As an exercise, another short `duplicate` function can be written by zipping over the `inits` and `tails` of the `squares` list.

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+1 for suggesting zipping over inits and tails. –  dave4420 Feb 10 '11 at 9:52
Very appreciated, thanks a lot for these tips. I will make sure to do this exercise. :) –  num3ric Feb 11 '11 at 1:03