# Notation for a recursive call on user defined type [duplicate]

I'm trying to implement a function that looks at a String ([Chars]) and checks for every letter whether this letter should be replaced with another string. For example we might have a [Chars] consisting of "XYF" and rules that says "X = HYHY", "Y = OO", then our output should become "HYHYOOF".

I want to use the following two types which I have defined:

``````type Letters = [Char]
data Rule = Rule Char Letters deriving Show
``````

My idea is that the function should look something like the following below using guards. The problem is however I can't find any information on how to the recursive call should look like when i want browse through all my rules to see if any of them fits to the current letter x. I hope anyone can give some hints on how the notation goes.

``````apply :: Letters -> [Rule] -> Letters
apply _ _ = []
apply (x:xs) (Rule t r:rs)
| x /= t = apply x (Rule t rs)
| x == t = r++rs:x
| otherwise  =
``````
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## marked as duplicate by casperOne♦Oct 22 '12 at 12:54

I would suggest a helper function to check whether a rule matches,

``````matches :: Char -> Rule -> Bool
matches c (Rule x _) = c == x
``````

and then you check for each character whether there are any matching rules

``````apply :: Letters -> [Rule] -> Letters
apply [] _ = []
apply s [] = s
apply (c:cs) rules = case filter (matches c) rules of
[] -> c : apply cs rules
(Rule _ rs : _) -> rs ++ apply cs rules
``````

If you try an explicit recursion on `rules` within `apply`, it will become too ugly, since you need to remember the full rules list for replacing later characters.

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i thought the helper function was not needed as you could just check whehther x was equal to t ( in my example ), but i see where your method is going. thanks for input. –  John Oct 19 '12 at 13:22
The problem is that you have two lists to traverse, the list of letters, and the rules. Doing that in the same function is not nice, since you need to reinstate the full set of rules for the next letter, you'd need three arguments. Separating the two traversals gives shorter, easier to understand and maintain code. –  Daniel Fischer Oct 19 '12 at 13:28

I'd suggest that you learn to do this with generic utility functions. Two key functions that you want here:

1. `lookup :: Eq a => a -> [(a, b)] -> Maybe b`. Finds a mapping in an association list—a list of pairs used to represent a map or dictionary.
2. `concatMap :: (a -> [b]) -> [a] -> [b]`. This is similar to `map`, but the function mapped over the list returns a list, and the results are concatenated (`concatMap = concat . map`).

To use `lookup` you need to change your `Rule` type to this more generic synonym:

``````type Rule = (Char, String)
``````

Remember also that `String` is a synonym for `[Char]`. This means that `concatMap`, when applied to `String`, replaces each character with a string. Now your example can be written this way (I've changed argument orders):

``````apply :: [Rule] -> String -> String
apply rules = concatMap (applyChar rules)

-- | Apply the first matching rule to the character.
applyChar :: [Rule] -> Char -> String
applyChar rules c = case lookup c rules of
Nothing -> [c]
Just str -> str

-- EXAMPLE
rules = [ ('X', "HYHY")
, ('Y', "OO") ]

example = apply rules "XYF"  -- evaluates to "HYHYOOF"
``````

I changed the argument order of `apply` because when an argument has the same type as the result, it often helps to make that argument the last one (makes it easier to chain functions).

We can go further and turn this into a one-liner by using the utility function `fromMaybe :: a -> Maybe a -> a` from the `Data.Maybe` module (`fromMaybe default Nothing` = `default`, `fromMaybe default (Just x)` = `x`):

``````import Data.Maybe

apply rules = concatMap (\c -> fromMaybe [c] \$ lookup c rules)
``````

An exercise you can do to complement this is to write your version of all of these utility functions on your own by hand: `lookup`, `concatMap` (break it down into `concat :: [[a]] -> [a]` and `map :: (a -> b) -> [a] -> [b]`), and `fromMaybe`. That way you can understand the "full stack" involved in this solution.

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My solution is structurally similar to the other ones, but uses monads:

``````import Control.Monad
import Data.Functor
import Data.Maybe

match :: Char -> Rule -> Maybe Letters
match c (Rule c' cs) = cs <\$ guard (c == c')

apply :: Letters -> [Rule] -> Letters
apply cs rules =
[s | c <- cs
, s <- fromMaybe [c] \$ msum \$ map (match c) rules]
``````

The first monad we're dealing with is `Maybe a`. It is actually a little bit more, a `MonadPlus`, which allows us to use `msum` (which boils down something like `[Nothing, Just 2, Nothing, Just 3]` to the first "hit", here `Just 2`).

The second monad is `[a]`, which allows us to use a list comprehension in `apply`.

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