My suggestion would be to use a somewhat different intermediate datastructure when processing the string that you want edited. Here is a solution that uses tries.

## Preliminaries

```
import Data.Map (Map)
import qualified Data.Map as M
```

## Tries

Here is a simple datatype of tries:

```
data Trie = Trie (Maybe String) (Map Char Trie)
```

Tries are constructed from the empty trie and a function for inserting key/value bindings into an existing trie:

```
empty :: Trie
empty = Trie Nothing M.empty
insert :: String -> String -> Trie -> Trie
insert [] val (Trie _ tries) = Trie (Just val) tries
insert (c : cs) val (Trie mbVal tries) = case M.lookup c tries of
Nothing -> Trie mbVal (M.insert c (insert cs val empty) tries)
Just trie -> Trie mbVal (M.insert c (insert cs val trie) tries)
```

## Matching

With tries, matching reduces to recursing over the input string while traversing the trie. When a match is found, the corresponding replacement value is returned together with the remaining part of the input string (so that it can be subjected to further replacements):

```
match :: Trie -> String -> Maybe (String, String)
match (Trie (Just val) _ ) s = Just (val, s)
match (Trie Nothing _ ) [] = Nothing
match (Trie Nothing tries) (c : cs) = case M.lookup c tries of
Nothing -> Nothing
Just trie -> match trie cs
```

Note that this function is greedy in the sense that it gives preference to the shortest match if multiple matches are possible. Adapting it so that it picks the longest match instead (and, hence, implements the "maximal-munch" principle) is not too hard.

## Replacement

Replacing occurrences of search words by their corresponding replacements can be implemented by looking for a match in the input string: if a match is found, the replacement is put into the output string and we continue processing with the unmatched part of the string. If no match is found, we keep the head of the input string and proceed with the tail.

```
replace :: Trie -> String -> String
replace trie = go
where
go [] = []
go s@(c : cs) = case match trie s of
Nothing -> c : go cs
Just (s', s'') -> s' ++ go s''
```

## Bringing it all together

Your required function `listReplace`

is now almost trivial:

```
listReplace :: [String] -> [String] -> String -> String
listReplace keys vals = replace trie
where
trie = foldr ($) empty (zipWith insert keys vals)
```

As you see, the part that you refer to as "tricky" is easily realised by "zipping" the two list arguments.

## Example

Here is a simple example (inspired by L. Peter Deutsch):

```
> let s = "to err is human; to forgive, divine"
> listReplace ["err", "forgive"] ["iterate", "recurse"] s
"to iterate is human; to recurse, divine"
```