I'm new to haskell and I have an assignment that involves parsing a string into a tree and doing some junk with it. I've just about finished (everything is functionally fine right now) but as I've gone through the development, I've been using a static string definition as opposed to entering the input each time.

Here is an example input. ex1 = "C1,8R1+4;R3-4C2C7+4;R5R2-3C1-6+3;R2-3C6+2;"

The last thing I need to do is handle user input (the input should come from standard in, not some definition). Not only do I not know how to get input for sure, but I'm beginning to think I'm royally screwed because of the nature of haskell. I mean, it seems like the entire language is just nested statements within nested statements with recursive nested statements and so on and so forth. It's a confusing mess to me. I'm not even sure what to ask... so far my attempts at getting user input have meant that I need to start throwing around the input as a parameter to every single function in the entire program just to get it to compile. Is there any way I can turn user input into a definition like the above? Or perhaps even just cheat with a global string variable? I'm desperate :( Thanks.

I know it's probably bad to be posting my entire program but I feel like I need to so I can show how intertwined it all is, making it difficult to figure out how to proceed.

It is the function createNodeContentList (near the bottom) that actually uses the definition of ex1.

```
import Text.Regex.Posix
import Data.List.Split
ex1 = "C1,8R1+4;R3-4C2C7+4;R5R2-3C1-6+3;R2-3C6+2;"
treePat = "(([RC][0-9]*[,-]?[0-9]*)*[+][0-9]*;)"
rangePat = "([RC][0-9]*[-][0-9]*)"
nodePat = "([RC][0-9,-]*)"
breakIntoInputTrees x = endBy ";" x
breakIntoInputNodes x = getAllTextMatches $ x =~ nodePat :: [String]
data NodeContent = NodeContent { idy::Char, vals::[Int] } deriving (Show)
data Tree = Node { content::NodeContent, children::[Tree]} deriving (Show)
data GridMod = GridMod { rows::[Int], cols::[Int], mod::[Int] } deriving (Show)
data Path = Path { pathSum::Int, corner::[Char] } deriving (Show, Eq, Ord)
go = printCornerNames $ maxOfMinPaths (maxOfMinValues 0 listOfMinPaths) listOfMinPaths
printCornerNames pathList = putStrLn $ unwords [ corner path | path <- pathList ]
maxOfMinPaths max [] = []
maxOfMinPaths max (h:t) = if (pathSum h == max)
then h:maxOfMinPaths max t
else maxOfMinPaths max t
maxOfMinValues max [] = max
maxOfMinValues max (h:t) = if (pathSum h > max)
then maxOfMinValues (pathSum h) t
else maxOfMinValues max t
listOfMinPaths = findMinimums finalArray
findMinimums array = [quadMinPath array center 0 rMod cMod | rMod <- [-1,1], cMod <- [-1,1]]
quadMinPath array (r,c) sum rMod cMod
| isCorner (r,c) = Path (sum + (posVal array r c)) (cornerName (r,c))
| otherwise = decidePaths array (r,c) sum rMod cMod
decidePaths array (r,c) sum rMod cMod
| (validRow (r + rMod) && validCol (c + cMod)) =
minimum [
quadMinPath array (r + rMod, c) (sum + (posVal array r c)) rMod cMod,
quadMinPath array (r, c + cMod) (sum + (posVal array r c)) rMod cMod
]
| (validRow (r + rMod)) = quadMinPath array (r + rMod, c) (sum + (posVal array r c)) rMod cMod
| otherwise = quadMinPath array (r, c + cMod) (sum + (posVal array r c)) rMod cMod
posVal array r c = array !! (toIndex r c)
isCorner x = elem x [(1,1), (1,cMax), (rMax,1), (rMax,cMax)]
cornerName x | x == (1,1) = "TOP-LEFT" | x == (1,cMax) = "TOP-RIGHT"
| x == (rMax,1) = "BOTTOM-LEFT" | x == (rMax,cMax) = "BOTTOM-RIGHT"
validRow r = if (r >= 1 && r <= rMax) then True else False
validCol c = if (c >= 1 && c <= cMax) then True else False
rMax = fst findMaximums
cMax = snd findMaximums
center = (quot (fst findMaximums) 2 + 1, quot (snd findMaximums) 2 + 1)
finalArray = modifyArray (createArray findMaximums) (toModifiers createGridModders)
modifyArray array [] = array
modifyArray array ((r,c,m):t) = modifyArray (addToArray array (toIndex r c) m) t
addToArray array index mod = (take index array) ++ [(mod + array !! index)] ++ (drop (index + 1) array)
toIndex r c = (r - 1) * (snd findMaximums) + c - 1
createArray (maxR,maxC) = (take (maxR * maxC)) (repeat 0)
printArray array = mapM_ putStrLn [ printRow row | row <- (chunksOf (snd findMaximums) array)]
printRow row = unwords (map show row)
toModifiers gridModders = flat [ toModifier gw | gw <- gridModders ]
toModifier (GridMod r c m) = [ (x,y,head m) | x <- r, y <- c]
createGridModders = adjustForMaximums (treeWalk (GridMod [] [] []) buildAllTrees)
adjustForMaximums gridMods = [ fillMax gm findMaximums | gm <- gridMods ]
fillMax (GridMod [] [] m) (maxR,maxC) = (GridMod [1..maxR] [1..maxC] m)
fillMax (GridMod [] c m) (maxR,maxC) = (GridMod [1..maxR] c m)
fillMax (GridMod r [] m) (maxR,maxC) = (GridMod r [1..maxC] m)
fillMax (GridMod r c m) (maxR,maxC) = (GridMod r c m)
treeWalk (GridMod r c m) (Node (NodeContent 'R' v) []) = [(GridMod v c m)]
treeWalk (GridMod r c m) (Node (NodeContent 'C' v) []) = [(GridMod r v m)]
treeWalk (GridMod r c m) (Node (NodeContent 'M' v) []) = [(GridMod r c v)]
treeWalk (GridMod r c m) (Node (NodeContent 'R' v) ch) = flat [ (treeWalk (GridMod v c m) tree) | tree <- ch ]
treeWalk (GridMod r c m) (Node (NodeContent 'C' v) ch) = flat [ (treeWalk (GridMod r v m) tree) | tree <- ch ]
treeWalk (GridMod r c m) (Node (NodeContent 'M' v) ch) = flat [ (treeWalk (GridMod r c v) tree) | tree <- ch ]
treeWalk (GridMod r c m) (Node (NodeContent 'Z' v) ch) = flat [ (treeWalk (GridMod r c m) tree) | tree <- ch ]
flat [] = []
flat (h:t) = h ++ flat t
findMaximums = (oddify(findMaxRows buildAllTrees), oddify(findMaxCols buildAllTrees))
oddify num = num + ((Prelude.mod num 2) - 1) * (-1)
findMaxRows (Node (NodeContent 'R' v) []) = maximum v
findMaxRows (Node (NodeContent _ _) []) = 0
findMaxRows (Node (NodeContent 'R' v) c) = maximum (v ++ [ findMaxRows x | x <- c ])
findMaxRows (Node (NodeContent _ _) c) = maximum [ findMaxRows x | x <- c ]
findMaxCols (Node (NodeContent 'C' v) []) = maximum v
findMaxCols (Node (NodeContent _ _) []) = 0
findMaxCols (Node (NodeContent 'C' v) c) = maximum (v ++ [ findMaxCols x | x <- c ])
findMaxCols (Node (NodeContent _ _) c) = maximum [ findMaxCols x | x <- c ]
buildAllTrees = Node (NodeContent 'Z' []) (buildIntoTrees (createNodeContentList))
buildIntoTrees x = [ buildIntoTree treeNodeContentList | treeNodeContentList <- x ]
buildIntoTree (h:t) = Node h [ buildSubTree subList | subList <- (easyList t) ]
buildSubTree (h:t) = Node h [ Node content [] | content <- t ]
easyList nodeContentList = tail (simplifyNodeList (idy (head nodeContentList)) nodeContentList [] [])
simplifyNodeList identity [] fullList nextList = fullList ++ [nextList]
simplifyNodeList identity (h:t) fullList nextList = if (idy h == identity)
then simplifyNodeList identity t (fullList ++ [nextList]) [h]
else simplifyNodeList identity t fullList (nextList ++ [h])
createNodeContentList = [ tupleTreeToNodeContentList tupleTree | tupleTree <- (parseToListOfTupleTrees ex1)]
parseToListOfTupleTrees input = [ toTupleTree x | x <- breakIntoInputTrees input]
toTupleTree x = ('M', [modifier x]):[ createTupleNode y | y <- breakIntoInputNodes x]
modifier x = read (last (splitOn "+" x )) :: Int
createTupleNode nodeStr = (head nodeStr, getNodeNumbers nodeStr)
getNodeNumbers nodeStr = if (nodeStr =~ rangePat :: Bool)
then extractRange (onlyNumbers nodeStr)
else onlyNumbers nodeStr
onlyNumbers str = toInt (words (replaceNonDigit str))
extractRange numList = [head numList .. last numList]
replaceNonDigit [] = []
replaceNonDigit ('R':t) = ' ':replaceNonDigit t
replaceNonDigit ('C':t) = ' ':replaceNonDigit t
replaceNonDigit ('-':t) = ' ':replaceNonDigit t
replaceNonDigit (',':t) = ' ':replaceNonDigit t
replaceNonDigit (h:t) = h:replaceNonDigit t
toInt :: [String] -> [Int]
toInt = map read
tupleTreeToNodeContentList x = [ tupleNodeToNodeContent tupleNode | tupleNode <- x ]
tupleNodeToNodeContent x = NodeContent (fst x) (snd x)
```

`ex1`

and pass it or parts of it to other functions? Just show us this one. – Ingo Mar 9 '14 at 17:51