# How to define a state monad?

I want to define a State monad that manages errors (in a sense like Maybe): if an error/problem occurs during the "do" computation, it is signal led and propagated by `>>=`. The error should also contain a string describing it. After, i want to apply this monad to `mapTreeM`, using for map a function that assumes states as numbers and a tree containing numbers, and at each visiting step updates the current state by adding to it the value of the current leaf; the resulting tree must contain a pair with the old leaf value and the state at the visiting instant. Such visit must fail if the state becomes negative during the computation, and succeed if it is positive.

e.g. Given this tree: `Branch (Branch (Leaf 7) (Branch (Leaf (-1)) (Leaf 3))) (Branch (Leaf (-2)) (Leaf 9))`

We obtain a tree (considering the initial state 0): `Branch (Branch (Leaf (7,7)) (Branch (Leaf (-1,6)) (Leaf (3,9)))) (Branch (Leaf (-2,7)) (Leaf (9,16)))`

If we put `-18` in the second leaf, we should obtain an erroneous value signaling that we reached a negative state `(-11)`.

I did a thing like this to print the tree without managing errors...i haven't understood how to do it. The following is my code:

``````module Main where

newtype State st a = State (st -> (st, a))

return x = State(\s -> (s,x))

State f >>= g = State(\oldstate ->
let (newstate, val) = f oldstate
State newf      = g val
in newf newstate)

-- Recursive data structure for representing trees
data Tree a = Leaf a | Branch (Tree a) (Tree a)
deriving (Show,Eq)

-- Utility methods
getState :: State state state
getState = State(\state -> (state,state))

putState :: state -> State state ()
putState new = State(\_ -> (new, ()))

mapTreeM :: (Num a) => (a -> State state b) -> Tree a -> State state (Tree b)
mapTreeM f (Leaf a) =
f a >>= (\b -> return (Leaf b))
mapTreeM f (Branch lhs rhs) = do
lhs' <- mapTreeM f lhs
rhs' <- mapTreeM f rhs
return (Branch lhs' rhs')

numberTree :: (Num a) => Tree a -> State a (Tree (a,a))
numberTree tree = mapTreeM number tree
where number v = do
cur <- getState
putState(cur+v)
return (v,cur+v)

-- An instance of a tree
testTree = (Branch
(Branch
(Leaf 7) (Branch (Leaf (-1)) (Leaf 3)))
(Branch
(Leaf (-2)) (Leaf (-20))))

runStateM :: State state a -> state -> a
runStateM (State f) st = snd (f st)

main :: IO()
main = print \$ runStateM (numberTree testTree) 0
``````
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Do you want monad transformers? – Aadit M Shah Jun 6 '14 at 14:10
You could just use mtl/transformers.... – alternative Jun 6 '14 at 14:16

Can I propose an alternative solution to your problem? While Monads are good for many things, what you want to do can be done with a simple function that keeps track of errors. My function `transferVal` below is an example of such function. The function `transferVal` traverses the `Tree` from left to right while keeping the last value found. If an error occurs, the function returns the error and stops traversing the `Tree`. Instead of using `Maybe`, it is often better to use `Either <error_type> <result_type>` to get a more clear error if something goes wrong. In my example, I use `([ChildDir],a)` where `[ChildDir]` contains the "direction" of the incriminated node and `a` is the erroneous value that triggered the error. The function `printErrorsOrTree` is an example of how you can use the output of `transferVal` and `main` contains 4 examples of which the first three are correct and the last one triggers the error that you was expecting.

``````module Main where

import Data.List     (intercalate)

data Tree a = Leaf a | Branch (Tree a) (Tree a)
deriving (Show,Eq)

-- given a Branch, in which child the error is?
data ChildDir = LeftChild | RightChild
deriving Show

-- an error is the direction to get to the error from the root and the
-- value that triggered the error
type Error a = ([ChildDir],a)

-- util to append a direction to an error
appendDir :: ChildDir -> Error a -> Error a
appendDir d (ds,x) = (d:ds,x)

transferVal :: (Ord a,Num a) => Tree a -> Either (Error a) (Tree (a,a))
transferVal = fmap fst . go 0
where go :: (Ord a,Num a) => a -> Tree a -> Either (Error a) (Tree (a,a),a)
go c (Leaf x) = let newC = x + c
in if newC < 0
then Left ([],newC)
else Right (Leaf (x,newC),newC)
go c (Branch t1 t2) = case go c t1 of
Left e             -> Left \$ appendDir LeftChild e
Right (newT1,newC) -> case go newC t2 of
Left              e -> Left \$ appendDir RightChild e
Right (newT2,newC') -> Right (Branch newT1 newT2,newC')

printErrorsOrTree :: (Show a,Show b) => Either (Error a) (Tree b) -> IO ()
printErrorsOrTree (Left (ds,x)) = putStrLn \$ "Error in position " ++ (intercalate " -> " \$ map show ds) ++ ". Error value is " ++ show x
printErrorsOrTree (Right     t) = putStrLn \$ "Result: " ++ show t

main :: IO ()
main = mapM_ runExample
[(Leaf 1)
,(Branch (Leaf 1) (Leaf 2))
,(Branch (Branch (Leaf 7) (Branch (Leaf (-1)) (Leaf 3))) (Branch (Leaf (-2)) (Leaf 9)))
,(Branch (Branch (Leaf 7) (Branch (Leaf (-11)) (Leaf 3))) (Branch (Leaf (-2)) (Leaf 9)))]
where runExample orig = do
let res = transferVal orig
print orig
printErrorsOrTree res
``````
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By making your `Tree` datatype an instance of `Traversable`, you can use `mapM` (from `Data.Traversable`) to map an action over a `Tree`. You can also layer the `StateT` monad transformer atop the `Either` monad to provide error handling.

``````import Control.Monad.State
import Control.Applicative
import Data.Monoid
import Data.Foldable
import Data.Traversable
import qualified Data.Traversable as T

-- our monad which carries state but allows for errors with string message
type M s = StateT s (Either String)

data Tree a = Leaf a | Branch (Tree a) (Tree a)
deriving (Show,Eq)

-- Traversable requires Functor
instance Functor Tree where
fmap f (Leaf a) = Leaf (f a)
fmap f (Branch lhs rhs) = Branch (fmap f lhs) (fmap f rhs)

-- Traversable requires Foldable
instance Foldable Tree where
foldMap f (Leaf a) = f a
foldMap f (Branch lhs rhs) = foldMap f lhs `mappend` foldMap f rhs

-- Finally, we can get to Traversable
instance Traversable Tree where
traverse f (Leaf a) = Leaf <\$> f a
traverse f (Branch lhs rhs) = Branch <\$> traverse f lhs <*> traverse f rhs

testTree = (Branch
(Branch
(Leaf 7) (Branch (Leaf (-1)) (Leaf 3)))
(Branch
(Leaf (-2)) (Leaf (-20))))

numberTree :: (Num a, Ord a) => Tree a -> M a (Tree (a,a))
numberTree = T.mapM number where
number v = do
cur <- get
let nxt = cur+v
-- lift the error into the StateT layer
when (nxt < 0) \$ throwError "state went negative"
put nxt
return (v, nxt)

main :: IO ()
main =
case evalStateT (numberTree testTree) 0 of
Left e -> putStrLn \$ "Error: " ++ e
Right t -> putStrLn \$ "Success: " ++ show t
``````
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