## Atomize your stateful updates

So, this is definitely a great time to use a `State`

monad. In particular, the atomic transform you're looking for is a way to take `String -> String`

enumerating strings by a unique id for each string. Let's call it `enumerate`

```
import Control.Monad.State
-- | This is the only function which is going to touch our 'Variable's
enumerate :: Variable -> State OurState Variable
```

To do this, we'll need to track state that maps `String`

s to counts (`Int`

s)

```
import qualified Data.Map as M
type OurState = Map String Int
runOurState :: State OurState a -> a
runOurState = flip evalState M.empty
runOurState $ mapM enumerate ["x", "y", "z", "x" ,"x", "x", "y"]
-- ["x1", "y1", "z1", "x2", "x3", "x4", "y2"]
```

so we can implement enumerate pretty directly as a stateful action.

```
enumerate :: Variable -> State OurState Variable
enumerate var = do m <- get
let n = 1 + M.findWithDefault 0 var m
put $ M.insert var n m
return $ var ++ show n
```

Cool!

## Folding generically over an expression tree

Now we really ought to write an elaborate folding apparatus which maps `Expr -> State OurState Expr`

by applying enumerate on each `Var`

-type leaf.

```
enumerateExpr :: Expr -> State OurState Expr
enumerateExpr T = return T
enumerateExpr (Var s) = fmap Var (enumerate s)
enumerateExpr (And e1 e2) = do em1 <- addCounter e1
em2 <- addCounter e2
return (Add em1 em2)
enumerateExpr (Not expr) = fmap Not (addCounter expr)
```

But this is pretty tedious, so we'll use the `Uniplate`

library to keep dry.

```
{-# LANGUAGE DeriveDataTypeable #-}
import Data.Data
import Data.Generics.Uniplate.Data
data Expr = T | Var Variable | And Expr Expr | Not Expr
deriving (Show,Eq,Ord,Data)
onVarStringM :: (Variable -> State OurState Variable) -> Expr -> State OurState Expr
onVarStringM action = transformM go
where go :: Expr -> State OurState Expr
go (Var s) = fmap Var (action s)
go x = return x
```

The `transformM`

operator does just what we want—apply a monadic transformation over all the pieces of a generic tree (our `Expr`

).

So now, we just unpack the `State`

ful action to make `addCounter`

```
addCounter :: Expr -> Expr
addCounter = runOurState . onVarStringM enumerate
```

## Oh, wait!

Just noticed, this doesn't actually have the right behavior—it doesn't enumerate your variables quite right (`prop_addCounter1`

fails but `prop_addCounter2`

passes). Unfortunately, I'm not really sure how it ought to be done... but given this separation of concerns laid out here it'd be very easy to just write the appropriate `enumerate`

`State`

ful action and apply it to the same generic `Expr`

-transforming machinery.

`prop_addCounter1`

, why does`x`

get updated to`x2`

?`x`

only occurs once in the input expression. – John L Feb 27 '13 at 4:08