This is exactly what the Reader monad is for:

The Reader monad (also called the Environment monad). Represents a
computation, which can read values from a shared environment, pass
values from function to function, and execute sub-computations in a
modified environment.

As Sjoerd notes, the monad gives more power here than you need, but you can still use the Reader monad for this problem without so much as typing `do`

:

```
import qualified Data.Map as M
import Control.Applicative ( (<$>), (<*>) )
import Control.Monad.Reader
data Expr = Const Bool
| Var Char
| Not Expr
| And Expr Expr
| Or Expr Expr
| Xor Expr Expr
```

Just put your environment type as the first argument to the `Reader`

type constructor, and your original result type as the second.

```
eval' :: Expr -> Reader (M.Map Char Bool) Bool
```

Instead of just `c`

as the value of the `Const`

case, use `return`

to lift it into the monad:

```
eval' (Const c) = return c
```

When you need the environment for looking up the value of a variable, use `ask`

. Using `do`

notation, you can write the `Var`

case like this:

```
eval' (Var v) = do values <- ask
return (M.findWithDefault False v values)
```

I think it's nicer, though, to use `fmap`

a.k.a. `<$>`

:

```
eval' (Var v) = M.findWithDefault False v <$> ask
```

Similarly, the unary `not`

can be `fmap`

ped over the result of the recursion:

```
eval' (Not x) = not <$> eval' x
```

Finally, the Applicative instance of Reader makes the binary cases pleasant:

```
eval' (And a b) = (&&) <$> eval' a <*> eval' b
eval' (Or a b) = (||) <$> eval' a <*> eval' b
eval' (Xor a b) = (/=) <$> eval' a <*> eval' b
```

Then, to get it all started, here's a helper to create the initial environment and run the computation:

```
eval :: Expr -> [(Char,Bool)] -> Bool
eval exp env = runReader (eval' exp) (M.fromList env)
```