# Environment

For handling environments, You can use

- either lookup from Prelude
- or its namesake lookup from Data.Map library (and the other functions of the library)

If You choose to use Data.Map module, it is worth writing

```
Data.Map.lookup
```

instead of just `lookup`

,

or -- another solution -- hiding Prelude's `lookup`

with

```
import Prelude hiding (lookup)
```

so that not to receive an error message about the clash of the two `lookup`

functions.

For simplicity's sake, first I write the solution with the simpler `lookup`

function, that of Prelude.

For simpicity's sake again, I do not incorporate error hadling yet.

Environment:

```
module Env (Env) where
type Env = [Binding]
type Binding = (Char, Integer)
```

Expression:

```
module Expr where
data Expr = Var Char
| Tall Int
| Sum Expr Expr
| Mult Expr Expr
| Neg Expr
| Let Char Expr Expr
```

Evaluation:

```
module Semantics (evaluate) where
import Expr (Expr)
import Env (Env)
evaluate :: Expr -> Integer
evaluate = evaluate' []
evaluate' :: Env -> Expr -> Integer
evaluate' _ (Tall n) = n
evaluate' env (Var x) = case lookup x env of
Just n -> n
Nothing -> error ("Variable" ++ [x] ++ "is free!")
evaluate' env (Sum a b) = evaluate' env a + evaluate' env b
evaluate' env (Mult a b) = evaluate' env a * evaluate' env b
evaluate' env (Neg a) = - evaluate' env a
evaluate' env (Let x a b) = evaluate' ((x, a) : env) b
```

# Clash of variables

As for planning Your object language: in later releases, it is worth planning a strategy, how to deal with clashing variable names:

```
let A be 5 in (A +3)
```

is clear, but what should be meant for

```
let A be 5 in (let A be 3 in A)
```

?

In earlier releases of Your evaluator, You do not have to plan this, because `lookup`

function will decide the situation "automatically" according to the default behavior immanent in its definition. But if You do not like its default behavior, You probably will augment Your evaluator with a conscious strategy for dealing with variable name clashes.

# Error handling

If You evaluate an expression in an environment, and the expression references a variable that is not contained in the environment, then the interpreter must report an error somehow.

You can do it several ways, the simplest ones:

## Bottom

With the `error`

function, You can force the program to halt with a user-defined error message. This solution has disadvantages, but it is easy to write.

## Maybe

You can alter Your `evaluate'`

function. It will not have signature

```
evaluate' :: Env -> Expr -> Integer
```

but, rather

```
evaluate' :: Env -> Expr -> Maybe Integer
```

In this case, You have to alter the definition of evaluate' severely. You cannot write any more:

```
evaluate' env (Sum a b) = evaluate' env a + evaluate' env b
```

but a much more complicated definition is needed

```
evaluate' env (Sum a b) = case (evaluate' env a, evaluate' env b) of
(Just a0, Just b0) -> Just (a0 + b0)
_ -> Nothing
```

We pack the Maybe-ed integers out, sum them, then pack them back into a Maybe-ed integer. It is like doing summation "inside the pack". We could save much work if we could tell Haskell that it can do summation "inside" the Maybe.

We can do that, if we exploit that Maybe is a monad: we can use the functions that have been designed for working with monads. Such auxiliary functions are provided in Control.Monad library. Here, liftM2 is the function that will help us to wrap summation around the Maybe-packed values:

```
evaluate' env (Sum a b) = liftM2 (+) (evaluate' env a) (evaluate' env b)
```

Some other auxiliary functions for Maybe-ed values can be found in Data.Maybe library, but here, we need not them.

```
module Semantics (evaluate) where
import Expr (Expr)
import Env (Env)
import Control.Monad (liftM, liftM2)
evaluate :: Expr -> Maybe Integer
evaluate = evaluate' []
evaluate' :: Env -> Expr -> Maybe Integer
evaluate' _ (Tall n) = Just n
evaluate' env (Var x) = lookup x env
evaluate' env (Sum a b) = liftM2 (+) (evaluate' env a) (evaluate' env b)
evaluate' env (Mult a b) = liftM2 (*) (evaluate' env a) (evaluate' env b)
evaluate' env (Neg a) = liftM negate (evaluate' env a)
evaluate' env (Let x a b) = evaluate' ((x, a) : env) b
```