The key thing to take away from the simply typed lambda calculus is that the types are annotated on the lambda binders itself, every lambda term has a type. The typing rules that Pierce provides are are how to mechanically **type-check** that the expression is well-typed. **type inference** is a topic he covers later in the book, which is recovering the types from untyped expressions.

Aside, what Pierce doesn't give in this example is a couple ground types (`Bool`

, `Int`

) , which are helpful when implementing the algorithm, so we'll just append those to our definition as well.

```
t = x
| λ x : T . t
| t t
| <num>
| true
| false
T = T -> T
| TInt
| TBool
```

If we translate this into Haskell we get:

```
type Sym = String
data Expr
= Var Sym
| Lam Sym Type Expr
| App Expr Expr
| Lit Ground
deriving (Show, Eq, Ord)
data Ground = LInt Int
| LBool Bool
deriving (Show, Eq, Ord)
data Type = TInt
| TBool
| TArr Type Type
deriving (Eq, Read, Show)
```

The `Γ`

that pierce threads through the equations is for type environment which we can represent in Haskell as a simple list structure.

```
type Env = [(Sym, Type)]
```

The empty environment `Ø`

is then simply `[]`

. When Pierce writes `Γ, x : T ⊢ ...`

he means the environment extended with the definition of `x`

bound to the type `T`

. In Haskell we would implement it like:

```
extend :: Env -> (Sym, Type) -> Env
extend env xt = xt : env
```

To write the checker from TAPL we implement a little error monad stack.

```
data TypeError = Err String deriving Show
instance Error TypeError where
noMsg = Err ""
type Check a = ErrorT TypeError Identity a
check :: Env -> Expr -> Check Type
check _ (Lit LInt{}) = return TInt
check _ (Lit LBool{}) = return TBool
-- x : T ∈ Γ
-- ----------
-- Γ ⊦ x : T
check env (Var x) = case (lookup x env) of
Just e -> return e
Nothing -> throwError $ Err "Not in Scope"
-- Γ, x : T ⊦ e : T'
-- --------------------
-- Γ ⊦ λ x . e : T → T'
check env (Lam x t e) = do
rhs <- (check (extend env (x,t)) e)
return (TArr t rhs)
-- Γ ⊦ e1 : T → T' Γ ⊦ e2 : T
-- ----------------------------
-- Γ ⊦ e1 e2 : T'
check env (App e1 e2) = do
t1 <- check env e1
t2 <- check env e2
case t1 of
(TArr t1a t1r) | t1a == t2 -> return t1r
(TArr t1a _) -> throwError $ Err "Type mismatch"
ty -> throwError $ Err "Trying to apply non-function"
runCheck :: Check a -> Either TypeError a
runCheck = runIdentity . runErrorT
checkExpr :: Expr -> Either TypeError Type
checkExpr x = runCheck $ check [] x
```

When we call `checkExpr`

on a expression we either get back the valid type of the expression or a `TypeError`

indicating what is wrong with the function.

For instance if we have the term:

```
(λx : Int -> Int . x) (λy : Int. y) 3
App (App (Lam "x" (TArr TInt TInt) (Var "x")) (Lam "y" TInt (Var "y"))) (Lit (LInt 3))
```

We expect our type checker to validate that it it has output type `TInt`

.

But to fail for a term like:

```
(λx : Int -> Int . x) 3
App (Lam "x" (TArr TInt TInt) (Var "x")) (Lit (LInt 3))
```

Since `TInt`

is not equal to `(TInt -> TInt)`

.

That's all there really is to typechecking the STLC.