I'd like to extend @Daniel Wagner's excellent answer with a slightly different approach: instead of typechecking returning a valid type (if there is one), return a typed expression that is then guaranteed we can evaluate it (since the simply-typed lambda calculus is strongly normalizing). The basic idea is that `check ctx t e`

returns `Just (ctx |- e :: t)`

iff `e`

can be typed at `t`

in some context `ctx`

, and then given some typed expression `ctx |- e :: t`

, we can evaluate it in some `Env`

ironment of the right type.

# The implementation

I will be using singletons to emulate the Pi type of `check :: (ctx :: [Type]) -> (a :: Type) -> Term -> Maybe (TTerm ctx a)`

, which means we will need to turn on every GHC extension and the kitchen sink:

```
{-# LANGUAGE GADTs #-}
{-# LANGUAGE DataKinds, KindSignatures, TypeFamilies, TypeOperators #-}
{-# LANGUAGE TemplateHaskell #-} -- sigh...
import Data.Singletons.Prelude
import Data.Singletons.TH
import Data.Type.Equality
```

The first bit is the untyped representation, straight from @Daniel Wagner's answer:

```
data Type = Base
| Arrow Type Type
deriving (Show, Eq)
data Term = Const
| Var Int
| Lam Type Term
| App Term Term
deriving Show
```

but we will also give semantics for these types by interpreting `Base`

as `()`

and `Arrow t1 t2`

as `t1 -> t2`

:

```
type family Interp (t :: Type) where
Interp Base = ()
Interp (Arrow t1 t2) = Interp t1 -> Interp t2
```

To keep with the de Bruijn theme, contexts are the list of types, and variables are indices of the context. Given an environment of a context type, we can look up a variable index to get a value. Note that `lookupVar`

is a total function.

```
data VarIdx (ts :: [Type]) (a :: Type) where
Here :: VarIdx (a ': ts) a
There :: VarIdx ts a -> VarIdx (b ': ts) a
data Env (ts :: [Type]) where
Nil :: Env '[]
Cons :: Interp a -> Env ts -> Env (a ': ts)
lookupVar :: VarIdx ts a -> Env ts -> Interp a
lookupVar Here (Cons x _) = x
lookupVar (There v) (Cons _ xs) = lookupVar v xs
```

OK we have all the infrastructure in place to actually write some code. First of all, let's define a typed representation of `Term`

, together with a (total!) evaluator:

```
data TTerm (ctx :: [Type]) (a :: Type) where
TConst :: TTerm ctx Base
TVar :: VarIdx ctx a -> TTerm ctx a
TLam :: TTerm (a ': ctx) b -> TTerm ctx (Arrow a b)
TApp :: TTerm ctx (Arrow a b) -> TTerm ctx a -> TTerm ctx b
eval :: Env ctx -> TTerm ctx a -> Interp a
eval env TConst = ()
eval env (TVar v) = lookupVar v env
eval env (TLam lam) = \x -> eval (Cons x env) lam
eval env (TApp f e) = eval env f $ eval env e
```

So far so good. `eval`

is nice & total because its input can only represent well-typed terms of the simply-typed lambda calculus. So part of the work from @Daniel's evaluator will have to be done in the transformation of the untyped representation to the typed one.

The basic idea behind `infer`

is that if type inference succeeds, it returns `Just $ TheTerm t e`

, where `t`

is a `Sing`

leton witness of `e`

's type.

```
$(genSingletons [''Type])
$(singDecideInstance ''Type)
-- I wish I had sigma types...
data SomeTerm (ctx :: [Type]) where
TheTerm :: Sing a -> TTerm ctx a -> SomeTerm ctx
data SomeVar (ctx :: [Type]) where
TheVar :: Sing a -> VarIdx ctx a -> SomeVar ctx
-- ... and pi ones as well
infer :: Sing ctx -> Term -> Maybe (SomeTerm ctx)
infer _ Const = return $ TheTerm SBase TConst
infer ts (Var n) = do
TheVar t v <- inferVar ts n
return $ TheTerm t $ TVar v
infer ts (App f e) = do
TheTerm t0 e' <- infer ts e
TheTerm (SArrow t0' t) f' <- infer ts f
Refl <- testEquality t0' t0
return $ TheTerm t $ TApp f' e'
infer ts (Lam ty e) = case toSing ty of
SomeSing t0 -> do
TheTerm t e' <- infer (SCons t0 ts) e
return $ TheTerm (SArrow t0 t) $ TLam e'
inferVar :: Sing ctx -> Int -> Maybe (SomeVar ctx)
inferVar (SCons t _) 0 = return $ TheVar t Here
inferVar (SCons _ ts) n = do
TheVar t v <- inferVar ts (n-1)
return $ TheVar t $ There v
inferVar _ _ = Nothing
```

Hopefully the last step is obvious: since we can only evaluate a well-typed term at a given type (since that's what gives us the type of its Haskell embedding), we turn type `infer`

ence into type `check`

ing:

```
check :: Sing ctx -> Sing a -> Term -> Maybe (TTerm ctx a)
check ctx t e = do
TheTerm t' e' <- infer ctx e
Refl <- testEquality t t'
return e'
```

# Example session

Let's try our functions out in GHCi:

```
λ» :set -XStandaloneDeriving -XGADTs
λ» deriving instance Show (VarIdx ctx a)
λ» deriving instance Show (TTerm ctx a)
λ» let id = Lam Base (Var 0) -- \x -> x
λ» check SNil (SBase `SArrow` SBase) id
Just (TLam (TVar Here))
λ» let const = Lam Base $ Lam Base $ Var 1 -- \x y -> x
λ» check SNil (SBase `SArrow` SBase) const
Nothing -- Oops, wrong type
λ» check SNil (SBase `SArrow` (SBase `SArrow` SBase)) const
Just (TLam (TLam (TVar Here)))
λ» :t eval Nil <$> check SNil (SBase `SArrow` (SBase `SArrow` SBase)) const
eval Nil <$> check SNil (SBase `SArrow` (SBase `SArrow` SBase)) const
:: Maybe (() -> () -> ())
-- Note that the `Maybe` there comes from `check`, not `eval`!
λ» let Just const' = check SNil (SBase `SArrow` (SBase `SArrow` SBase)) const
λ» :t eval Nil const'
eval Nil const' :: () -> () -> ()
λ» eval Nil const' () ()
()
```

`()`

, tuples`(,)`

, and the lambda constructor for functions, it tries to deduce an object with a given type. There's a related question about deducing Haskell code from types. – Cirdec Jan 8 '15 at 1:39`s`

seems to indicate you want dynamic checking, but you should clarify that. – chi Jan 8 '15 at 8:53