I’m not sure how I would go about enforcing this at compile time—I think it requires that your graphs be completely static?—but it’s relatively straightforward to enforce at runtime using `Typeable`

. Here’s a sketch of what that would look like. First, I’ll start with typed `Node`

and `Edge`

types:

```
data Node a = Node a
data Edge a b = Edge !Int !Int
```

Wrap them in existentials:

```
{-# LANGUAGE ExistentialQuantification #-}
import Data.Typeable
data SomeNode
= forall a. (Typeable a)
=> SomeNode (Node a)
data SomeEdge
= forall a b. (Typeable a, Typeable b)
=> SomeEdge (Edge a b)
```

Have a heterogeneous graph data type that uses the existentially quantified types:

```
import Data.IntMap (IntMap)
-- Not a great representation, but simple for illustration.
data Graph = Graph !(IntMap SomeNode) [SomeEdge]
```

And then operations that perform dynamic type checks:

```
{-# LANGUAGE ScopedTypeVariables #-}
{-# LANGUAGE TypeApplications #-}
import qualified Data.IntMap as IntMap
addNode
:: forall a. (Typeable a)
=> Int -> a -> Graph -> Maybe Graph
addNode i x (Graph ns es) = case IntMap.lookup i ns of
-- If a node already exists at a given index:
Just (SomeNode (existing :: Node e)) -> case eqT @e @a of
-- Type-preserving replacement is allowed, but…
Just Refl -> Just $ Graph ns' es
-- …*type-changing* replacement is *not* allowed,
-- since it could invalidate existing edges.
Nothing -> Nothing
-- Insertion is of course allowed.
Nothing -> Just $ Graph ns' es
where
ns' = IntMap.insert i (SomeNode (Node x)) ns
-- To add an edge:
addEdge
:: forall a b. (Typeable a, Typeable b)
=> Edge a b -> Graph -> Maybe Graph
addEdge e@(Edge f t) (Graph ns es) = do
-- The ‘from’ node must exist…
SomeNode (fn :: Node tfn) <- IntMap.lookup f ns
-- …and have the correct type; and
Refl <- eqT @a @tfn
-- The ‘to’ node must exist…
SomeNode (tn :: Node ttn) <- IntMap.lookup t ns
-- …and have the correct type.
Refl <- eqT @b @ttn
pure $ Graph ns $ SomeEdge e : es
```

Now this succeeds:

```
pure (Graph mempty mempty)
>>= addNode 0 (1 :: Int)
>>= addNode 1 ('x' :: Char)
>>= addEdge (Edge 0 1 :: Edge Int Char)
```

But changing `Int`

/`Char`

in `Edge Int Char`

to invalid types, or `0`

/`1`

to invalid indices, will fail and return `Nothing`

.

`Typeable`

if the set of types is not easy to enumerate. – Carl Apr 28 '18 at 3:47`Any`

, exposes an interface using tagged types, uses`unsafeCoerce`

internally, and maybe a higher rank type (like`runST`

) to make sure nodes of different graphs are not confused. But it would be helpful to see the your “dream interface” first. – Joachim Breitner May 3 '18 at 15:14