Here's a type for cyclic, directed graphs with labelled nodes and edges.

import qualified Data.Map as M
import Data.Foldable
import Data.Monoid

data Node n e = N n [(e, Node n e)]  -- the node's label and its list of neighbors
newtype Graph n e = G (M.Map n (Node n e))

To handle the case where the graph has a loop, it's possible to 'tie the knot' and create infinitely recursive graphs in finite space.

type GraphInput n e = M.Map n [(e, n)]

mkGraph :: Ord n => GraphInput n e -> Graph n e
mkGraph spec = G $ nodeMap
    where nodeMap = M.mapWithKey mkNode (makeConsistent spec)
          -- mkNode :: n -> [(e, n)] -> Node n e
          mkNode lbl edges = N lbl $ map getEdge edges
          -- We know that (!) can't fail because we ensured that
          -- all edges have a key in the map (see makeConsistent)
          getEdge (e, lbl) = (e, nodeMap ! lbl)

makeConsistent :: Ord n => GraphInput n e -> GraphInput n e
makeConsistent m = foldr addMissing m nodesLinkedTo
    where addMissing el m = M.insertWith (\_ old -> old) el [] m
          nodesLinkedTo = map snd $ join $ M.elems m

By viewing the graph as a collection of nodes, we can write a Foldable instance which performs a depth-first traversal.*

newtype NodeGraph e n = NG {getNodeGraph :: Graph n e}

instance Foldable (NodeGraph e) where
    foldMap f (NG (G m)) = foldMap mapNode (M.elems m)
        where mapNode (N n es) = f n `mappend` foldMap mapEdge es
              mapEdge (e, n) = mapNode n

However, even for simple tree-shaped graphs, this produces duplicate elements:

--   A
--  / \    X
-- B   C
--     |
--     D
ghci> let ng = NG $ mkGraph [('A', [(1, 'B'), (1, 'C')]), ('C', [(1, 'D')]), ('X', [])]
ghci> let toList = Data.Foldable.foldr (:) []
ghci> toList ng

When the graph has a cycle, the effect is even more dramatic - foldMap recurses forever! The items in the loop are repeated, and some elements are never returned!

Is this okay? Can a instance of Foldable return some of its elements more than once, or am I violating the contract of the class? Can an instance loop on a part of the structure infinitely? I've been looking for guidance on this issue - I was hoping for a set of 'Foldable laws' that would settle the question - but I haven't been able to find any discussion of the question online.

One approach to get out of this would be to 'remember' the elements which have already been visited as I traverse the graph. However, this would add an Eq or Ord constraint to the signature of foldMap, which precludes my type being a member of Foldable.

* Incidentally, we can't write a Functor instance for NodeGraph, because it would break the invariant that nodes in a graph are uniquely labelled. (fmap (const "foo"), for example, will relabel every node to "foo", though they'll all have different sets of edges!) We can (with the appropriate newtype) write a Functor which maps all the edge labels, though.

  • Do you intentionally want the instance to perform DFS? – is7s Jan 24 '15 at 17:13
  • @is7s It'd be pretty straightforward to write a newtype which utilises some other form of search strategy. – Benjamin Hodgson Jan 24 '15 at 17:33

There are currently very few Foldable laws, so you can do all sorts of things. In fact, there are several different Foldable instances you could write, corresponding to different traversal orders. The Foldable laws describe relationships among the different Foldable members and, if the type is also a Functor, an additional law relating fold, foldMap, and fmap.

Some specifics: There are straightforward "laws" about the relationships between foldMap, foldl, foldr, sum, etc., which just say that they should act pretty much like their default implementations except for strictness. For fold, this law is fold = foldMap id. If the container is also a Functor, there's a law specifying that you can go the other way: foldMap f = fold . fmap f. Nothing too exciting at all, as I said.

On the other hand, I think trying to combine knot-tying with unique labeling smells a bit funny. I'm not sure what you're up to with that, or whether it really makes sense. The trouble, as I see it, is that although sharing leads to the graph being represented in memory as you want, this sharing is not reflected in the language at all. Within Haskell, a graph with cycles looks exactly like an infinite tree. There is, in fact, very little you can do with a cyclic graph that won't (potentially) turn it into an infinite tree. This is why people bother using things like Data.Map to represent graphs in the first place—knot tying doesn't offer a clear view of the graph structure.

  • Could you elaborate on the specifics of the two laws you mention? And why do you think knot-tying with unique labelling doesn't make sense? – Benjamin Hodgson Jan 24 '15 at 10:09
  • @BenjaminHodgson, I added some more remarks. – dfeuer Jan 24 '15 at 13:48
  • I see. Thanks for the advice – Benjamin Hodgson Jan 24 '15 at 15:10

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