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Here's the offending code (also on lpaste.net):

module Data.Graph.Dijkstra
       ( dijkstra
       , dijkstraPath
       ) where

-- Graph library import
import Data.Graph.Inductive hiding (dijkstra)

-- Priority queue import
import qualified Data.PQueue.Prio.Min as PQ

-- Standard imports
import Data.List (find)
import Data.Maybe (fromJust)
import Data.Monoid

-- Internal routine implementing Dijkstra's shortest paths
-- algorithm. Deemed internal because it needs to be kickstarted with
-- a singleton node queue. Based on FGL's current implementation of
-- Dijkstra.
dijkstraInternal ::
  (Graph gr, Ord b, Monoid b) => gr a b -> PQ.MinPQueue b [Node] -> [[Node]]
dijkstraInternal g q
  | PQ.null q = []
  | otherwise =
    case match v g of
      (Just cxt,g') -> p:dijkstraInternal  g' (PQ.unions (q' : expand cxt minDist p))
      (Nothing, g') -> dijkstraInternal g' q'
  where ((minDist,p@(v:_)), q') = PQ.deleteFindMin q
        expand (_,_,_,s) dist pathToC =
          map (\(edgeCost,n) -> PQ.singleton (dist `mappend` edgeCost) (n:pathToC)) s

-- Given a graph and a start node, returns a list of lists of nodes
-- corresponding to the shortest paths from the start to all other
-- nodes, where the edge costs are accumulated according to the Monoid
-- instance of the edge label type and costs are compared by the edge
-- label's Ord instance.
dijkstra :: (Graph gr, Ord b, Monoid b) => gr a b -> Node -> [[Node]]
dijkstra g start = dijkstraInternal g (PQ.singleton `mempty` [start])  -- !!!

dijkstraPath :: (Graph gr, Ord b, Monoid b) => gr a b -> Node -> Node -> [LNode a]
dijkstraPath g start goal =
  let paths = dijkstra g start
      pathNodes  = find ((goal ==) . head) paths -- Can paths be empty?
  in
   case pathNodes of
     Nothing -> []
     Just ps -> reverse $ map (\n -> (n, fromJust $ lab g n)) ps

The weirdness is in line 39, marked with the -- !!! comment. This code compiles, but the runtime error is that no matter what, the PQ.singleton function returns an empty priority queue. I realized I had accidentally added backticks to mempty, so when I removed those the code compiled and worked as expected.

This however struck me as strange. How could the code have correctly compiled with backticks around mempty, which is not a binary function at all (mempty :: a)?

After some very generous help on #haskell, I found that it had something to do with the Monoid instance for functions:

instance Monoid b => Monoid (a -> b)

I now have an extremely vague understanding of why this error successfully typechecked, but I still feel somehow morally wronged. Can someone explain exactly how this happened?

Additionally, I'd also like to direct attention to the priority queue's singleton function that I'm using: according to the source, it doesn’t return an empty queue. However, at line 24, that same priority queue immediately gets evaluated as being empty. (I verified this with trace calls.)

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What's the problem you're having with the monoid instance? You said #haskell explained it, so what's still unclear? –  bennofs Dec 10 '13 at 17:07
    
From their explanation I understand that this particular Monoid instance must be the root cause, but I still can't wrap my head around exactly how it works. Also, I believe that a public answer to this question would be really helpful to the Haskell community at large (and myself!) for understanding the Monoid instance of (->). –  giogadi Dec 10 '13 at 17:09
1  
Not that you can apply that instance twice, meaning that a -> b -> c is an instance of Monoid if c is a Monoid, so it's a perfectly valid binary function. –  Gabriel Gonzalez Dec 10 '13 at 17:22
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3 Answers 3

up vote 10 down vote accepted

So, in general, the code:

a `f` b

is just syntactic sugar for:

f a b

Therefore your code became:

mempty PQ.singleton [start]

So the type-checker inferred the type for that particular mempty:

mempty :: (k -> a -> PQ.MinPQueue k a) -> [Node] -> PQ.MinPQueue b [Node]

You correctly found the right instance that is the problem. Anything of type a -> b is a Monoid, provided that b is. So let's bracket that type above:

mempty :: (k -> a -> PQ.MinPQueue k a) -> ([Node] -> PQ.MinPQueue b [Node])

So, that type can be a Monoid if [Node] -> PQ.MinPQueue b [Node] is a Monoid. And by the same logic, [Node] -> PQ.MinPQueue b [Node] can be a Monoid if PQ.MinPQueue b [Node] is one. Which it is. So the type-checker is fine with this code.

Presumably the implementation of our troublesome instance is:

instance Monoid => Monoid (a -> b) where
  mempty = const mempty

So overall, you get an empty priority queue. So really, I think it comes down to a question of whether it was wise for the designers to include this instance at all. Its net effect is that any function returning a monoid can be a monoid, which should allow you to combine the results. The more useful case here is mappend, which can append two a -> b functions by applying them both and using mappend to combine the results. For example:

extremes = (return . minimum) `mappend` (return . maximum)

rather than:

extremes xs = [minimum xs, maximum xs]

Hmmm, maybe someone else can produce a sensible terser example.

share|improve this answer
    
Thanks for the explanation! I actually hadn't realized that PQ.MinPQueue b [Node] was a Monoid. –  giogadi Dec 10 '13 at 17:30
    
So do you think anything could have been done to prevent this kind of strangeness from occurring, or was this just a rare, unavoidable perfect storm of types perfectly re-aligning unexpectedly? You hinted at possibly pointing blame at the Monoid instance of (a -> b); would we really lose anything useful by removing that? Or maybe just hiding that instance behind a newtype? –  giogadi Dec 10 '13 at 17:48
4  
A use of this Monoid (a -> b) instance is sortBy (comparing foo `mappend` comparing bar). –  Reid Barton Dec 10 '13 at 17:49
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So backticks turn a binary function into an infix operator, making

x `op` y

equivalent to

op x y

So op needs to be of type a -> b -> c where x :: a and y :: b.

In your case, op was mempty, with the type Monoid m => m. But we know it to be of the form a -> b -> c, so substitute that and you get (this is no longer valid syntax) Monoid (a -> b -> c) => a -> b -> c, because we can substitute that m for anything as long as the constraint holds.

Now we know (due to the instance declaration) that any function of the form s -> t, where t is a Monoid, is a Monoid itself, and we also know that a -> b -> c is really a -> (b -> c), i.e. a function taking one argument and returning another function. So if we substitute a for s and (b -> c) for t, the we fulfill the Monoid instance, if t is a Monoid. Of course, t is (b -> c), so we can apply the same Monoid instance again (with s = b and t = c), so if c is a Monoid, we're good.

So what is c? The expression you had was

PQ.singleton `mempty` [start]

i.e.

mempty PQ.singleton [start]

The instance declaration for Monoid (a -> b) defines mempty _ = mempty, i.e. it's a function that ignores its argument and returns the empty element of the b Monoid. In other words, we can expand the call above to

mempty [start]

i.e. we ignore the argument and use mempty of the inner Monoid (which is b -> c). Then we repeat, ignoring the argument again:

mempty

So the expression you had is just equivalent to a single mempty, which has the type Monoid c => c, i.e. it can be any Monoid whatsoever.

In your case, the larger expression deduces c to be a PQ.MinPQueue. And MinPQueue is a Monoid instance with mempty being the empty queue.

This is how you end up with the result you're seeing.

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You've had a couple good answers here already, I thought I would just post this since it's a bit simpler and helped me as I was puzzling this out in ghci.

mempty :: (a -> b) = mempty _ = mempty So it's essentially const mempty.

λ> :t mempty :: (a -> b)
<interactive>:1:1:
    No instance for (Monoid b) arising from a use of `mempty'

So b has to be a Monoid since we're asking for the mempty of that type, makes sense.

λ> :t mempty :: (a -> [b])
mempty :: (a -> [b]) :: a -> [b]
λ> :t mempty :: (a -> c -> [b])
mempty :: (a -> c -> [b]) :: a -> c -> [b]

We can recursively chain these. Since (->) is right associative (a -> b) may represent (a -> c -> d) when b == (c -> d). So we can supply an arbitrary number of arguments and the mempty for functions will be recursively applied until it's consumed all arguments.

λ> import Data.Map
λ> (mempty :: (a -> c -> Map Int Int)) 4 5
fromList []
λ> (mempty :: (a -> c -> d -> Map Int Int)) 4 5 6
fromList []

So we see that applying the function mempty will throw away any arguments it's given and return the mempty for whatever type is expected at the position the expression is in.

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