Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

I am reading through this excellent paper "Functional Programming with Structured Graphs, Bruno C. d. S. Oliveira" (some video here) and I'm trying to implement all the structures as I go. I'm struggling with the use of existentials. Although the author mentions Haskell throghout, it seems the types are more easily expressed in Coq or Agda. How can I make this compile? Thanks.

Code

data PStream a v = Var v
                 | Mu (v -> PStream a v)
                 | Cons a (PStream a v)

data Stream a = forall v. Pack {pop :: PStream a v} 


foldStream :: (a -> b -> b) -> b -> Stream a -> b
foldStream f k (Pack s) = pfoldStream s
    where pfoldStream (Var x)     = x
          pfoldStream (Mu g)      = pfoldStream (g k)
          pfoldStream (Cons x xs) = f x (pfoldStream xs)

Errors

error:
 Couldn't match type `v' with `b'
      `v' is a rigid type variable bound by
          a pattern with constructor
            Pack :: forall a v. PStream a v -> Stream a,
          in an equation for `foldStream'
          at C:\...\StructuredGraph.hs:17:17
      `b' is a rigid type variable bound by
          the type signature for
            foldStream :: (a -> b -> b) -> b -> Stream a -> b
          at C:\...\StructuredGraph.hs:17:1
    Expected type: PStream a b
      Actual type: PStream a v
    In the first argument of `pfoldStream', namely `s'
    In the expression: pfoldStream s
share|improve this question
    
MFlamer, I added some links (to the paper and a video on some of the content). In the process I messed up your spelling of 'excellent' in the first line, sorry about that. Could you correct? I don't want to submit such a minor edit to the edit queue. Thanks. Cool question, BTW, although I'm not up to speed enough to give an answer. –  DWright Jan 11 '13 at 17:10
    
@DWright, Thanks. –  MFlamer Jan 11 '13 at 17:15

3 Answers 3

up vote 6 down vote accepted

You have an existential type, but it looks like the type mentioned in the paper is universal (though I haven't read it beyond the definition of Stream).

There's a big difference between

newtype Stream a = forall v. Pack { pop :: PStream a v }

and

newtype Stream a = Pack { forall v. pop :: PStream a v }

The former doesn't seem very useful for this type, because you have no way of knowing what v is. The latter makes your code compile.

share|improve this answer
    
That's it. I guess its time to learn the difference between "universal type" and "existential type". Thanks. –  MFlamer Jan 11 '13 at 17:20
    
Hah, you beat me to it. (Although the first newtype definition is illegal.) –  Dietrich Epp Jan 11 '13 at 17:20
    
@DietrichEpp: True, GHC doesn't accept it. I'm not sure that it should be illegal, though -- is an existential newtype necessarily a problem, if it doesn't have any class constraints? –  shachaf Jan 11 '13 at 17:34
    
@shachaf it is if your core language is based on universal only system F + boxed ADTs (including boxed existentials). In such a language an existential newtype has nothing to erase to. –  Philip JF Jan 11 '13 at 20:25

So, what do you think the type of this (partial) function is?

pfoldStream (Var x) = x

It's simple:

pfoldStream :: Stream a v -> v

Your foldStream f k operation basically computes pfoldstream . pop. What would the type be?

-- this is wrong
pfoldstream . pop :: PStream a -> v

You can't do that. You can't just return the type from inside an existential. Note how there's a v on the right side. How do we know what the correct v is? We don't, because v is existentially qualified: the only information that the type checker has is that the type v exists, it has no information about whether that type is equal to b.

I can give a simpler illustration:

data E = forall a. E a
unpack (E x) = x

The type of unpack is not expressable in Haskell's type system, and that's basically what you're asking for. The type would be unpack :: E -> x, but not for any x (x is not universally quantified), but for a specific x (x is existentially quantified).

Fixing the problem

The next problem is "How do I make it compile?" That's not the problem -- the problem is that the request is ill-specified. I don't know what you want any more than the compiler does. I can suggest one way to make it compile:

foldStream :: (a -> b -> b) -> b -> PStream a b -> b
foldStream f k s = pfoldStream s
    where pfoldStream (Var x)     = x
          pfoldStream (Mu g)      = pfoldStream (g k)
          pfoldStream (Cons x xs) = f x (pfoldStream xs)

This gets rid of the existential qualifier, but I don't know how else to do it and I'm guessing it's not what you want. An alternative way to make it compile is to replace the code with a function that plays "O Canada" through the user's speakers, but I suspect that is even less similar to what you want than the above code.

Reading the paper

I looked at the paper and I don't think the type is supposed to be existential: I think you're supposed to use higher order types. So instead of the existential type:

data Stream a = forall v. Pack {pop :: PStream a v} 

We are really looking at the rank 2 type:

type Stream a = forall v. Stream a v

You can see in section 4.1 the way that the v variable is used to feed a stream into itself. The reason this is universal is because it allows the consumer of the stream to use any type for v, therefore, v does not need to appear in the signature for foldStream.

share|improve this answer
    
Should "pfoldStream :: Stream a v -> v" above be "pfoldStream :: PStream a v -> v"? Thanks for the detailed response. –  MFlamer Jan 11 '13 at 19:23
    
@MFlamer: I can't keep PStream and Stream straight in my head, because "P" doesn't mean anything to me. If you want to figure out where my errors are, feel free to edit the answer. –  Dietrich Epp Jan 11 '13 at 22:05
    
The error was just 1 letter and S.O. wont let me make a change of less than 5. I understood your point and it was enlightening. –  MFlamer Jan 11 '13 at 22:49

Everyone seems to have answered at once. I was just going to make the point that GADT syntax, as with Str below, always makes this more intelligible to me -- in this case why foldStream is hopeless with the quantifier the other way. I have a quasi-readable version of the code from the paper, so I put it up here: https://github.com/applicative/structured_graphs

{-#LANGUAGE GADTs, RankNTypes#-}
data PStream a v = Var v
                 | Mu (v -> PStream a v)
                 | Cons a (PStream a v)
ones :: PStream Int v
ones = Cons (1 :: Int) ones

data Stream a where P :: forall a  . (forall v . PStream a v) -> Stream a

-- i.e. we use a (hard to construct) v-independent PStream a v -- an item of type forall v . PStream a v to make a Str a. So P ones for ones defined as above, because I didn't use v to define it. By contrast, with your

data Stream a where P :: forall a v .      PStream a v        -> Stream a 

the type of P would let us construct a Str a with any old a and v you like and even the type of v will be invisible in the resulting Str a. So P "Hello" would be valid member of this type. So good luck extracting x below, when the type b is specialized to Int rather than String:

foldStream  :: (a -> b -> b) -> b -> Stream a -> b
foldStream f k = pfoldStream . pop
    where pfoldStream (Var x)     = x
          pfoldStream (Mu g)      = pfoldStream (g k)
          pfoldStream (Cons x xs) = f x (pfoldStream xs)
          pop (P x) = x

With the first (intended) declaration of Stream, the values are hard to construct, but easy to use. With the other ("existential") declaration it is easy to construct a value but hard to use it, since the underlying type is 'hidden'. You were running into this difficulty of using such a value in attempting to define pfoldStream.

share|improve this answer
    
Thanks for posting this code. It was helpful. –  MFlamer Jan 26 '13 at 8:13

Your Answer

 
discard

By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.