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Reading up on quotient types and their use in functional programming, I came across this post. The author mentions Data.Set as an example of a module which provides a ton of functions which need access to module's internals:

Data.Set has 36 functions, when all that are really needed to ensure the meaning of a set ("These elements are distinct") are toList and fromList.

The author's point seems to be that we need to "open up the module and break the abstraction" if we forgot some function which can be implemented efficiently only using module's internals.

He then says

We could alleviate all of this mess with quotient types.

but gives no explanation to that claim.

So my question is: how are quotient types helping here?


I've done a bit more research and found a paper "Constructing Polymorphic Programs with Quotient Types". It elaborates on declaring quotient containers and mentions the word "efficient" in abstract and introduction. But if I haven't misread, it does not give any example of an efficient representation "hiding behind" a quotient container.


A bit more is revealed in "[PDF] Programming in Homotopy Type Theory" paper in Chapter 3. The fact that quotient type can be implemented as a dependent sum is used. Views on abstract types are introduced (which look very similar to type classes to me) and some relevant Agda code is provided. Yet the chapter focuses on reasoning about abstract types, so I'm not sure how this relates to my question.

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I'll give a simpler example where it's reasonably clear. Admittedly I myself don't really see how this would translate to something like Set, efficiently.

data Nat = Nat (Integer / abs)

To use this safely, we must be sure that any function Nat -> T (with some non-quotient T, for simplicity's sake) does not depend on the actual integer value, but only on its absolute. To do so, it's not really necessary to hide Integer completely; it would be sufficient to prevent you from matching on it directly. Instead, the compiler might rewrite the matches, e.g.

even' :: Nat -> Bool
even' (Nat 0) = True
even' (Nat 1) = False
even' (Nat n) = even' . Nat $ n - 2

could be rewritten to

even' (Nat n') = case abs n' of
           [|abs 0|]  -> True
           [|abs 1|]  -> False
           n          -> even' . Nat $ n - 2

Such a rewriting would point out equivalence violations, e.g.

bad (Nat 1) = "foo"
bad (Nat (-1)) = "bar"
bad _ = undefined

would rewrite to

bad (Nat n') = case n' of
      1 -> "foo"
      1 -> "bar"
      _ -> undefined

which is obviously an overlapped pattern.

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Both your and @alecb answers use a single function (abs in your case) and Eq instance to specify a relation. Seems like you both are specifying setoids rather than actual quotient types (though I can't see the exact difference) which require from/to functions (see paper from edit 2 in my question). – fizruk May 15 '14 at 13:58

Disclaimer: I just read up on quotient types upon reading this question.

I think the author's just saying that sets can be described as quotient types over lists. Ie: (making up some haskell-like syntax):

data Set a = Set [a] / (sort . nub) deriving (Eq)

Ie, a Set a is just a [a] with equality between two Set a's determined by whether the sort . nub of the underlying lists are equal.

We could do this explicitly like this, I guess:

import Data.List

data Set a = Set [a] deriving (Show)

instance (Ord a, Eq a) => Eq (Set a) where
  (Set xs) == (Set ys) = (sort $ nub xs) == (sort $ nub ys)

Not sure if this is actually what the author intended as this isn't a particularly efficient way of implementing a set. Someone can feel free to correct me.

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For efficient version I guess you can do something like data Set a = Set (InternalSet a / toList). But you have to hide InternalSet then to avoid breaking abstraction. So I still can't see how quotient types help. – fizruk May 12 '14 at 10:04

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