A discussion came up at work recently about Sets, which in Scala support the `zip`

method and how this can lead to bugs, e.g.

```
scala> val words = Set("one", "two", "three")
scala> words zip (words map (_.length))
res1: Set[(java.lang.String, Int)] = Set((one,3), (two,5))
```

I think it's pretty clear that `Set`

s shouldn't support a `zip`

operation, since the elements are not ordered. However, it was suggested that the problem is that `Set`

isn't really a functor, and shouldn't have a `map`

method. Certainly, you can get yourself into trouble by mapping over a set. Switching to Haskell now,

```
data AlwaysEqual a = Wrap { unWrap :: a }
instance Eq (AlwaysEqual a) where
_ == _ = True
instance Ord (AlwaysEqual a) where
compare _ _ = EQ
```

and now in ghci

```
ghci> import Data.Set as Set
ghci> let nums = Set.fromList [1, 2, 3]
ghci> Set.map unWrap $ Set.map Wrap $ nums
fromList [3]
ghci> Set.map (unWrap . Wrap) nums
fromList [1, 2, 3]
```

So `Set`

fails to satisfy the functor law

```
fmap f . fmap g = fmap (f . g)
```

It can be argued that this is not a failing of the `map`

operation on `Set`

s, but a failing of the `Eq`

instance that we defined, because it doesn't respect the substitution law, namely that for two instances of `Eq`

on A and B and a mapping `f : A -> B`

then

```
if x == y (on A) then f x == f y (on B)
```

which doesn't hold for `AlwaysEqual`

(e.g. consider `f = unWrap`

).

Is the substition law a sensible law for the `Eq`

type that we should try to respect? Certainly, other equality laws are respected by our `AlwaysEqual`

type (symmetry, transitivity and reflexivity are trivially satisfied) so substitution is the only place that we can get into trouble.

To me, substition seems like a very desirable property for the `Eq`

class. On the other hand, some comments on a recent Reddit discussion include

"Substitution seems stronger than necessary, and is basically quotienting the type, putting requirements on every function using the type."

--

godofpumpkins"I also really don't want substitution/congruence since there are many legitimate uses for values which we want to equate but are somehow distinguishable."

--

sclv"Substitution only holds for structural equality, but nothing insists

`Eq`

is structural."--

edwardkmett

These three are all pretty well known in the Haskell community, so I'd be hesitant to go against them and insist on substitability for my `Eq`

types!

Another argument against `Set`

being a `Functor`

- it is widely accepted that being a `Functor`

allows you to transform the "elements" of a "collection" while preserving the shape. For example, this quote on the Haskell wiki (note that `Traversable`

is a generalization of `Functor`

)

"Where

`Foldable`

gives you the ability to go through the structure processing the elements but throwing away the shape,`Traversable`

allows you to do that whilst preserving the shape and, e.g., putting new values in.""

`Traversable`

is about preserving the structure exactly as-is."

and in Real World Haskell

"...[A] functor must preserve shape. The structure of a collection should not be affected by a functor; only the values that it contains should change."

Clearly, any functor instance for `Set`

has the possibility to change the shape, by reducing the number of elements in the set.

But it seems as though `Set`

s really should be functors (ignoring the `Ord`

requirement for the moment - I see that as an artificial restriction imposed by our desire to work efficiently with sets, not an absolute requirement for any set. For example, sets of functions are a perfectly sensible thing to consider. In any case, Oleg has shown how to write efficient Functor and Monad instances for `Set`

that don't require an `Ord`

constraint). There are just too many nice uses for them (the same is true for the non-existant `Monad`

instance).

Can anyone clear up this mess? Should `Set`

be a `Functor`

? If so, what does one do about the potential for breaking the Functor laws? What should the laws for `Eq`

be, and how do they interact with the laws for `Functor`

and the `Set`

instance in particular?

`map`

operation". That's all that`Functor`

is (well, that plus some laws).`addOne`

function and apply it to each`Int`

". I doubt that biggest part of Scala Devs thinks about`flatMap/bind`

in terms of Monads and some abstraction over computation flow with context, it's just call function and from`List[List[A]]`

make`List[A]`

.`map`

for`Set`

is not the`Functor`

map!`Set`

is a functor on the subcategory whose objects are types with a sane`Eq`

/`Ord`

instance (here "sane" includes substitutability).7more comments