The Enum typeclass implies that the implementing types can be ordered in some meaningful way. In Haskell, the Real type implements Enum. Coming from a mathematics background, this is very strange. A hundred years ago, Georg Cantor proved that reals cannot not be indexed, that is, there is no way to say what is the n-th real for all reals.

Now, concrete types such as Double do in fact have a finite domain. So you could argue that they can implement Enum. One would assume the the successor of a Double would be the next valid Double. Instead, it is simply the addition of 1. Hence, we see weirdness like:

Prelude> succ (1e20 :: Double) == (1e20 :: Double)

In my opinion, this behavior breaks the usefulness of Enum. Can anyone explain the reasoning behind this?

Edit: Corrected Ord to Enum and clarified that reals are not aleph zero.

Post-Script: This comment illumined the answer to me:

Enum Double is nowadays considered a mistake by several Haskellers. It was added to allow e.g. [1.0 .. 20.0] to count with a step of one unit. That required succ to be (+1) instead of the true "next" double. Also, it opens a can of worms since length [1.0 .. 99.5] might be 99 or 100 depending on rounding errors. Worse, this can't be fixed, it's inherently fragile.

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    I'm slightly confused. Your question claims to be about Ord but seems to actually be about Enum. succ is a method from the Enum typeclass, and it's obvious that reals can be totally ordered - I'm not sure which Cantor result you're referring to but I guess it's the fact that the reals are uncountable (with the original version of the famous "diagonal argument"), which does relate to enumeration. You question in short seems to be about why Double implements Enum - which is an excellent question, I hadn't realised it does until I read your question and looked it up! Jul 25 at 21:49
  • @RobinZigmond Trivially, Double can implement Enum because it is represented as a finite number of bits, and hence apart from the special values for any x :: Double there exists a y :: Double where y>x but there does not exist a z where y > z > x. However in practice the Enum instance in this and similar cases has succ = (+1), which makes no sense. Maybe its because the "right" answer would depend on the hardware arithmetic. Jul 25 at 21:58
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    Enum Double is nowadays considered a mistake by several Haskellers. It was added to allow e.g. [1.0 .. 20.0] to count with a step of one unit. That required succ to be (+1) instead of the true "next" double. Also, it opens a can of worms since length [1.0 .. 99.5] might be 99 or 100 depending on rounding errors. Worse, this can't be fixed, it's inherently fragile.
    – chi
    Jul 25 at 22:09
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    A historical note: some of the standard typeclasses like Enum and Num are really just for overloading. They were introduced before Haskell even had an established custom of using typeclasses to model algebraic structures. A lot of us would like to update the standard library design (e.g. replacing Num with something like Ring), but it will be a process, since it affects a lot of code, and requires striking a delicate balance between generality and ergonomics.
    – Jon Purdy
    Jul 26 at 7:00

As Robin Zigmond commented, you're confusing the Ord and Enum classes. Ord is what's a superclass of Real, but Enum is what succ belongs to.

Ord does not allow you to enumerate, or otherwise generate any elements of a type, it only allows you to compare given elements. And being able to check whether x < y for two real numbers would seem perfectly straightforward and uncontroversial.

By contrast, the Enum class is an absolute mathematical mess. This is not a class for enumerating all values of a type (that would be Universe), rather you should just think of it as the class that can be used for list builders of the form [1, 1.5, .. 9] or ['q'..]. These don't really have any clear mathematical interpretation, they're just useful for writing concise practical code.

It has been argued that Float and Double should not have Enum instances. But IMO those instances are ok in as far as the class itself is ok – not good, but not bad enough to warrant the hassle of replacing it with something new (and braking lots of existing code that makes use of list comprehensions).

Actually, this is worth some consideration. Unlike x < y, which is generally a perfectly fine thing to check, x==y is actually problematic in some ways, both mathematically for exact reals and practically for floating-point numbers. Speaking constructive-mathematically, all you can do is check in finite time that x < y or x > y, but you can never be sure that two values are equal. And for floating-point numbers, you should never assume that two values are ==-equal even if they come out of mathematically equivalent comparisons. Instead, what you should do in testing is to check that x-ε < y < x+ε for some small ε. (How small is appropriate can be tricky to determine.)

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    Is there a computable algorithm that will always successfully determine whether one real number is less than another? I thought this was impossible, since there are situations where two computable numbers might be really close to each other or they could be exactly equal and it wouldn't be possible to tell which, making it semi-decidable. IIRC this is related to why every computable function on the computable reals is continuous, based on Sections 2 & 4 of this paper for instance (if I understand correctly) Jul 25 at 22:58
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    @DavidYoung All the comparison operations are semi-decidable for the computable reals. That is, the tests m == n, m < n, m > n, etc., will each terminate if and only if m≠n.
    – dfeuer
    Jul 26 at 0:13
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    "Given that x<y, it is possible to confirm that." Okay, but that doesn't imply there's a decision procedure for x<y; a decision procedure must always give an answer. So it is not perfectly fine to check x<y. Or, to say it another way: given that x<y, it is possible to check x==y; so why do you distinguish between == and <? Jul 26 at 3:27
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    @leftaroundabout For two nonequal numbers, x==y is decidable, it's only the equal case that causes trouble! You don't get to rule out equal numbers when talking about < but not when talking about ==. There's no difference in decidability between the two. Jul 26 at 13:49
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    ...A thought Re symbolic: wonder whether there are tools that combine symbolic and computable-reals, as both have kind of the opposite problem: with symbolic you can prove that two terms are equal, but just because you haven't found a way to rewrite two terms to be identical doesn't prove that they're not equal. With computable-real you can prove that two values are unequal, but just because you haven't manages yet doesn't prove that they're equal. — Perhaps Mathematica can do that. Jul 26 at 20:31

I'm not a mathematician, but my understanding is that real numbers can be ordered, they just can't be well-ordered.

The Ord class in Haskell basically just says that for any two elements of the type, you can distinguish whether one is less than, greater than, or equal to the other. Mathematical real numbers support this with the usual ≤ and ≥ relationships.

However the usual order on real numbers is not a well-order, which would require that every non-empty subset of the reals would have a least element. The Haskell class Ord says nothing about finding least elements for arbitrary subsets (or anything equivalent), so there's no problem with a type that purports to represent real numbers being in Ord.

When you talk about succ, you're asking about the Enum type class. That has nothing to do with Ord1.

The Enum class is often considered a wart in the language. The few laws it documents actually mandate that its implementations should not be total2. It defines enumerability by ability to be translated to/from Int, which is fundamentally finite while also being too large for any user-defined finite type to have a total toEnum. It is not a good representation of the mathematical concept of an enumerable set. I don't think Enum would end up the way it is if the standard library were being invented from scratch now.

What Enum does do is support Haskell's [n..m] syntax. This is why it made sense for non-integral number types like Double to have succ x = x + 1 instead of attempting to find the next representable number. The spec wants [1..3] :: [Double] to be [1.0, 2.0, 3.0], not a list of every representable number between 1 and 3.

So Double having an Enum instance just isn't a very sensible idea from a pure mathematics point of view (with the Enum we have), and neither is the whole Enum class itself, but they aren't really intended to be either; pure mathematics wasn't what motivated their creation. If you want to think of Doubles as representing mathematical reals then Enum is just a wart you have to remember to avoid (but also, that is far from your only problem with thinking of Doubles as reals). There isn't really a hugely satisfying answer to your question. Not everything in Haskell is perfect representation of mathematical concepts.

1 Other than perhaps an implied law that if the type is also in Ord then x < succ x should hold whenever succ x is defined? It's not actually stated as a law, and Enum is a pretty ad-hoc class, it's arguable either way, but I'd be a bit disappointed in an instance that didn't satisfy that.

2 From the docs:

For any type that is an instance of class Bounded as well as Enum, the following should hold:

  • The calls succ maxBound and pred minBound should result in a runtime error.
  • fromEnum and toEnum should give a runtime error if the result value is not representable in the result type. For example, toEnum 7 :: Bool is an error.
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    The axiom of choice can be used to (non constructively) prove that any set can be well-ordered, including reals. The issue is that, as you correctly state above, the standard ordering on reals is not a well-order.
    – chi
    Jul 26 at 9:04

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