I agree with you that, from a mathematical perspective, this behavior really doesn't make sense.
There are two interesting questions here: first, to what extent were the designers of the
Set interface trying to implement a mathematical set? Secondly, even if they weren't, to what extent does that exempt them from the rules of set theory?
For the first question, I will point you to the documentation of the Set:
A collection that contains no duplicate elements. More formally, sets contain no pair of elements e1 and e2 such that e1.equals(e2), and at most one null element. As implied by its name, this interface models the mathematical set abstraction.
It's worth mentioning here that current formulations of set theory don't permit sets to be members of themselves. (See the Axiom of regularity). This is due in part to Russell's Paradox, which exposed a contradiction in naive set theory (which permitted a set to be any collection of objects - there was no prohibition against sets including themselves). This is often illustrated by the Barber Paradox: suppose that, in a particular town, a barber shaves all of the men - and only the men - who do not shave themselves. Question: does the barber shave himself? If he does, it violates the second constraint; if he doesn't, it violates the first constraint. This is clearly logically impossible, but it's actually perfectly permissible under the rules of naive set theory (which is why the newer "standard" formulation of set theory explicitly bans sets from containing themselves).
There's more discussion in this question on Math.SE about why sets cannot be an element of themselves.
With that said, this brings up the second question: even if the designers hadn't been explicitly trying to model a mathematical set, would this be completely "exempt" from the problems associated with naive set theory? I think not - I think that many of the problems that plagued naive set theory would plague any kind of a collection that was insufficiently constrained in ways that were analogous to naive set theory. Indeed, I may be reading too much into this, but the first part of the definition of a
Set in the documentation sounds suspiciously like the intuitive concept of a set in naive set theory:
A collection that contains no duplicate elements.
Admittedly (and to their credit), they do place at least some constraints on this later (including stating that you really shouldn't try to have a Set contain itself), but you could question whether it's really "enough" to avoid the problems with naive set theory. This is why, for example, you have a "turtles all the way down" problem when trying to calculate the hash code of a HashSet that contains itself. This is not, as some others have suggested, merely a practical problem - it's an illustration of the fundamental theoretical problems with this type of formulation.
As a brief digression, I do recognize that there are, of course, some limitations on how closely any collection class can really model a mathematical set. For example, Java's documentation warns against the dangers of including mutable objects in a set. Some other languages, such as Python, at least attempt to ban many kinds of mutable objects entirely:
The set classes are implemented using dictionaries. Accordingly, the requirements for set elements are the same as those for dictionary keys; namely, that the element defines both
__hash__(). As a result, sets cannot contain mutable elements such as lists or dictionaries. However, they can contain immutable collections such as tuples or instances of ImmutableSet. For convenience in implementing sets of sets, inner sets are automatically converted to immutable form, for example,
Set([Set(['dog'])]) is transformed to
Two other major differences that others have pointed out are
- Java sets are mutable
- Java sets are finite. Obviously, this will be true of any collection class: apart from concerns about actual infinity, computers only have a finite amount of memory. (Some languages, like Haskell, have lazy infinite data structures; however, in my opinion, a lawlike choice sequence seems like a more natural way model these than classical set theory, but that's just my opinion).
TL;DR No, it really shouldn't be permitted (or, at least, you should never do that) because sets can't be members of themselves.