There can hardly be one ("acceptable") answer, so I'll just add some thoughts:
As mentioned in the comments, the
Collection#add(E) already allows for throwing an
IllegalArgumentException, with the reason
if some property of the element prevents it from being added to this collection
So one could say that this case was explicitly considered in the design of the collection interface, and there is no obvious, profound, purely technical (interface-contract related) reason to not allow creating such a collection.
However, when thinking about possible application patterns, one quickly finds cases where the observed behavior of such a collection could be ... counterintuitive, to say the least.
One was already mentioned by dcsohl in the comments, and referred to cases where such a collection would only be a view on another collection:
List<Integer> listWithIntegers = new ArrayList<Integer>();
List<Integer> listWithPositiveIntegers =
createView(listWithIntegers, e -> e > 0);
//listWithPositiveIntegers.add(-1); // Would throw IllegalArgumentException
listWithIntegers.add(-1); // Fine
// This would be true:
However, one could argue that
- Such a collection would not necessarily have to be only a view. Instead, one could enforce that only new collections with such constraints may be created
- The behavior is similar to that of
Collections.unmodifiableCollection(Collection), which is widely anticipated as it is. (Although it serves a far broader and omnipresent use-case, namely avoiding the internal state of a class to be exposed by returning a modifiable version of a collection via an accessor method)
But in this case, the potential for "inconsistencies" is much higher.
For example, consider a call to
Collection#addAll(Collection). It also allows throwing an
IllegalArgumentException "if some property of an element of the specified collection prevents it from being added to this collection". But there are no guarantees about things like atomicity. To phrase it that way: It is not specified what the state of the collection will be when such an exception was thrown. Imagine a case like this:
List<Integer> listWithPositiveIntegers = createList(e -> e > 0);
listWithPositiveIntegers.add(1); // Fine
listWithPositiveIntegers.add(2); // Fine
listWithPositiveIntegers.add(Arrays.asList(3,-4,5)); // Throws
assert(listWithPositiveIntegers.contains(3)); // True or false?
assert(listWithPositiveIntegers.contains(5)); // True or false?
(It may be subtle, but it may be an issue).
All this might become even trickier when the condition changes after the collection has been created (regardless of whether it is only a view or not). For example, one could imagine a sequence of calls like this:
List<Integer> listWithPredicate = create(predicate);
listWithPredicate.add(-1); // Fine
listWithPredicate.add(-1); // Throws
someMethod(), there is an innocent line like
One of the comments already mentioned possible performance issues. This is certainly true, but I think that this is not really a strong technical argument: There are no formal complexity guarantees for the runtime of any method of the
Collection interface, anyhow. You don't know how long a
collection.add(e) call takes. For a
LinkedList it is O(1), but for a
TreeSet it may be O(n log n) (and who knows what
n is at this point in time).
Maybe the performance issue and the possible inconsistencies can be considered as special cases of a more general statement:
Such a collection would allow to basically execute arbitrary code during many operations - depending on the implementation of the predicate.
This may literally have arbitrary implications, and makes reasoning about algorithms, performance and the exact behavior (in terms of consistency) impossible.
The bottom line is: There are many possible reasons to not use such a collection. But I can't think of a strong and general technical reason. So there may be application cases for such a collection, but the caveats should be kept in mind, considering how exactly such a collection is intended to be used.