In several programming languages there are Set collections which are supposed to be implementations of the mathematical concept of a finite set.
However, this is not necessarily true, for example in
Java, both implementations of
HashSet<T> allow you to add any
HashSet<T> collection as a member of itself. Which by the modern definition of a mathematical set is not allowed.
According to naive set theory, the definition of a set is:
A set is a collection of distinct objects.
However, this definition lead famously to Russel's Paradox as well as other paradoxes. For convenience, Russel's Paradox is:
Let R be the set of all sets that are not members of themselves. If R is not a member of itself, then its definition dictates that it must contain itself, and if it contains itself, then it contradicts its own definition as the set of all sets that are not members of themselves.
So according to modern set theory (See: ZFC), the definition of a set is:
A set is a collection of distinct objects, none of which is the set itself.
Specifically, this is a result of the axiom of regularity.
Well so what? What are the implications of this? Why is this question on StackOverflow?
One of the implications of Russel's Paradox is that not all collections are sets. Additionally, this was the point where mathematicians dropped the definition of a set as being the usual English definition. So I believe this question has a lot of weight when it comes to programming language design in general.
So why would programming languages, who in some form, use these principles in their very design just ignore it in the implementation of the Set in their languages libraries?
Secondly, is this a common occurrence with other implementations of mathematical concepts?
Perhaps I'm being a bit nit picky, but if these are to be true implementations of Sets, then why would part of the very definition be ignored?
Addition of C# and Java code snippets exemplifying behavior:
Set<Object> hashSet = new HashSet<Object>(); hashSet.add(1); hashSet.add("Tiger"); hashSet.add(hashSet); hashSet.add('f'); Object array = hashSet.toArray(); HashSet<Object> hash = (HashSet<Object>)array; System.out.println("HashSet in HashSet:"); for (Object obj : hash) System.out.println(obj); System.out.println("\nPrinciple HashSet:"); for (Object obj : hashSet) System.out.println(obj);
Which prints out:
HashSet in HashSet: f 1 Tiger [f, 1, Tiger, (this Collection)] Principle HashSet: f 1 Tiger [f, 1, Tiger, (this Collection)]
HashSet<object> hashSet = new HashSet<object>(); hashSet.Add(1); hashSet.Add("Tiger"); hashSet.Add(hashSet); hashSet.Add('f'); object array = hashSet.ToArray(); var hash = (HashSet<object>)array; Console.WriteLine("HashSet in HashSet:"); foreach (object obj in hash) Console.WriteLine(obj); Console.WriteLine("\nPrinciple HashSet:"); foreach (object obj in hashSet) Console.WriteLine(obj);
Which prints out:
HashSet in HashSet: 1 Tiger System.Collections.Generic.HashSet`1[System.Object] f Principle HashSet: 1 Tiger System.Collections.Generic.HashSet`1[System.Object] f
In regards to Martijn Courteaux's second point which was that it could be done in the name of computational efficiency:
I made two test collections in C#. They were identical, except in the Add method of one of the them - I added the following check:
if (this != obj) where
obj is the item being added to the collection.
I clocked both of them separately where they were to add 100,000 random integers:
With Check: ~ 28 milliseconds
Without Check: ~ 21 milliseconds
This is a fairly significant performance jump.