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I have a list L, and x in L evaluates to True if x is a member of L. What can I use instead of L in order x in smth will evaluate to True independently on the value of x?

So, I need something, what contains all objects, including itself, because x can also be this "smth".

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what do you mean ? something like x in [x] ??? –  mouad Feb 2 '11 at 15:39
What's the use case for something like this? If x in L is always True, why can't you just replace x in L with True? –  Falmarri Feb 2 '11 at 15:42
@Falmarri: suppose a container class provides a filtering interface that wants an object with in defined on it instead of a predicate. –  larsmans Feb 2 '11 at 15:51

3 Answers 3

up vote 5 down vote accepted
class Universe:
    def __contains__(_,x): return True
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Note that this creates the possibility of multiple universes, each containing all the others as elements. Set theory on steroids! –  larsmans Feb 2 '11 at 15:48
A set cannot contain all other sets. There is no universal set. You cannot, therefore, have multiple "universe" sets since you can't have a single universal set in the first place. This is basically a pythonic way of just answering True to the query - you have no rules for x belonging to universe - which is basically Falmarri's suggestion. -1. –  Rhino Feb 2 '11 at 17:05
@Ninefingers: this isn't seriously meant as a set theoretic construct, nor as a container. Universe() satisfies the OP's requirement of a smth to "use instead of L in order that x in smth will evaluate to True independently on the value of x." –  larsmans Feb 2 '11 at 17:19
Hmmm. Maybe I'm being a bit harsh. It does evaluate to true as required, I'll give you that. Python will actually let you implement a set that contains itself, too. –  Rhino Feb 2 '11 at 17:42

You can inherit from the built-in list class and redefine the __contains__ method that is called when you do tests like item in list:

>>> class my_list(list):
    def __contains__(self, item):
        return True

>>> L = my_list()
>>> L
>>> x = 2
>>> x
>>> x in L
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Theorem: There is no universal set.

Proof. Let X be a set such that X = {\empty, x} where x is every possible element in the domain. The question arises, is X \in X? Most sets are not defined that way, so let us define a new set Y. Y = {A \in X; A \notin A} i.e. Y is the set of all sets not belonging to themselves.

Now, does Y \in Y? Well, we have defined Y as all sets not belonging to themselves, so Y cannot exist in Y, which contradicts our assumption.

So now assume Y is not in Y. Now A definitely contains Y, as Y is not in itself, but the definition of Y is such that if we define Y to be in Y, we contradict our own definition.

Thus, there is no set of all sets. This is known as Russell's Paradox.

So, why programmatically try to create an object that violates a result proved and tested by set theorists far more intelligent than I am? If that was my interview, this would be my answer and if they insisted it was possible, I'd suggest explaining what the problem domain is, since conceptually Russell has fundamentally proved it is impossible.

If you want a user-friendly problem usually posed for people studying introductory set theory, try the Barber Paradox.

Edit: Python lets you implement an object that contains itself. See this:

class Universal(object):
    def __init__(self):
        self.contents = []

    def add(self, x):

    def remove(self, x):

    def __contains__(self, x):
        return ( x in self.contents )

However, this is not a strict set theoretic object, since the contents actually contains a reference to the parent object. If you require that objects be distinct as per the proof above, this cannot happen.

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In a computer program I can also prove that there are exist such primes, which are different from usual sequence {2,3,5,7,11,...}. Seriously, any set theory is just a product of the human nature, its perception and its physical environment. There are many set theories (non-naive, non-ZFC), which postulate existence of a Universal set. –  psihodelia Feb 2 '11 at 18:01
Well, yes, it is fair to say that any such theorem is a result of the assumptions you make; namely that it depends on the axioms you have postulated. Prime is the name we give to irreducible quantities under our usual system of working, but it is quite acceptable to produce an entirely different set of axioms, which result in different "numbers" being irreducible. However, I'd say most people have a set of common assumptions. ZFC is what most people seem to go with; it is what is taught to undergrads. –  Rhino Feb 2 '11 at 18:19

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