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I have a method that accepts a parameter that can be of several types, and has to do one thing or other depending on the type, but if I check the type of said parameter, I don't get the 'real' type, I always get <type 'instance'>, and that is messing up with my comparisons.

I have something like:

from classes import Class1
from classes import Class2
# Both classes are declared in the same file.
# I don't know if that can be a problem         #
# ... #
def foo(parameter)
    if (type(parameter) == type(Class1()):
    # ... #
    elif (type(parameter) == type(Class2()):
    # ... #

And as type(parameter) returns <type 'instance'> and type(Class1()) is <type 'instance'> as well, it turns out that even if the parameter is an instance of Class2, it is going into the first comparison...

By the way, str(parameter.__class__) properly shows classes.Class1 . I guess I could always use that, but I would like to understand what's going on... I have made tenths of comparisons like this and all them worked properly...

Thank you!! :)

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3 Answers 3

up vote 8 down vote accepted

Old-style classes do that. Derive your classes from object in their definitions.

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Wooo... That works! :) Now I am going to try to figure out "why"... :D –  BorrajaX Jun 24 '10 at 14:15
It has to do with the fact that new-style classes have more metadata, including the stuff that type() touches. –  Ignacio Vazquez-Abrams Jun 24 '10 at 14:21
Thx again, I was reading this: cafepy.com/article/python_types_and_objects/… And I kind of (kind of) figured that something like that had to be reason –  BorrajaX Jun 24 '10 at 14:38

you should really use isinstance:

In [26]: def foo(param):
   ....:     print type(param)
   ....:     print isinstance(param, Class1)

In [27]: foo(x)
<type 'instance'>

Type is better for built-in types.

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Woo! Thank you for the really fast answer... I considered that, but then I read this: canonical.org/~kragen/isinstance And I chickened out... :S Although I must say that, on the other hand, 'isinstance' my be suitable for my needs... –  BorrajaX Jun 24 '10 at 14:06
isinstance is certainly usually preferable to direct type() checking, and definitely the form of type checking you're using where you actually instantiate a Class1() for each check is undesirable. However what that article is saying is that in many cases checking for types at all (whichever method you use for that) is a sign of bad coding practice. IMO the article is unhelpfully religious and there are still valid uses for type-checking, but if you are doing ‘tens’ of checks against your own defined types that does sound like a potential ‘not object-oriented enough’ code-smell. –  bobince Jun 24 '10 at 14:16
You can clearly see in the Ops code why doing type-checking means that you're not doing OOP: Whatever code would come after if isinstace( obj, Cls) should be in a method of Cls. It might sound religious, but if you want to use OOP (not that you have to) then you have to get at least that right. –  Jochen Ritzel Jun 24 '10 at 14:34
Well... What I wrote was a simple example to make it as clear as possible, but the thing is that I can actually receive (as a parameter) an object of Class1, or a list of objects of Class1 (and then walk the list and recursively call the method so it would behave as if one object was received) or an object that is not a Class1, but has values that allow me to initialize a Class1 object and call the method again with that Class1 instance, etc. That's why I need to check the type –  BorrajaX Jun 24 '10 at 15:11
@BorrajaX that's not better, instead this method and all similar should always take and return lists of Class1. Sometimes the lists have just one element, so they might look kind of pointless, but the interface stays the same and that's pretty much the point of OOP. –  Jochen Ritzel Jun 24 '10 at 22:09

The fact that type(x) returns the same type object for all instances x of legacy, aka old-style, classes, is one of many infuriating defects of those kinds of classes -- unfortunately they have to stay (and be the default for a class without base) in Python 2.* for reasons of backwards compatibility.

Nevertheless, don't use old-style classes unless you're forced to maintain a bunch of old, legacy code (without a good test suite to give you the confidence to try and switch kind o classes). When a class has no "natural" bases, subclass it from object rather than from nothing. Alternatively, your module, at the top, can set

__metaclass__ = type

which changes the default from the crufty, legacy old-style classes, to the shiny bright new-style ones -- while explicitly inheriting from object is usually preferred ("explicit is better than implicit"), the module-global setting of __metaclass__ may feel "less invasive" to existing old modules where you're switching from old to new classes, so it's offered as a possibility.

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Thank you! Good answer too! I had already used the one Ignacio proposed. but well... in the end, if my understanding is correct, they are pretty similar, right? –  BorrajaX Jun 25 '10 at 15:01
@Borrajax, the end result of explicitly inheriting from object vs not inheriting and having a module-global __metaclass__=type is exactly the same - very different styles, undistinguishable results. –  Alex Martelli Jun 25 '10 at 22:18

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