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For example I have class

Class Cls:
   var 1 
   var 2

   def func(self):
      --- do some statement

Now, I can simply import class and create object

import Cls
clsObj = Cls()

Here, Cls is class and clsObj is instance of class. Is there any way that I distinguish between them.

Thank you

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1  
You can't really import classes - are you sure this is the real code? –  Eli Bendersky Aug 8 '11 at 6:14
1  
@Krishna - Please accept answers to your old, answered questions by clicking the check mark next to the best one. –  agf Aug 8 '11 at 6:45

4 Answers 4

up vote 2 down vote accepted

Yes, just use the builtin type() which gives the type of a particular object. type(clsObj) will give Instance as the answer. You can also check with isinstance isinstance(clsObj,Cls) will return True whereas isinstance(Cls,Cls) will return False

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Only old-style class instances are of type instance. The type of a new style class instance is it's class. –  agf Aug 8 '11 at 6:21
    
I can pass one parameter only e.g. Cls or clsObj. So based on coming parameter, I have to identify. e.g. doSomething(clsObj): if clsObj is class: do something object else: do something class –  Elisa Aug 8 '11 at 6:26
1  
You can use the hasattr(Obj,'class') to check if it is object of the class. Note it depends that you have __init__ call in your class and create an object. –  Senthil Kumaran Aug 8 '11 at 7:02
    
@Senthil hasattr(Obj,'class') worked, thank you! –  Elisa Aug 9 '11 at 4:04

I think this takes all cases into account:

def isclass(obj):
    try:
        class_ = obj.__class__
    except AttributeError:
        # It's an old-style class
        return True
    try:
        class_.__class__
    except AttributeError:
        # It's an old-style instance
        return False
    # It's new-style
    return isinstance(obj, type)

Now let's test it to make sure it works as intended/expected:

def test():
    class OldStyle: pass

    class NewStyle(object): pass

    def class_factory():
        return type("DynamicClass", (object,), {})

    class MetaClass(type):
        def __new__(mcls, *args):
            if args:
                return type(*args)
            return class_factory()

    class WithMeta(object):
        __metaclass__ = MetaClass
        def __call__(self):
            return self

    confusing = WithMeta()

    for name, obj in locals().items():
        templ = "{0:>26s} == {1!r:>5}, {2:>26s} == {3!r:>5}"
        print templ.format(
            "isclass({0})".format(name), isclass(obj),
            "isclass({0}())".format(name), isclass(obj()))

Output:

         isclass(OldStyle) ==  True,        isclass(OldStyle()) == False
         isclass(NewStyle) ==  True,        isclass(NewStyle()) == False
         isclass(WithMeta) ==  True,        isclass(WithMeta()) == False
        isclass(MetaClass) ==  True,       isclass(MetaClass()) ==  True
    isclass(class_factory) == False,   isclass(class_factory()) ==  True
        isclass(confusing) == False,       isclass(confusing()) == False

MetaClass, class_factory and confusing illustrate that what constitutes a class in python is debatable, and shows how the isclass function handles these cases.

Re: agf

MetaClass isn't meant to be instantiated like that, so your tricks to avoid an error really just confuse the issue; printing "Error" for MetaClass() would be more correct.

Did you or I write MetaClass? I meant it to be instantiated like that. I'll grant you it makes little sense to have a metaclass (or a class factory function) that creates "the same" class each time it's invoked, and of course it's confusing. However, for these specific purposes I wanted to illustrate that a metaclass creates a class when instantiated, and having lots of arguments to MetaClass() would be a combo-breaker in the output. :) So in principle I agree with you, but for this specific purpose I do it this way, and python allows me to do so.

__call__ happens BEFORE __new__ so what WithMeta(), confusing, and confusing() show is correct.

If you by "happens" means "is parsed, compiled and bound" then yes, that happens first. I'm not sure I understand what you're getting at here. I agree it's correct -- of course it's correct, this code was written and run, and I posted the results I got, so it can't help but be correct. I don't see what __call__ has to do with it. Could you elaborate?

You never actually instantiate WithMeta. You should just remove that __call__ and show Error for confusing()

I'm quite sure I do instantiate WithMeta:

>>> WithMeta()
<isclass.WithMeta object at 0xb784574c>

When I write WithMeta(), python will check if type(WithMeta).__new__ is defined, and it is, so python then supplies the class name, bases and namespace dict as arguments to MetaClass.__new__(). It returns the WithMeta class object, which is made by calling type with the same arguments.

On the other hand, confusing() is the same as type(confusing).__dict__["__call__"](confusing), which just returns the argument, so that confusing == confusing().

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Use isinstance not issubclass. Otherwise, great answer. –  agf Aug 8 '11 at 10:19
    
There could be a problem if the class is a subclass of type, so its instances are actually classes... as in a metaclass. Anyway this can't be solved without an explicit registry of what is to be considered a 'class' rather than an 'instance'. –  rewritten Aug 8 '11 at 10:22
    
@agf isinstance(obj, cls) and issubclass(type(obj), cls) are the same. So the answer is correct, and you have to change the argument if you want to use isinstance. –  rewritten Aug 8 '11 at 10:24
    
I know it works, and I know you'd need to change the argument. It's one less call and it's really what you want to check there -- whether or not the object is an instance of type. –  agf Aug 8 '11 at 10:29
    
@saverio Since OP didn't define it, I've interpreted him to mean that a class is anything that may be instantiated. –  Lauritz V. Thaulow Aug 8 '11 at 10:33

I don't see why you'd need to, but you can do this:

if type(obj) == type:
    # It's a class.
else:
    # It's an instance of a class.
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This is only true for new-style classes without metaclasses -- he's created an old-style class above. –  agf Aug 8 '11 at 6:18

You can use the property __class__ - clsObj.__class__

From python tutorial:

Each value is an object, and therefore has a class (also called its type). It is stored as object.__class__.

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for both Class or Class object, it returns class name. My job ti identify given input is class or object isntance –  Elisa Aug 8 '11 at 6:26
    
So I didn't understand your question, sorry! –  MByD Aug 8 '11 at 6:27
    
But you should remember that every class is an object too! –  MByD Aug 8 '11 at 6:27
    
@Krishna - No, it doesn't. A new style class without a metaclass will have <type 'type'> in it's __class__ field, and an old style class will have no class field. An instance of a class will have it's class in the __class__ field –  agf Aug 8 '11 at 6:44

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