Now that it's clear what a metaclass is, there is an associated concept that I use all the time without knowing what it really means.

I suppose everybody made once a mistake with parenthesis, resulting in an "object is not callable" exception. What's more, using __init__ and __new__ lead to wonder what this bloody __call__ can be used for.

Could you give me some explanations, including examples with the magic method ?


13 Answers 13


A callable is anything that can be called.

The built-in callable (PyCallable_Check in objects.c) checks if the argument is either:

  • an instance of a class with a __call__ method or
  • is of a type that has a non null tp_call (c struct) member which indicates callability otherwise (such as in functions, methods etc.)

The method named __call__ is (according to the documentation)

Called when the instance is ''called'' as a function


class Foo:
  def __call__(self):
    print 'called'

foo_instance = Foo()
foo_instance() #this is calling the __call__ method
  • 7
    Note that the builtin callable is being removed in Python 3.0 in favor of checking for call Commented Sep 22, 2008 at 0:31
  • 18
    @Eli: Hmm that sounds like a very bad move. callable actually tells you if something is callable or not, while checking for __call__ tells you nothing; If an object o provides __getattribute__ or __getattr__, hasattr(o, '__call__') may return True, yet o will still not be callable because Python skips __getattribute__ and __getattr__ for calls. The only real way left to check if something is callable is thus EAFP. Commented Jul 1, 2010 at 23:03
  • 65
    @Longpoke: Just for the record, please see the documentation for callable() in Python 3.x: "This function was first removed in Python 3.0 and then brought back in Python 3.2.".
    – Tadeck
    Commented May 8, 2013 at 4:41
  • It seems in python 3.8 only the presence of tp_call is checked. See implementation of PyCallable_Check, it's 3 lines. Commented May 28, 2020 at 13:38
  • 1
    @MichelePiccolini It's been that way for over a decade actually, but it still works to do what it's documented to do, which is to check if something is callable or not. When Python 3 was still young they changed the implementation, and now objects with a __call__ method just always have tp_call set as well. I'm not sure when "all callables have tp_call" was implemented, but the PyCallable_Check change happened in back in August 2006: github.com/python/cpython/commit/…
    – mtraceur
    Commented Jan 29, 2021 at 19:11

From Python's sources object.c:

/* Test whether an object can be called */

PyCallable_Check(PyObject *x)
    if (x == NULL)
        return 0;
    if (PyInstance_Check(x)) {
        PyObject *call = PyObject_GetAttrString(x, "__call__");
        if (call == NULL) {
            return 0;
        /* Could test recursively but don't, for fear of endless
           recursion if some joker sets self.__call__ = self */
        return 1;
    else {
        return x->ob_type->tp_call != NULL;

It says:

  1. If an object is an instance of some class then it is callable iff it has __call__ attribute.
  2. Else the object x is callable iff x->ob_type->tp_call != NULL

Desciption of tp_call field:

ternaryfunc tp_call An optional pointer to a function that implements calling the object. This should be NULL if the object is not callable. The signature is the same as for PyObject_Call(). This field is inherited by subtypes.

You can always use built-in callable function to determine whether given object is callable or not; or better yet just call it and catch TypeError later. callable is removed in Python 3.0 and 3.1, use callable = lambda o: hasattr(o, '__call__') or isinstance(o, collections.Callable).

Example, a simplistic cache implementation:

class Cached:
    def __init__(self, function):
        self.function = function
        self.cache = {}

    def __call__(self, *args):
        try: return self.cache[args]
        except KeyError:
            ret = self.cache[args] = self.function(*args)
            return ret    


def ack(x, y):
    return ack(x-1, ack(x, y-1)) if x*y else (x + y + 1) 

Example from standard library, file site.py, definition of built-in exit() and quit() functions:

class Quitter(object):
    def __init__(self, name):
        self.name = name
    def __repr__(self):
        return 'Use %s() or %s to exit' % (self.name, eof)
    def __call__(self, code=None):
        # Shells like IDLE catch the SystemExit, but listen when their
        # stdin wrapper is closed.
        raise SystemExit(code)
__builtin__.quit = Quitter('quit')
__builtin__.exit = Quitter('exit')
  • 10
    I find the example for the call method highly missleading because it mixes it with a recipe for caching and decorators, which add nothing to the understanding of call Commented Sep 26, 2008 at 16:13
  • 3
    J.F. Sebastian, also piling more examples you copy&pasted from somewhere else that are not minimal doesn't help. Commented Sep 27, 2008 at 13:10
  • 20
    @J.F. Sebastian: It's BS that more life-like examples are better. I could show you life-like code that would make you weep as an example. Simple examples work too, and they work better to illustrate something because they don't distract. Commented Sep 28, 2008 at 22:32
  • 5
    You are explaining what's a callable, but you gave an example how to use callable objects to define a decorator. I know it's a typical usage of callable but this can confuse readers who just want to know what is callable and how to use callable. I'd prefer @Florian Bösch's answer.
    – KFL
    Commented Mar 6, 2012 at 19:01
  • 2
    @Kay: I also like the @Florian Bösch's answer (in its current form). btw, a decorator is not a typical usage of a "callable". The most typical "callables" are functions/methods such as def f(): ..., and class objects such as class C: ... i.e., f, ''.strip, len, and C all are callable. Instances that have a __call__() method in their class are relatively rare.
    – jfs
    Commented Mar 6, 2012 at 20:30

A callable is an object allows you to use round parenthesis ( ) and eventually pass some parameters, just like functions.

Every time you define a function python creates a callable object. In example, you could define the function func in these ways (it's the same):

class a(object):
    def __call__(self, *args):
        print 'Hello'

func = a()

# or ... 
def func(*args):
    print 'Hello'

You could use this method instead of methods like doit or run, I think it's just more clear to see obj() than obj.doit()


Let me explain backwards:

Consider this...


... as syntactic sugar for:


Where foo can be any object that responds to __call__. When I say any object, I mean it: built-in types, your own classes and their instances.

In the case of built-in types, when you write:


You're essentially doing:


That's also why you don't have foo = new int in Python: you just make the class object return an instance of it on __call__. The way Python solves this is very elegant in my opinion.

  • 1
    You're essentially doing type(int).__call__(int, '10') and type(unicode).__call__(unicode, '10'). Dunders are always called on their class, not through the instance. And they never go through the metaclass either. For most cases that's just a nitpick, but it matters sometimes. Commented Sep 19, 2018 at 3:24
  • 1
    Built-in types work in special ways in the reference C implementation, although what happens is essentially equivalent to this, yes. For user-defined types, writing MyClass() attempts to call the class, by looking for a __call__ method on MyClass 's class, i.e. it skips doing attribute lookup within MyClass (otherwise it could find a user-defined __call__ intended for the instances!) and finds type.__call__ - which then evaluates to a bound method on MyClass via the usual mechanisms, which is then called. Commented Jul 5, 2022 at 5:35

__call__ makes any object be callable as a function.

This example will output 8:

class Adder(object):
  def __init__(self, val):
    self.val = val

  def __call__(self, val):
    return self.val + val

func = Adder(5)
print func(3)

A Callable is an object that has the __call__ method. This means you can fake callable functions or do neat things like Partial Function Application where you take a function and add something that enhances it or fills in some of the parameters, returning something that can be called in turn (known as Currying in functional programming circles).

Certain typographic errors will have the interpreter attempting to call something you did not intend, such as (for example) a string. This can produce errors where the interpreter attempts to execute a non-callable application. You can see this happening in a python interpreter by doing something like the transcript below.

[nigel@k9 ~]$ python
Python 2.5 (r25:51908, Nov  6 2007, 15:55:44) 
[GCC 4.1.2 20070925 (Red Hat 4.1.2-27)] on linux2
Type "help", "copyright", "credits" or "license" for more information.
>>> 'aaa'()    # <== Here we attempt to call a string.
Traceback (most recent call last):
  File "<stdin>", line 1, in <module>
TypeError: 'str' object is not callable

Quite simply, a "callable" is something that can be called like a method. The built in function "callable()" will tell you whether something appears to be callable, as will checking for a call property. Functions are callable as are classes, class instances can be callable. See more about this here and here.

  • 1
    To warp the readers' mind a bit: classes are callable because they are instances of a class that has callable instances. You may have heard of it: it's called type. This object, uniquely, is its own type, and an instance of itself. It defines a __call__ method so that classes can be callable; that's where the implementation-specific magic is invoked to actually allocate memory, as well as potentially using the class' __new__ hook and then calling __init__ on the resultant object. Commented Jul 5, 2022 at 5:39

In Python a callable is an object which type has a __call__ method:

>>> class Foo:
...  pass
>>> class Bar(object):
...  pass
>>> type(Foo).__call__(Foo)
<__main__.Foo instance at 0x711440>
>>> type(Bar).__call__(Bar)
<__main__.Bar object at 0x712110>
>>> def foo(bar):
...  return bar
>>> type(foo).__call__(foo, 42)

As simple as that :)

This of course can be overloaded:

>>> class Foo(object):
...  def __call__(self):
...   return 42
>>> f = Foo()
>>> f()

It's something you can put "(args)" after and expect it to work. A callable is usually a method or a class. Methods get called, classes get instantiated.


To check function or method of class is callable or not that means we can call that function.

Class A:
    def __init__(self,val):
        self.val = val
    def bar(self):
        print "bar"

obj = A()      
def foo(): return "s"
  • 2
    Are you sure callable(obj.__init___) doesn't have an extra underscore (as in AttributeError)? If it doesn't, are you sure the answer isn't True for that one? Commented Sep 19, 2018 at 3:34

callables implement the __call__ special method so any object with such a method is callable.

  • An instance on which you define __call__ won't be callable if the class doesn't define such a method. Commented Sep 19, 2018 at 3:35

Callable is a type or class of "Build-in function or Method" with a method call

>>> type(callable)
<class 'builtin_function_or_method'>

Example: print is a callable object. With a build-in function call When you invoke the print function, Python creates an object of type print and invokes its method call passing the parameters if any.

>>> type(print)
<class 'builtin_function_or_method'>
>>> print.__call__(10)
>>> print(10)
  • 2
    Some of the info here is straight up wrong. E.g. "When you invoke the print function, Python creates an object of type print and invokes its method __call__". Python does not create a print object. It just calls something equivalent to type(print).__call__(print, *args, **kwargs). And the first sentence doesn't make much sense. You appear to be confusing a callable object and "callable" the function. Commented Sep 19, 2018 at 3:30

A class, function, method and object which has __call__() are callable.

You can check if callable with callable() which returns True if callable and returns False if not callable as shown below:

class Class1:
    def __call__(self):

class Class2:

def func():

print(callable(Class1))   # Class1
print(callable(Class2))   # Class2

print(callable(Class1())) # Class1 object
print(callable(Class2())) # Class2 object

print(callable(func))     # func

Then, only Class2 object which doesn't have __call__() is not callable returning False as shown below:

True  # Class1
True  # Class2
True  # Class1 object
False # Class2 object
True  # func

In addition, all of them below are not callable returning False as shown below:

print(callable("Hello"))  # "str" type
print(callable(100))      # "int" type
print(callable(100.23))   # "float" type
print(callable(100 + 2j)) # "complex" type
print(callable(True))     # "bool" type
print(callable(None))     # "NoneType"
print(callable([]))       # "list" type
print(callable(()))       # "tuple" type
print(callable({}))       # "dict" type
print(callable({""}))     # "set" type


False # "str" type
False # "int" type
False # "float" type
False # "complex" type
False # "bool" type
False # "NoneType"
False # "list" type
False # "tuple" type
False # "dict" type
False # "set" type

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