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I know that __call__ method in a class is triggered when the instance of a class is called. However, I have no idea when I can use this special method, because one can simply create a new method and perform the same operation done in __call__ method and instead of calling the instance, you can call the method.

I would really appreciate it if someone gives me a practical usage of this special method.

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the functionality of _call_ is just like the overloaded operator of () in C++. If you simply create a new method outside of the class, you may not access the internal data in a class. – andy Mar 13 '14 at 4:45
up vote 55 down vote accepted

Django forms module uses __call__ method nicely to implement a consistent API for form validation. You can write your own validator for a form in Django as a function.

def custom_validator(value):
    #your validation logic

Django has some default built-in validators such as email validators, url validators etc., which broadly fall under the umbrella of RegEx validators. To implement these cleanly, Django resorts to callable classes (instead of functions). It implements default Regex Validation logic in a RegexValidator and then extends these classes for other validations.

class RegexValidator(object):
    def __call__(self, value):
        # validation logic

class URLValidator(RegexValidator):
    def __call__(self, value):
        super(URLValidator, self).__call__(value)
        #additional logic

class EmailValidator(RegexValidator):
    # some logic

Now both your custom function and built-in EmailValidator can be called with the same syntax.

for v in [custom_validator, EmailValidator()]:
    v(value) # <-----

As you can see, this implementation in Django is similar to what others have explained in their answers below. Can this be implemented in any other way? You could, but IMHO it will not be as readable or as easily extensible for a big framework like Django.

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So if used correctly, it can make the code more readable. I assume if it is used on the wrong place, it would make the code very unreadable as well. – mohi666 Apr 29 '11 at 0:19
This is an example of how it can be used, but not a good one in my opinion. There's no advantage in this case to having a callable instance. It would be better to have an interface/abstract class with a method, like .validate(); it's the same thing only more explicit. The real value of __call__ is being able to use an instance in a place where a callable is expected. I use __call__ most often when creating decorators, for example. – Daniel Oct 1 '13 at 9:24

This example uses memoization, basically storing values in a table (dictionary in this case) so you can look them up later instead of recalculating them.

Here we use a simple class with a __call__ method to calculate factorials (through a callable object) instead of a factorial function that contains a static variable (as that's not possible in Python).

class Factorial:
    def __init__(self):
        self.cache = {}
    def __call__(self, n):
        if n not in self.cache:
            if n == 0:
                self.cache[n] = 1
                self.cache[n] = n * self.__call__(n-1)
        return self.cache[n]

fact = Factorial()

Now you have a fact object which is callable, just like every other function. For example

for i in xrange(10):                                                             
    print("{}! = {}".format(i, fact(i)))

# output
0! = 1
1! = 1
2! = 2
3! = 6
4! = 24
5! = 120
6! = 720
7! = 5040
8! = 40320
9! = 362880

And it is also stateful.

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I'd rather have a fact object that is indexable since your __call__ function is essentially an index. Also would use a list instead of a dict, but that's just me. – Chris Lutz Apr 28 '11 at 20:59
This can be done with closures as well (and that wouldn't be one of the cases of "oh, X and Y are theoretically equivalent, let's go out of our way to emulate one with the other when it doesn't make the slightest sense" scenarios, the code would be even shorter and, arguably, more readable). – delnan Apr 28 '11 at 21:01
@delnan - Almost anything can be done several distinct ways. Which one's more readable depends on the reader. – Chris Lutz Apr 28 '11 at 21:04
@delnan: This is not intended to be shortest. No one wins at code golf. It's intended to show __call__, be simple and nothing more. – S.Lott Apr 28 '11 at 21:06
But it kind of ruins the example when the demonstrated technique isn't ideal for the tasks, doesn't it? (And I wasn't about the "let's save lines for the heck of it"-short, I was talking about the "write it in this equally clear manner and save some boilerplate code"-short. Rest assured that I'm not one of those madmen trying to write the shortest code possible, I merely want to avoid boilerplate code that adds nothing for the reader.) – delnan Apr 28 '11 at 21:07

I find it useful because it allows me to create APIs that are easy to use (you have some callable object that requires some specific arguments), and are easy to implement because you can use Object Oriented practices.

The following is code I wrote yesterday that makes a version of the methods that hash entire files rather than strings:

import hashlib

class Hasher(object):
    A wrapper around the hashlib hash algorithms that allows an entire file to
    be hashed in a chunked manner.
    def __init__(self, algorithm):
        self.algorithm = algorithm

    def __call__(self, file):
        hash = self.algorithm()
        with open(file, 'rb') as f:
            for chunk in iter(lambda:, ''):
        return hash.hexdigest()

md5    = Hasher(hashlib.md5)
sha1   = Hasher(hashlib.sha1)
sha224 = Hasher(hashlib.sha224)
sha256 = Hasher(hashlib.sha256)
sha384 = Hasher(hashlib.sha384)
sha512 = Hasher(hashlib.sha512)

This implementation allows me to use the functions in a similar fashion to the functions:

from filehash import sha1
print sha1('somefile.txt')

Of course I could have implemented it a different way, but in this case it seemed like a simple approach.

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Again, closures ruin this example. is 80% the lines and just as clear. – delnan Apr 28 '11 at 21:13
I'm not convinced it would always be just as clear to someone (e.g. perhaps someone who has only used Java). Nested functions and variable lookup/scope might be confusing. I suppose my point was that __call__ gives you a tool that lets you use OO techniques to solve problems. – bradley.ayers Apr 28 '11 at 21:18
I think the question "why use X over Y" when both provide equivalent functionality is terribly subjective. For some people the OO approach is easier to understand, for others the closure approach is. There's no compelling argument to use one over the other, unless you had a situation where you had to use isinstance or something similar. – bradley.ayers Apr 28 '11 at 21:26
@delnan Your closures example is less lines of code, but that it's just as clear is more difficult to argue. – Dennis Feb 21 '13 at 18:53
An example of where you would rather use a __call__ method instead of a closure is when you're dealing with the multiprocessing module, which uses pickling to pass information between processes. You can't pickle a closure, but you can pickle an instance of a class. – John Peter Thompson Garcés Apr 4 '13 at 14:55

__call__ is also used to implement decorator classes in python. In this case the instance of the class is called when the method with the decorator is called.

class EnterExitParam(object):

    def __init__(self, p1):
        self.p1 = p1

    def __call__(self, f):
        def new_f():
            print("Entering", f.__name__)
            print("p1=", self.p1)
            print("Leaving", f.__name__)
        return new_f

@EnterExitParam("foo bar")
def hello():

if __name__ == "__main__":
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Yes, when you know you're dealing with objects, it's perfectly possible (and in many cases advisable) to use an explicit method call. However, sometimes you deal with code that expects expects callable objects - typically functions, but thanks to __call__ you can build more complex objects, with instance data and more methods to delegate repetive tasks, etc. that are still callable.

Also, sometimes you're using both objects for complex tasks (where it makes sense to write a dedicated class) and objects for simple tasks (that already exist in functions, or are more easily written as functions). To have a common interface, you either have to write tiny classes wrapping those functions with the expected interface, or you keep the functions functions and make the more complex objects callable. Let's take threads as example. The Thread objects from the standard libary module threading want a callable as target argument (i.e. as action to be done in the new thread). With a callable object, you are not restricted to functions, you can pass other objects as well, such as a relatively complex worker that gets tasks to do from other threads and executes them sequentially:

class Worker(object):
    def __init__(self, *args, **kwargs):
        self.queue = queue.Queue()
        self.args = args
        self.kwargs = kwargs

    def add_task(self, task):

    def __call__(self):
        while True:
            next_action = self.queue.get()
            success = next_action(*self.args, **self.kwargs)
            if not success:

This is just an example off the top of my head, but I think it is already complex enough to warrant the class. Doing this only with functions is hard, at least it requires returning two functions and that's slowly getting complex. One could rename __call__ to something else and pass a bound method, but that makes the code creating the thread slightly less obvious, and doesn't add any value.

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It's probably useful to use the phrase "duck typing" ( here -- you can mimic a function using a more complicated class object this way. – Andrew Jaffe Apr 28 '11 at 21:19
As a related example, I've seen __call__ used to use class instances (instead of functions) as WSGI applications. Here's an example from "The Definitive Guide to Pylons": Using Instances of Classes – Josh Rosen Apr 29 '11 at 0:48

Class-based decorators use __call__ to reference the wrapped function. E.g.:

class Deco(object):
    def __init__(self,f):
        self.f = f
    def __call__(self, *args, **kwargs):
        print args
        print kwargs
        self.f(*args, **kwargs)

There is a good description of the various options here at

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I rarely see class decorators though, as they require some nonobvious boilerplate code to work with methods. – delnan Apr 28 '11 at 21:15

IMHO __call__ method and closures give us a natural way to create STRATEGY design pattern in Python. We define a family of algorithms, encapsulate each one, make them interchangeable and in the end we can execute a common set of steps and, for example, calculate a hash for a file.

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Specify a __metaclass__ and override the __call__ method, and have the specified meta classes' __new__ method return an instance of the class, viola you have a "function" with methods.

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I just stumbled upon a usage of __call__() in concert with __getattr__() which I think is beautiful. It allows you to hide multiple levels of a JSON/HTTP/(however_serialized) API inside an object.

The __getattr__() part takes care of iteratively returning a modified instance of the same class, filling in one more attribute at a time. Then, after all information has been exhausted, __call__() takes over with whatever arguments you passed in.

Using this model, you can for example make a call like api.v2.volumes.ssd.update(size=20), which ends up in a PUT request to https://some.tld/api/v2/volumes/ssd/update.

The particular code is a block storage driver for a certain volume backend in OpenStack, you can check it out here:

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