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What is the difference between a function decorated with @staticmethod and one decorated with @classmethod?

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12 Answers 12

up vote 798 down vote accepted

Maybe a bit of example code will help: Notice the difference in the call signatures of foo, class_foo and static_foo:

class A(object):
    def foo(self,x):
        print "executing foo(%s,%s)"%(self,x)

    @classmethod
    def class_foo(cls,x):
        print "executing class_foo(%s,%s)"%(cls,x)

    @staticmethod
    def static_foo(x):
        print "executing static_foo(%s)"%x    

a=A()

Below is the usual way an object instance calls a method. The object instance, a, is implicitly passed as the first argument.

a.foo(1)
# executing foo(<__main__.A object at 0xb7dbef0c>,1)

With classmethods, the class of the object instance is implicitly passed as the first argument instead of self.

a.class_foo(1)
# executing class_foo(<class '__main__.A'>,1)

You can also call class_foo using the class. In fact, if you define something to be a classmethod, it is probably because you intend to call it from the class rather than from a class instance. A.foo(1) would have raised a TypeError, but A.class_foo(1) works just fine:

A.class_foo(1)
# executing class_foo(<class '__main__.A'>,1)

One use people have found for class methods is to create inheritable alternative constructors.


With staticmethods, neither self (the object instance) nor cls (the class) is implicitly passed as the first argument. They behave like plain functions except that you can call them from an instance or the class:

a.static_foo(1)
# executing static_foo(1)

A.static_foo('hi')
# executing static_foo(hi)

Staticmethods are used to group functions which have some logical connection with a class to the class.


foo is just a function, but when you call a.foo you don't just get the function, you get a "partially applied" version of the function with the object instance a bound as the first argument to the function. foo expects 2 arguments, while a.foo only expects 1 argument.

a is bound to foo. That is what is meant by the term "bound" below:

print(a.foo)
# <bound method A.foo of <__main__.A object at 0xb7d52f0c>>

With a.class_foo, a is not bound to class_foo, rather the class A is bound to class_foo.

print(a.class_foo)
# <bound method type.class_foo of <class '__main__.A'>>

Here, with a staticmethod, even though it is a method, a.static_foo just returns a good 'ole function with no arguments bound. static_foo expects 1 argument, and a.static_foo expects 1 argument too.

print(a.static_foo)
# <function static_foo at 0xb7d479cc>
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22  
I don't understand what's the catch for using staticmethod. we can just use a simple outside-of-class function. –  Alcott Sep 19 '11 at 3:08
67  
@Alcott: You might want to move a function into a class because it logically belongs with the class. In the Python source code (e.g. multiprocessing,turtle,dist-packages), it is used to "hide" single-underscore "private" functions from the module namespace. Its use, though, is highly concentrated in just a few modules -- perhaps an indication that it is mainly a stylistic thing. Though I could not find any example of this, @staticmethod might help organize your code by being overridable by subclasses. Without it you'd have variants of the function floating around in the module namespace. –  unutbu Sep 19 '11 at 10:34
28  
@Alcott: as unutbu said, static methods are an organization/stylistic feature. Sometimes a module have many classes, and some helper functions are logically tied to a a given class and not to the others, so it makes sense not to "pollute" the module with many "free functions", and it is better to use a static method than relying on the poor style of mixing classes and function defs together in code just to show they are "related" –  MestreLion May 3 '12 at 9:55
12  
@unutbu: You should however delete that Guido quote: It was from an early draft of python 2.2 release notes, and it was changed in 2.2.3 to: However, class methods are still useful in other places, for example, to program inheritable alternate constructors. Even the original quote is very misleading, as he only said that the python distribuition does not use classmethod. But just because python itself don't use a given feature, it doesn't mean it's a useless feature. Think about complex numbers or even sqrt: python itself may not use either, but it's far from being useless to offer –  MestreLion May 3 '12 at 10:44
3  
Python doesn't support namespacing like in C++. A @staticmethod then just moves your function out of the "global" namespace which is nice for keeping imports clean. –  SilentDirge Dec 26 '13 at 5:58

I think a better question is "When would you use @classmethod vs @staticmethod?"

@classmethod allows you easy access to private members that are associated to the class definition. this is a great way to do singletons, or factory classes that control the number of instances of the created objects exist.

@staticmethod provides marginal performance gains, but I have yet to see a productive use of a static method within a class that couldn't be achieved as a standalone function outside the class.

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I just wanted to add that the @decorators were added in python 2.4.

If you're using python < 2.4 you can use the classmethod() and staticmethod() function. For example, if you want to create a factory method (A function returning an instance of a different implementation of a class depending on what argument it gets) you can do something like:

class Cluster(object):

    def _is_cluster_for(cls, name):
        """
        see if this class is the cluster with this name
        this is a classmethod
        """ 
        return cls.__name__ == name
    _is_cluster_for = classmethod(_is_cluster_for)

    #static method
    def getCluster(name):
        """
        static factory method, should be in Cluster class
        returns a cluster object of the given name
        """
        for cls in Cluster.__subclasses__():
            if cls._is_cluster_for(name):
                return cls()
    getCluster = staticmethod(getCluster)

Also observe that this is a good example for using a classmethod and a static method, The static method clearly belongs to the class, since it uses the class Cluster internally. The classmethod only needs information about the class, and no instance of the object.

Another benefit of making the _is_cluster_for method a classmethod is so a subclass can decide to change it's implementation, maybe because it is pretty generic and can handle more than one type of clusters, so just checking the name of the class would not be enough.

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What is the difference between @staticmethod and @classmethod in Python?

You may have seen Python code like this pseudocode, which demonstrates the signatures of the various method types and provides a docstring to explain each:

class Foo(object):

    def a_normal_method(self, arg_1, kwarg_2=None):
        '''
        Return a value that is a function of the instance with its
        attributes, and other arguments such as arg_1 and kwarg2
        '''

    @staticmethod
    def a_static_method(arg_0):
        '''
        Return a value that is a function of arg_0. It does not know the 
        instance or class it is called from.
        '''

    @classmethod
    def a_class_method(cls, arg1):
        '''
        Return a value that is a function of the class and other arguments.
        respects subclassing, it is called with the class it is called from.
        '''

The Normal Method

First I'll explain the normal_method. This may be better called an "instance method". When an instance method is used, it is used as a partial function (as opposed to a total function, defined for all values when viewed in source code) that is, when used, the first of the arguments is predefined as the instance of the object, with all of its given attributes. It has the instance of the object bound to it, and it must be called from an instance of the object. Typically, it will access various attributes of the instance.

For example, this is an instance of a string:

', '

if we use the instance method, join on this string, to join another iterable, it quite obviously is a function of the instance, in addition to being a function of the iterable list, ['a', 'b', 'c']:

>>>', '.join(['a', 'b', 'c'])
'a, b, c'

Static Method

The static method does not take the instance as an argument. Yes it is very similar to a module level function. However, a module level function must live in the module and be specially imported to other places where it is used. If it is attached to the object, however, it will follow the object conveniently through importing and inheritance as well.

An example is the str.maketrans static method, moved from the string module in Python 3. It makes a translation table suitable for consumption by str.translate. It does seem rather silly when used from an instance of a string, as demonstrated below, but importing the function from the string module is rather clumsy, and it's nice to be able to call it from the class, as in str.maketrans

# demonstrate same function whether called from instance or not:
>>> ', '.maketrans('ABC', 'abc')
{65: 97, 66: 98, 67: 99}
>>> str.maketrans('ABC', 'abc')
{65: 97, 66: 98, 67: 99}

In python 2, you have to import this function from the increasingly deprecated string module:

>>> import string
>>> 'ABCDEFG'.translate(string.maketrans('ABC', 'abc'))
'abcDEFG'

Class Method

A class method is a similar to a static method in that it takes an implicit first argument, but instead of taking the instance, it takes the class. Frequently these are used as alternative constructors for better semantic usage and it will support inheritance.

The most canonical example of a builtin classmethod is dict.fromkeys. It is used as an alternative constructor of dict, (well suited for when you know what your keys are and want a default value for them.)

>>> dict.fromkeys(['a', 'b', 'c'])
{'c': None, 'b': None, 'a': None}

When we subclass dict, we can use the same constructor, which creates an instance of the subclass.

>>> class MyDict(dict): '''A dict subclass, demonstrates classmethods'''
>>> md = MyDict.fromkeys(['a', 'b', 'c'])
>>> md
{'a': None, 'c': None, 'b': None}
>>> type(md)
<class '__main__.MyDict'>

See the pandas source code for other similar examples of alternative constructors, and see also the official Python documentation on classmethod and staticmethod.

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#!/usr/bin/python
#coding:utf-8

class Demo(object):
    def __init__(self,x):
        self.x = x

    @classmethod
    def addone(self, x):
        return x+1

    @staticmethod
    def addtwo(x):
        return x+2

    def addthree(self, x):
        return x+3

def main():
    print Demo.addone(2)
    print Demo.addtwo(2)

    #print Demo.addthree(2) #Error
    demo = Demo(2)
    print demo.addthree(2)


if __name__ == '__main__':
    main()
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A quick hack-up ofotherwise identical methods in iPython reveals that @staticmethod yields marginal performance gains (in the nanoseconds), but otherwise it seems to serve no function. Also, any performance gains will probably be wiped out by the additional work of processing the method through staticmethod() during compilation (which happens prior to any code execution when you run a script).

For the sake of code readability I'd avoid @staticmethod unless your method will be used for loads of work, where the nanoseconds count.

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2  
"Otherwise seems to serve no function": not strictly true. See above discussion. –  Keith Pinson Dec 17 '12 at 19:46

Official python docs:

@classmethod

A class method receives the class as implicit first argument, just like an instance method receives the instance. To declare a class method, use this idiom:

class C:
    @classmethod
    def f(cls, arg1, arg2, ...): ... 

The @classmethod form is a function decorator – see the description of function definitions in Function definitions for details.

It can be called either on the class (such as C.f()) or on an instance (such as C().f()). The instance is ignored except for its class. If a class method is called for a derived class, the derived class object is passed as the implied first argument.

Class methods are different than C++ or Java static methods. If you want those, see staticmethod() in this section.

@staticmethod

A static method does not receive an implicit first argument. To declare a static method, use this idiom:

class C:
    @staticmethod
    def f(arg1, arg2, ...): ... 

The @staticmethod form is a function decorator – see the description of function definitions in Function definitions for details.

It can be called either on the class (such as C.f()) or on an instance (such as C().f()). The instance is ignored except for its class.

Static methods in Python are similar to those found in Java or C++. For a more advanced concept, see classmethod() in this section.

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I disagree that static methods are not useful, but I also use Python differently than most. It is being used as a scripting language for another piece of software and anything I write must be able to use a default python install, no custom modules allowed except for very specific circumstances. All my classes are in one file(ugh!!) and a utility class with random, unrelated static helper methods, mostly related to interacting with the software being extended, becomes extremely useful and helps clean up the code quite a bit. Doing "normal" Python programming, however, I never do use them and use modules. Best part about Python is how versatile it can be. The more creative you get, the more it seems it can do for you.

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Basically @classmethod makes a method whose first argument is the class it's called from (rather than the class instance), @staticmethod does not have any implicit arguments.

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A staticmethod is a method that knows nothing about the class or instance it was called on. It just gets the arguments that were passed, no implicit first argument. It is basically useless in Python -- you can just use a module function instead of a staticmethod.

A classmethod, on the other hand, is a method that gets passed the class it was called on, or the class of the instance it was called on, as first argument. This is useful when you want the method to be a factory for the class: since it gets the actual class it was called on as first argument, you can always instantiate the right class, even when subclasses are involved. Observe for instance how dict.fromkeys(), a classmethod, returns an instance of the subclass when called on a subclass:

>>> class DictSubclass(dict):
...     def __repr__(self):
...         return "DictSubclass"
... 
>>> dict.fromkeys("abc")
{'a': None, 'c': None, 'b': None}
>>> DictSubclass.fromkeys("abc")
DictSubclass
>>> 
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450  
A staticmethod isn't useless - it's a way of putting a function into a class (because it logically belongs there), while indicating that it does not require access to the class. –  Tony Meyer Sep 26 '08 at 10:10
88  
Hence only 'basically' useless. Such organization, as well as dependency injection, are valid uses of staticmethods, but since modules, not classes like in Java, are the basic elements of code organization in Python, their use and usefulness is rare. –  Thomas Wouters Sep 26 '08 at 13:40
27  
What's logical about defining a method inside a class, when it has nothing to do with either the class or its instances? –  Ben James Mar 12 '10 at 9:11
73  
Perhaps for the inheritance sake? Static methods can be inherited and overridden just like instance methods and class methods and the lookup works as expected (unlike in Java). Static methods are not really resolved statically whether called on the class or instance, so the only difference between class and static methods is the implicit first argument. –  haridsv Apr 8 '10 at 1:32
48  
They also create a cleaner namespace, and makes it easier to understand the function have something to do with the class. –  Imbrondir Aug 22 '11 at 11:58

Here is a short article on this question

@staticmethod function is nothing more than a function defined inside a class. It is callable without instantiating the class first. It’s definition is immutable via inheritance.

@classmethod function also callable without instantiating the class, but its definition follows Sub class, not Parent class, via inheritance. That’s because the first argument for @classmethod function must always be cls (class).

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1  
So does that mean that by using a staticmethod I am always bound to the Parent class and with the classmethod I am bound the class that I declare the classmethod in (in this case the sub class)? –  Mohan Gulati Nov 3 '09 at 19:06
5  
No. By using a staticmethod you aren't bound at all; there is no implicit first parameter. By using classmethod, you get as implicit first parameter the class you called the method on (if you called it directly on a class), or the class of the instance you called the method on (if you called it on an instance). –  Matt Anderson Nov 3 '09 at 19:18
3  
+1: a brief, simple, but solid explanation. Could be expanded a bit to show that, by having a class as a first argument, class methods have direct access to other class attributes and methods, while static methods do not (they would need to hardcode MyClass.attr for that) –  MestreLion May 3 '12 at 10:01

@staticmethod just disables the default function as method descriptor. classmethod wraps your function in a container callable that passes a reference to the owning class as first argument:

>>> class C(object):
...  pass
... 
>>> def f():
...  pass
... 
>>> staticmethod(f).__get__(None, C)
<function f at 0x5c1cf0>
>>> classmethod(f).__get__(None, C)
<bound method type.f of <class '__main__.C'>>

As a matter of fact, classmethod has a runtime overhead but makes it possible to access the owning class. Alternatively I recommend using a metaclass and putting the class methods on that metaclass:

>>> class CMeta(type):
...  def foo(cls):
...   print cls
... 
>>> class C(object):
...  __metaclass__ = CMeta
... 
>>> C.foo()
<class '__main__.C'>
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3  
What's the problem with a metaclass? –  Armin Ronacher Sep 26 '08 at 3:20
5  
What are the advantages to using a metaclass for this? –  Daryl Spitzer Jan 18 '09 at 17:51

protected by Jon Clements Jan 7 '13 at 9:36

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