When should I prefer #classmethod over a #staticmethod and vice versa? [duplicate] - python

What is the difference between a method decorated with #staticmethod and one decorated with #classmethod?

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(f"executing foo({self}, {x})")
#classmethod
def class_foo(cls, x):
print(f"executing class_foo({cls}, {x})")
#staticmethod
def static_foo(x):
print(f"executing static_foo({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>
And of course the same thing happens when you call static_foo with the class A instead.
print(A.static_foo)
# <function static_foo at 0xb7d479cc>

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
>>>

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.

To decide whether to use #staticmethod or #classmethod you have to look inside your method. If your method accesses other variables/methods in your class then use #classmethod. On the other hand, if your method does not touches any other parts of the class then use #staticmethod.
class Apple:
_counter = 0
#staticmethod
def about_apple():
print('Apple is good for you.')
# note you can still access other member of the class
# but you have to use the class instance
# which is not very nice, because you have repeat yourself
#
# For example:
# #staticmethod
# print('Number of apples have been juiced: %s' % Apple._counter)
#
# #classmethod
# print('Number of apples have been juiced: %s' % cls._counter)
#
# #classmethod is especially useful when you move your function to another class,
# you don't have to rename the referenced class
#classmethod
def make_apple_juice(cls, number_of_apples):
print('Making juice:')
for i in range(number_of_apples):
cls._juice_this(i)
#classmethod
def _juice_this(cls, apple):
print('Juicing apple %d...' % apple)
cls._counter += 1

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.

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).

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_instance_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 Instance Method
First I'll explain a_normal_instance_method. This is precisely 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'
Bound methods
Instance methods can be bound via a dotted lookup for use later.
For example, this binds the str.join method to the ':' instance:
>>> join_with_colons = ':'.join
And later we can use this as a function that already has the first argument bound to it. In this way, it works like a partial function on the instance:
>>> join_with_colons('abcde')
'a:b:c:d:e'
>>> join_with_colons(['FF', 'FF', 'FF', 'FF', 'FF', 'FF'])
'FF:FF:FF:FF:FF:FF'
Static Method
The static method does not take the instance as an argument.
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 of a static method is str.maketrans, 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 less useful string module:
>>> import string
>>> 'ABCDEFG'.translate(string.maketrans('ABC', 'abc'))
'abcDEFG'
Class Method
A class method is a similar to an instance 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, use to demo 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.

I started learning programming language with C++ and then Java and then Python and so this question bothered me a lot as well, until I understood the simple usage of each.
Class Method: Python unlike Java and C++ doesn't have constructor overloading. And so to achieve this you could use classmethod. Following example will explain this
Let's consider we have a Person class which takes two arguments first_name and last_name and creates the instance of Person.
class Person(object):
def __init__(self, first_name, last_name):
self.first_name = first_name
self.last_name = last_name
Now, if the requirement comes where you need to create a class using a single name only, just a first_name, you can't do something like this in Python.
This will give you an error when you will try to create an object (instance).
class Person(object):
def __init__(self, first_name, last_name):
self.first_name = first_name
self.last_name = last_name
def __init__(self, first_name):
self.first_name = first_name
However, you could achieve the same thing using #classmethod as mentioned below
class Person(object):
def __init__(self, first_name, last_name):
self.first_name = first_name
self.last_name = last_name
#classmethod
def get_person(cls, first_name):
return cls(first_name, "")
Static Method: This is rather simple, it's not bound to instance or class and you can simply call that using class name.
So let's say in above example you need a validation that first_name should not exceed 20 characters, you can simply do this.
#staticmethod
def validate_name(name):
return len(name) <= 20
and you could simply call using class name
Person.validate_name("Gaurang Shah")

Only the first argument differs:
normal method: the current object is automatically passed as an (additional) first argument
classmethod: the class of the current object is automatically passed as an (additional) fist argument
staticmethod: no extra arguments are automatically passed. What you passed to the function is what you get.
In more detail...
normal method
The "standard" method, as in every object oriented language. When an object's method is called, it is automatically given an extra argument self as its first argument. That is, method
def f(self, x, y)
must be called with 2 arguments. self is automatically passed, and it is the object itself. Similar to the this that magically appears in eg. java/c++, only in python it is shown explicitly.
actually, the first argument does not have to be called self, but it's the standard convention, so keep it
class method
When the method is decorated
#classmethod
def f(cls, x, y)
the automatically provided argument is not self, but the class of self.
static method
When the method is decorated
#staticmethod
def f(x, y)
the method is not given any automatic argument at all. It is only given the parameters that it is called with.
usages
classmethod is mostly used for alternative constructors.
staticmethod does not use the state of the object, or even the structure of the class itself. It could be a function external to a class. It only put inside the class for grouping functions with similar functionality (for example, like Java's Math class static methods)
class Point
def __init__(self, x, y):
self.x = x
self.y = y
#classmethod
def frompolar(cls, radius, angle):
"""The `cls` argument is the `Point` class itself"""
return cls(radius * cos(angle), radius * sin(angle))
#staticmethod
def angle(x, y):
"""this could be outside the class, but we put it here
just because we think it is logically related to the class."""
return atan(y, x)
p1 = Point(3, 2)
p2 = Point.frompolar(3, pi/4)
angle = Point.angle(3, 2)

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.

Static Methods:
Simple functions with no self argument.
Work on class attributes; not on instance attributes.
Can be called through both class and instance.
The built-in function staticmethod()is used to create them.
Benefits of Static Methods:
It localizes the function name in the classscope
It moves the function code closer to where it is used
More convenient to import versus module-level functions since each method does not have to be specially imported
#staticmethod
def some_static_method(*args, **kwds):
pass
Class Methods:
Functions that have first argument as classname.
Can be called through both class and instance.
These are created with classmethod in-built function.
#classmethod
def some_class_method(cls, *args, **kwds):
pass

#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 for 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 cluster, so just checking the name of the class would not be enough.

Let me tell the similarity between a method decorated with #classmethod vs #staticmethod first.
Similarity: Both of them can be called on the Class itself, rather than just the instance of the class. So, both of them in a sense are Class's methods.
Difference: A classmethod will receive the class itself as the first argument, while a staticmethod does not.
So a static method is, in a sense, not bound to the Class itself and is just hanging in there just because it may have a related functionality.
>>> class Klaus:
#classmethod
def classmthd(*args):
return args
#staticmethod
def staticmthd(*args):
return args
# 1. Call classmethod without any arg
>>> Klaus.classmthd()
(__main__.Klaus,) # the class gets passed as the first argument
# 2. Call classmethod with 1 arg
>>> Klaus.classmthd('chumma')
(__main__.Klaus, 'chumma')
# 3. Call staticmethod without any arg
>>> Klaus.staticmthd()
()
# 4. Call staticmethod with 1 arg
>>> Klaus.staticmthd('chumma')
('chumma',)

#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'>

Another consideration with respect to staticmethod vs classmethod comes up with inheritance. Say you have the following class:
class Foo(object):
#staticmethod
def bar():
return "In Foo"
And you then want to override bar() in a child class:
class Foo2(Foo):
#staticmethod
def bar():
return "In Foo2"
This works, but note that now the bar() implementation in the child class (Foo2) can no longer take advantage of anything specific to that class. For example, say Foo2 had a method called magic() that you want to use in the Foo2 implementation of bar():
class Foo2(Foo):
#staticmethod
def bar():
return "In Foo2"
#staticmethod
def magic():
return "Something useful you'd like to use in bar, but now can't"
The workaround here would be to call Foo2.magic() in bar(), but then you're repeating yourself (if the name of Foo2 changes, you'll have to remember to update that bar() method).
To me, this is a slight violation of the open/closed principle, since a decision made in Foo is impacting your ability to refactor common code in a derived class (ie it's less open to extension). If bar() were a classmethod we'd be fine:
class Foo(object):
#classmethod
def bar(cls):
return "In Foo"
class Foo2(Foo):
#classmethod
def bar(cls):
return "In Foo2 " + cls.magic()
#classmethod
def magic(cls):
return "MAGIC"
print Foo2().bar()
Gives: In Foo2 MAGIC
Also: historical note: Guido Van Rossum (Python's creator) once referred to staticmethod's as "an accident": https://mail.python.org/pipermail/python-ideas/2012-May/014969.html
we all know how limited static methods are. (They're basically an accident -- back in the Python 2.2 days when I was inventing new-style classes and descriptors, I meant to implement class methods but at first I didn't understand them and accidentally implemented static methods first. Then it was too late to remove them and only provide class methods.
Also: https://mail.python.org/pipermail/python-ideas/2016-July/041189.html
Honestly, staticmethod was something of a mistake -- I was trying to do something like Java class methods but once it was released I found what was really needed was classmethod. But it was too late to get rid of staticmethod.

The definitive guide on how to use static, class or abstract methods in Python is one good link for this topic, and summary it as following.
#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.
Python does not have to instantiate a bound-method for object.
It eases the readability of the code, and it does not depend on the state of object itself;
#classmethod function also callable without instantiating the class, but its definition follows Sub class, not Parent class, via inheritance, can be overridden by subclass. That’s because the first argument for #classmethod function must always be cls (class).
Factory methods, that are used to create an instance for a class using for example some sort of pre-processing.
Static methods calling static methods: if you split a static methods in several static methods, you shouldn't hard-code the class name but use class methods

I will try to explain the basic difference using an example.
class A(object):
x = 0
def say_hi(self):
pass
#staticmethod
def say_hi_static():
pass
#classmethod
def say_hi_class(cls):
pass
def run_self(self):
self.x += 1
print self.x # outputs 1
self.say_hi()
self.say_hi_static()
self.say_hi_class()
#staticmethod
def run_static():
print A.x # outputs 0
# A.say_hi() # wrong
A.say_hi_static()
A.say_hi_class()
#classmethod
def run_class(cls):
print cls.x # outputs 0
# cls.say_hi() # wrong
cls.say_hi_static()
cls.say_hi_class()
1 - we can directly call static and classmethods without initializing
# A.run_self() # wrong
A.run_static()
A.run_class()
2- Static method cannot call self method but can call other static and classmethod
3- Static method belong to class and will not use object at all.
4- Class method are not bound to an object but to a class.

The difference occurs when there is inheritance.
Suppose that there are two classes-- Parent and Child. If one wants to use #staticmethod, print_name method should be written twice because the name of the class should be written in the print line.
class Parent:
_class_name = "Parent"
#staticmethod
def print_name():
print(Parent._class_name)
class Child(Parent):
_class_name = "Child"
#staticmethod
def print_name():
print(Child._class_name)
Parent.print_name()
Child.print_name()
However, for #classmethod, it is not required to write print_name method twice.
class Parent:
_class_name = "Parent"
#classmethod
def print_name(cls):
print(cls._class_name)
class Child(Parent):
_class_name = "Child"
Parent.print_name()
Child.print_name()

Python comes with several built-in decorators. The big three are:
#classmethod
#staticmethod
#property
First let's note that any function of a class can be called with instance of this class (after we initialized this class).
#classmethod is the way to call function not only as an instance of a class but also directly by the class itself as its first argument.
#staticmethod is 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 (so we don't need to use self in function definition).
Let's consider the following class:
class DecoratorTest(object):
def __init__(self):
pass
def doubler(self, x):
return x*2
#classmethod
def class_doubler(cls, x): # we need to use 'cls' instead of 'self'; 'cls' reference to the class instead of an instance of the class
return x*2
#staticmethod
def static_doubler(x): # no need adding 'self' here; static_doubler() could be just a function not inside the class
return x*2
Let's see how it works:
decor = DecoratorTest()
print(decor.doubler(5))
# 10
print(decor.class_doubler(5)) # a call with an instance of a class
# 10
print(DecoratorTest.class_doubler(5)) # a direct call by the class itself
# 10
# staticmethod could be called in the same way as classmethod.
print(decor.static_doubler(5)) # as an instance of the class
# 10
print(DecoratorTest.static_doubler(5)) # or as a direct call
# 10
Here you can see some use cases for those methods.
Bonus: you can read about #property decorator here

Instance Method:
+ Can modify object instance state
+ Can modify class state
Class Method:
- Can't modify object instance state
+ Can modify class state
Static Method:
- Can't modify object instance state
- Can't modify class state
class MyClass:
'''
Instance method has a mandatory first attribute self which represent the instance itself.
Instance method must be called by a instantiated instance.
'''
def method(self):
return 'instance method called', self
'''
Class method has a mandatory first attribute cls which represent the class itself.
Class method can be called by an instance or by the class directly.
Its most common using scenario is to define a factory method.
'''
#classmethod
def class_method(cls):
return 'class method called', cls
'''
Static method doesn’t have any attributes of instances or the class.
It also can be called by an instance or by the class directly.
Its most common using scenario is to define some helper or utility functions which are closely relative to the class.
'''
#staticmethod
def static_method():
return 'static method called'
obj = MyClass()
print(obj.method())
print(obj.class_method()) # MyClass.class_method()
print(obj.static_method()) # MyClass.static_method()
output:
('instance method called', <__main__.MyClass object at 0x100fb3940>)
('class method called', <class '__main__.MyClass'>)
static method called
The instance method we actually had access to the object instance , right so this was an instance off a my class object whereas with the class method we have access to the class itself. But not to any of the objects, because the class method doesn't really care about an object existing. However you can both call a class method and static method on an object instance. This is going to work it doesn't really make a difference, so again when you call static method here it's going to work and it's going to know which method you want to call.
The Static methods are used to do some utility tasks, and class methods are used for factory methods. The factory methods can return class objects for different use cases.
And finally, a short example for better understanding:
class Student:
def __init__(self, first_name, last_name):
self.first_name = first_name
self.last_name = last_name
#classmethod
def get_from_string(cls, name_string: str):
first_name, last_name = name_string.split()
if Student.validate_name(first_name) and Student.validate_name(last_name):
return cls(first_name, last_name)
else:
print('Invalid Names')
#staticmethod
def validate_name(name):
return len(name) <= 10
stackoverflow_student = Student.get_from_string('Name Surname')
print(stackoverflow_student.first_name) # Name
print(stackoverflow_student.last_name) # Surname

#classmethod : can be used to create a shared global access to all the instances created of that class..... like updating a record by multiple users....
I particulary found it use ful when creating singletons as well..:)
#static method: has nothing to do with the class or instance being associated with ...but for readability can use static method

My contribution demonstrates the difference amongst #classmethod, #staticmethod, and instance methods, including how an instance can indirectly call a #staticmethod. But instead of indirectly calling a #staticmethod from an instance, making it private may be more "pythonic." Getting something from a private method isn't demonstrated here but it's basically the same concept.
#!python3
from os import system
system('cls')
# % % % % % % % % % % % % % % % % % % % %
class DemoClass(object):
# instance methods need a class instance and
# can access the instance through 'self'
def instance_method_1(self):
return 'called from inside the instance_method_1()'
def instance_method_2(self):
# an instance outside the class indirectly calls the static_method
return self.static_method() + ' via instance_method_2()'
# class methods don't need a class instance, they can't access the
# instance (self) but they have access to the class itself via 'cls'
#classmethod
def class_method(cls):
return 'called from inside the class_method()'
# static methods don't have access to 'cls' or 'self', they work like
# regular functions but belong to the class' namespace
#staticmethod
def static_method():
return 'called from inside the static_method()'
# % % % % % % % % % % % % % % % % % % % %
# works even if the class hasn't been instantiated
print(DemoClass.class_method() + '\n')
''' called from inside the class_method() '''
# works even if the class hasn't been instantiated
print(DemoClass.static_method() + '\n')
''' called from inside the static_method() '''
# % % % % % % % % % % % % % % % % % % % %
# >>>>> all methods types can be called on a class instance <<<<<
# instantiate the class
democlassObj = DemoClass()
# call instance_method_1()
print(democlassObj.instance_method_1() + '\n')
''' called from inside the instance_method_1() '''
# # indirectly call static_method through instance_method_2(), there's really no use
# for this since a #staticmethod can be called whether the class has been
# instantiated or not
print(democlassObj.instance_method_2() + '\n')
''' called from inside the static_method() via instance_method_2() '''
# call class_method()
print(democlassObj.class_method() + '\n')
''' called from inside the class_method() '''
# call static_method()
print(democlassObj.static_method())
''' called from inside the static_method() '''
"""
# whether the class is instantiated or not, this doesn't work
print(DemoClass.instance_method_1() + '\n')
'''
TypeError: TypeError: unbound method instancemethod() must be called with
DemoClass instance as first argument (got nothing instead)
'''
"""

A class method receives the class as implicit first argument, just like an instance method receives the instance. It is a method which is bound to the class and not the object of the class.It has access to the state of the class as it takes a class parameter that points to the class and not the object instance. It can modify a class state that would apply across all the instances of the class. For example it can modify a class variable that will be applicable to all the instances.
On the other hand, a static method does not receive an implicit first argument, compared to class methods or instance methods. And can’t access or modify class state. It only belongs to the class because from design point of view that is the correct way. But in terms of functionality is not bound, at runtime, to the class.
as a guideline, use static methods as utilities, use class methods for example as factory . Or maybe to define a singleton. And use instance methods to model the state and behavior of instances.
Hope I was clear !

You might want to consider the difference between:
class A:
def foo(): # no self parameter, no decorator
pass
and
class B:
#staticmethod
def foo(): # no self parameter
pass
This has changed between python2 and python3:
python2:
>>> A.foo()
TypeError
>>> A().foo()
TypeError
>>> B.foo()
>>> B().foo()
python3:
>>> A.foo()
>>> A().foo()
TypeError
>>> B.foo()
>>> B().foo()
So using #staticmethod for methods only called directly from the class has become optional in python3. If you want to call them from both class and instance, you still need to use the #staticmethod decorator.
The other cases have been well covered by unutbus answer.

Class methods, as the name suggests, are used to make changes to classes and not the objects. To make changes to classes, they will modify the class attributes(not object attributes), since that is how you update classes.
This is the reason that class methods take the class(conventionally denoted by 'cls') as the first argument.
class A(object):
m=54
#classmethod
def class_method(cls):
print "m is %d" % cls.m
Static methods on the other hand, are used to perform functionalities that are not bound to the class i.e. they will not read or write class variables. Hence, static methods do not take classes as arguments. They are used so that classes can perform functionalities that are not directly related to the purpose of the class.
class X(object):
m=54 #will not be referenced
#staticmethod
def static_method():
print "Referencing/calling a variable or function outside this class. E.g. Some global variable/function."

I think giving a purely Python version of staticmethod and classmethod would help to understand the difference between them at language level (Refers to Descriptor Howto Guide).
Both of them are non-data descriptors (It would be easier to understand them if you are familiar with descriptors first).
class StaticMethod(object):
"Emulate PyStaticMethod_Type() in Objects/funcobject.c"
def __init__(self, f):
self.f = f
def __get__(self, obj, objtype=None):
return self.f
class ClassMethod(object):
"Emulate PyClassMethod_Type() in Objects/funcobject.c"
def __init__(self, f):
self.f = f
def __get__(self, obj, cls=None):
def inner(*args, **kwargs):
if cls is None:
cls = type(obj)
return self.f(cls, *args, **kwargs)
return inner

Analyze #staticmethod literally providing different insights.
A normal method of a class is an implicit dynamic method which takes the instance as first argument.
In contrast, a staticmethod does not take the instance as first argument, so is called 'static'.
A staticmethod is indeed such a normal function the same as those outside a class definition.
It is luckily grouped into the class just in order to stand closer where it is applied, or you might scroll around to find it.

One pretty important practical difference occurs when subclassing. If you don't mind, I'll hijack #unutbu's example:
class A:
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)
class B(A):
pass
In class_foo, the method knows which class it is called on:
A.class_foo(1)
# => executing class_foo(<class '__main__.A'>, 1)
B.class_foo(1)
# => executing class_foo(<class '__main__.B'>, 1)
In static_foo, there is no way to determine whether it is called on A or B:
A.static_foo(1)
# => executing static_foo(1)
B.static_foo(1)
# => executing static_foo(1)
Note that this doesn't mean you can't use other methods in a staticmethod, you just have to reference the class directly, which means subclasses' staticmethods will still reference the parent class:
class A:
#classmethod
def class_qux(cls, x):
print(f"executing class_qux({cls}, {x})")
#classmethod
def class_bar(cls, x):
cls.class_qux(x)
#staticmethod
def static_bar(x):
A.class_qux(x)
class B(A):
pass
A.class_bar(1)
# => executing class_qux(<class '__main__.A'>, 1)
B.class_bar(1)
# => executing class_qux(<class '__main__.B'>, 1)
A.static_bar(1)
# => executing class_qux(<class '__main__.A'>, 1)
B.static_bar(1)
# => executing class_qux(<class '__main__.A'>, 1)

tldr;
A staticmethod is essentially a function bound to a class (and consequently its instances)
A classmethod is essentially an inheritable staticmethod.
For details, see the excellent answers by others.

First let's start with an example code that we'll use to understand both concepts:
class Employee:
NO_OF_EMPLOYEES = 0
def __init__(self, first_name, last_name, salary):
self.first_name = first_name
self.last_name = last_name
self.salary = salary
self.increment_employees()
def give_raise(self, amount):
self.salary += amount
#classmethod
def employee_from_full_name(cls, full_name, salary):
split_name = full_name.split(' ')
first_name = split_name[0]
last_name = split_name[1]
return cls(first_name, last_name, salary)
#classmethod
def increment_employees(cls):
cls.NO_OF_EMPLOYEES += 1
#staticmethod
def get_employee_legal_obligations_txt():
legal_obligations = """
1. An employee must complete 8 hours per working day
2. ...
"""
return legal_obligations
Class method
A class method accepts the class itself as an implicit argument and -optionally- any other arguments specified in the definition. It’s important to understand that a class method, does not have access to object instances (like instance methods do). Therefore, class methods cannot be used to alter the state of an instantiated object but instead, they are capable of changing the class state which is shared amongst all the instances of that class.
Class methods are typically useful when we need to access the class itself — for example, when we want to create a factory method, that is a method that creates instances of the class. In other words, class methods can serve as alternative constructors.
In our example code, an instance of Employee can be constructed by providing three arguments; first_name , last_name and salary.
employee_1 = Employee('Andrew', 'Brown', 85000)
print(employee_1.first_name)
print(employee_1.salary)
'Andrew'
85000
Now let’s assume that there’s a chance that the name of an Employee can be provided in a single field in which the first and last names are separated by a whitespace. In this case, we could possibly use our class method called employee_from_full_name that accepts three arguments in total. The first one, is the class itself, which is an implicit argument which means that it won’t be provided when calling the method — Python will automatically do this for us:
employee_2 = Employee.employee_from_full_name('John Black', 95000)
print(employee_2.first_name)
print(employee_2.salary)
'John'
95000
Note that it is also possible to call employee_from_full_name from object instances although in this context it doesn’t make a lot of sense:
employee_1 = Employee('Andrew', 'Brown', 85000)
employee_2 = employee_1.employee_from_full_name('John Black', 95000)
Another reason why we might want to create a class method, is when we need to change the state of the class. In our example, the class variable NO_OF_EMPLOYEES keeps track of the number of employees currently working for the company. This method is called every time a new instance of Employee is created and it updates the count accordingly:
employee_1 = Employee('Andrew', 'Brown', 85000)
print(f'Number of employees: {Employee.NO_OF_EMPLOYEES}')
employee_2 = Employee.employee_from_full_name('John Black', 95000)
print(f'Number of employees: {Employee.NO_OF_EMPLOYEES}')
Number of employees: 1
Number of employees: 2
Static methods
On the other hand, in static methods neither the instance (i.e. self) nor the class itself (i.e. cls) is passed as an implicit argument. This means that such methods, are not capable of accessing the class itself or its instances.
Now one could argue that static methods are not useful in the context of classes as they can also be placed in helper modules instead of adding them as members of the class. In object oriented programming, it is important to structure your classes into logical chunks and thus, static methods are quite useful when we need to add a method under a class simply because it logically belongs to the class.
In our example, the static method named get_employee_legal_obligations_txt simply returns a string that contains the legal obligations of every single employee of a company. This function, does not interact with the class itself nor with any instance. It could have been placed into a different helper module however, it is only relevant to this class and therefore we have to place it under the Employee class.
A static method can be access directly from the class itself
print(Employee.get_employee_legal_obligations_txt())
1. An employee must complete 8 hours per working day
2. ...
or from an instance of the class:
employee_1 = Employee('Andrew', 'Brown', 85000)
print(employee_1.get_employee_legal_obligations_txt())
1. An employee must complete 8 hours per working day
2. ...
References
What's the difference between static and class methods in Python?

Related

Why do I need to use "self" when calling a class method? [duplicate]

Consider this example:
class MyClass:
def func(self, name):
self.name = name
I know that self refers to the specific instance of MyClass. But why must func explicitly include self as a parameter? Why do we need to use self in the method's code? Some other languages make this implicit, or use special syntax instead.
For a language-agnostic consideration of the design decision, see What is the advantage of having this/self pointer mandatory explicit?.
To close debugging questions where OP omitted a self parameter for a method and got a TypeError, use TypeError: method() takes 1 positional argument but 2 were given instead. If OP omitted self. in the body of the method and got a NameError, consider How can I call a function within a class?.
The reason you need to use self. is because Python does not use special syntax to refer to instance attributes. Python decided to do methods in a way that makes the instance to which the method belongs be passed automatically, but not received automatically: the first parameter of methods is the instance the method is called on. That makes methods entirely the same as functions, and leaves the actual name to use up to you (although self is the convention, and people will generally frown at you when you use something else.) self is not special to the code, it's just another object.
Python could have done something else to distinguish normal names from attributes -- special syntax like Ruby has, or requiring declarations like C++ and Java do, or perhaps something yet more different -- but it didn't. Python's all for making things explicit, making it obvious what's what, and although it doesn't do it entirely everywhere, it does do it for instance attributes. That's why assigning to an instance attribute needs to know what instance to assign to, and that's why it needs self..
Let's say you have a class ClassA which contains a method methodA defined as:
def methodA(self, arg1, arg2):
# do something
and objectA is an instance of this class.
Now when objectA.methodA(arg1, arg2) is called, python internally converts it for you as:
ClassA.methodA(objectA, arg1, arg2)
The self variable refers to the object itself.
Let’s take a simple vector class:
class Vector:
def __init__(self, x, y):
self.x = x
self.y = y
We want to have a method which calculates the length. What would it look like if we wanted to define it inside the class?
def length(self):
return math.sqrt(self.x ** 2 + self.y ** 2)
What should it look like when we were to define it as a global method/function?
def length_global(vector):
return math.sqrt(vector.x ** 2 + vector.y ** 2)
So the whole structure stays the same. How can me make use of this? If we assume for a moment that we hadn’t written a length method for our Vector class, we could do this:
Vector.length_new = length_global
v = Vector(3, 4)
print(v.length_new()) # 5.0
This works because the first parameter of length_global, can be re-used as the self parameter in length_new. This would not be possible without an explicit self.
Another way of understanding the need for the explicit self is to see where Python adds some syntactical sugar. When you keep in mind, that basically, a call like
v_instance.length()
is internally transformed to
Vector.length(v_instance)
it is easy to see where the self fits in. You don't actually write instance methods in Python; what you write is class methods which must take an instance as a first parameter. And therefore, you’ll have to place the instance parameter somewhere explicitly.
When objects are instantiated, the object itself is passed into the self parameter.
Because of this, the object’s data is bound to the object. Below is an example of how you might like to visualize what each object’s data might look. Notice how ‘self’ is replaced with the objects name. I'm not saying this example diagram below is wholly accurate but it hopefully with serve a purpose in visualizing the use of self.
The Object is passed into the self parameter so that the object can keep hold of its own data.
Although this may not be wholly accurate, think of the process of instantiating an object like this: When an object is made it uses the class as a template for its own data and methods. Without passing it's own name into the self parameter, the attributes and methods in the class would remain as a general template and would not be referenced to (belong to) the object. So by passing the object's name into the self parameter it means that if 100 objects are instantiated from the one class, they can all keep track of their own data and methods.
See the illustration below:
I like this example:
class A:
foo = []
a, b = A(), A()
a.foo.append(5)
b.foo
ans: [5]
class A:
def __init__(self):
self.foo = []
a, b = A(), A()
a.foo.append(5)
b.foo
ans: []
I will demonstrate with code that does not use classes:
def state_init(state):
state['field'] = 'init'
def state_add(state, x):
state['field'] += x
def state_mult(state, x):
state['field'] *= x
def state_getField(state):
return state['field']
myself = {}
state_init(myself)
state_add(myself, 'added')
state_mult(myself, 2)
print( state_getField(myself) )
#--> 'initaddedinitadded'
Classes are just a way to avoid passing in this "state" thing all the time (and other nice things like initializing, class composition, the rarely-needed metaclasses, and supporting custom methods to override operators).
Now let's demonstrate the above code using the built-in python class machinery, to show how it's basically the same thing.
class State(object):
def __init__(self):
self.field = 'init'
def add(self, x):
self.field += x
def mult(self, x):
self.field *= x
s = State()
s.add('added') # self is implicitly passed in
s.mult(2) # self is implicitly passed in
print( s.field )
[migrated my answer from duplicate closed question]
The following excerpts are from the Python documentation about self:
As in Modula-3, there are no shorthands [in Python] for referencing the object’s members from its methods: the method function is declared with an explicit first argument representing the object, which is provided implicitly by the call.
Often, the first argument of a method is called self. This is nothing more than a convention: the name self has absolutely no special meaning to Python. Note, however, that by not following the convention your code may be less readable to other Python programmers, and it is also conceivable that a class browser program might be written that relies upon such a convention.
For more information, see the Python documentation tutorial on classes.
As well as all the other reasons already stated, it allows for easier access to overridden methods; you can call Class.some_method(inst).
An example of where it’s useful:
class C1(object):
def __init__(self):
print "C1 init"
class C2(C1):
def __init__(self): #overrides C1.__init__
print "C2 init"
C1.__init__(self) #but we still want C1 to init the class too
>>> C2()
"C2 init"
"C1 init"
Its use is similar to the use of this keyword in Java, i.e. to give a reference to the current object.
Python is not a language built for Object Oriented Programming unlike Java or C++.
When calling a static method in Python, one simply writes a method with regular arguments inside it.
class Animal():
def staticMethod():
print "This is a static method"
However, an object method, which requires you to make a variable, which is an Animal, in this case, needs the self argument
class Animal():
def objectMethod(self):
print "This is an object method which needs an instance of a class"
The self method is also used to refer to a variable field within the class.
class Animal():
#animalName made in constructor
def Animal(self):
self.animalName = "";
def getAnimalName(self):
return self.animalName
In this case, self is referring to the animalName variable of the entire class. REMEMBER: If you have a variable within a method, self will not work. That variable is simply existent only while that method is running. For defining fields (the variables of the entire class), you have to define them OUTSIDE the class methods.
If you don't understand a single word of what I am saying, then Google "Object Oriented Programming." Once you understand this, you won't even need to ask that question :).
First of all, self is a conventional name, you could put anything else (being coherent) in its stead.
It refers to the object itself, so when you are using it, you are declaring that .name and .age are properties of the Student objects (note, not of the Student class) you are going to create.
class Student:
#called each time you create a new Student instance
def __init__(self,name,age): #special method to initialize
self.name=name
self.age=age
def __str__(self): #special method called for example when you use print
return "Student %s is %s years old" %(self.name,self.age)
def call(self, msg): #silly example for custom method
return ("Hey, %s! "+msg) %self.name
#initializing two instances of the student class
bob=Student("Bob",20)
alice=Student("Alice",19)
#using them
print bob.name
print bob.age
print alice #this one only works if you define the __str__ method
print alice.call("Come here!") #notice you don't put a value for self
#you can modify attributes, like when alice ages
alice.age=20
print alice
Code is here
self is an object reference to the object itself, therefore, they are same.
Python methods are not called in the context of the object itself.
self in Python may be used to deal with custom object models or something.
It’s there to follow the Python zen “explicit is better than implicit”. It’s indeed a reference to your class object. In Java and PHP, for example, it's called this.
If user_type_name is a field on your model you access it by self.user_type_name.
I'm surprised nobody has brought up Lua. Lua also uses the 'self' variable however it can be omitted but still used. C++ does the same with 'this'. I don't see any reason to have to declare 'self' in each function but you should still be able to use it just like you can with lua and C++. For a language that prides itself on being brief it's odd that it requires you to declare the self variable.
The use of the argument, conventionally called self isn't as hard to understand, as is why is it necessary? Or as to why explicitly mention it? That, I suppose, is a bigger question for most users who look up this question, or if it is not, they will certainly have the same question as they move forward learning python. I recommend them to read these couple of blogs:
1: Use of self explained
Note that it is not a keyword.
The first argument of every class method, including init, is always a reference to the current instance of the class. By convention, this argument is always named self. In the init method, self refers to the newly created object; in other class methods, it refers to the instance whose method was called. For example the below code is the same as the above code.
2: Why do we have it this way and why can we not eliminate it as an argument, like Java, and have a keyword instead
Another thing I would like to add is, an optional self argument allows me to declare static methods inside a class, by not writing self.
Code examples:
class MyClass():
def staticMethod():
print "This is a static method"
def objectMethod(self):
print "This is an object method which needs an instance of a class, and that is what self refers to"
PS:This works only in Python 3.x.
In previous versions, you have to explicitly add #staticmethod decorator, otherwise self argument is obligatory.
Take a look at the following example, which clearly explains the purpose of self
class Restaurant(object):
bankrupt = False
def open_branch(self):
if not self.bankrupt:
print("branch opened")
#create instance1
>>> x = Restaurant()
>>> x.bankrupt
False
#create instance2
>>> y = Restaurant()
>>> y.bankrupt = True
>>> y.bankrupt
True
>>> x.bankrupt
False
self is used/needed to distinguish between instances.
Source: self variable in python explained - Pythontips
Is because by the way python is designed the alternatives would hardly work. Python is designed to allow methods or functions to be defined in a context where both implicit this (a-la Java/C++) or explicit # (a-la ruby) wouldn't work. Let's have an example with the explicit approach with python conventions:
def fubar(x):
self.x = x
class C:
frob = fubar
Now the fubar function wouldn't work since it would assume that self is a global variable (and in frob as well). The alternative would be to execute method's with a replaced global scope (where self is the object).
The implicit approach would be
def fubar(x)
myX = x
class C:
frob = fubar
This would mean that myX would be interpreted as a local variable in fubar (and in frob as well). The alternative here would be to execute methods with a replaced local scope which is retained between calls, but that would remove the posibility of method local variables.
However the current situation works out well:
def fubar(self, x)
self.x = x
class C:
frob = fubar
here when called as a method frob will receive the object on which it's called via the self parameter, and fubar can still be called with an object as parameter and work the same (it is the same as C.frob I think).
In the __init__ method, self refers to the newly created object; in other class methods, it refers to the instance whose method was called.
self, as a name, is just a convention, call it as you want ! but when using it, for example to delete the object, you have to use the same name: __del__(var), where var was used in the __init__(var,[...])
You should take a look at cls too, to have the bigger picture. This post could be helpful.
self is acting as like current object name or instance of class .
# Self explanation.
class classname(object):
def __init__(self,name):
self.name=name
# Self is acting as a replacement of object name.
#self.name=object1.name
def display(self):
print("Name of the person is :",self.name)
print("object name:",object1.name)
object1=classname("Bucky")
object2=classname("ford")
object1.display()
object2.display()
###### Output
Name of the person is : Bucky
object name: Bucky
Name of the person is : ford
object name: Bucky
"self" keyword holds the reference of class and it is upto you if you want to use it or not but if you notice, whenever you create a new method in python, python automatically write self keyword for you. If you do some R&D, you will notice that if you create say two methods in a class and try to call one inside another, it does not recognize method unless you add self (reference of class).
class testA:
def __init__(self):
print('ads')
def m1(self):
print('method 1')
self.m2()
def m2(self):
print('method 2')
Below code throws unresolvable reference error.
class testA:
def __init__(self):
print('ads')
def m1(self):
print('method 1')
m2() #throws unresolvable reference error as class does not know if m2 exist in class scope
def m2(self):
print('method 2')
Now let see below example
class testA:
def __init__(self):
print('ads')
def m1(self):
print('method 1')
def m2():
print('method 2')
Now when you create object of class testA, you can call method m1() using class object like this as method m1() has included self keyword
obj = testA()
obj.m1()
But if you want to call method m2(), because is has no self reference so you can call m2() directly using class name like below
testA.m2()
But keep in practice to live with self keyword as there are other benefits too of it like creating global variable inside and so on.
self is inevitable.
There was just a question should self be implicit or explicit.
Guido van Rossum resolved this question saying self has to stay.
So where the self live?
If we would just stick to functional programming we would not need self.
Once we enter the Python OOP we find self there.
Here is the typical use case class C with the method m1
class C:
def m1(self, arg):
print(self, ' inside')
pass
ci =C()
print(ci, ' outside')
ci.m1(None)
print(hex(id(ci))) # hex memory address
This program will output:
<__main__.C object at 0x000002B9D79C6CC0> outside
<__main__.C object at 0x000002B9D79C6CC0> inside
0x2b9d79c6cc0
So self holds the memory address of the class instance.
The purpose of self would be to hold the reference for instance methods and for us to have explicit access to that reference.
Note there are three different types of class methods:
static methods (read: functions),
class methods,
instance methods (mentioned).
The word 'self' refers to instance of a class
class foo:
def __init__(self, num1, num2):
self.n1 = num1 #now in this it will make the perimeter num1 and num2 access across the whole class
self.n2 = num2
def add(self):
return self.n1 + self.n2 # if we had not written self then if would throw an error that n1 and n2 is not defined and we have to include self in the function's perimeter to access it's variables
it's an explicit reference to the class instance object.
from the docs,
the special thing about methods is that the instance object is passed as the first argument of the function. In our example, the call x.f() is exactly equivalent to MyClass.f(x). In general, calling a method with a list of n arguments is equivalent to calling the corresponding function with an argument list that is created by inserting the method’s instance object before the first argument.
preceding this the related snippet,
class MyClass:
"""A simple example class"""
i = 12345
def f(self):
return 'hello world'
x = MyClass()
I would say for Python at least, the self parameter can be thought of as a placeholder.
Take a look at this:
class Person:
def __init__(self, name, age):
self.name = name
self.age = age
p1 = Person("John", 36)
print(p1.name)
print(p1.age)
Self in this case and a lot of others was used as a method to say store the name value. However, after that, we use the p1 to assign it to the class we're using. Then when we print it we use the same p1 keyword.
Hope this helps for Python!
my little 2 cents
In this class Person, we defined out init method with the self and interesting thing to notice here is the memory location of both the self and instance variable p is same <__main__.Person object at 0x106a78fd0>
class Person:
def __init__(self, name, age):
self.name = name
self.age = age
def say_hi(self):
print("the self is at:", self)
print((f"hey there, my name is {self.name} and I am {self.age} years old"))
def say_bye(self):
print("the self is at:", self)
print(f"good to see you {self.name}")
p = Person("john", 78)
print("the p is at",p)
p.say_hi()
p.say_bye()
so as explained in above, both self and instance variable are same object.

What does self do in this Distribution class? [duplicate]

Consider this example:
class MyClass:
def func(self, name):
self.name = name
I know that self refers to the specific instance of MyClass. But why must func explicitly include self as a parameter? Why do we need to use self in the method's code? Some other languages make this implicit, or use special syntax instead.
For a language-agnostic consideration of the design decision, see What is the advantage of having this/self pointer mandatory explicit?.
To close debugging questions where OP omitted a self parameter for a method and got a TypeError, use TypeError: method() takes 1 positional argument but 2 were given instead. If OP omitted self. in the body of the method and got a NameError, consider How can I call a function within a class?.
The reason you need to use self. is because Python does not use special syntax to refer to instance attributes. Python decided to do methods in a way that makes the instance to which the method belongs be passed automatically, but not received automatically: the first parameter of methods is the instance the method is called on. That makes methods entirely the same as functions, and leaves the actual name to use up to you (although self is the convention, and people will generally frown at you when you use something else.) self is not special to the code, it's just another object.
Python could have done something else to distinguish normal names from attributes -- special syntax like Ruby has, or requiring declarations like C++ and Java do, or perhaps something yet more different -- but it didn't. Python's all for making things explicit, making it obvious what's what, and although it doesn't do it entirely everywhere, it does do it for instance attributes. That's why assigning to an instance attribute needs to know what instance to assign to, and that's why it needs self..
Let's say you have a class ClassA which contains a method methodA defined as:
def methodA(self, arg1, arg2):
# do something
and objectA is an instance of this class.
Now when objectA.methodA(arg1, arg2) is called, python internally converts it for you as:
ClassA.methodA(objectA, arg1, arg2)
The self variable refers to the object itself.
Let’s take a simple vector class:
class Vector:
def __init__(self, x, y):
self.x = x
self.y = y
We want to have a method which calculates the length. What would it look like if we wanted to define it inside the class?
def length(self):
return math.sqrt(self.x ** 2 + self.y ** 2)
What should it look like when we were to define it as a global method/function?
def length_global(vector):
return math.sqrt(vector.x ** 2 + vector.y ** 2)
So the whole structure stays the same. How can me make use of this? If we assume for a moment that we hadn’t written a length method for our Vector class, we could do this:
Vector.length_new = length_global
v = Vector(3, 4)
print(v.length_new()) # 5.0
This works because the first parameter of length_global, can be re-used as the self parameter in length_new. This would not be possible without an explicit self.
Another way of understanding the need for the explicit self is to see where Python adds some syntactical sugar. When you keep in mind, that basically, a call like
v_instance.length()
is internally transformed to
Vector.length(v_instance)
it is easy to see where the self fits in. You don't actually write instance methods in Python; what you write is class methods which must take an instance as a first parameter. And therefore, you’ll have to place the instance parameter somewhere explicitly.
When objects are instantiated, the object itself is passed into the self parameter.
Because of this, the object’s data is bound to the object. Below is an example of how you might like to visualize what each object’s data might look. Notice how ‘self’ is replaced with the objects name. I'm not saying this example diagram below is wholly accurate but it hopefully with serve a purpose in visualizing the use of self.
The Object is passed into the self parameter so that the object can keep hold of its own data.
Although this may not be wholly accurate, think of the process of instantiating an object like this: When an object is made it uses the class as a template for its own data and methods. Without passing it's own name into the self parameter, the attributes and methods in the class would remain as a general template and would not be referenced to (belong to) the object. So by passing the object's name into the self parameter it means that if 100 objects are instantiated from the one class, they can all keep track of their own data and methods.
See the illustration below:
I like this example:
class A:
foo = []
a, b = A(), A()
a.foo.append(5)
b.foo
ans: [5]
class A:
def __init__(self):
self.foo = []
a, b = A(), A()
a.foo.append(5)
b.foo
ans: []
I will demonstrate with code that does not use classes:
def state_init(state):
state['field'] = 'init'
def state_add(state, x):
state['field'] += x
def state_mult(state, x):
state['field'] *= x
def state_getField(state):
return state['field']
myself = {}
state_init(myself)
state_add(myself, 'added')
state_mult(myself, 2)
print( state_getField(myself) )
#--> 'initaddedinitadded'
Classes are just a way to avoid passing in this "state" thing all the time (and other nice things like initializing, class composition, the rarely-needed metaclasses, and supporting custom methods to override operators).
Now let's demonstrate the above code using the built-in python class machinery, to show how it's basically the same thing.
class State(object):
def __init__(self):
self.field = 'init'
def add(self, x):
self.field += x
def mult(self, x):
self.field *= x
s = State()
s.add('added') # self is implicitly passed in
s.mult(2) # self is implicitly passed in
print( s.field )
[migrated my answer from duplicate closed question]
The following excerpts are from the Python documentation about self:
As in Modula-3, there are no shorthands [in Python] for referencing the object’s members from its methods: the method function is declared with an explicit first argument representing the object, which is provided implicitly by the call.
Often, the first argument of a method is called self. This is nothing more than a convention: the name self has absolutely no special meaning to Python. Note, however, that by not following the convention your code may be less readable to other Python programmers, and it is also conceivable that a class browser program might be written that relies upon such a convention.
For more information, see the Python documentation tutorial on classes.
As well as all the other reasons already stated, it allows for easier access to overridden methods; you can call Class.some_method(inst).
An example of where it’s useful:
class C1(object):
def __init__(self):
print "C1 init"
class C2(C1):
def __init__(self): #overrides C1.__init__
print "C2 init"
C1.__init__(self) #but we still want C1 to init the class too
>>> C2()
"C2 init"
"C1 init"
Its use is similar to the use of this keyword in Java, i.e. to give a reference to the current object.
Python is not a language built for Object Oriented Programming unlike Java or C++.
When calling a static method in Python, one simply writes a method with regular arguments inside it.
class Animal():
def staticMethod():
print "This is a static method"
However, an object method, which requires you to make a variable, which is an Animal, in this case, needs the self argument
class Animal():
def objectMethod(self):
print "This is an object method which needs an instance of a class"
The self method is also used to refer to a variable field within the class.
class Animal():
#animalName made in constructor
def Animal(self):
self.animalName = "";
def getAnimalName(self):
return self.animalName
In this case, self is referring to the animalName variable of the entire class. REMEMBER: If you have a variable within a method, self will not work. That variable is simply existent only while that method is running. For defining fields (the variables of the entire class), you have to define them OUTSIDE the class methods.
If you don't understand a single word of what I am saying, then Google "Object Oriented Programming." Once you understand this, you won't even need to ask that question :).
First of all, self is a conventional name, you could put anything else (being coherent) in its stead.
It refers to the object itself, so when you are using it, you are declaring that .name and .age are properties of the Student objects (note, not of the Student class) you are going to create.
class Student:
#called each time you create a new Student instance
def __init__(self,name,age): #special method to initialize
self.name=name
self.age=age
def __str__(self): #special method called for example when you use print
return "Student %s is %s years old" %(self.name,self.age)
def call(self, msg): #silly example for custom method
return ("Hey, %s! "+msg) %self.name
#initializing two instances of the student class
bob=Student("Bob",20)
alice=Student("Alice",19)
#using them
print bob.name
print bob.age
print alice #this one only works if you define the __str__ method
print alice.call("Come here!") #notice you don't put a value for self
#you can modify attributes, like when alice ages
alice.age=20
print alice
Code is here
self is an object reference to the object itself, therefore, they are same.
Python methods are not called in the context of the object itself.
self in Python may be used to deal with custom object models or something.
It’s there to follow the Python zen “explicit is better than implicit”. It’s indeed a reference to your class object. In Java and PHP, for example, it's called this.
If user_type_name is a field on your model you access it by self.user_type_name.
I'm surprised nobody has brought up Lua. Lua also uses the 'self' variable however it can be omitted but still used. C++ does the same with 'this'. I don't see any reason to have to declare 'self' in each function but you should still be able to use it just like you can with lua and C++. For a language that prides itself on being brief it's odd that it requires you to declare the self variable.
The use of the argument, conventionally called self isn't as hard to understand, as is why is it necessary? Or as to why explicitly mention it? That, I suppose, is a bigger question for most users who look up this question, or if it is not, they will certainly have the same question as they move forward learning python. I recommend them to read these couple of blogs:
1: Use of self explained
Note that it is not a keyword.
The first argument of every class method, including init, is always a reference to the current instance of the class. By convention, this argument is always named self. In the init method, self refers to the newly created object; in other class methods, it refers to the instance whose method was called. For example the below code is the same as the above code.
2: Why do we have it this way and why can we not eliminate it as an argument, like Java, and have a keyword instead
Another thing I would like to add is, an optional self argument allows me to declare static methods inside a class, by not writing self.
Code examples:
class MyClass():
def staticMethod():
print "This is a static method"
def objectMethod(self):
print "This is an object method which needs an instance of a class, and that is what self refers to"
PS:This works only in Python 3.x.
In previous versions, you have to explicitly add #staticmethod decorator, otherwise self argument is obligatory.
Take a look at the following example, which clearly explains the purpose of self
class Restaurant(object):
bankrupt = False
def open_branch(self):
if not self.bankrupt:
print("branch opened")
#create instance1
>>> x = Restaurant()
>>> x.bankrupt
False
#create instance2
>>> y = Restaurant()
>>> y.bankrupt = True
>>> y.bankrupt
True
>>> x.bankrupt
False
self is used/needed to distinguish between instances.
Source: self variable in python explained - Pythontips
Is because by the way python is designed the alternatives would hardly work. Python is designed to allow methods or functions to be defined in a context where both implicit this (a-la Java/C++) or explicit # (a-la ruby) wouldn't work. Let's have an example with the explicit approach with python conventions:
def fubar(x):
self.x = x
class C:
frob = fubar
Now the fubar function wouldn't work since it would assume that self is a global variable (and in frob as well). The alternative would be to execute method's with a replaced global scope (where self is the object).
The implicit approach would be
def fubar(x)
myX = x
class C:
frob = fubar
This would mean that myX would be interpreted as a local variable in fubar (and in frob as well). The alternative here would be to execute methods with a replaced local scope which is retained between calls, but that would remove the posibility of method local variables.
However the current situation works out well:
def fubar(self, x)
self.x = x
class C:
frob = fubar
here when called as a method frob will receive the object on which it's called via the self parameter, and fubar can still be called with an object as parameter and work the same (it is the same as C.frob I think).
In the __init__ method, self refers to the newly created object; in other class methods, it refers to the instance whose method was called.
self, as a name, is just a convention, call it as you want ! but when using it, for example to delete the object, you have to use the same name: __del__(var), where var was used in the __init__(var,[...])
You should take a look at cls too, to have the bigger picture. This post could be helpful.
self is acting as like current object name or instance of class .
# Self explanation.
class classname(object):
def __init__(self,name):
self.name=name
# Self is acting as a replacement of object name.
#self.name=object1.name
def display(self):
print("Name of the person is :",self.name)
print("object name:",object1.name)
object1=classname("Bucky")
object2=classname("ford")
object1.display()
object2.display()
###### Output
Name of the person is : Bucky
object name: Bucky
Name of the person is : ford
object name: Bucky
"self" keyword holds the reference of class and it is upto you if you want to use it or not but if you notice, whenever you create a new method in python, python automatically write self keyword for you. If you do some R&D, you will notice that if you create say two methods in a class and try to call one inside another, it does not recognize method unless you add self (reference of class).
class testA:
def __init__(self):
print('ads')
def m1(self):
print('method 1')
self.m2()
def m2(self):
print('method 2')
Below code throws unresolvable reference error.
class testA:
def __init__(self):
print('ads')
def m1(self):
print('method 1')
m2() #throws unresolvable reference error as class does not know if m2 exist in class scope
def m2(self):
print('method 2')
Now let see below example
class testA:
def __init__(self):
print('ads')
def m1(self):
print('method 1')
def m2():
print('method 2')
Now when you create object of class testA, you can call method m1() using class object like this as method m1() has included self keyword
obj = testA()
obj.m1()
But if you want to call method m2(), because is has no self reference so you can call m2() directly using class name like below
testA.m2()
But keep in practice to live with self keyword as there are other benefits too of it like creating global variable inside and so on.
self is inevitable.
There was just a question should self be implicit or explicit.
Guido van Rossum resolved this question saying self has to stay.
So where the self live?
If we would just stick to functional programming we would not need self.
Once we enter the Python OOP we find self there.
Here is the typical use case class C with the method m1
class C:
def m1(self, arg):
print(self, ' inside')
pass
ci =C()
print(ci, ' outside')
ci.m1(None)
print(hex(id(ci))) # hex memory address
This program will output:
<__main__.C object at 0x000002B9D79C6CC0> outside
<__main__.C object at 0x000002B9D79C6CC0> inside
0x2b9d79c6cc0
So self holds the memory address of the class instance.
The purpose of self would be to hold the reference for instance methods and for us to have explicit access to that reference.
Note there are three different types of class methods:
static methods (read: functions),
class methods,
instance methods (mentioned).
The word 'self' refers to instance of a class
class foo:
def __init__(self, num1, num2):
self.n1 = num1 #now in this it will make the perimeter num1 and num2 access across the whole class
self.n2 = num2
def add(self):
return self.n1 + self.n2 # if we had not written self then if would throw an error that n1 and n2 is not defined and we have to include self in the function's perimeter to access it's variables
it's an explicit reference to the class instance object.
from the docs,
the special thing about methods is that the instance object is passed as the first argument of the function. In our example, the call x.f() is exactly equivalent to MyClass.f(x). In general, calling a method with a list of n arguments is equivalent to calling the corresponding function with an argument list that is created by inserting the method’s instance object before the first argument.
preceding this the related snippet,
class MyClass:
"""A simple example class"""
i = 12345
def f(self):
return 'hello world'
x = MyClass()
I would say for Python at least, the self parameter can be thought of as a placeholder.
Take a look at this:
class Person:
def __init__(self, name, age):
self.name = name
self.age = age
p1 = Person("John", 36)
print(p1.name)
print(p1.age)
Self in this case and a lot of others was used as a method to say store the name value. However, after that, we use the p1 to assign it to the class we're using. Then when we print it we use the same p1 keyword.
Hope this helps for Python!
my little 2 cents
In this class Person, we defined out init method with the self and interesting thing to notice here is the memory location of both the self and instance variable p is same <__main__.Person object at 0x106a78fd0>
class Person:
def __init__(self, name, age):
self.name = name
self.age = age
def say_hi(self):
print("the self is at:", self)
print((f"hey there, my name is {self.name} and I am {self.age} years old"))
def say_bye(self):
print("the self is at:", self)
print(f"good to see you {self.name}")
p = Person("john", 78)
print("the p is at",p)
p.say_hi()
p.say_bye()
so as explained in above, both self and instance variable are same object.

what is the difference instance method and #classmethod and #staticmethod in python? [duplicate]

What is the difference between a method decorated with #staticmethod and one decorated with #classmethod?
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(f"executing foo({self}, {x})")
#classmethod
def class_foo(cls, x):
print(f"executing class_foo({cls}, {x})")
#staticmethod
def static_foo(x):
print(f"executing static_foo({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>
And of course the same thing happens when you call static_foo with the class A instead.
print(A.static_foo)
# <function static_foo at 0xb7d479cc>
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
>>>
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.
To decide whether to use #staticmethod or #classmethod you have to look inside your method. If your method accesses other variables/methods in your class then use #classmethod. On the other hand, if your method does not touches any other parts of the class then use #staticmethod.
class Apple:
_counter = 0
#staticmethod
def about_apple():
print('Apple is good for you.')
# note you can still access other member of the class
# but you have to use the class instance
# which is not very nice, because you have repeat yourself
#
# For example:
# #staticmethod
# print('Number of apples have been juiced: %s' % Apple._counter)
#
# #classmethod
# print('Number of apples have been juiced: %s' % cls._counter)
#
# #classmethod is especially useful when you move your function to another class,
# you don't have to rename the referenced class
#classmethod
def make_apple_juice(cls, number_of_apples):
print('Making juice:')
for i in range(number_of_apples):
cls._juice_this(i)
#classmethod
def _juice_this(cls, apple):
print('Juicing apple %d...' % apple)
cls._counter += 1
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.
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).
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_instance_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 Instance Method
First I'll explain a_normal_instance_method. This is precisely 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'
Bound methods
Instance methods can be bound via a dotted lookup for use later.
For example, this binds the str.join method to the ':' instance:
>>> join_with_colons = ':'.join
And later we can use this as a function that already has the first argument bound to it. In this way, it works like a partial function on the instance:
>>> join_with_colons('abcde')
'a:b:c:d:e'
>>> join_with_colons(['FF', 'FF', 'FF', 'FF', 'FF', 'FF'])
'FF:FF:FF:FF:FF:FF'
Static Method
The static method does not take the instance as an argument.
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 of a static method is str.maketrans, 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 less useful string module:
>>> import string
>>> 'ABCDEFG'.translate(string.maketrans('ABC', 'abc'))
'abcDEFG'
Class Method
A class method is a similar to an instance 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, use to demo 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.
I started learning programming language with C++ and then Java and then Python and so this question bothered me a lot as well, until I understood the simple usage of each.
Class Method: Python unlike Java and C++ doesn't have constructor overloading. And so to achieve this you could use classmethod. Following example will explain this
Let's consider we have a Person class which takes two arguments first_name and last_name and creates the instance of Person.
class Person(object):
def __init__(self, first_name, last_name):
self.first_name = first_name
self.last_name = last_name
Now, if the requirement comes where you need to create a class using a single name only, just a first_name, you can't do something like this in Python.
This will give you an error when you will try to create an object (instance).
class Person(object):
def __init__(self, first_name, last_name):
self.first_name = first_name
self.last_name = last_name
def __init__(self, first_name):
self.first_name = first_name
However, you could achieve the same thing using #classmethod as mentioned below
class Person(object):
def __init__(self, first_name, last_name):
self.first_name = first_name
self.last_name = last_name
#classmethod
def get_person(cls, first_name):
return cls(first_name, "")
Static Method: This is rather simple, it's not bound to instance or class and you can simply call that using class name.
So let's say in above example you need a validation that first_name should not exceed 20 characters, you can simply do this.
#staticmethod
def validate_name(name):
return len(name) <= 20
and you could simply call using class name
Person.validate_name("Gaurang Shah")
Only the first argument differs:
normal method: the current object is automatically passed as an (additional) first argument
classmethod: the class of the current object is automatically passed as an (additional) fist argument
staticmethod: no extra arguments are automatically passed. What you passed to the function is what you get.
In more detail...
normal method
The "standard" method, as in every object oriented language. When an object's method is called, it is automatically given an extra argument self as its first argument. That is, method
def f(self, x, y)
must be called with 2 arguments. self is automatically passed, and it is the object itself. Similar to the this that magically appears in eg. java/c++, only in python it is shown explicitly.
actually, the first argument does not have to be called self, but it's the standard convention, so keep it
class method
When the method is decorated
#classmethod
def f(cls, x, y)
the automatically provided argument is not self, but the class of self.
static method
When the method is decorated
#staticmethod
def f(x, y)
the method is not given any automatic argument at all. It is only given the parameters that it is called with.
usages
classmethod is mostly used for alternative constructors.
staticmethod does not use the state of the object, or even the structure of the class itself. It could be a function external to a class. It only put inside the class for grouping functions with similar functionality (for example, like Java's Math class static methods)
class Point
def __init__(self, x, y):
self.x = x
self.y = y
#classmethod
def frompolar(cls, radius, angle):
"""The `cls` argument is the `Point` class itself"""
return cls(radius * cos(angle), radius * sin(angle))
#staticmethod
def angle(x, y):
"""this could be outside the class, but we put it here
just because we think it is logically related to the class."""
return atan(y, x)
p1 = Point(3, 2)
p2 = Point.frompolar(3, pi/4)
angle = Point.angle(3, 2)
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.
Static Methods:
Simple functions with no self argument.
Work on class attributes; not on instance attributes.
Can be called through both class and instance.
The built-in function staticmethod()is used to create them.
Benefits of Static Methods:
It localizes the function name in the classscope
It moves the function code closer to where it is used
More convenient to import versus module-level functions since each method does not have to be specially imported
#staticmethod
def some_static_method(*args, **kwds):
pass
Class Methods:
Functions that have first argument as classname.
Can be called through both class and instance.
These are created with classmethod in-built function.
#classmethod
def some_class_method(cls, *args, **kwds):
pass
#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 for 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 cluster, so just checking the name of the class would not be enough.
Let me tell the similarity between a method decorated with #classmethod vs #staticmethod first.
Similarity: Both of them can be called on the Class itself, rather than just the instance of the class. So, both of them in a sense are Class's methods.
Difference: A classmethod will receive the class itself as the first argument, while a staticmethod does not.
So a static method is, in a sense, not bound to the Class itself and is just hanging in there just because it may have a related functionality.
>>> class Klaus:
#classmethod
def classmthd(*args):
return args
#staticmethod
def staticmthd(*args):
return args
# 1. Call classmethod without any arg
>>> Klaus.classmthd()
(__main__.Klaus,) # the class gets passed as the first argument
# 2. Call classmethod with 1 arg
>>> Klaus.classmthd('chumma')
(__main__.Klaus, 'chumma')
# 3. Call staticmethod without any arg
>>> Klaus.staticmthd()
()
# 4. Call staticmethod with 1 arg
>>> Klaus.staticmthd('chumma')
('chumma',)
#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'>
Another consideration with respect to staticmethod vs classmethod comes up with inheritance. Say you have the following class:
class Foo(object):
#staticmethod
def bar():
return "In Foo"
And you then want to override bar() in a child class:
class Foo2(Foo):
#staticmethod
def bar():
return "In Foo2"
This works, but note that now the bar() implementation in the child class (Foo2) can no longer take advantage of anything specific to that class. For example, say Foo2 had a method called magic() that you want to use in the Foo2 implementation of bar():
class Foo2(Foo):
#staticmethod
def bar():
return "In Foo2"
#staticmethod
def magic():
return "Something useful you'd like to use in bar, but now can't"
The workaround here would be to call Foo2.magic() in bar(), but then you're repeating yourself (if the name of Foo2 changes, you'll have to remember to update that bar() method).
To me, this is a slight violation of the open/closed principle, since a decision made in Foo is impacting your ability to refactor common code in a derived class (ie it's less open to extension). If bar() were a classmethod we'd be fine:
class Foo(object):
#classmethod
def bar(cls):
return "In Foo"
class Foo2(Foo):
#classmethod
def bar(cls):
return "In Foo2 " + cls.magic()
#classmethod
def magic(cls):
return "MAGIC"
print Foo2().bar()
Gives: In Foo2 MAGIC
Also: historical note: Guido Van Rossum (Python's creator) once referred to staticmethod's as "an accident": https://mail.python.org/pipermail/python-ideas/2012-May/014969.html
we all know how limited static methods are. (They're basically an accident -- back in the Python 2.2 days when I was inventing new-style classes and descriptors, I meant to implement class methods but at first I didn't understand them and accidentally implemented static methods first. Then it was too late to remove them and only provide class methods.
Also: https://mail.python.org/pipermail/python-ideas/2016-July/041189.html
Honestly, staticmethod was something of a mistake -- I was trying to do something like Java class methods but once it was released I found what was really needed was classmethod. But it was too late to get rid of staticmethod.
The definitive guide on how to use static, class or abstract methods in Python is one good link for this topic, and summary it as following.
#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.
Python does not have to instantiate a bound-method for object.
It eases the readability of the code, and it does not depend on the state of object itself;
#classmethod function also callable without instantiating the class, but its definition follows Sub class, not Parent class, via inheritance, can be overridden by subclass. That’s because the first argument for #classmethod function must always be cls (class).
Factory methods, that are used to create an instance for a class using for example some sort of pre-processing.
Static methods calling static methods: if you split a static methods in several static methods, you shouldn't hard-code the class name but use class methods
I will try to explain the basic difference using an example.
class A(object):
x = 0
def say_hi(self):
pass
#staticmethod
def say_hi_static():
pass
#classmethod
def say_hi_class(cls):
pass
def run_self(self):
self.x += 1
print self.x # outputs 1
self.say_hi()
self.say_hi_static()
self.say_hi_class()
#staticmethod
def run_static():
print A.x # outputs 0
# A.say_hi() # wrong
A.say_hi_static()
A.say_hi_class()
#classmethod
def run_class(cls):
print cls.x # outputs 0
# cls.say_hi() # wrong
cls.say_hi_static()
cls.say_hi_class()
1 - we can directly call static and classmethods without initializing
# A.run_self() # wrong
A.run_static()
A.run_class()
2- Static method cannot call self method but can call other static and classmethod
3- Static method belong to class and will not use object at all.
4- Class method are not bound to an object but to a class.
The difference occurs when there is inheritance.
Suppose that there are two classes-- Parent and Child. If one wants to use #staticmethod, print_name method should be written twice because the name of the class should be written in the print line.
class Parent:
_class_name = "Parent"
#staticmethod
def print_name():
print(Parent._class_name)
class Child(Parent):
_class_name = "Child"
#staticmethod
def print_name():
print(Child._class_name)
Parent.print_name()
Child.print_name()
However, for #classmethod, it is not required to write print_name method twice.
class Parent:
_class_name = "Parent"
#classmethod
def print_name(cls):
print(cls._class_name)
class Child(Parent):
_class_name = "Child"
Parent.print_name()
Child.print_name()
Python comes with several built-in decorators. The big three are:
#classmethod
#staticmethod
#property
First let's note that any function of a class can be called with instance of this class (after we initialized this class).
#classmethod is the way to call function not only as an instance of a class but also directly by the class itself as its first argument.
#staticmethod is 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 (so we don't need to use self in function definition).
Let's consider the following class:
class DecoratorTest(object):
def __init__(self):
pass
def doubler(self, x):
return x*2
#classmethod
def class_doubler(cls, x): # we need to use 'cls' instead of 'self'; 'cls' reference to the class instead of an instance of the class
return x*2
#staticmethod
def static_doubler(x): # no need adding 'self' here; static_doubler() could be just a function not inside the class
return x*2
Let's see how it works:
decor = DecoratorTest()
print(decor.doubler(5))
# 10
print(decor.class_doubler(5)) # a call with an instance of a class
# 10
print(DecoratorTest.class_doubler(5)) # a direct call by the class itself
# 10
# staticmethod could be called in the same way as classmethod.
print(decor.static_doubler(5)) # as an instance of the class
# 10
print(DecoratorTest.static_doubler(5)) # or as a direct call
# 10
Here you can see some use cases for those methods.
Bonus: you can read about #property decorator here
Instance Method:
+ Can modify object instance state
+ Can modify class state
Class Method:
- Can't modify object instance state
+ Can modify class state
Static Method:
- Can't modify object instance state
- Can't modify class state
class MyClass:
'''
Instance method has a mandatory first attribute self which represent the instance itself.
Instance method must be called by a instantiated instance.
'''
def method(self):
return 'instance method called', self
'''
Class method has a mandatory first attribute cls which represent the class itself.
Class method can be called by an instance or by the class directly.
Its most common using scenario is to define a factory method.
'''
#classmethod
def class_method(cls):
return 'class method called', cls
'''
Static method doesn’t have any attributes of instances or the class.
It also can be called by an instance or by the class directly.
Its most common using scenario is to define some helper or utility functions which are closely relative to the class.
'''
#staticmethod
def static_method():
return 'static method called'
obj = MyClass()
print(obj.method())
print(obj.class_method()) # MyClass.class_method()
print(obj.static_method()) # MyClass.static_method()
output:
('instance method called', <__main__.MyClass object at 0x100fb3940>)
('class method called', <class '__main__.MyClass'>)
static method called
The instance method we actually had access to the object instance , right so this was an instance off a my class object whereas with the class method we have access to the class itself. But not to any of the objects, because the class method doesn't really care about an object existing. However you can both call a class method and static method on an object instance. This is going to work it doesn't really make a difference, so again when you call static method here it's going to work and it's going to know which method you want to call.
The Static methods are used to do some utility tasks, and class methods are used for factory methods. The factory methods can return class objects for different use cases.
And finally, a short example for better understanding:
class Student:
def __init__(self, first_name, last_name):
self.first_name = first_name
self.last_name = last_name
#classmethod
def get_from_string(cls, name_string: str):
first_name, last_name = name_string.split()
if Student.validate_name(first_name) and Student.validate_name(last_name):
return cls(first_name, last_name)
else:
print('Invalid Names')
#staticmethod
def validate_name(name):
return len(name) <= 10
stackoverflow_student = Student.get_from_string('Name Surname')
print(stackoverflow_student.first_name) # Name
print(stackoverflow_student.last_name) # Surname
#classmethod : can be used to create a shared global access to all the instances created of that class..... like updating a record by multiple users....
I particulary found it use ful when creating singletons as well..:)
#static method: has nothing to do with the class or instance being associated with ...but for readability can use static method
My contribution demonstrates the difference amongst #classmethod, #staticmethod, and instance methods, including how an instance can indirectly call a #staticmethod. But instead of indirectly calling a #staticmethod from an instance, making it private may be more "pythonic." Getting something from a private method isn't demonstrated here but it's basically the same concept.
#!python3
from os import system
system('cls')
# % % % % % % % % % % % % % % % % % % % %
class DemoClass(object):
# instance methods need a class instance and
# can access the instance through 'self'
def instance_method_1(self):
return 'called from inside the instance_method_1()'
def instance_method_2(self):
# an instance outside the class indirectly calls the static_method
return self.static_method() + ' via instance_method_2()'
# class methods don't need a class instance, they can't access the
# instance (self) but they have access to the class itself via 'cls'
#classmethod
def class_method(cls):
return 'called from inside the class_method()'
# static methods don't have access to 'cls' or 'self', they work like
# regular functions but belong to the class' namespace
#staticmethod
def static_method():
return 'called from inside the static_method()'
# % % % % % % % % % % % % % % % % % % % %
# works even if the class hasn't been instantiated
print(DemoClass.class_method() + '\n')
''' called from inside the class_method() '''
# works even if the class hasn't been instantiated
print(DemoClass.static_method() + '\n')
''' called from inside the static_method() '''
# % % % % % % % % % % % % % % % % % % % %
# >>>>> all methods types can be called on a class instance <<<<<
# instantiate the class
democlassObj = DemoClass()
# call instance_method_1()
print(democlassObj.instance_method_1() + '\n')
''' called from inside the instance_method_1() '''
# # indirectly call static_method through instance_method_2(), there's really no use
# for this since a #staticmethod can be called whether the class has been
# instantiated or not
print(democlassObj.instance_method_2() + '\n')
''' called from inside the static_method() via instance_method_2() '''
# call class_method()
print(democlassObj.class_method() + '\n')
''' called from inside the class_method() '''
# call static_method()
print(democlassObj.static_method())
''' called from inside the static_method() '''
"""
# whether the class is instantiated or not, this doesn't work
print(DemoClass.instance_method_1() + '\n')
'''
TypeError: TypeError: unbound method instancemethod() must be called with
DemoClass instance as first argument (got nothing instead)
'''
"""
A class method receives the class as implicit first argument, just like an instance method receives the instance. It is a method which is bound to the class and not the object of the class.It has access to the state of the class as it takes a class parameter that points to the class and not the object instance. It can modify a class state that would apply across all the instances of the class. For example it can modify a class variable that will be applicable to all the instances.
On the other hand, a static method does not receive an implicit first argument, compared to class methods or instance methods. And can’t access or modify class state. It only belongs to the class because from design point of view that is the correct way. But in terms of functionality is not bound, at runtime, to the class.
as a guideline, use static methods as utilities, use class methods for example as factory . Or maybe to define a singleton. And use instance methods to model the state and behavior of instances.
Hope I was clear !
You might want to consider the difference between:
class A:
def foo(): # no self parameter, no decorator
pass
and
class B:
#staticmethod
def foo(): # no self parameter
pass
This has changed between python2 and python3:
python2:
>>> A.foo()
TypeError
>>> A().foo()
TypeError
>>> B.foo()
>>> B().foo()
python3:
>>> A.foo()
>>> A().foo()
TypeError
>>> B.foo()
>>> B().foo()
So using #staticmethod for methods only called directly from the class has become optional in python3. If you want to call them from both class and instance, you still need to use the #staticmethod decorator.
The other cases have been well covered by unutbus answer.
Class methods, as the name suggests, are used to make changes to classes and not the objects. To make changes to classes, they will modify the class attributes(not object attributes), since that is how you update classes.
This is the reason that class methods take the class(conventionally denoted by 'cls') as the first argument.
class A(object):
m=54
#classmethod
def class_method(cls):
print "m is %d" % cls.m
Static methods on the other hand, are used to perform functionalities that are not bound to the class i.e. they will not read or write class variables. Hence, static methods do not take classes as arguments. They are used so that classes can perform functionalities that are not directly related to the purpose of the class.
class X(object):
m=54 #will not be referenced
#staticmethod
def static_method():
print "Referencing/calling a variable or function outside this class. E.g. Some global variable/function."
I think giving a purely Python version of staticmethod and classmethod would help to understand the difference between them at language level (Refers to Descriptor Howto Guide).
Both of them are non-data descriptors (It would be easier to understand them if you are familiar with descriptors first).
class StaticMethod(object):
"Emulate PyStaticMethod_Type() in Objects/funcobject.c"
def __init__(self, f):
self.f = f
def __get__(self, obj, objtype=None):
return self.f
class ClassMethod(object):
"Emulate PyClassMethod_Type() in Objects/funcobject.c"
def __init__(self, f):
self.f = f
def __get__(self, obj, cls=None):
def inner(*args, **kwargs):
if cls is None:
cls = type(obj)
return self.f(cls, *args, **kwargs)
return inner
Analyze #staticmethod literally providing different insights.
A normal method of a class is an implicit dynamic method which takes the instance as first argument.
In contrast, a staticmethod does not take the instance as first argument, so is called 'static'.
A staticmethod is indeed such a normal function the same as those outside a class definition.
It is luckily grouped into the class just in order to stand closer where it is applied, or you might scroll around to find it.
One pretty important practical difference occurs when subclassing. If you don't mind, I'll hijack #unutbu's example:
class A:
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)
class B(A):
pass
In class_foo, the method knows which class it is called on:
A.class_foo(1)
# => executing class_foo(<class '__main__.A'>, 1)
B.class_foo(1)
# => executing class_foo(<class '__main__.B'>, 1)
In static_foo, there is no way to determine whether it is called on A or B:
A.static_foo(1)
# => executing static_foo(1)
B.static_foo(1)
# => executing static_foo(1)
Note that this doesn't mean you can't use other methods in a staticmethod, you just have to reference the class directly, which means subclasses' staticmethods will still reference the parent class:
class A:
#classmethod
def class_qux(cls, x):
print(f"executing class_qux({cls}, {x})")
#classmethod
def class_bar(cls, x):
cls.class_qux(x)
#staticmethod
def static_bar(x):
A.class_qux(x)
class B(A):
pass
A.class_bar(1)
# => executing class_qux(<class '__main__.A'>, 1)
B.class_bar(1)
# => executing class_qux(<class '__main__.B'>, 1)
A.static_bar(1)
# => executing class_qux(<class '__main__.A'>, 1)
B.static_bar(1)
# => executing class_qux(<class '__main__.A'>, 1)
tldr;
A staticmethod is essentially a function bound to a class (and consequently its instances)
A classmethod is essentially an inheritable staticmethod.
For details, see the excellent answers by others.
First let's start with an example code that we'll use to understand both concepts:
class Employee:
NO_OF_EMPLOYEES = 0
def __init__(self, first_name, last_name, salary):
self.first_name = first_name
self.last_name = last_name
self.salary = salary
self.increment_employees()
def give_raise(self, amount):
self.salary += amount
#classmethod
def employee_from_full_name(cls, full_name, salary):
split_name = full_name.split(' ')
first_name = split_name[0]
last_name = split_name[1]
return cls(first_name, last_name, salary)
#classmethod
def increment_employees(cls):
cls.NO_OF_EMPLOYEES += 1
#staticmethod
def get_employee_legal_obligations_txt():
legal_obligations = """
1. An employee must complete 8 hours per working day
2. ...
"""
return legal_obligations
Class method
A class method accepts the class itself as an implicit argument and -optionally- any other arguments specified in the definition. It’s important to understand that a class method, does not have access to object instances (like instance methods do). Therefore, class methods cannot be used to alter the state of an instantiated object but instead, they are capable of changing the class state which is shared amongst all the instances of that class.
Class methods are typically useful when we need to access the class itself — for example, when we want to create a factory method, that is a method that creates instances of the class. In other words, class methods can serve as alternative constructors.
In our example code, an instance of Employee can be constructed by providing three arguments; first_name , last_name and salary.
employee_1 = Employee('Andrew', 'Brown', 85000)
print(employee_1.first_name)
print(employee_1.salary)
'Andrew'
85000
Now let’s assume that there’s a chance that the name of an Employee can be provided in a single field in which the first and last names are separated by a whitespace. In this case, we could possibly use our class method called employee_from_full_name that accepts three arguments in total. The first one, is the class itself, which is an implicit argument which means that it won’t be provided when calling the method — Python will automatically do this for us:
employee_2 = Employee.employee_from_full_name('John Black', 95000)
print(employee_2.first_name)
print(employee_2.salary)
'John'
95000
Note that it is also possible to call employee_from_full_name from object instances although in this context it doesn’t make a lot of sense:
employee_1 = Employee('Andrew', 'Brown', 85000)
employee_2 = employee_1.employee_from_full_name('John Black', 95000)
Another reason why we might want to create a class method, is when we need to change the state of the class. In our example, the class variable NO_OF_EMPLOYEES keeps track of the number of employees currently working for the company. This method is called every time a new instance of Employee is created and it updates the count accordingly:
employee_1 = Employee('Andrew', 'Brown', 85000)
print(f'Number of employees: {Employee.NO_OF_EMPLOYEES}')
employee_2 = Employee.employee_from_full_name('John Black', 95000)
print(f'Number of employees: {Employee.NO_OF_EMPLOYEES}')
Number of employees: 1
Number of employees: 2
Static methods
On the other hand, in static methods neither the instance (i.e. self) nor the class itself (i.e. cls) is passed as an implicit argument. This means that such methods, are not capable of accessing the class itself or its instances.
Now one could argue that static methods are not useful in the context of classes as they can also be placed in helper modules instead of adding them as members of the class. In object oriented programming, it is important to structure your classes into logical chunks and thus, static methods are quite useful when we need to add a method under a class simply because it logically belongs to the class.
In our example, the static method named get_employee_legal_obligations_txt simply returns a string that contains the legal obligations of every single employee of a company. This function, does not interact with the class itself nor with any instance. It could have been placed into a different helper module however, it is only relevant to this class and therefore we have to place it under the Employee class.
A static method can be access directly from the class itself
print(Employee.get_employee_legal_obligations_txt())
1. An employee must complete 8 hours per working day
2. ...
or from an instance of the class:
employee_1 = Employee('Andrew', 'Brown', 85000)
print(employee_1.get_employee_legal_obligations_txt())
1. An employee must complete 8 hours per working day
2. ...
References
What's the difference between static and class methods in Python?

Why is "self" in "__init__" method in python neccessary? [duplicate]

This question already has answers here:
What is the purpose of the `self` parameter? Why is it needed?
(26 answers)
Why do we use __init__ in Python classes?
(9 answers)
Closed 6 months ago.
I'm learning the Python programming language and I've came across something I don't fully understand.
In a method like:
def method(self, blah):
def __init__(?):
....
....
What does self do? What is it meant to be? Is it mandatory?
What does the __init__ method do? Why is it necessary? (etc.)
I think they might be OOP constructs, but I don't know very much.
In this code:
class A(object):
def __init__(self):
self.x = 'Hello'
def method_a(self, foo):
print self.x + ' ' + foo
... the self variable represents the instance of the object itself. Most object-oriented languages pass this as a hidden parameter to the methods defined on an object; Python does not. You have to declare it explicitly. When you create an instance of the A class and call its methods, it will be passed automatically, as in ...
a = A() # We do not pass any argument to the __init__ method
a.method_a('Sailor!') # We only pass a single argument
The __init__ method is roughly what represents a constructor in Python. When you call A() Python creates an object for you, and passes it as the first parameter to the __init__ method. Any additional parameters (e.g., A(24, 'Hello')) will also get passed as arguments--in this case causing an exception to be raised, since the constructor isn't expecting them.
Yep, you are right, these are oop constructs.
__init__ is the constructor for a class. The self parameter refers to the instance of the object (like this in C++).
class Point:
def __init__(self, x, y):
self._x = x
self._y = y
The __init__ method gets called after memory for the object is allocated:
x = Point(1,2)
It is important to use the self parameter inside an object's method if you want to persist the value with the object. If, for instance, you implement the __init__ method like this:
class Point:
def __init__(self, x, y):
_x = x
_y = y
Your x and y parameters would be stored in variables on the stack and would be discarded when the init method goes out of scope. Setting those variables as self._x and self._y sets those variables as members of the Point object (accessible for the lifetime of the object).
N.B. Some clarification of the use of the word "constructor" in this answer. Technically the responsibilities of a "constructor" are split over two methods in Python. Those methods are __new__ (responsible for allocating memory) and __init__ (as discussed here, responsible for initialising the newly created instance).
A brief illustrative example
In the hope it might help a little, here's a simple example I used to understand the difference between a variable declared inside a class, and a variable declared inside an __init__ function:
class MyClass(object):
i = 123
def __init__(self):
self.i = 345
a = MyClass()
print(a.i)
print(MyClass.i)
Output:
345
123
In short:
self as it suggests, refers to itself- the object which has called the method. That is, if you have N objects calling the method, then self.a will refer to a separate instance of the variable for each of the N objects. Imagine N copies of the variable a for each object
__init__ is what is called as a constructor in other OOP languages such as C++/Java. The basic idea is that it is a special method which is automatically called when an object of that Class is created
Class objects support two kinds of operations: attribute references and instantiation
Attribute references use the standard syntax used for all attribute references in Python: obj.name. Valid attribute names are all the names that were in the class’s namespace when the class object was created. So, if the class definition looked like this:
class MyClass:
"""A simple example class"""
i = 12345
def f(self):
return 'hello world'
then MyClass.i and MyClass.f are valid attribute references, returning an integer and a function object, respectively. Class attributes can also be assigned to, so you can change the value of MyClass.i by assignment. __doc__ is also a valid attribute, returning the docstring belonging to the class: "A simple example class".
Class instantiation uses function notation. Just pretend that the class object is a parameterless function that returns a new instance of the class. For example:
x = MyClass()
The instantiation operation (“calling” a class object) creates an empty object. Many classes like to create objects with instances customized to a specific initial state. Therefore a class may define a special method named __init__(), like this:
def __init__(self):
self.data = []
When a class defines an __init__() method, class instantiation automatically invokes __init__() for the newly-created class instance. So in this example, a new, initialized instance can be obtained by:
x = MyClass()
Of course, the __init__() method may have arguments for greater flexibility. In that case, arguments given to the class instantiation operator are passed on to __init__(). For example,
class Complex:
def __init__(self, realpart, imagpart):
self.r = realpart
self.i = imagpart
x = Complex(3.0, -4.5)
x.r, x.i
Taken from official documentation which helped me the most in the end.
Here is my example
class Bill():
def __init__(self,apples,figs,dates):
self.apples = apples
self.figs = figs
self.dates = dates
self.bill = apples + figs + dates
print ("Buy",self.apples,"apples", self.figs,"figs
and",self.dates,"dates.
Total fruitty bill is",self.bill," pieces of fruit :)")
When you create instance of class Bill:
purchase = Bill(5,6,7)
You get:
> Buy 5 apples 6 figs and 7 dates. Total fruitty bill is 18 pieces of
> fruit :)
__init__ does act like a constructor. You'll need to pass "self" to any class functions as the first argument if you want them to behave as non-static methods. "self" are instance variables for your class.
Try out this code. Hope it helps many C programmers like me to Learn Py.
#! /usr/bin/python2
class Person:
'''Doc - Inside Class '''
def __init__(self, name):
'''Doc - __init__ Constructor'''
self.n_name = name
def show(self, n1, n2):
'''Doc - Inside Show'''
print self.n_name
print 'Sum = ', (n1 + n2)
def __del__(self):
print 'Destructor Deleting object - ', self.n_name
p=Person('Jay')
p.show(2, 3)
print p.__doc__
print p.__init__.__doc__
print p.show.__doc__
Output:
Jay
Sum = 5
Doc - Inside Class
Doc - __init__ Constructor
Doc - Inside Show
Destructor Deleting object - Jay
Had trouble undestanding this myself. Even after reading the answers here.
To properly understand the __init__ method you need to understand self.
The self Parameter
The arguments accepted by the __init__ method are :
def __init__(self, arg1, arg2):
But we only actually pass it two arguments :
instance = OurClass('arg1', 'arg2')
Where has the extra argument come from ?
When we access attributes of an object we do it by name (or by reference). Here instance is a reference to our new object. We access the printargs method of the instance object using instance.printargs.
In order to access object attributes from within the __init__ method we need a reference to the object.
Whenever a method is called, a reference to the main object is passed as the first argument. By convention you always call this first argument to your methods self.
This means in the __init__ method we can do :
self.arg1 = arg1
self.arg2 = arg2
Here we are setting attributes on the object. You can verify this by doing the following :
instance = OurClass('arg1', 'arg2')
print instance.arg1
arg1
values like this are known as object attributes. Here the __init__ method sets the arg1 and arg2 attributes of the instance.
source: http://www.voidspace.org.uk/python/articles/OOP.shtml#the-init-method
note that self could actually be any valid python identifier. For example, we could just as easily write, from Chris B's example:
class A(object):
def __init__(foo):
foo.x = 'Hello'
def method_a(bar, foo):
print bar.x + ' ' + foo
and it would work exactly the same. It is however recommended to use self because other pythoners will recognize it more easily.
What does self do? What is it meant to be? Is it mandatory?
The first argument of every class method, including init, is always a reference to the current instance of the class. By convention, this argument is always named self. In the init method, self refers to the newly created object; in other class methods, it refers to the instance whose method was called.
Python doesn't force you on using "self". You can give it any name you want. But remember the first argument in a method definition is a reference to the object. Python adds the self argument to the list for you; you do not need to include it when you call the methods.
if you didn't provide self in init method then you will get an error
TypeError: __init___() takes no arguments (1 given)
What does the init method do? Why is it necessary? (etc.)
init is short for initialization. It is a constructor which gets called when you make an instance of the class and it is not necessary. But usually it our practice to write init method for setting default state of the object. If you are not willing to set any state of the object initially then you don't need to write this method.
__init__ is basically a function which will "initialize"/"activate" the properties of the class for a specific object, once created and matched to the corresponding class..
self represents that object which will inherit those properties.
Basically, you need to use the 'self' keyword when using a variable in multiple functions within the same class. As for init, it's used to setup default values incase no other functions from within that class are called.
The 'self' is a reference to the class instance
class foo:
def bar(self):
print "hi"
Now we can create an instance of foo and call the method on it, the self parameter is added by Python in this case:
f = foo()
f.bar()
But it can be passed in as well if the method call isn't in the context of an instance of the class, the code below does the same thing
f = foo()
foo.bar(f)
Interestingly the variable name 'self' is just a convention. The below definition will work exactly the same.. Having said that it is very strong convention which should be followed always, but it does say something about flexible nature of the language
class foo:
def bar(s):
print "hi"
Just a demo for the question.
class MyClass:
def __init__(self):
print('__init__ is the constructor for a class')
def __del__(self):
print('__del__ is the destructor for a class')
def __enter__(self):
print('__enter__ is for context manager')
return self
def __exit__(self, exc_type, exc_value, traceback):
print('__exit__ is for context manager')
def greeting(self):
print('hello python')
if __name__ == '__main__':
with MyClass() as mycls:
mycls.greeting()
$ python3 class.objects_instantiation.py
__init__ is the constructor for a class
__enter__ is for context manager
hello python
__exit__ is for context manager
__del__ is the destructor for a class
In this code:
class Cat:
def __init__(self, name):
self.name = name
def info(self):
print 'I am a cat and I am called', self.name
Here __init__ acts as a constructor for the class and when an object is instantiated, this function is called. self represents the instantiating object.
c = Cat('Kitty')
c.info()
The result of the above statements will be as follows:
I am a cat and I am called Kitty
# Source: Class and Instance Variables
# https://docs.python.org/2/tutorial/classes.html#class-and-instance-variables
class MyClass(object):
# class variable
my_CLS_var = 10
# sets "init'ial" state to objects/instances, use self argument
def __init__(self):
# self usage => instance variable (per object)
self.my_OBJ_var = 15
# also possible, class name is used => init class variable
MyClass.my_CLS_var = 20
def run_example_func():
# PRINTS 10 (class variable)
print MyClass.my_CLS_var
# executes __init__ for obj1 instance
# NOTE: __init__ changes class variable above
obj1 = MyClass()
# PRINTS 15 (instance variable)
print obj1.my_OBJ_var
# PRINTS 20 (class variable, changed value)
print MyClass.my_CLS_var
run_example_func()
Here, the guy has written pretty well and simple: https://www.jeffknupp.com/blog/2014/06/18/improve-your-python-python-classes-and-object-oriented-programming/
Read above link as a reference to this:
self? So what's with that self parameter to all of the Customer
methods? What is it? Why, it's the instance, of course! Put another
way, a method like withdraw defines the instructions for withdrawing
money from some abstract customer's account. Calling
jeff.withdraw(100.0) puts those instructions to use on the jeff
instance.
So when we say def withdraw(self, amount):, we're saying, "here's how
you withdraw money from a Customer object (which we'll call self) and
a dollar figure (which we'll call amount). self is the instance of the
Customer that withdraw is being called on. That's not me making
analogies, either. jeff.withdraw(100.0) is just shorthand for
Customer.withdraw(jeff, 100.0), which is perfectly valid (if not often
seen) code.
init self may make sense for other methods, but what about init? When we call init, we're in the process of creating an object, so how can there already be a self? Python allows us to extend
the self pattern to when objects are constructed as well, even though
it doesn't exactly fit. Just imagine that jeff = Customer('Jeff
Knupp', 1000.0) is the same as calling jeff = Customer(jeff, 'Jeff
Knupp', 1000.0); the jeff that's passed in is also made the result.
This is why when we call init, we initialize objects by saying
things like self.name = name. Remember, since self is the instance,
this is equivalent to saying jeff.name = name, which is the same as
jeff.name = 'Jeff Knupp. Similarly, self.balance = balance is the same
as jeff.balance = 1000.0. After these two lines, we consider the
Customer object "initialized" and ready for use.
Be careful what you __init__
After init has finished, the caller can rightly assume that the
object is ready to use. That is, after jeff = Customer('Jeff Knupp',
1000.0), we can start making deposit and withdraw calls on jeff; jeff is a fully-initialized object.
Python __init__ and self what do they do?
What does self do? What is it meant to be? Is it mandatory?
What does the __init__ method do? Why is it necessary? (etc.)
The example given is not correct, so let me create a correct example based on it:
class SomeObject(object):
def __init__(self, blah):
self.blah = blah
def method(self):
return self.blah
When we create an instance of the object, the __init__ is called to customize the object after it has been created. That is, when we call SomeObject with 'blah' below (which could be anything), it gets passed to the __init__ function as the argument, blah:
an_object = SomeObject('blah')
The self argument is the instance of SomeObject that will be assigned to an_object.
Later, we might want to call a method on this object:
an_object.method()
Doing the dotted lookup, that is, an_object.method, binds the instance to an instance of the function, and the method (as called above) is now a "bound" method - which means we do not need to explicitly pass the instance to the method call.
The method call gets the instance because it was bound on the dotted lookup, and when called, then executes whatever code it was programmed to perform.
The implicitly passed self argument is called self by convention. We could use any other legal Python name, but you will likely get tarred and feathered by other Python programmers if you change it to something else.
__init__ is a special method, documented in the Python datamodel documentation. It is called immediately after the instance is created (usually via __new__ - although __new__ is not required unless you are subclassing an immutable datatype).

What do __init__ and self do in Python? [duplicate]

This question already has answers here:
What is the purpose of the `self` parameter? Why is it needed?
(26 answers)
Why do we use __init__ in Python classes?
(9 answers)
Closed 6 months ago.
I'm learning the Python programming language and I've came across something I don't fully understand.
In a method like:
def method(self, blah):
def __init__(?):
....
....
What does self do? What is it meant to be? Is it mandatory?
What does the __init__ method do? Why is it necessary? (etc.)
I think they might be OOP constructs, but I don't know very much.
In this code:
class A(object):
def __init__(self):
self.x = 'Hello'
def method_a(self, foo):
print self.x + ' ' + foo
... the self variable represents the instance of the object itself. Most object-oriented languages pass this as a hidden parameter to the methods defined on an object; Python does not. You have to declare it explicitly. When you create an instance of the A class and call its methods, it will be passed automatically, as in ...
a = A() # We do not pass any argument to the __init__ method
a.method_a('Sailor!') # We only pass a single argument
The __init__ method is roughly what represents a constructor in Python. When you call A() Python creates an object for you, and passes it as the first parameter to the __init__ method. Any additional parameters (e.g., A(24, 'Hello')) will also get passed as arguments--in this case causing an exception to be raised, since the constructor isn't expecting them.
Yep, you are right, these are oop constructs.
__init__ is the constructor for a class. The self parameter refers to the instance of the object (like this in C++).
class Point:
def __init__(self, x, y):
self._x = x
self._y = y
The __init__ method gets called after memory for the object is allocated:
x = Point(1,2)
It is important to use the self parameter inside an object's method if you want to persist the value with the object. If, for instance, you implement the __init__ method like this:
class Point:
def __init__(self, x, y):
_x = x
_y = y
Your x and y parameters would be stored in variables on the stack and would be discarded when the init method goes out of scope. Setting those variables as self._x and self._y sets those variables as members of the Point object (accessible for the lifetime of the object).
N.B. Some clarification of the use of the word "constructor" in this answer. Technically the responsibilities of a "constructor" are split over two methods in Python. Those methods are __new__ (responsible for allocating memory) and __init__ (as discussed here, responsible for initialising the newly created instance).
A brief illustrative example
In the hope it might help a little, here's a simple example I used to understand the difference between a variable declared inside a class, and a variable declared inside an __init__ function:
class MyClass(object):
i = 123
def __init__(self):
self.i = 345
a = MyClass()
print(a.i)
print(MyClass.i)
Output:
345
123
In short:
self as it suggests, refers to itself- the object which has called the method. That is, if you have N objects calling the method, then self.a will refer to a separate instance of the variable for each of the N objects. Imagine N copies of the variable a for each object
__init__ is what is called as a constructor in other OOP languages such as C++/Java. The basic idea is that it is a special method which is automatically called when an object of that Class is created
Class objects support two kinds of operations: attribute references and instantiation
Attribute references use the standard syntax used for all attribute references in Python: obj.name. Valid attribute names are all the names that were in the class’s namespace when the class object was created. So, if the class definition looked like this:
class MyClass:
"""A simple example class"""
i = 12345
def f(self):
return 'hello world'
then MyClass.i and MyClass.f are valid attribute references, returning an integer and a function object, respectively. Class attributes can also be assigned to, so you can change the value of MyClass.i by assignment. __doc__ is also a valid attribute, returning the docstring belonging to the class: "A simple example class".
Class instantiation uses function notation. Just pretend that the class object is a parameterless function that returns a new instance of the class. For example:
x = MyClass()
The instantiation operation (“calling” a class object) creates an empty object. Many classes like to create objects with instances customized to a specific initial state. Therefore a class may define a special method named __init__(), like this:
def __init__(self):
self.data = []
When a class defines an __init__() method, class instantiation automatically invokes __init__() for the newly-created class instance. So in this example, a new, initialized instance can be obtained by:
x = MyClass()
Of course, the __init__() method may have arguments for greater flexibility. In that case, arguments given to the class instantiation operator are passed on to __init__(). For example,
class Complex:
def __init__(self, realpart, imagpart):
self.r = realpart
self.i = imagpart
x = Complex(3.0, -4.5)
x.r, x.i
Taken from official documentation which helped me the most in the end.
Here is my example
class Bill():
def __init__(self,apples,figs,dates):
self.apples = apples
self.figs = figs
self.dates = dates
self.bill = apples + figs + dates
print ("Buy",self.apples,"apples", self.figs,"figs
and",self.dates,"dates.
Total fruitty bill is",self.bill," pieces of fruit :)")
When you create instance of class Bill:
purchase = Bill(5,6,7)
You get:
> Buy 5 apples 6 figs and 7 dates. Total fruitty bill is 18 pieces of
> fruit :)
__init__ does act like a constructor. You'll need to pass "self" to any class functions as the first argument if you want them to behave as non-static methods. "self" are instance variables for your class.
Try out this code. Hope it helps many C programmers like me to Learn Py.
#! /usr/bin/python2
class Person:
'''Doc - Inside Class '''
def __init__(self, name):
'''Doc - __init__ Constructor'''
self.n_name = name
def show(self, n1, n2):
'''Doc - Inside Show'''
print self.n_name
print 'Sum = ', (n1 + n2)
def __del__(self):
print 'Destructor Deleting object - ', self.n_name
p=Person('Jay')
p.show(2, 3)
print p.__doc__
print p.__init__.__doc__
print p.show.__doc__
Output:
Jay
Sum = 5
Doc - Inside Class
Doc - __init__ Constructor
Doc - Inside Show
Destructor Deleting object - Jay
Had trouble undestanding this myself. Even after reading the answers here.
To properly understand the __init__ method you need to understand self.
The self Parameter
The arguments accepted by the __init__ method are :
def __init__(self, arg1, arg2):
But we only actually pass it two arguments :
instance = OurClass('arg1', 'arg2')
Where has the extra argument come from ?
When we access attributes of an object we do it by name (or by reference). Here instance is a reference to our new object. We access the printargs method of the instance object using instance.printargs.
In order to access object attributes from within the __init__ method we need a reference to the object.
Whenever a method is called, a reference to the main object is passed as the first argument. By convention you always call this first argument to your methods self.
This means in the __init__ method we can do :
self.arg1 = arg1
self.arg2 = arg2
Here we are setting attributes on the object. You can verify this by doing the following :
instance = OurClass('arg1', 'arg2')
print instance.arg1
arg1
values like this are known as object attributes. Here the __init__ method sets the arg1 and arg2 attributes of the instance.
source: http://www.voidspace.org.uk/python/articles/OOP.shtml#the-init-method
note that self could actually be any valid python identifier. For example, we could just as easily write, from Chris B's example:
class A(object):
def __init__(foo):
foo.x = 'Hello'
def method_a(bar, foo):
print bar.x + ' ' + foo
and it would work exactly the same. It is however recommended to use self because other pythoners will recognize it more easily.
What does self do? What is it meant to be? Is it mandatory?
The first argument of every class method, including init, is always a reference to the current instance of the class. By convention, this argument is always named self. In the init method, self refers to the newly created object; in other class methods, it refers to the instance whose method was called.
Python doesn't force you on using "self". You can give it any name you want. But remember the first argument in a method definition is a reference to the object. Python adds the self argument to the list for you; you do not need to include it when you call the methods.
if you didn't provide self in init method then you will get an error
TypeError: __init___() takes no arguments (1 given)
What does the init method do? Why is it necessary? (etc.)
init is short for initialization. It is a constructor which gets called when you make an instance of the class and it is not necessary. But usually it our practice to write init method for setting default state of the object. If you are not willing to set any state of the object initially then you don't need to write this method.
__init__ is basically a function which will "initialize"/"activate" the properties of the class for a specific object, once created and matched to the corresponding class..
self represents that object which will inherit those properties.
Basically, you need to use the 'self' keyword when using a variable in multiple functions within the same class. As for init, it's used to setup default values incase no other functions from within that class are called.
The 'self' is a reference to the class instance
class foo:
def bar(self):
print "hi"
Now we can create an instance of foo and call the method on it, the self parameter is added by Python in this case:
f = foo()
f.bar()
But it can be passed in as well if the method call isn't in the context of an instance of the class, the code below does the same thing
f = foo()
foo.bar(f)
Interestingly the variable name 'self' is just a convention. The below definition will work exactly the same.. Having said that it is very strong convention which should be followed always, but it does say something about flexible nature of the language
class foo:
def bar(s):
print "hi"
Just a demo for the question.
class MyClass:
def __init__(self):
print('__init__ is the constructor for a class')
def __del__(self):
print('__del__ is the destructor for a class')
def __enter__(self):
print('__enter__ is for context manager')
return self
def __exit__(self, exc_type, exc_value, traceback):
print('__exit__ is for context manager')
def greeting(self):
print('hello python')
if __name__ == '__main__':
with MyClass() as mycls:
mycls.greeting()
$ python3 class.objects_instantiation.py
__init__ is the constructor for a class
__enter__ is for context manager
hello python
__exit__ is for context manager
__del__ is the destructor for a class
In this code:
class Cat:
def __init__(self, name):
self.name = name
def info(self):
print 'I am a cat and I am called', self.name
Here __init__ acts as a constructor for the class and when an object is instantiated, this function is called. self represents the instantiating object.
c = Cat('Kitty')
c.info()
The result of the above statements will be as follows:
I am a cat and I am called Kitty
# Source: Class and Instance Variables
# https://docs.python.org/2/tutorial/classes.html#class-and-instance-variables
class MyClass(object):
# class variable
my_CLS_var = 10
# sets "init'ial" state to objects/instances, use self argument
def __init__(self):
# self usage => instance variable (per object)
self.my_OBJ_var = 15
# also possible, class name is used => init class variable
MyClass.my_CLS_var = 20
def run_example_func():
# PRINTS 10 (class variable)
print MyClass.my_CLS_var
# executes __init__ for obj1 instance
# NOTE: __init__ changes class variable above
obj1 = MyClass()
# PRINTS 15 (instance variable)
print obj1.my_OBJ_var
# PRINTS 20 (class variable, changed value)
print MyClass.my_CLS_var
run_example_func()
Here, the guy has written pretty well and simple: https://www.jeffknupp.com/blog/2014/06/18/improve-your-python-python-classes-and-object-oriented-programming/
Read above link as a reference to this:
self? So what's with that self parameter to all of the Customer
methods? What is it? Why, it's the instance, of course! Put another
way, a method like withdraw defines the instructions for withdrawing
money from some abstract customer's account. Calling
jeff.withdraw(100.0) puts those instructions to use on the jeff
instance.
So when we say def withdraw(self, amount):, we're saying, "here's how
you withdraw money from a Customer object (which we'll call self) and
a dollar figure (which we'll call amount). self is the instance of the
Customer that withdraw is being called on. That's not me making
analogies, either. jeff.withdraw(100.0) is just shorthand for
Customer.withdraw(jeff, 100.0), which is perfectly valid (if not often
seen) code.
init self may make sense for other methods, but what about init? When we call init, we're in the process of creating an object, so how can there already be a self? Python allows us to extend
the self pattern to when objects are constructed as well, even though
it doesn't exactly fit. Just imagine that jeff = Customer('Jeff
Knupp', 1000.0) is the same as calling jeff = Customer(jeff, 'Jeff
Knupp', 1000.0); the jeff that's passed in is also made the result.
This is why when we call init, we initialize objects by saying
things like self.name = name. Remember, since self is the instance,
this is equivalent to saying jeff.name = name, which is the same as
jeff.name = 'Jeff Knupp. Similarly, self.balance = balance is the same
as jeff.balance = 1000.0. After these two lines, we consider the
Customer object "initialized" and ready for use.
Be careful what you __init__
After init has finished, the caller can rightly assume that the
object is ready to use. That is, after jeff = Customer('Jeff Knupp',
1000.0), we can start making deposit and withdraw calls on jeff; jeff is a fully-initialized object.
Python __init__ and self what do they do?
What does self do? What is it meant to be? Is it mandatory?
What does the __init__ method do? Why is it necessary? (etc.)
The example given is not correct, so let me create a correct example based on it:
class SomeObject(object):
def __init__(self, blah):
self.blah = blah
def method(self):
return self.blah
When we create an instance of the object, the __init__ is called to customize the object after it has been created. That is, when we call SomeObject with 'blah' below (which could be anything), it gets passed to the __init__ function as the argument, blah:
an_object = SomeObject('blah')
The self argument is the instance of SomeObject that will be assigned to an_object.
Later, we might want to call a method on this object:
an_object.method()
Doing the dotted lookup, that is, an_object.method, binds the instance to an instance of the function, and the method (as called above) is now a "bound" method - which means we do not need to explicitly pass the instance to the method call.
The method call gets the instance because it was bound on the dotted lookup, and when called, then executes whatever code it was programmed to perform.
The implicitly passed self argument is called self by convention. We could use any other legal Python name, but you will likely get tarred and feathered by other Python programmers if you change it to something else.
__init__ is a special method, documented in the Python datamodel documentation. It is called immediately after the instance is created (usually via __new__ - although __new__ is not required unless you are subclassing an immutable datatype).

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