Is it possible to have static class variables or methods in Python? What syntax is required to do this?

  • 9
    Yes. The absence of the keyword "static" might be misleading, but any object initialised inside the class (just one indent inside the class, and not in the constructor) is static. It is not dependent on instantiation (because it is not part of the constructor). As for methods, you can do that with an @staticmethod decorator.
    – user11991978
    Oct 30 '20 at 9:16
  • 3
    using the term static for something that exists for all instancess of a class, always seemed odd to me Oct 31 '20 at 20:10
  • 2
    @TonySuffolk66 Blame (I think) C++, which simply appropriated the existing keyword "static" from C (where it indicated that the lifetime of the variable persisted beyond the scope in which it was declared). C++ extended that to mean a variable whose value was outside the "scope" of a single instance of a class. Python (more logically) simply calls them class attributes, as they are attributes associated with the class itself, rather than an instance of the class.
    – chepner
    Dec 23 '20 at 13:25
  • 1
    @chepner static actually means several things in C++ (abbreviated definitions due to very strict comment length). There's file scoped static inherited from C which means "this variable/function is usable in this file only", there's class scoped static which means "this method or field is associated with the type and not any instance of the type" (rarely used in C++ but common in C#/Java/ObjC, for example, I think this is what the OP is asking about), there's local variable static in functions which means "this variable's value is retained between function calls".
    – jrh
    Apr 18 at 23:41
  • 2
    Flipping the switch into "opinion", I think a lot of the times, static methods in C#/Java were made because the languages took a hard line "no functions" stance, in C#/Java you can only have methods (i.e., a function that's part of a class), Python doesn't have this restriction (which is for the best, in my opinion). I'd rather use C++'s namespaces or import functions from a file (Python), personally, than create a class for no reason other than to hold functions. OOP has its uses, but sometimes you just want a function.
    – jrh
    Apr 18 at 23:47

24 Answers 24


Variables declared inside the class definition, but not inside a method are class or static variables:

>>> class MyClass:
...     i = 3
>>> MyClass.i

As @millerdev points out, this creates a class-level i variable, but this is distinct from any instance-level i variable, so you could have

>>> m = MyClass()
>>> m.i = 4
>>> MyClass.i, m.i
>>> (3, 4)

This is different from C++ and Java, but not so different from C#, where a static member can't be accessed using a reference to an instance.

See what the Python tutorial has to say on the subject of classes and class objects.

@Steve Johnson has already answered regarding static methods, also documented under "Built-in Functions" in the Python Library Reference.

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

@beidy recommends classmethods over staticmethod, as the method then receives the class type as the first argument, but I'm still a little fuzzy on the advantages of this approach over staticmethod. If you are too, then it probably doesn't matter.

  • 21
    I'm just learning Python, but the advantages of @classmethod over @staticmethod AFAIK is that you always get the name of the class the method was invoked on, even if it's a subclass. A static method lacks this information, so it cannot call an overridden method, for example.
    – Seb
    Oct 2 '12 at 15:58
  • 62
    @theJollySin the pythonic way for constants is to not grow a class for constants. Just have some const.py with PI = 3.14 and you can import it everywhere. from const import PI
    – Giszmo
    Jun 21 '13 at 17:54
  • 45
    This answer is likely to confuse the static variable issue. To begin with, i = 3 is not a static variable, it is a class attribute, and since it is distinct from an instance-level attribute i it does not behave like a static variable in other languages. See millerdev's answer, Yann's answer, and my answer below. Dec 19 '14 at 15:40
  • 6
    so only one copy of i(static variable) will be in memory even if I create hundreds of instance of this class ? Jul 21 '17 at 12:53
  • 2
    For anyone's interested who's Daniel mentioned in @Dubslow comment, it is millerdev (wayback machine)
    – OfirD
    Feb 26 '18 at 21:22

@Blair Conrad said static variables declared inside the class definition, but not inside a method are class or "static" variables:

>>> class Test(object):
...     i = 3
>>> Test.i

There are a few gotcha's here. Carrying on from the example above:

>>> t = Test()
>>> t.i     # "static" variable accessed via instance
>>> t.i = 5 # but if we assign to the instance ...
>>> Test.i  # we have not changed the "static" variable
>>> t.i     # we have overwritten Test.i on t by creating a new attribute t.i
>>> Test.i = 6 # to change the "static" variable we do it by assigning to the class
>>> t.i
>>> Test.i
>>> u = Test()
>>> u.i
6           # changes to t do not affect new instances of Test

# Namespaces are one honking great idea -- let's do more of those!
>>> Test.__dict__
{'i': 6, ...}
>>> t.__dict__
{'i': 5}
>>> u.__dict__

Notice how the instance variable t.i got out of sync with the "static" class variable when the attribute i was set directly on t. This is because i was re-bound within the t namespace, which is distinct from the Test namespace. If you want to change the value of a "static" variable, you must change it within the scope (or object) where it was originally defined. I put "static" in quotes because Python does not really have static variables in the sense that C++ and Java do.

Although it doesn't say anything specific about static variables or methods, the Python tutorial has some relevant information on classes and class objects.

@Steve Johnson also answered regarding static methods, also documented under "Built-in Functions" in the Python Library Reference.

class Test(object):
    def f(arg1, arg2, ...):

@beid also mentioned classmethod, which is similar to staticmethod. A classmethod's first argument is the class object. Example:

class Test(object):
    i = 3 # class (or static) variable
    def g(cls, arg):
        # here we can use 'cls' instead of the class name (Test)
        if arg > cls.i:
            cls.i = arg # would be the same as Test.i = arg1

Pictorial Representation Of Above Example

  • 6
    I suggest you extend the example just a little: if, after setting Test.i=6, you then instantiate a new object (e.g., u=Test()), the new object will "inherit" the new class value (e.g., u.i==6)
    – Mark
    Aug 20 '14 at 13:48
  • 7
    A way to keep the static variables in sync is to make them properties: class Test(object):, _i = 3, @property, def i(self),return type(self)._i, @i.setter, def i(self,val):, type(self)._i = val. Now you can do x = Test(), x.i = 12, assert x.i == Test.i. Dec 19 '14 at 15:05
  • 1
    So I could say all variables are static initially and then accessing instances makes instance variables at runtime?
    – Ali
    Nov 4 '15 at 7:17
  • 2
    Perhaps this is interesting: if you define a method in Test that changes Test.i, that will affect BOTH Test.i and t.i values.
    – Pablo
    Mar 7 '18 at 13:41
  • @millerdev, like u mentioned Python doesn't have static variables as C++ or JAVA have..So will it be okay to say, Test.i is more of a class variable rather than a static variable?
    – NightOwl19
    Sep 21 '18 at 10:12

Static and Class Methods

As the other answers have noted, static and class methods are easily accomplished using the built-in decorators:

class Test(object):

    # regular instance method:
    def MyMethod(self):

    # class method:
    def MyClassMethod(klass):

    # static method:
    def MyStaticMethod():

As usual, the first argument to MyMethod() is bound to the class instance object. In contrast, the first argument to MyClassMethod() is bound to the class object itself (e.g., in this case, Test). For MyStaticMethod(), none of the arguments are bound, and having arguments at all is optional.

"Static Variables"

However, implementing "static variables" (well, mutable static variables, anyway, if that's not a contradiction in terms...) is not as straight forward. As millerdev pointed out in his answer, the problem is that Python's class attributes are not truly "static variables". Consider:

class Test(object):
    i = 3  # This is a class attribute

x = Test()
x.i = 12   # Attempt to change the value of the class attribute using x instance
assert x.i == Test.i  # ERROR
assert Test.i == 3    # Test.i was not affected
assert x.i == 12      # x.i is a different object than Test.i

This is because the line x.i = 12 has added a new instance attribute i to x instead of changing the value of the Test class i attribute.

Partial expected static variable behavior, i.e., syncing of the attribute between multiple instances (but not with the class itself; see "gotcha" below), can be achieved by turning the class attribute into a property:

class Test(object):

    _i = 3

    def i(self):
        return type(self)._i

    def i(self,val):
        type(self)._i = val

## (except with separate methods for getting and setting i) ##

class Test(object):

    _i = 3

    def get_i(self):
        return type(self)._i

    def set_i(self,val):
        type(self)._i = val

    i = property(get_i, set_i)

Now you can do:

x1 = Test()
x2 = Test()
x1.i = 50
assert x2.i == x1.i  # no error
assert x2.i == 50    # the property is synced

The static variable will now remain in sync between all class instances.

(NOTE: That is, unless a class instance decides to define its own version of _i! But if someone decides to do THAT, they deserve what they get, don't they???)

Note that technically speaking, i is still not a 'static variable' at all; it is a property, which is a special type of descriptor. However, the property behavior is now equivalent to a (mutable) static variable synced across all class instances.

Immutable "Static Variables"

For immutable static variable behavior, simply omit the property setter:

class Test(object):

    _i = 3

    def i(self):
        return type(self)._i

## (except with separate methods for getting i) ##

class Test(object):

    _i = 3

    def get_i(self):
        return type(self)._i

    i = property(get_i)

Now attempting to set the instance i attribute will return an AttributeError:

x = Test()
assert x.i == 3  # success
x.i = 12         # ERROR

One Gotcha to be Aware of

Note that the above methods only work with instances of your class - they will not work when using the class itself. So for example:

x = Test()
assert x.i == Test.i  # ERROR

# x.i and Test.i are two different objects:
type(Test.i)  # class 'property'
type(x.i)     # class 'int'

The line assert Test.i == x.i produces an error, because the i attribute of Test and x are two different objects.

Many people will find this surprising. However, it should not be. If we go back and inspect our Test class definition (the second version), we take note of this line:

    i = property(get_i) 

Clearly, the member i of Test must be a property object, which is the type of object returned from the property function.

If you find the above confusing, you are most likely still thinking about it from the perspective of other languages (e.g. Java or c++). You should go study the property object, about the order in which Python attributes are returned, the descriptor protocol, and the method resolution order (MRO).

I present a solution to the above 'gotcha' below; however I would suggest - strenuously - that you do not try to do something like the following until - at minimum - you thoroughly understand why assert Test.i = x.i causes an error.

REAL, ACTUAL Static Variables - Test.i == x.i

I present the (Python 3) solution below for informational purposes only. I am not endorsing it as a "good solution". I have my doubts as to whether emulating the static variable behavior of other languages in Python is ever actually necessary. However, regardless as to whether it is actually useful, the below should help further understanding of how Python works.

UPDATE: this attempt is really pretty awful; if you insist on doing something like this (hint: please don't; Python is a very elegant language and shoe-horning it into behaving like another language is just not necessary), use the code in Ethan Furman's answer instead.

Emulating static variable behavior of other languages using a metaclass

A metaclass is the class of a class. The default metaclass for all classes in Python (i.e., the "new style" classes post Python 2.3 I believe) is type. For example:

type(int)  # class 'type'
type(str)  # class 'type'
class Test(): pass
type(Test) # class 'type'

However, you can define your own metaclass like this:

class MyMeta(type): pass

And apply it to your own class like this (Python 3 only):

class MyClass(metaclass = MyMeta):

type(MyClass)  # class MyMeta

Below is a metaclass I have created which attempts to emulate "static variable" behavior of other languages. It basically works by replacing the default getter, setter, and deleter with versions which check to see if the attribute being requested is a "static variable".

A catalog of the "static variables" is stored in the StaticVarMeta.statics attribute. All attribute requests are initially attempted to be resolved using a substitute resolution order. I have dubbed this the "static resolution order", or "SRO". This is done by looking for the requested attribute in the set of "static variables" for a given class (or its parent classes). If the attribute does not appear in the "SRO", the class will fall back on the default attribute get/set/delete behavior (i.e., "MRO").

from functools import wraps

class StaticVarsMeta(type):
    '''A metaclass for creating classes that emulate the "static variable" behavior
    of other languages. I do not advise actually using this for anything!!!

    Behavior is intended to be similar to classes that use __slots__. However, "normal"
    attributes and __statics___ can coexist (unlike with __slots__). 

    Example usage: 

        class MyBaseClass(metaclass = StaticVarsMeta):
            __statics__ = {'a','b','c'}
            i = 0  # regular attribute
            a = 1  # static var defined (optional)

        class MyParentClass(MyBaseClass):
            __statics__ = {'d','e','f'}
            j = 2              # regular attribute
            d, e, f = 3, 4, 5  # Static vars
            a, b, c = 6, 7, 8  # Static vars (inherited from MyBaseClass, defined/re-defined here)

        class MyChildClass(MyParentClass):
            __statics__ = {'a','b','c'}
            j = 2  # regular attribute (redefines j from MyParentClass)
            d, e, f = 9, 10, 11   # Static vars (inherited from MyParentClass, redefined here)
            a, b, c = 12, 13, 14  # Static vars (overriding previous definition in MyParentClass here)'''
    statics = {}
    def __new__(mcls, name, bases, namespace):
        # Get the class object
        cls = super().__new__(mcls, name, bases, namespace)
        # Establish the "statics resolution order"
        cls.__sro__ = tuple(c for c in cls.__mro__ if isinstance(c,mcls))

        # Replace class getter, setter, and deleter for instance attributes
        cls.__getattribute__ = StaticVarsMeta.__inst_getattribute__(cls, cls.__getattribute__)
        cls.__setattr__ = StaticVarsMeta.__inst_setattr__(cls, cls.__setattr__)
        cls.__delattr__ = StaticVarsMeta.__inst_delattr__(cls, cls.__delattr__)
        # Store the list of static variables for the class object
        # This list is permanent and cannot be changed, similar to __slots__
            mcls.statics[cls] = getattr(cls,'__statics__')
        except AttributeError:
            mcls.statics[cls] = namespace['__statics__'] = set() # No static vars provided
        # Check and make sure the statics var names are strings
        if any(not isinstance(static,str) for static in mcls.statics[cls]):
            typ = dict(zip((not isinstance(static,str) for static in mcls.statics[cls]), map(type,mcls.statics[cls])))[True].__name__
            raise TypeError('__statics__ items must be strings, not {0}'.format(typ))
        # Move any previously existing, not overridden statics to the static var parent class(es)
        if len(cls.__sro__) > 1:
            for attr,value in namespace.items():
                if attr not in StaticVarsMeta.statics[cls] and attr != ['__statics__']:
                    for c in cls.__sro__[1:]:
                        if attr in StaticVarsMeta.statics[c]:
        return cls
    def __inst_getattribute__(self, orig_getattribute):
        '''Replaces the class __getattribute__'''
        def wrapper(self, attr):
            if StaticVarsMeta.is_static(type(self),attr):
                return StaticVarsMeta.__getstatic__(type(self),attr)
                return orig_getattribute(self, attr)
        return wrapper
    def __inst_setattr__(self, orig_setattribute):
        '''Replaces the class __setattr__'''
        def wrapper(self, attr, value):
            if StaticVarsMeta.is_static(type(self),attr):
                StaticVarsMeta.__setstatic__(type(self),attr, value)
                orig_setattribute(self, attr, value)
        return wrapper
    def __inst_delattr__(self, orig_delattribute):
        '''Replaces the class __delattr__'''
        def wrapper(self, attr):
            if StaticVarsMeta.is_static(type(self),attr):
                orig_delattribute(self, attr)
        return wrapper
    def __getstatic__(cls,attr):
        '''Static variable getter'''
        for c in cls.__sro__:
            if attr in StaticVarsMeta.statics[c]:
                    return getattr(c,attr)
                except AttributeError:
        raise AttributeError(cls.__name__ + " object has no attribute '{0}'".format(attr))
    def __setstatic__(cls,attr,value):
        '''Static variable setter'''
        for c in cls.__sro__:
            if attr in StaticVarsMeta.statics[c]:
    def __delstatic__(cls,attr):
        '''Static variable deleter'''
        for c in cls.__sro__:
            if attr in StaticVarsMeta.statics[c]:
                except AttributeError:
        raise AttributeError(cls.__name__ + " object has no attribute '{0}'".format(attr))
    def __delattr__(cls,attr):
        '''Prevent __sro__ attribute from deletion'''
        if attr == '__sro__':
            raise AttributeError('readonly attribute')
    def is_static(cls,attr):
        '''Returns True if an attribute is a static variable of any class in the __sro__'''
        if any(attr in StaticVarsMeta.statics[c] for c in cls.__sro__):
            return True
        return False
  • I tried to use your way but I faced a problem, kindly have a look at my question here stackoverflow.com/questions/29329850/get-static-variable-value Mar 29 '15 at 15:22
  • @RickTeachey: I guess you should generally view anything you do on the class Instance Test (before using it for instantiating instances) as being in the domain of meta-programming? For instance, you alter the class-behavior by doing Test.i = 0 (here you simply destroy the property object entirely). I guess the "property-mechanism" kicks in only on property-access on instances of a class (unless you change underlying behavior using a meta-class as an intermediate, perhaps). Btw, please finish this answer :-) May 11 '15 at 15:20
  • 1
    @RickTeachey Thanks :-) Your metaclass in the end is interesting but is actually a bit too complex for my liking. It might be useful in a large framework/application where this mechanism is absolutely required. Anyway, this exemplifies that if new (complex) non-default meta-behavior is really needed, Python makes it possible :) May 14 '15 at 21:54
  • 1
    @OleThomsenBuus: Check my answer for a simpler metaclass that does the job. Feb 22 '17 at 16:40
  • 1
    @taper You are correct; I have edited the answer to fix the problem (can't believe it's been sitting there wrong for so long!). Sorry for the confusion. Dec 8 '17 at 16:14

You can also add class variables to classes on the fly

>>> class X:
...     pass
>>> X.bar = 0
>>> x = X()
>>> x.bar
>>> x.foo
Traceback (most recent call last):
  File "<interactive input>", line 1, in <module>
AttributeError: X instance has no attribute 'foo'
>>> X.foo = 1
>>> x.foo

And class instances can change class variables

class X:
  l = []
  def __init__(self):

print X().l
print X().l

>python test.py
[1, 1]
  • 3
    Will the new class variables stick even if the class is imported into another module?
    – zakdances
    Mar 1 '13 at 12:20
  • Yes. Classes are effectively singletons, regardless of the namespace you call them from.
    – Pedro
    Jul 25 '18 at 14:11
  • @Gregory you said "And class instances can change class variables" Actually this example is called access not modification. The modification was done by the object itself through its own append() function. Nov 26 '19 at 12:18

Personally I would use a classmethod whenever I needed a static method. Mainly because I get the class as an argument.

class myObj(object):
   def myMethod(cls)
   myMethod = classmethod(myMethod) 

or use a decorator

class myObj(object):
   def myMethod(cls)

For static properties.. Its time you look up some python definition.. variable can always change. There are two types of them mutable and immutable.. Also, there are class attributes and instance attributes.. Nothing really like static attributes in the sense of java & c++

Why use static method in pythonic sense, if it has no relation whatever to the class! If I were you, I'd either use classmethod or define the method independent from the class.

  • 2
    Variables are not mutable or immutable; objects are. (However, an object can, with varying degrees of success, try to prevent assignment to certain of its attributes.) Sep 21 '17 at 3:55
  • Java and C++ use static (ill use of the word, imho) exactly as you use instance versus class attribute. A class attribute/method is static in Java and C++, no difference, except that in Python the first parameter to a class method call is the class. Nov 1 '19 at 8:35

Static methods in python are called classmethods. Take a look at the following code

class MyClass:

    def myInstanceMethod(self):
        print 'output from an instance method'

    def myStaticMethod(cls):
        print 'output from a static method'

>>> MyClass.myInstanceMethod()
Traceback (most recent call last):
  File "<stdin>", line 1, in <module>
TypeError: unbound method myInstanceMethod() must be called [...]

>>> MyClass.myStaticMethod()
output from a static method

Notice that when we call the method myInstanceMethod, we get an error. This is because it requires that method be called on an instance of this class. The method myStaticMethod is set as a classmethod using the decorator @classmethod.

Just for kicks and giggles, we could call myInstanceMethod on the class by passing in an instance of the class, like so:

>>> MyClass.myInstanceMethod(MyClass())
output from an instance method
  • 2
    Umm... static methods are made with @staticmethod; @classmethod is (obviously) for class methods (which are primarily intended for use as alternate constructors, but can serve in a pinch as static methods which happen to receive a reference to the class that they were called through). Jun 14 '19 at 3:20

One special thing to note about static properties & instance properties, shown in the example below:

class my_cls:
  my_prop = 0

#static property
print my_cls.my_prop  #--> 0

#assign value to static property
my_cls.my_prop = 1 
print my_cls.my_prop  #--> 1

#access static property thru' instance
my_inst = my_cls()
print my_inst.my_prop #--> 1

#instance property is different from static property 
#after being assigned a value
my_inst.my_prop = 2
print my_cls.my_prop  #--> 1
print my_inst.my_prop #--> 2

This means before assigning the value to instance property, if we try to access the property thru' instance, the static value is used. Each property declared in python class always has a static slot in memory.


When define some member variable outside any member method, the variable can be either static or non-static depending on how the variable is expressed.

  • CLASSNAME.var is static variable
  • INSTANCENAME.var is not static variable.
  • self.var inside class is not static variable.
  • var inside the class member function is not defined.

For example:


class A:

    def printvar(self):
        print "self.var is %d" % self.var
        print "A.var is %d" % A.var

    a = A()
    a.var = 2

    A.var = 3

The results are

self.var is 2
A.var is 1
self.var is 2
A.var is 3
  • The indentation is broken. This won't execute Jul 16 '19 at 8:56

It is possible to have static class variables, but probably not worth the effort.

Here's a proof-of-concept written in Python 3 -- if any of the exact details are wrong the code can be tweaked to match just about whatever you mean by a static variable:

class Static:
    def __init__(self, value, doc=None):
        self.deleted = False
        self.value = value
        self.__doc__ = doc
    def __get__(self, inst, cls=None):
        if self.deleted:
            raise AttributeError('Attribute not set')
        return self.value
    def __set__(self, inst, value):
        self.deleted = False
        self.value = value
    def __delete__(self, inst):
        self.deleted = True

class StaticType(type):
    def __delattr__(cls, name):
        obj = cls.__dict__.get(name)
        if isinstance(obj, Static):
            super(StaticType, cls).__delattr__(name)
    def __getattribute__(cls, *args):
        obj = super(StaticType, cls).__getattribute__(*args)
        if isinstance(obj, Static):
            obj = obj.__get__(cls, cls.__class__)
        return obj
    def __setattr__(cls, name, val):
        # check if object already exists
        obj = cls.__dict__.get(name)
        if isinstance(obj, Static):
            obj.__set__(name, val)
            super(StaticType, cls).__setattr__(name, val)

and in use:

class MyStatic(metaclass=StaticType):
    Testing static vars
    a = Static(9)
    b = Static(12)
    c = 3

class YourStatic(MyStatic):
    d = Static('woo hoo')
    e = Static('doo wop')

and some tests:

ms1 = MyStatic()
ms2 = MyStatic()
ms3 = MyStatic()
assert ms1.a == ms2.a == ms3.a == MyStatic.a
assert ms1.b == ms2.b == ms3.b == MyStatic.b
assert ms1.c == ms2.c == ms3.c == MyStatic.c
ms1.a = 77
assert ms1.a == ms2.a == ms3.a == MyStatic.a
ms2.b = 99
assert ms1.b == ms2.b == ms3.b == MyStatic.b
MyStatic.a = 101
assert ms1.a == ms2.a == ms3.a == MyStatic.a
MyStatic.b = 139
assert ms1.b == ms2.b == ms3.b == MyStatic.b
del MyStatic.b
for inst in (ms1, ms2, ms3):
        getattr(inst, 'b')
    except AttributeError:
        print('AttributeError not raised on %r' % attr)
ms1.c = 13
ms2.c = 17
ms3.c = 19
assert ms1.c == 13
assert ms2.c == 17
assert ms3.c == 19
MyStatic.c = 43
assert ms1.c == 13
assert ms2.c == 17
assert ms3.c == 19

ys1 = YourStatic()
ys2 = YourStatic()
ys3 = YourStatic()
MyStatic.b = 'burgler'
assert ys1.a == ys2.a == ys3.a == YourStatic.a == MyStatic.a
assert ys1.b == ys2.b == ys3.b == YourStatic.b == MyStatic.b
assert ys1.d == ys2.d == ys3.d == YourStatic.d
assert ys1.e == ys2.e == ys3.e == YourStatic.e
ys1.a = 'blah'
assert ys1.a == ys2.a == ys3.a == YourStatic.a == MyStatic.a
ys2.b = 'kelp'
assert ys1.b == ys2.b == ys3.b == YourStatic.b == MyStatic.b
ys1.d = 'fee'
assert ys1.d == ys2.d == ys3.d == YourStatic.d
ys2.e = 'fie'
assert ys1.e == ys2.e == ys3.e == YourStatic.e
MyStatic.a = 'aargh'
assert ys1.a == ys2.a == ys3.a == YourStatic.a == MyStatic.a

You could also enforce a class to be static using metaclass.

class StaticClassError(Exception):

class StaticClass:
    __metaclass__ = abc.ABCMeta

    def __new__(cls, *args, **kw):
        raise StaticClassError("%s is a static class and cannot be initiated."
                                % cls)

class MyClass(StaticClass):
    a = 1
    b = 3

    def add(x, y):
        return x+y

Then whenever by accident you try to initialize MyClass you'll get an StaticClassError.

  • 4
    Why is it even a class if you aren't going to instantiate it? This feels like twisting Python to turn it into Java.... Aug 24 '14 at 17:44
  • 1
    The Borg idiom is a better way to handle this. Jan 26 '15 at 15:03
  • @NedBatchelder It's an abstract class, intended only for subclassing (and instantiating the subclasses) Sep 24 '18 at 16:53
  • 1
    I hope the subclasses don't use super() to invoke the __new__ of its parents... Sep 24 '18 at 20:29

One very interesting point about Python's attribute lookup is that it can be used to create "virtual variables":

class A(object):


  def __init__(self,d): 

  def say(self): 
      print("%s %s!"%(self.label,self.data))

class B(A):
  label="Bold"  # overrides A.label

A(5).say()      # Amazing 5!
B(3).say()      # Bold 3!

Normally there aren't any assignments to these after they are created. Note that the lookup uses self because, although label is static in the sense of not being associated with a particular instance, the value still depends on the (class of the) instance.


Yes, definitely possible to write static variables and methods in python.

Static Variables : Variable declared at class level are called static variable which can be accessed directly using class name.

    >>> class A:
        ...my_var = "shagun"

    >>> print(A.my_var)

Instance variables: Variables that are related and accessed by instance of a class are instance variables.

   >>> a = A()
   >>> a.my_var = "pruthi"
   >>> print(A.my_var,a.my_var)
       shagun pruthi

Static Methods: Similar to variables, static methods can be accessed directly using class Name. No need to create an instance.

But keep in mind, a static method cannot call a non-static method in python.

    >>> class A:
   ...     @staticmethod
   ...     def my_static_method():
   ...             print("Yippey!!")
   >>> A.my_static_method()
  • What you call 'static' variables are, I think, class variables. Viz: class A(): inner_var = 0 class B(A): pass A.inner_var = 15 B.inner_var = 30 print ("A:static=" + str(A.inner_var)) print ("B:static=" + str(B.inner_var)) # Output: # A:static=15 # B:static=30
    – Andrew
    Jan 16 at 13:13

In regards to this answer, for a constant static variable, you can use a descriptor. Here's an example:

class ConstantAttribute(object):
    '''You can initialize my value but not change it.'''
    def __init__(self, value):
        self.value = value

    def __get__(self, obj, type=None):
        return self.value

    def __set__(self, obj, val):

class Demo(object):
    x = ConstantAttribute(10)

class SubDemo(Demo):
    x = 10

demo = Demo()
subdemo = SubDemo()
# should not change
demo.x = 100
# should change
subdemo.x = 100
print "small demo", demo.x
print "small subdemo", subdemo.x
print "big demo", Demo.x
print "big subdemo", SubDemo.x

resulting in ...

small demo 10
small subdemo 100
big demo 10
big subdemo 10

You can always raise an exception if quietly ignoring setting value (pass above) is not your thing. If you're looking for a C++, Java style static class variable:

class StaticAttribute(object):
    def __init__(self, value):
        self.value = value

    def __get__(self, obj, type=None):
        return self.value

    def __set__(self, obj, val):
        self.value = val

Have a look at this answer and the official docs HOWTO for more information about descriptors.

  • 2
    You could also just use @property, which is the same as using a descriptor, but it's a lot less code. Dec 19 '14 at 15:34

Absolutely Yes, Python by itself don't have any static data member explicitly, but We can have by doing so

class A:
    counter =0
    def callme (self):
        A.counter +=1
    def getcount (self):
        return self.counter  
>>> x=A()
>>> y=A()
>>> print(x.getcount())
>>> print(y.getcount())
>>> x.callme() 
>>> print(x.getcount())
>>> print(y.getcount())




here object (x) alone increment the counter variable
from 0 to 1 by not object y. But result it as "static counter"

To avoid any potential confusion, I would like to contrast static variables and immutable objects.

Some primitive object types like integers, floats, strings, and touples are immutable in Python. This means that the object that is referred to by a given name cannot change if it is of one of the aforementioned object types. The name can be reassigned to a different object, but the object itself may not be changed.

Making a variable static takes this a step further by disallowing the variable name to point to any object but that to which it currently points. (Note: this is a general software concept and not specific to Python; please see others' posts for information about implementing statics in Python).


The best way I found is to use another class. You can create an object and then use it on other objects.

class staticFlag:
    def __init__(self):
        self.__success = False
    def isSuccess(self):
        return self.__success
    def succeed(self):
        self.__success = True

class tryIt:
    def __init__(self, staticFlag):
        self.isSuccess = staticFlag.isSuccess
        self.succeed = staticFlag.succeed

tryArr = []
flag = staticFlag()
for i in range(10):
    if i == 5:
    print tryArr[i].isSuccess()

With the example above, I made a class named staticFlag.

This class should present the static var __success (Private Static Var).

tryIt class represented the regular class we need to use.

Now I made an object for one flag (staticFlag). This flag will be sent as reference to all the regular objects.

All these objects are being added to the list tryArr.

This Script Results:


With Object datatypes it is possible. But with primitive types like bool, int, float or str bahaviour is different from other OOP languages. Because in inherited class static attribute does not exist. If attribute does not exists in inherited class, Python start to look for it in parent class. If found in parent class, its value will be returned. When you decide to change value in inherited class, static attribute will be created in runtime. In next time of reading inherited static attribute its value will be returned, bacause it is already defined. Objects (lists, dicts) works as a references so it is safe to use them as static attributes and inherit them. Object address is not changed when you change its attribute values.

Example with integer data type:

class A:
    static = 1

class B(A):

print(f"int {A.static}")  # get 1 correctly
print(f"int {B.static}")  # get 1 correctly

A.static = 5
print(f"int {A.static}")  # get 5 correctly
print(f"int {B.static}")  # get 5 correctly

B.static = 6
print(f"int {A.static}")  # expected 6, but get 5 incorrectly
print(f"int {B.static}")  # get 6 correctly

A.static = 7
print(f"int {A.static}")  # get 7 correctly
print(f"int {B.static}")  # get unchanged 6

Solution based on refdatatypes library:

from refdatatypes.refint import RefInt

class AAA:
    static = RefInt(1)

class BBB(AAA):

print(f"refint {AAA.static.value}")  # get 1 correctly
print(f"refint {BBB.static.value}")  # get 1 correctly

AAA.static.value = 5
print(f"refint {AAA.static.value}")  # get 5 correctly
print(f"refint {BBB.static.value}")  # get 5 correctly

BBB.static.value = 6
print(f"refint {AAA.static.value}")  # get 6 correctly
print(f"refint {BBB.static.value}")  # get 6 correctly

AAA.static.value = 7
print(f"refint {AAA.static.value}")  # get 7 correctly
print(f"refint {BBB.static.value}")  # get 7 correctly

@dataclass definitions provide class-level names that are used to define the instance variables and the initialization method, __init__(). If you want class-level variable in @dataclass you should use typing.ClassVar type hint. The ClassVar type's parameters define the class-level variable's type.

from typing import ClassVar
from dataclasses import dataclass

class Test:
    i: ClassVar[int] = 10
    x: int
    y: int
    def __repr__(self):
        return f"Test({self.x=}, {self.y=}, {Test.i=})"

Usage examples:

> test1 = Test(5, 6)
> test2 = Test(10, 11)

> test1
Test(self.x=5, self.y=6, Test.i=10)
> test2
Test(self.x=10, self.y=11, Test.i=10)

Static Variables in Class factory python3.6

For anyone using a class factory with python3.6 and up use the nonlocal keyword to add it to the scope / context of the class being created like so:

>>> def SomeFactory(some_var=None):
...     class SomeClass(object):
...         nonlocal some_var
...         def print():
...             print(some_var)
...     return SomeClass
>>> SomeFactory(some_var="hello world").print()
hello world
  • yes, but in this case hasattr(SomeClass, 'x') is False. i doubt this is what anyone means by a static variable at all. Jul 25 '17 at 2:55
  • @RickTeachey lol, saw your static variable code, stackoverflow.com/a/27568860/2026508 +1 internet sir, and i thought hasattr didn't work like that? so is some_var immutable, and statically defined, or is it not? What does outside getter access have to do with a variable being static or not? i have so many questions now. would love to hear some answers when you get the time.
    – jmunsch
    Jul 25 '17 at 19:09
  • Yeah that metaclass is pretty ridiculous. I'm not certain I understand the questions but to my mind, some_var above isn't a class member at all. In Python all class members can be accessed from outside the class. Jul 25 '17 at 19:55
  • The nonlocal keywoard "bumps" the scope of the variable. The scope of a class body definition is independent of the scope it finds itself in- when you say nonlocal some_var, that is just creating a non-local (read: NOT in the class definition scope) name reference to another named object. Therefore it doesn't get attached to the class definition because it is not in the class body scope. Jul 25 '17 at 19:59

So this is probably a hack, but I've been using eval(str) to obtain an static object, kind of a contradiction, in python 3.

There is an Records.py file that has nothing but class objects defined with static methods and constructors that save some arguments. Then from another .py file I import Records but i need to dynamically select each object and then instantiate it on demand according to the type of data being read in.

So where object_name = 'RecordOne' or the class name, I call cur_type = eval(object_name) and then to instantiate it you do cur_inst = cur_type(args) However before you instantiate you can call static methods from cur_type.getName() for example, kind of like abstract base class implementation or whatever the goal is. However in the backend, it's probably instantiated in python and is not truly static, because eval is returning an object....which must have been instantiated....that gives static like behavior.


You can use a list or a dictionary to get "static behavior" between instances.

class Fud:

     class_vars = {'origin_open':False}

     def __init__(self, origin = True):
         self.origin = origin
         self.opened = True
         if origin:
             self.class_vars['origin_open'] = True

     def make_another_fud(self):
         ''' Generating another Fud() from the origin instance '''

         return Fud(False)

     def close(self):
         self.opened = False
         if self.origin:
             self.class_vars['origin_open'] = False

fud1 = Fud()
fud2 = fud1.make_another_fud()

print (f"is this the original fud: {fud2.origin}")
print (f"is the original fud open: {fud2.class_vars['origin_open']}")
# is this the original fud: False
# is the original fud open: True


print (f"is the original fud open: {fud2.class_vars['origin_open']}")
# is the original fud open: False

If you are attempting to share a static variable for, by example, increasing it across other instances, something like this script works fine:

# -*- coding: utf-8 -*-
class Worker:
    id = 1

    def __init__(self):
        self.name = ''
        self.document = ''
        self.id = Worker.id
        Worker.id += 1

    def __str__(self):
        return u"{}.- {} {}".format(self.id, self.name, self.document).encode('utf8')

class Workers:
    def __init__(self):
        self.list = []

    def add(self, name, doc):
        worker = Worker()
        worker.name = name
        worker.document = doc

if __name__ == "__main__":
    workers = Workers()
    for item in (('Fiona', '0009898'), ('Maria', '66328191'), ("Sandra", '2342184'), ('Elvira', '425872')):
        workers.add(item[0], item[1])
    for worker in workers.list:
    print("next id: %i" % Worker.id)

Put it this way the static variable is created when a user-defined a class come into existence and the define a static variable it should follow the keyword self,

class Student:

    the correct way of static declaration
    i = 10

    self.i = 10

Not like the @staticmethod but class variables are static method of class and are shared with all the instances.

Now you can access it like

instance = MyClass()



you have to assign the value to these variables

I was trying

class MyClass:
  i: str

and assigning the value in one method call, in that case it will not work and will throw an error

i is not attribute of MyClass

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