I'm interested in subclassing the built-in int type in Python (I'm using v. 2.5), but having some trouble getting the initialization working.

Here's some example code, which should be fairly obvious.

class TestClass(int):
    def __init__(self):
        int.__init__(self, 5)

However, when I try to use this I get:

>>> a = TestClass()
>>> a

where I'd expect the result to be 5.

What am I doing wrong? Google, so far, hasn't been very helpful, but I'm not really sure what I should be searching for


2 Answers 2


int is immutable so you can't modify it after it is created, use __new__ instead

class TestClass(int):
    def __new__(cls, *args, **kwargs):
        return  super(TestClass, cls).__new__(cls, 5)

print TestClass()

Though correct the current answers are potentially not complete.


In [1]: a = TestClass()
In [2]: b = a - 5
In [3]: print(type(b))
<class 'int'>

Shows b as an integer, where you might want it to be a TestClass.

Here is an improved answer, where the functions of the base class are overloaded to return the correct type.

    class positive(int):
        def __new__(cls, value, *args, **kwargs):
            if value < 0:
                raise ValueError("positive types must not be less than zero")
            return  super(cls, cls).__new__(cls, value)
        def __add__(self, other):
            res = super(positive, self).__add__(other)
            return self.__class__(max(res, 0))
        def __sub__(self, other):
            res = super(positive, self).__sub__(other)
            return self.__class__(max(res, 0))
        def __mul__(self, other):
            res = super(positive, self).__mul__(other)
            return self.__class__(max(res, 0))
        def __div__(self, other):
            res = super(positive, self).__div__(other)
            return self.__class__(max(res, 0))

        def __str__(self):
            return "%d" % int(self)

        def __repr__(self):
            return "positive(%d)" % int(self)

Now the same sort of test

In [1]: a = positive(10)
In [2]: b = a - 9
In [3]: print(type(b))
<class '__main__.positive'>

Added repr and str examples so that the new class prints itself properly. Also changed to Python 3 syntax, even though OP used Python 2, to maintain relevancy.

UPDATE 04/22:
I found myself wanting to do something similar on two recent projects. One where I wanted an Unsigned() type (i.e. x-y, where x is 0 and y is positive is still zero)
I also wanted a set() like type the was able to be updated and queried in a certain way.
The above method works but it's repetitive and tedious. What if there was a generic solution using metaclasses?

I could not find one so I wrote one. This will only work in recent Python (I would guess 3.8+, tested on 3.10)

First, the MetaClass

class ModifiedType(type):
    ModifedType takes an exising type and wraps all its members
    in a new class, such that methods return objects of that new class.
    The new class can leave or change the behaviour of each
    method and add further customisation as required

    # We don't usually need to wrap these
    _dont_wrap = {
    "__str__", "__repr__", "__hash__", "__getattribute__", "__init_subclass__", "__subclasshook__",
    "__reduce_ex__", "__getnewargs__", "__format__", "__sizeof__", "__doc__", "__class__"}

    def __prepare__(typ, name, bases, base_type, do_wrap=None, verbose=False):
        return super().__prepare__(name, bases, base_type, do_wrap=do_wrap, verbose=verbose)

    def __new__(typ, name, bases, attrs, base_type, do_wrap=None, verbose=False):
        bases += (base_type,)

        #  Provide a call to the base class __new__
        attrs["__new__"] = typ.__class_new__

        cls = type.__new__(typ, name, bases, attrs)

        if "dont_wrap" not in attrs:
            attrs["dont_wrap"] = {}

        if do_wrap is not None:
            attrs["dont_wrap"] -= set(do_wrap)

        base_members = set(dir(base_type))
        typ.wrapped = base_members - set(attrs) - attrs["dont_wrap"]

        for member in typ.wrapped:
            obj = object.__getattribute__(base_type, member)
            if callable(obj):
                if verbose:
                    print(f"Wrapping {obj.__name__} with {cls.wrapper.__name__}")
                wrapped = cls.wrapper(obj)
                setattr(cls, member, wrapped)
        return cls

    def __class_new__(typ, *args, **kw):
        "Save boilerplate in our implementation"
        return typ.base_type.__new__(typ, *args, **kw)

An example usage to create a new Unsigned type

# Create the new Unsigned type and describe its behaviour
class Unsigned(metaclass=ModifiedType, base_type=int):
    The Unsigned type behaves like int, with all it's methods present but updated for unsigned behaviour
    # Here we list base class members that we won't wrap in our derived class as the
    # original implementation is still useful. Other common methods are also excluded in the metaclass
    # Note you can alter the metaclass exclusion list using 'do_wrap' in the metaclass parameters
    dont_wrap = {"bit_length", "to_bytes", "__neg__", "__int__", "__bool__"}
    import functools

    def __init__(self, value=0, *args, **kw):
        Init ensures the supplied initial data is correct and passes the rest of the
        implementation onto the base class
        if value < 0:
            raise ValueError("Unsigned numbers can't be negative")

    def wrapper(cls, func):
        The wrapper handles the behaviour of the derived type
        This can be generic or specific to a particular method
        Unsigned behavior is:
            If a function or operation would return an int of less than zero it is returned as zero
        def wrapper(*args, **kw):
            ret = func(*args, **kw)
            ret = cls(max(0, ret))
            return ret
        return wrapper

And some tests for the example

In [1]: from unsigned import Unsigned
In [2]: a = Unsigned(10)
   ...: print(f"a={type(a).__name__}({a})")

In [3]: try:
   ...:     b = Unsigned(-10)
   ...: except ValueError as er:
   ...:     print(" !! Exception\n", er, "(This is expected)")
   ...:     b = -10  # Ok, let's let that happen but use an int type instead
   ...:     print(f" let b={b} anyway")
 !! Exception
 Unsigned numbers can't be negative (This is expected)
 let b=-10 anyway
In [4]: c = a - b
   ...: print(f"c={type(c).__name__}({c})")

In [5]: d = a + 10
   ...: print(f"d={type(d).__name__}({d})")

In [6]: e = -Unsigned(10)
   ...: print(f"e={type(e).__name__}({e})")

In [7]: f = 10 - a
   ...: print(f"f={type(f).__name__}({f})")

UPDATE for @Kazz:
To answer your question. Though it would be simpler to just int(u) * 0.2

Here is a small updated wrapper to handle the exception case e.g. (Unsigned * float) that serves as an example of how to modify behavior to match the desired subclass behaviour without having to individually overload each possible combination of argument types.

    # NOTE: also add '__float__' to the list of non-wrapped methods

    def wrapper(cls, func):
        fn_name = func.__name__
        def wrapper(*args, **kw):
            compatible_types = [issubclass(type(a), cls.base_type) for a in args]

            if not all(compatible_types):
                # Try converting
                type_list = set(type(a) for a in args) - set((cls.base_type, cls))
                if type_list != set((float,)):
                    raise ValueError(f"I can't handle types {type_list}")
                args = (float(x) for x in args)
                ret = getattr(float, fn_name)(*args, **kw)
                ret = func(*args, **kw)
                ret = cls(max(0, ret))
            return ret
        return wrapper
  • what do I need to do to make positive(10)*0.2 work ?
    – Kazz
    Jul 14, 2020 at 21:09
  • 1
    The whole point of this example is that operations on instances of this class return objects of the same class. Results of adding 0.2 (a float) to a positive type integer can't be of type positive, it makes no sense. I would suggest using the example given by @Anurag Uniyal, above where the resulting object can be of a different type.
    – Jay M
    Jul 16, 2020 at 9:14
  • The new generic version of my ansser handles your case (though I can't see a reason to use it)
    – Jay M
    Apr 11, 2022 at 16:36

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