I think that the idea of using a metaclass is the way to go. The trick is to cast the values dynamically when you get them instead of up front. That's basically what python is all about: not knowing quite what you'll get or what's there until you actually get it.
To do that, you have to redefine __getattribute__
and __getattr__
on your class with some caveats:
- Operators don't go through the normal attribute access methods. Even defining the right
__getattribute__
and __getattr__
on your metaclass won't help. Dunders have to be overridden explicitly for each class.
- Methods returned by
__getattribute__
and __getattr__
need to have their return values cast to the target type. Same applies to dunders called as operators.
- Some methods should be excepted from #2 to ensure proper operation of the machinery.
The same basic casting wrapper can be used for all the attribute and method return values. It just needs to recurse exactly oncewhen it's called on the result of __getattribute__
or __getattr__
.
The solution shown below does exactly that. It explicitly wraps all dunders that aren't listed as exceptions. All other attributes are either cast immediately or wrapped if they are functions. It allows any method to be customized by checking everything in the __mro__
, including the class itself. The solution will work correctly with class and static methods because it stores the casting routine and doesn't rely on type(self)
(as some of my previous attempts did). It will correctly exclude any attributes listed in exceptions
, not just dunder methods.
import functools
def isdunder(x):
return isinstance(x, str) and x.startswith('__') and x.endswith('__')
class DunderSet:
def __contains__(self, x):
return isdunder(x)
def wrap_method(method, xtype, cast):
@functools.wraps(method)
def retval(*args, **kwargs):
result = method(*args, **kwargs)
return cast(result) if type(result) == xtype else result
return retval
def wrap_getter(method, xtype, cast, exceptions):
@functools.wraps(method)
def retval(self, name, *args, **kwargs):
result = method(self, name, *args, **kwargs)
return result if name in exceptions else check_type(result, xtype, cast)
return retval
def check_type(value, xtype, cast):
if type(value) == xtype:
return cast(value)
if callable(value):
return wrap_method(value, xtype, cast)
return value
class ClosedMeta(type):
def __new__(meta, name, bases, dct, **kwargs):
if 'exceptions' in kwargs:
exceptions = set([
'__new__', '__init__', '__del__',
'__init_subclass__', '__instancecheck__', '__subclasscheck__',
*map(str, kwargs.pop('exceptions'))
])
else:
exceptions = DunderSet()
target = kwargs.pop('target', bases[0] if bases else object)
cls = super().__new__(meta, name, bases, dct, **kwargs)
for base in cls.__mro__:
for name, item in base.__dict__.items():
if isdunder(name) and (base is cls or name not in dct) and callable(item):
if name in ('__getattribute__', '__getattr__'):
setattr(cls, name, wrap_getter(item, target, cls, exceptions))
elif name not in exceptions:
setattr(cls, name, wrap_method(item, target, cls))
return cls
def __init__(cls, *args, **kwargs):
return super().__init__(*args)
class MyInt(int):
def __contains__(self, x):
return x == self
def my_op(self, other):
return int(self * self // other)
class ClosedInt(MyInt, metaclass=ClosedMeta, target=int,
exceptions=['__index__', '__int__', '__trunc__', '__hash__']):
pass
class MyClass(ClosedInt, metaclass=type):
def __add__(self, other):
return 1
print(type(MyInt(1) + MyInt(2)))
print(0 in MyInt(0), 1 in MyInt(0))
print(type(MyInt(4).my_op(16)))
print(type(ClosedInt(1) + ClosedInt(2)))
print(0 in ClosedInt(0), 1 in ClosedInt(0))
print(type(ClosedInt(4).my_op(16)))
print(type(MyClass(1) + ClosedInt(2)))
The result is
<class 'int'>
True False
<class 'int'>
<class '__main__.ClosedInt'>
True False
<class '__main__.ClosedInt'>
<class 'int'>
The last example is a tribute to @wim's answer. It shows that you have to want to do this for it to work.
IDEOne link because I don't have access to a computer right now: https://ideone.com/iTBFW3
Appendix 1: Improved default exceptions
I think that a better default set of exceptions than all dunder methods can be complied by looking carefully through the special method names section of the documentation. Methods can be categorized into two broad classes: methods with very specific return types that make the python machinery work, and methods whose output should be checked and wrapped when they return an instance of your type of interest. There is a third category, which is methods that should always be excepted, even when you forget to mention them explicitly.
Here is a list of the methods that are always excepted:
__new__
__init__
__del__
__init_subclass__
__instancecheck__
__subclasscheck__
Here is a list of everything that should be excepted by default:
__repr__
__str__
__bytes__
__format__
__lt__
__le__
__eq__
__ne__
__gt__
__ge__
__hash__
__bool__
__setattr__
__delattr__
__dir__
__set__
__delete__
__set_name__
__slots__
(not a method, but still)
__len__
__length_hint__
__setitem__
__delitem__
__iter__
__reversed__
__contains__
__complex__
__int__
__float__
__index__
__enter__
__exit__
__await__
__aiter__
__anext__
__aenter__
__aexit__
If we stash this list into a variable called default_exceptions
, the class DunderSet
can be removed entirely, and the conditional that extracts exceptions
can be replaced by:
exceptions = set([
'__new__', '__init__', '__del__',
'__init_subclass__', '__instancecheck__', '__subclasscheck__',
*map(str, kwargs.pop('exceptions', default_exceptions))
])
Appendix 2: Improved targetting
It should be possible to target multiple types pretty easily. This is especially useful when extending other instances of ClosedMeta
, which may not override all the methods we want.
The first step in doing this is making target
into a container of classes instead of a single class reference. Instead of
target = kwargs.pop('target', bases[0] if bases else object)
do
target = kwargs.pop('target', bases[:1] if bases else [object])
try:
target = set(target)
except TypeError:
target = {target}
Now replace every occurrence of blah == target
(or blah == xtype
in the wrappers) with blah in target
(or blah in xtype
).
class BasicIntContainer(int)
is not an int container, it is an int.list
or adict
. Here, aBasicIntContainer
instance isn't a collection of other objects, it is a specialized kind ofint
object. I don't want to distract from an interesting question with more terminology nitpicking. Anyway, I would just rephrase as "how to create a type that is closed under inherited operations"__new__
knows how to cast from all of its superclasses. Also, this decorator solution is basicaly what I implemented with a metaclass. I am currently fixing it, but it is getting very complex and I am for sure forgetting a lot of cornercases.