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below is a description of an oop design scenario in python:

  1. a library developer made 2 classes A and B for others to use:

    class A:
        def foo(self):
            print('A')
    
    class B(A):
        def foo(self):
            super().foo()
            print('B')
    

    they are very intuitive and work correctly in his test:

    A().foo()   #   A
    B().foo()   #   AB
    
  2. an application developer takes this library, and wants to use it in his own project; so he makes 2 new classes C and D;

    he decided C is a subclass of A, but the specific function foo in C does not need to call its super class implementation:

    class C(A):
        def foo(self):
            print('C')
    

    his test of C:

    C().foo()   #   C
    

    finally, D is a minimal multiple inheritance from both B and C;

    class D(B, C): pass
    

    note. if you want to make it explicit what D.foo() does here, you can use either super().foo() or B.foo(self), but the result is the same:

    class D(B, C):
        def foo(self):
            super().foo()   # semantic: call `foo` in *that* super class
            #B.foo(self)     # semantic: call `foo` in `B`
    

till now, each step is simple and logical, right? but when he tests D:

D().foo()   #   CB

given D extends in order of B then C, the output CB looks illogical; one would typically expect D().foo() to call at least one of B().foo() and C().foo(), but this result is neither AB nor C nor ABC;

my question is not about the machinery of class inheritance or mro in python; it is: why do we get an illogical result following logical design choices in each step? specifically, when we utilize super() in multiple inheritance, do we really need to check the whole class hierarchy to make sure every class involved (which can be defined in library, library of library, ...) is working cooperatively?

i hope the answer can focus on the application developer perspective; what principles he needs to follow so that he knows the library classes work correctly in his own extended class hierarchy?


to give a more realistic example, suppose we are writing a game of wildlife; we need to implement, for each kind of animal, what they say when they are being kicked:

class Animal:
    def kick(self):
        return 'are you ok? '

class RunnableAnimal(Animal):
    def kick(self):
        return super().kick() + \
                'i am running away. '

class FuriousAnimal(Animal):
    def kick(self):
        return 'i am attacking you! '

class Tiger(RunnableAnimal, FuriousAnimal):
    def kick(self):
        return super().kick()

print(Tiger().kick())

output:

i am attacking you! i am running away. 

this is obviously illogical: the tiger cannot perform two different actions at the same time;

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  • The result is as expected. When you define D as inheriting from B, C, D ends up with a mro of D -> B -> C -> A so when you call D().foo() you get the call to super from B which calls and prints C.foo and then prints "B" as C.foo returns. The illogical thing here is C.foo returning and not calling super Dec 29 '19 at 0:14
  • @IainShelvington If you call super().foo() in C.foo(), then C().foo() outputs AC not C.
    – Cyker
    Dec 29 '19 at 0:26
  • that depends if you put the call to super before or after the print, no? Dec 29 '19 at 0:27
  • @IainShelvington Yes, either CA or AC but neither is the wanted C;
    – Cyker
    Dec 29 '19 at 0:30
  • What is your desired output? You have inherited from a class that has decided that is does not need to call super for the foo method and that is the behaviour you are getting Dec 29 '19 at 0:36

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