From Python in a Nutshell

The lookup of an attribute name in a class essentially occurs by visiting ancestor classes in left-to-right, depth-first order


>>> class A(object): x = 'a'
>>> class B(A): pass
>>> class C(A): x = 'c'
>>> class D(B, C): pass
>>> D.x
>>> D.__mro__
(<class '__main__.D'>, <class '__main__.B'>, <class '__main__.C'>, 
    <class '__main__.A'>, <type 'object'>)

D.__mro__ lists the classes not in depth-first order, but breadth-first order. So do I misunderstand something? Thanks.

Ignoring classic classes, Python resolves method and attribute lookups using the C3 linearisation of the class and its parents. The C3 linearisation is neither depth-first nor breadth-first in complex multiple inheritance hierarchies. In some sense, it is:

depth-first until classes are encountered that will share a parent, and then breadth-first over those

although that is a very loose characterisation.

In particular however, in simple multiple inheritance hierarchies that do not share a parent, it is depth-first (conveniently ignoring object of course, which is always shared)

Simple Example – Depth First

>>> class a_0(object): pass
>>> class a_1(object): pass
>>> class b_0(a_0): pass
>>> class b_1(a_1): pass
>>> class c(b_0, b_1): pass


>>> [x.__name__ for x in c.__mro__]
['c', 'b_0', 'a_0', 'b_1', 'a_1', 'object']

Shared Base Example – Depth then Breadth First

Note that in your example, you have a shared parent (A) which causes B and C to be traversed in a breadth first fashion. If you instead have an evern more complex hierarchy:

>>> class A(object): pass
>>> class B(A): pass
>>> class C(A): pass
>>> class D_0(B, C): pass
>>> class D_1(B, C): pass
>>> class E_0(D_0): pass
>>> class E_1(D_1): pass
>>> class F(E_0, E_1): pass


>>> [x.__name__ for x in F.__mro__]
['F', 'E_0', 'D_0', 'E_1', 'D_1', 'B', 'C', 'A', 'object']

And you will observe that the search is depth first F, E_0, D_0 until it strikes the point where shared base classes are encountered (B and C that are also bases of D_1, at which point the depth first goes sideways to E_1 and depth first from there again.

  • "absolutely depth-first" in those cases except for object, anyway. Also, I think you mixed up your example code, because that first MRO doesn't correspond to the class hierarchy you wrote. – user2357112 Nov 5 '17 at 2:32
  • @user2357112 yes I relabelled it, all fixed now I hope! – donkopotamus Nov 5 '17 at 2:34
  • Not fixed yet. The MRO shows a_0 and a_1, but those aren't ancestors of c at all in the class heirarchy you wrote. I suspect you wanted different parents for b_0 and b_1. – user2357112 Nov 5 '17 at 2:35
  • That looks better. – user2357112 Nov 5 '17 at 2:38

I was reading this article and then I found this stackoverflow question but in this question some programmers like Alex Martelli said it uses the depth-first approach so i was also in confusion here is explanation :


class H():
    def m(self):

class G(H):
    def m(self):

class I(G):
    def m(self):

class F(H):
    def m(self):

class E(H):
    def m(self):

class D(F):
    def m(self):

class C(E, F, G):
    def m(self):

class B():
    def m(self):

class A(B, C, D):
    def m(self):

x = A()

enter image description here

and path should be :


But if you run above code you will get :


Because its following this path :


Now node "D" or class "D" in depth first it comes when earlier and in MRO it comes later.

From @aaron Hall answer :

and path should be:


F cannot come before D - that would be a contradiction - see class D.

The way the C3 linearization algorithm works, you have to linearize the parents, then, as long as there isn't a contradiction, you can linearize the children. So I linearized these one at a time, starting with the parents. Most are trivial until we get to C and then A:

The 3 Criteria are, as I would paraphrase it:

  1. The parents MRO's remain consistent
  2. The local MRO's remain consistent
  3. No cyclicality

The algorithm, as I would put it, is that you respect parents left to right, but go depth first unless you would get to a shared parent blocked by a child (e.g. F blocked by it's child, D) in which case you would look for other candidates (D then, not being a contradiction, is fine, then you can select F and the remainder of C's MRO.)

>>> A.mro()
[A, B, C, E, D, F, G, H, O, <class 'object'>]

enter image description here


Left to Right

Depth first - Unless shared parent is blocked (must be able to come back)

No cyclical relationship allowed

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