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22 KiB
ReStructuredText
.. _python_2.3_mro:
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The Python 2.3 Method Resolution Order
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======================================
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.. note::
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This is a historical document, provided as an appendix to the official
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documentation.
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The Method Resolution Order discussed here was *introduced* in Python 2.3,
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but it is still used in later versions -- including Python 3.
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By `Michele Simionato <https://www.phyast.pitt.edu/~micheles/>`__.
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:Abstract:
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*This document is intended for Python programmers who want to
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understand the C3 Method Resolution Order used in Python 2.3.
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Although it is not intended for newbies, it is quite pedagogical with
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many worked out examples. I am not aware of other publicly available
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documents with the same scope, therefore it should be useful.*
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Disclaimer:
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*I donate this document to the Python Software Foundation, under the
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Python 2.3 license. As usual in these circumstances, I warn the
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reader that what follows* should *be correct, but I don't give any
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warranty. Use it at your own risk and peril!*
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Acknowledgments:
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*All the people of the Python mailing list who sent me their support.
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Paul Foley who pointed out various imprecisions and made me to add the
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part on local precedence ordering. David Goodger for help with the
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formatting in reStructuredText. David Mertz for help with the editing.
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Finally, Guido van Rossum who enthusiastically added this document to
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the official Python 2.3 home-page.*
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The beginning
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-------------
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*Felix qui potuit rerum cognoscere causas* -- Virgilius
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Everything started with a post by Samuele Pedroni to the Python
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development mailing list [#]_. In his post, Samuele showed that the
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Python 2.2 method resolution order is not monotonic and he proposed to
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replace it with the C3 method resolution order. Guido agreed with his
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arguments and therefore now Python 2.3 uses C3. The C3 method itself
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has nothing to do with Python, since it was invented by people working
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on Dylan and it is described in a paper intended for lispers [#]_. The
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present paper gives a (hopefully) readable discussion of the C3
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algorithm for Pythonistas who want to understand the reasons for the
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change.
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First of all, let me point out that what I am going to say only applies
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to the *new style classes* introduced in Python 2.2: *classic classes*
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maintain their old method resolution order, depth first and then left to
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right. Therefore, there is no breaking of old code for classic classes;
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and even if in principle there could be breaking of code for Python 2.2
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new style classes, in practice the cases in which the C3 resolution
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order differs from the Python 2.2 method resolution order are so rare
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that no real breaking of code is expected. Therefore:
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*Don't be scared!*
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Moreover, unless you make strong use of multiple inheritance and you
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have non-trivial hierarchies, you don't need to understand the C3
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algorithm, and you can easily skip this paper. On the other hand, if
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you really want to know how multiple inheritance works, then this paper
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is for you. The good news is that things are not as complicated as you
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might expect.
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Let me begin with some basic definitions.
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1) Given a class C in a complicated multiple inheritance hierarchy, it
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is a non-trivial task to specify the order in which methods are
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overridden, i.e. to specify the order of the ancestors of C.
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2) The list of the ancestors of a class C, including the class itself,
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ordered from the nearest ancestor to the furthest, is called the
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class precedence list or the *linearization* of C.
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3) The *Method Resolution Order* (MRO) is the set of rules that
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construct the linearization. In the Python literature, the idiom
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"the MRO of C" is also used as a synonymous for the linearization of
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the class C.
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4) For instance, in the case of single inheritance hierarchy, if C is a
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subclass of C1, and C1 is a subclass of C2, then the linearization of
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C is simply the list [C, C1 , C2]. However, with multiple
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inheritance hierarchies, the construction of the linearization is
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more cumbersome, since it is more difficult to construct a
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linearization that respects *local precedence ordering* and
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*monotonicity*.
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5) I will discuss the local precedence ordering later, but I can give
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the definition of monotonicity here. A MRO is monotonic when the
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following is true: *if C1 precedes C2 in the linearization of C,
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then C1 precedes C2 in the linearization of any subclass of C*.
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Otherwise, the innocuous operation of deriving a new class could
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change the resolution order of methods, potentially introducing very
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subtle bugs. Examples where this happens will be shown later.
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6) Not all classes admit a linearization. There are cases, in
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complicated hierarchies, where it is not possible to derive a class
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such that its linearization respects all the desired properties.
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Here I give an example of this situation. Consider the hierarchy
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>>> O = object
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>>> class X(O): pass
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>>> class Y(O): pass
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>>> class A(X,Y): pass
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>>> class B(Y,X): pass
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which can be represented with the following inheritance graph, where I
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have denoted with O the ``object`` class, which is the beginning of any
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hierarchy for new style classes:
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.. code-block:: text
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-----------
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| O |
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- X Y /
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| / | /
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| / |/
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A B
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\ /
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?
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In this case, it is not possible to derive a new class C from A and B,
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since X precedes Y in A, but Y precedes X in B, therefore the method
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resolution order would be ambiguous in C.
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Python 2.3 raises an exception in this situation (TypeError: MRO
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conflict among bases Y, X) forbidding the naive programmer from creating
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ambiguous hierarchies. Python 2.2 instead does not raise an exception,
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but chooses an *ad hoc* ordering (CABXYO in this case).
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The C3 Method Resolution Order
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------------------------------
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Let me introduce a few simple notations which will be useful for the
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following discussion. I will use the shortcut notation::
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C1 C2 ... CN
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to indicate the list of classes [C1, C2, ... , CN].
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The *head* of the list is its first element::
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head = C1
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whereas the *tail* is the rest of the list::
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tail = C2 ... CN.
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I shall also use the notation::
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C + (C1 C2 ... CN) = C C1 C2 ... CN
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to denote the sum of the lists [C] + [C1, C2, ... ,CN].
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Now I can explain how the MRO works in Python 2.3.
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Consider a class C in a multiple inheritance hierarchy, with C
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inheriting from the base classes B1, B2, ... , BN. We want to
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compute the linearization L[C] of the class C. The rule is the
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following:
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*the linearization of C is the sum of C plus the merge of the
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linearizations of the parents and the list of the parents.*
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In symbolic notation::
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L[C(B1 ... BN)] = C + merge(L[B1] ... L[BN], B1 ... BN)
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In particular, if C is the ``object`` class, which has no parents, the
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linearization is trivial::
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L[object] = object.
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However, in general one has to compute the merge according to the following
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prescription:
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*take the head of the first list, i.e L[B1][0]; if this head is not in
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the tail of any of the other lists, then add it to the linearization
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of C and remove it from the lists in the merge, otherwise look at the
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head of the next list and take it, if it is a good head. Then repeat
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the operation until all the class are removed or it is impossible to
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find good heads. In this case, it is impossible to construct the
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merge, Python 2.3 will refuse to create the class C and will raise an
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exception.*
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This prescription ensures that the merge operation *preserves* the
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ordering, if the ordering can be preserved. On the other hand, if the
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order cannot be preserved (as in the example of serious order
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disagreement discussed above) then the merge cannot be computed.
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The computation of the merge is trivial if C has only one parent
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(single inheritance); in this case::
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L[C(B)] = C + merge(L[B],B) = C + L[B]
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However, in the case of multiple inheritance things are more cumbersome
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and I don't expect you can understand the rule without a couple of
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examples ;-)
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Examples
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--------
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First example. Consider the following hierarchy:
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>>> O = object
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>>> class F(O): pass
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>>> class E(O): pass
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>>> class D(O): pass
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>>> class C(D,F): pass
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>>> class B(D,E): pass
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>>> class A(B,C): pass
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In this case the inheritance graph can be drawn as:
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.. code-block:: text
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6
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---
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Level 3 | O | (more general)
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/ --- \
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/ | \ |
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/ | \ |
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/ | \ |
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--- --- --- |
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Level 2 3 | D | 4| E | | F | 5 |
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--- --- --- |
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\ \ _ / | |
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\ / \ _ | |
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\ / \ | |
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--- --- |
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Level 1 1 | B | | C | 2 |
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--- --- |
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\ / |
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\ / \ /
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---
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Level 0 0 | A | (more specialized)
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---
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The linearizations of O,D,E and F are trivial::
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L[O] = O
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L[D] = D O
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L[E] = E O
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L[F] = F O
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The linearization of B can be computed as::
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L[B] = B + merge(DO, EO, DE)
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We see that D is a good head, therefore we take it and we are reduced to
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compute ``merge(O,EO,E)``. Now O is not a good head, since it is in the
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tail of the sequence EO. In this case the rule says that we have to
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skip to the next sequence. Then we see that E is a good head; we take
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it and we are reduced to compute ``merge(O,O)`` which gives O. Therefore::
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L[B] = B D E O
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Using the same procedure one finds::
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L[C] = C + merge(DO,FO,DF)
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= C + D + merge(O,FO,F)
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= C + D + F + merge(O,O)
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= C D F O
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Now we can compute::
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L[A] = A + merge(BDEO,CDFO,BC)
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= A + B + merge(DEO,CDFO,C)
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= A + B + C + merge(DEO,DFO)
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= A + B + C + D + merge(EO,FO)
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= A + B + C + D + E + merge(O,FO)
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= A + B + C + D + E + F + merge(O,O)
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= A B C D E F O
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In this example, the linearization is ordered in a pretty nice way
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according to the inheritance level, in the sense that lower levels (i.e.
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more specialized classes) have higher precedence (see the inheritance
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graph). However, this is not the general case.
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I leave as an exercise for the reader to compute the linearization for
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my second example:
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>>> O = object
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>>> class F(O): pass
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>>> class E(O): pass
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>>> class D(O): pass
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>>> class C(D,F): pass
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>>> class B(E,D): pass
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>>> class A(B,C): pass
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The only difference with the previous example is the change B(D,E) -->
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B(E,D); however even such a little modification completely changes the
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ordering of the hierarchy:
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.. code-block:: text
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6
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---
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Level 3 | O |
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/ --- \
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/ | \
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/ | \
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/ | \
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--- --- ---
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Level 2 2 | E | 4 | D | | F | 5
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--- --- ---
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\ / \ /
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\ / \ /
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\ / \ /
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--- ---
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Level 1 1 | B | | C | 3
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--- ---
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\ /
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\ /
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---
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Level 0 0 | A |
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---
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Notice that the class E, which is in the second level of the hierarchy,
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precedes the class C, which is in the first level of the hierarchy, i.e.
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E is more specialized than C, even if it is in a higher level.
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A lazy programmer can obtain the MRO directly from Python 2.2, since in
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this case it coincides with the Python 2.3 linearization. It is enough
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to invoke the :meth:`~type.mro` method of class A:
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>>> A.mro() # doctest: +NORMALIZE_WHITESPACE
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[<class 'A'>, <class 'B'>, <class 'E'>,
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<class 'C'>, <class 'D'>, <class 'F'>,
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<class 'object'>]
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Finally, let me consider the example discussed in the first section,
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involving a serious order disagreement. In this case, it is
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straightforward to compute the linearizations of O, X, Y, A and B:
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.. code-block:: text
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L[O] = 0
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L[X] = X O
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L[Y] = Y O
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L[A] = A X Y O
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L[B] = B Y X O
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However, it is impossible to compute the linearization for a class C
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that inherits from A and B::
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L[C] = C + merge(AXYO, BYXO, AB)
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= C + A + merge(XYO, BYXO, B)
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= C + A + B + merge(XYO, YXO)
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At this point we cannot merge the lists XYO and YXO, since X is in the
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tail of YXO whereas Y is in the tail of XYO: therefore there are no
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good heads and the C3 algorithm stops. Python 2.3 raises an error and
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refuses to create the class C.
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Bad Method Resolution Orders
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----------------------------
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A MRO is *bad* when it breaks such fundamental properties as local
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precedence ordering and monotonicity. In this section, I will show
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that both the MRO for classic classes and the MRO for new style classes
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in Python 2.2 are bad.
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It is easier to start with the local precedence ordering. Consider the
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following example:
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>>> F=type('Food',(),{'remember2buy':'spam'})
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>>> E=type('Eggs',(F,),{'remember2buy':'eggs'})
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>>> G=type('GoodFood',(F,E),{}) # under Python 2.3 this is an error! # doctest: +SKIP
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with inheritance diagram
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.. code-block:: text
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O
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(buy spam) F
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| E (buy eggs)
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| /
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G
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(buy eggs or spam ?)
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We see that class G inherits from F and E, with F *before* E: therefore
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we would expect the attribute *G.remember2buy* to be inherited by
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*F.rembermer2buy* and not by *E.remember2buy*: nevertheless Python 2.2
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gives
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>>> G.remember2buy # doctest: +SKIP
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'eggs'
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This is a breaking of local precedence ordering since the order in the
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local precedence list, i.e. the list of the parents of G, is not
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preserved in the Python 2.2 linearization of G::
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L[G,P22]= G E F object # F *follows* E
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One could argue that the reason why F follows E in the Python 2.2
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linearization is that F is less specialized than E, since F is the
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superclass of E; nevertheless the breaking of local precedence ordering
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is quite non-intuitive and error prone. This is particularly true since
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it is a different from old style classes:
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>>> class F: remember2buy='spam'
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>>> class E(F): remember2buy='eggs'
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>>> class G(F,E): pass # doctest: +SKIP
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>>> G.remember2buy # doctest: +SKIP
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'spam'
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In this case the MRO is GFEF and the local precedence ordering is
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preserved.
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As a general rule, hierarchies such as the previous one should be
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avoided, since it is unclear if F should override E or vice-versa.
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Python 2.3 solves the ambiguity by raising an exception in the creation
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of class G, effectively stopping the programmer from generating
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ambiguous hierarchies. The reason for that is that the C3 algorithm
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fails when the merge::
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merge(FO,EFO,FE)
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cannot be computed, because F is in the tail of EFO and E is in the tail
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of FE.
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The real solution is to design a non-ambiguous hierarchy, i.e. to derive
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G from E and F (the more specific first) and not from F and E; in this
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case the MRO is GEF without any doubt.
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.. code-block:: text
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O
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F (spam)
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/ |
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(eggs) E |
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\ |
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G
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(eggs, no doubt)
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Python 2.3 forces the programmer to write good hierarchies (or, at
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least, less error-prone ones).
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On a related note, let me point out that the Python 2.3 algorithm is
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smart enough to recognize obvious mistakes, as the duplication of
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classes in the list of parents:
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>>> class A(object): pass
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>>> class C(A,A): pass # error
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Traceback (most recent call last):
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File "<stdin>", line 1, in ?
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TypeError: duplicate base class A
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Python 2.2 (both for classic classes and new style classes) in this
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situation, would not raise any exception.
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Finally, I would like to point out two lessons we have learned from this
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example:
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1. despite the name, the MRO determines the resolution order of
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attributes, not only of methods;
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2. the default food for Pythonistas is spam ! (but you already knew
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that ;-)
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Having discussed the issue of local precedence ordering, let me now
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consider the issue of monotonicity. My goal is to show that neither the
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MRO for classic classes nor that for Python 2.2 new style classes is
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monotonic.
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To prove that the MRO for classic classes is non-monotonic is rather
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trivial, it is enough to look at the diamond diagram:
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.. code-block:: text
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C
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/ \
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/ \
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A B
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\ /
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\ /
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D
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One easily discerns the inconsistency::
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L[B,P21] = B C # B precedes C : B's methods win
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L[D,P21] = D A C B C # B follows C : C's methods win!
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On the other hand, there are no problems with the Python 2.2 and 2.3
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MROs, they give both::
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L[D] = D A B C
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Guido points out in his essay [#]_ that the classic MRO is not so bad in
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practice, since one can typically avoids diamonds for classic classes.
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But all new style classes inherit from ``object``, therefore diamonds are
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unavoidable and inconsistencies shows up in every multiple inheritance
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graph.
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The MRO of Python 2.2 makes breaking monotonicity difficult, but not
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impossible. The following example, originally provided by Samuele
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Pedroni, shows that the MRO of Python 2.2 is non-monotonic:
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>>> class A(object): pass
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>>> class B(object): pass
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>>> class C(object): pass
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>>> class D(object): pass
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>>> class E(object): pass
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>>> class K1(A,B,C): pass
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>>> class K2(D,B,E): pass
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|
>>> class K3(D,A): pass
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|
>>> class Z(K1,K2,K3): pass
|
|
|
|
Here are the linearizations according to the C3 MRO (the reader should
|
|
verify these linearizations as an exercise and draw the inheritance
|
|
diagram ;-) ::
|
|
|
|
L[A] = A O
|
|
L[B] = B O
|
|
L[C] = C O
|
|
L[D] = D O
|
|
L[E] = E O
|
|
L[K1]= K1 A B C O
|
|
L[K2]= K2 D B E O
|
|
L[K3]= K3 D A O
|
|
L[Z] = Z K1 K2 K3 D A B C E O
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|
|
|
Python 2.2 gives exactly the same linearizations for A, B, C, D, E, K1,
|
|
K2 and K3, but a different linearization for Z::
|
|
|
|
L[Z,P22] = Z K1 K3 A K2 D B C E O
|
|
|
|
It is clear that this linearization is *wrong*, since A comes before D
|
|
whereas in the linearization of K3 A comes *after* D. In other words, in
|
|
K3 methods derived by D override methods derived by A, but in Z, which
|
|
still is a subclass of K3, methods derived by A override methods derived
|
|
by D! This is a violation of monotonicity. Moreover, the Python 2.2
|
|
linearization of Z is also inconsistent with local precedence ordering,
|
|
since the local precedence list of the class Z is [K1, K2, K3] (K2
|
|
precedes K3), whereas in the linearization of Z K2 *follows* K3. These
|
|
problems explain why the 2.2 rule has been dismissed in favor of the C3
|
|
rule.
|
|
|
|
The end
|
|
-------
|
|
|
|
This section is for the impatient reader, who skipped all the previous
|
|
sections and jumped immediately to the end. This section is for the
|
|
lazy programmer too, who didn't want to exercise her/his brain.
|
|
Finally, it is for the programmer with some hubris, otherwise s/he would
|
|
not be reading a paper on the C3 method resolution order in multiple
|
|
inheritance hierarchies ;-) These three virtues taken all together (and
|
|
*not* separately) deserve a prize: the prize is a short Python 2.2
|
|
script that allows you to compute the 2.3 MRO without risk to your
|
|
brain. Simply change the last line to play with the various examples I
|
|
have discussed in this paper.::
|
|
|
|
#<mro.py>
|
|
|
|
"""C3 algorithm by Samuele Pedroni (with readability enhanced by me)."""
|
|
|
|
class __metaclass__(type):
|
|
"All classes are metamagically modified to be nicely printed"
|
|
__repr__ = lambda cls: cls.__name__
|
|
|
|
class ex_2:
|
|
"Serious order disagreement" #From Guido
|
|
class O: pass
|
|
class X(O): pass
|
|
class Y(O): pass
|
|
class A(X,Y): pass
|
|
class B(Y,X): pass
|
|
try:
|
|
class Z(A,B): pass #creates Z(A,B) in Python 2.2
|
|
except TypeError:
|
|
pass # Z(A,B) cannot be created in Python 2.3
|
|
|
|
class ex_5:
|
|
"My first example"
|
|
class O: pass
|
|
class F(O): pass
|
|
class E(O): pass
|
|
class D(O): pass
|
|
class C(D,F): pass
|
|
class B(D,E): pass
|
|
class A(B,C): pass
|
|
|
|
class ex_6:
|
|
"My second example"
|
|
class O: pass
|
|
class F(O): pass
|
|
class E(O): pass
|
|
class D(O): pass
|
|
class C(D,F): pass
|
|
class B(E,D): pass
|
|
class A(B,C): pass
|
|
|
|
class ex_9:
|
|
"Difference between Python 2.2 MRO and C3" #From Samuele
|
|
class O: pass
|
|
class A(O): pass
|
|
class B(O): pass
|
|
class C(O): pass
|
|
class D(O): pass
|
|
class E(O): pass
|
|
class K1(A,B,C): pass
|
|
class K2(D,B,E): pass
|
|
class K3(D,A): pass
|
|
class Z(K1,K2,K3): pass
|
|
|
|
def merge(seqs):
|
|
print '\n\nCPL[%s]=%s' % (seqs[0][0],seqs),
|
|
res = []; i=0
|
|
while 1:
|
|
nonemptyseqs=[seq for seq in seqs if seq]
|
|
if not nonemptyseqs: return res
|
|
i+=1; print '\n',i,'round: candidates...',
|
|
for seq in nonemptyseqs: # find merge candidates among seq heads
|
|
cand = seq[0]; print ' ',cand,
|
|
nothead=[s for s in nonemptyseqs if cand in s[1:]]
|
|
if nothead: cand=None #reject candidate
|
|
else: break
|
|
if not cand: raise "Inconsistent hierarchy"
|
|
res.append(cand)
|
|
for seq in nonemptyseqs: # remove cand
|
|
if seq[0] == cand: del seq[0]
|
|
|
|
def mro(C):
|
|
"Compute the class precedence list (mro) according to C3"
|
|
return merge([[C]]+map(mro,C.__bases__)+[list(C.__bases__)])
|
|
|
|
def print_mro(C):
|
|
print '\nMRO[%s]=%s' % (C,mro(C))
|
|
print '\nP22 MRO[%s]=%s' % (C,C.mro())
|
|
|
|
print_mro(ex_9.Z)
|
|
|
|
#</mro.py>
|
|
|
|
That's all folks,
|
|
|
|
enjoy !
|
|
|
|
|
|
Resources
|
|
---------
|
|
|
|
.. [#] The thread on python-dev started by Samuele Pedroni:
|
|
https://mail.python.org/pipermail/python-dev/2002-October/029035.html
|
|
|
|
.. [#] The paper *A Monotonic Superclass Linearization for Dylan*:
|
|
https://doi.org/10.1145/236337.236343
|
|
|
|
.. [#] Guido van Rossum's essay, *Unifying types and classes in Python 2.2*:
|
|
https://web.archive.org/web/20140210194412/http://www.python.org/download/releases/2.2.2/descrintro
|