python MRO

python MRO

一个小题目

你可以计算一个这样的题目，来验证你是否掌握了MRO，如果答案对的话，我想你可以不用看这个文章了

""" Created by FizLin on 2017/08/03/-下午6:58
    mail: https://github.com/Fiz1994
    新式类的继承
"""


class Init(object):
    def __init__(self, value):
        print('Init')
        self.value = value


class Add2(Init):
    def __init__(self, value):
        super(Add2, self).__init__(value)
        print('Add2')
        # self.value += 2
        self.value = 2 + self.value


class Mul5(Init):
    def __init__(self, value):
        super(Mul5, self).__init__(value)
        print('Mul5')
        # self.value *= 5
        self.value = self.value * 5


class Pro(Mul5, Add2):
    pass


class Incr(Pro):
    def __init__(self, value):
        super(Incr, self).__init__(value)
        # self.value += 1
        self.value = self.value + 1


'''
p = Incr(5)
print(p.value) #查看你的结果如果是36

如果你的答案是36恭喜你可以不用看了
如果你不知道36是怎么计算的那你可以继续看

MRO

我们首先来定义一些符号：

用 CN 表示一个类：C1, C2, C3, ..., CN
C1 C2 C3 ... CN 表示的是一个包含多个类的列表 [C1, C2, C3, ..., CN]

其中

head = C1
tail = C2 ... CN

加法运算

C + (C1 C2 ... CN) = C C1 C2 ... CN
[C] + [C1, C2, ... ,CN] = [C, C1, C2, ..., CN]

L[C] 表示类 C 的线性值，其实就是 C 的 MRO, 其中

L[object] = object

class C(B1, B2, ..., BN): pass

那么

L[C(B1 ... BN)] = C + merge(L[B1] ... L[BN], B1 ... BN)

merge 计算规则

1. take the head of the first list, i.e L[B1][0];
2. if this head is not in the tail of any of the other lists, then add it to the linearization of C and remove it from the lists in the merge, otherwise look at the head of the next list and take it, if it is a good head.
3. Then repeat the operation until all the class are removed or it is impossible to find good heads. In this case, it is impossible to construct the merge, Python 2.3 will refuse to create the class C and will raise an exception.1.

其实我也看不懂上面的内容，我们通过一些实例来说明

merge 学习

class B(object): pass

L[B] = L[B(object)]
     = B + merge(L[object])
     = B + L[object]
     = B object

>>> B.mro()
[<class '__main__.B'>, <type 'object'>]

第一个例子

class C(B): pass

L[C] = L[C(B)]
     = C + merge(L[B])
     = C + L[B]
     = C B object     # 从上面已经知道了 L[B] = B object

>>> C.mro()
[<class '__main__.C'>, <class '__main__.B'>, <type 'object'>]

下面来看一个复杂的例子:

>>> O = object
>>> 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

很容易可以算出来

L[O] = O = object
L[F] = L[F(O)] = F  O
L[E] = L[E(O)] = E  O
L[D] = L[D(O)] = D  O

下面来计算 C, B, A:

L[C]:

L[C] = L[C(D, F)]
     = C + merge(L[D], L[F], DF)
     # 从前面可知 L[D] 和 L[F] 的结果
     = C +  merge(DO, FO, DF)
     # 因为 D 是顺序第一个并且在几个包含 D 的 list 中是 head，
     # 所以这一次取 D 同时从列表中删除 D
     = C + D + merge(O, FO, F)
     # 因为 O 虽然是顺序第一个但在其他 list (FO)中不是 head, 跳过,
     # 改为检查第二个list FO # F 是第二个 list 和其他 list 的 head,
     # 取 F同时从列表中删除 F
     = C + D + F + merge(O)
     = C D F O

>>> C.mro()
[<class '__main__.C'>, <class '__main__.D'>, <class '__main__.F'>, <type 'object'>]

L[B]:

L[B] = L[B(D, E)]
     = B + merge(L[D], L[E], DE)
     = B + merge(DO, EO, DE)
     = B + D + merge(O, EO, E)
     = B + D + E + merge(O)
     = B D E O

>>> B.mro()
[<class '__main__.B'>, <class '__main__.D'>, <class '__main__.E'>, <type 'object'>]

L[A]:

L[A] = L[A(B, C)]
     = A + merge(L(B), L(C), BC)
     = A + merge(BDEO, CDFO, BC)
     = A + B + merge(DEO, CDFO, C)
     # 注意这里是 C , 因为第一个list 的 head D 不是其他list 的 head
     # 所以改为从下一个 list CDFO 开始
     = A + B + C + merge(DEO, DFO)
     = A + B + C + D + merge(EO, FO)
     = A + B + C  + D + E + merge(O, FO)
     = A + B + C + D + E + F + merge(O)
     = A B C D E F O

>>> A.mro()
[<class '__main__.A'>, <class '__main__.B'>, <class '__main__.C'>,
 <class '__main__.D'>, <class '__main__.E'>, <class '__main__.F'>, <type 'object'>]

到这里应该已经有一点眉目了。下面再来个上面那些类的变种，可以先自己算算看，后面有详细的计算过程。

>>> O = object
>>> 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

L[O] = O = object
L[F(O)] = F  O
L[E(O)] = E  O
L[D(O)] = D  O

L[C] = L[C(D, F)]
     = C + merge(L[D], L[F], DF)
     = C D F O

L[B] = L[B(E, D)]
     = B + merge(L[E], L[D], ED)
     = B + merge(EO, DO, ED)
     = B + E + merge(O, DO, D)
     = B + E + D + merge(O)
     = B E D O
>>> B.mro()
[<class '__main__.B'>, <class '__main__.E'>, <class '__main__.D'>, <type 'object'>]

L[A] = L[A(B, C)]
     = A + merge(L[B], L[C], BC)
     = A + merge(BEDO, CDFO, BC)
     = A + B + merge(EDO, CDFO, C)
     = A + B + E + merge(DO, CDFO, C)
     = A + B + E + C + merge(DO, DFO)
     = A + B + E + C + D + merge(O, FO)
     = A + B + E + C + D + F + merge(O)
     = A B E C D F O
>>> A.mro()
[<class '__main__.A'>, <class '__main__.B'>, <class '__main__.E'>,
 <class '__main__.C'>, <class '__main__.D'>, <class '__main__.F'>, <type 'object'>]

资料

你可以看看官方对这个的解释
https://www.python.org/download/releases/2.3/mro/

回归题目

根据MRO 的计算方式我们可以指导题目的MRO 顺讯wei：

print(Incr.__mro__)#(<class '__main__.Incr'>, <class '__main__.Pro'>, <class '__main__.Mul5'>, <class '__main__.Add2'>, <class '__main__.Init'>, <class 'object'>)

print(Init.__mro__)  # (<class '__main__.Init'>, <class 'object'>)
print(
    Pro.__mro__)  # (<class '__main__.Pro'>, <class '__main__.Mul5'>, <class '__main__.Add2'>, <class '__main__.Init'>, <class 'object'>)
print(Add2.__mro__)  # (<class '__main__.Add2'>, <class '__main__.Init'>, <class 'object'>)

因此可以得到这个结果

引用

这个文章中MRO 的计算是引用此https://mozillazg.github.io/2016/11/python-mro-compute.html