觉得 Python 太“简单了”，这些题你能答对几个？

前言

觉得 Python 太“简单了”？作为一个 Python 开发者，我必须要给你一点人生经验，不然你不知道天高地厚！）一份满分 100 分的题，这篇文章就是记录下做这套题所踩过的坑。

下面的代码会报错，为什么？

class A(object):
x = 1
gen = (x for _ in xrange(10))  # gen=(x for _ in range(10))
if __name__ == "__main__":
print(list(A.gen))

答案

这个问题是变量作用域问题，在 

gen=(x for _ in xrange(10))

gen

generator

generator

NameError: name 'x' is not defined

class A(object):
x = 1
gen = (lambda x: (x for _ in xrange(10)))(x)  # gen=(x for _ in range(10))
if __name__ == "__main__":
print(list(A.gen))

2.装饰器

描述

我想写一个类装饰器用来度量函数/方法运行时间

import time
class Timeit(object):
def __init__(self, func):
self._wrapped = func
def __call__(self, *args, **kws):
start_time = time.time()
result = self._wrapped(*args, **kws)
print("elapsed time is %s " % (time.time() - start_time))
return result

这个装饰器能够运行在普通函数上：

@Timeit
def func():
time.sleep(1)
return "invoking function func"
if __name__ == '__main__':
func()  # output: elapsed time is 1.00044410133

但是运行在方法上会报错，为什么？

class A(object):
@Timeit
def func(self):
time.sleep(1)
return 'invoking method func'
if __name__ == '__main__':
a = A()
a.func()  # Boom!

如果我坚持使用类装饰器，应该如何修改？

答案

使用类装饰器后，在调用 

func

__call__

mehtod unbound

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class Timeit(object):
def __init__(self, func):
self.func = func
def __call__(self, *args, **kwargs):
print('invoking Timer')
def __get__(self, instance, owner):
return lambda *args, **kwargs: self.func(instance, *args, **kwargs)

3.Python 调用机制

描述

我们知道 

__call__

class A(object):
def __call__(self):
print("invoking __call__ from A!")
if __name__ == "__main__":
a = A()
a()  # output: invoking __call__ from A

现在我们可以看到 

a()

a.__call__()

a.__call__ = lambda: "invoking __call__ from lambda"
a.__call__()
# output:invoking __call__ from lambda
a()
# output:invoking __call__ from A!

请大佬们解释下，为什么 

a()

a.__call__()

答案

原因在于，在 Python 中，新式类（ new class )的内建特殊方法，和实例的属性字典是相互隔离的，具体可以看看 Python 官方文档对于这一情况的说明

For new-style classes, implicit invocations of special methods are only guaranteed to work correctly if defined on an object’s type, not in the object’s instance dictionary. That behaviour is the reason why the following code raises an exception (unlike the equivalent example with old-style classes):

同时官方也给出了一个例子：

class C(object):
pass
c = C()
c.__len__ = lambda: 5
len(c)
# Traceback (most recent call last):
#  File "", line 1, in
# TypeError: object of type 'C' has no len()

回到我们的例子上来，当我们在执行 

a.__call__=lambda:"invoking __call__ from lambda"

a.__dict__

__call__

a()

a.__dict__

tyee(a).__dict__

4.描述符

描述

我想写一个 Exam 类，其属性 math 为 [0,100] 的整数，若赋值时不在此范围内则抛出异常，我决定用描述符来实现这个需求。

class Grade(object):
def __init__(self):
self._score = 0
def __get__(self, instance, owner):
return self._score
def __set__(self, instance, value):
if 0 <= 0="" 75="" 90="" value="" <="100:" self._score="value" else:="" raise="" valueerror('grade="" must="" be="" between="" and="" 100')="" exam(object):="" math="Grade()" def="" __init__(self,="" math):="" self.math="math" if="" __name__="=" '__main__':="" niche="Exam(math=90)" print(niche.math)="" #="" output="" :="" snake="Exam(math=75)" print(snake.math)="" snake.math="120" output:="" valueerror:grade="" 100!<="" code="">

看起来一切正常。不过这里面有个巨大的问题，尝试说明是什么问题
为了解决这个问题，我改写了 Grade 描述符如下：

class Grad(object):
def __init__(self):
self._grade_pool = {}
def __get__(self, instance, owner):
return self._grade_pool.get(instance, None)
def __set__(self, instance, value):
if 0 <= value="" <="100:" _grade_pool="self.__dict__.setdefault('_grade_pool'," {})="" _grade_pool[instance]="value" else:="" raise="" valueerror("fuck")<="" code="">

不过这样会导致更大的问题，请问该怎么解决这个问题？

答案

1.第一个问题的其实很简单，如果你再运行一次 

print(niche.math)

120

__dict__

Exam

self.math

__dict__

Exam

self.math

math

__set__

__get__

__delete__

__set_name__

__get__

__set__

__delete__

__set_name__

__get__

Non-Data descriptor

__dict__

__dict__

Data descriptors

Non-Data descriptors

Non-Data descriptor

__set__

Data descriptors

math

2.经过改良的做法，利用 

dict

dict

dict

dict

dict

key

class Grad(object):
def __init__(self):
import weakref
self._grade_pool = weakref.WeakKeyDictionary()
def __get__(self, instance, owner):
return self._grade_pool.get(instance, None)
def __set__(self, instance, value):
if 0 <= value="" <="100:" _grade_pool="self.__dict__.setdefault('_grade_pool'," {})="" _grade_pool[instance]="value" else:="" raise="" valueerror("fuck")<="" code="">

weakref 库中的 

WeakKeyDictionary

WeakValueDictionary

class Grad(object):
def __get__(self, instance, owner):
return instance.__dict__[self.key]
def __set__(self, instance, value):
if 0 <= value="" <="100:" instance.__dict__[self.key]="value" else:="" raise="" valueerror("fuck")="" def="" __set_name__(self,="" owner,="" name):="" self.key="name

这道题涉及的东西比较多，这里给出一点参考链接，invoking-descriptors , Descriptor HowTo Guide , PEP 487 , what`s new in Python 3.6 。

5.Python 继承机制

描述

试求出以下代码的输出结果。

class Init(object):
def __init__(self, value):
self.val = value
class Add2(Init):
def __init__(self, val):
super(Add2, self).__init__(val)
self.val += 2
class Mul5(Init):
def __init__(self, val):
super(Mul5, self).__init__(val)
self.val *= 5
class Pro(Mul5, Add2):
pass
class Incr(Pro):
csup = super(Pro)
def __init__(self, val):
self.csup.__init__(val)
self.val += 1
p = Incr(5)
print(p.val)

答案

输出是 36 ，具体可以参考 New-style Classes , multiple-inheritance

6. Python 特殊方法

描述

我写了一个通过重载 new 方法来实现单例模式的类。

class Singleton(object):
_instance = None
def __new__(cls, *args, **kwargs):
if cls._instance:
return cls._instance
cls._isntance = cv = object.__new__(cls, *args, **kwargs)
return cv
sin1 = Singleton()
sin2 = Singleton()
print(sin1 is sin2)
# output: True

现在我有一堆类要实现为单例模式，所以我打算照葫芦画瓢写一个元类，这样可以让代码复用：

class SingleMeta(type):
def __init__(cls, name, bases, dict):
cls._instance = None
__new__o = cls.__new__
def __new__(cls, *args, **kwargs):
if cls._instance:
return cls._instance
cls._instance = cv = __new__o(cls, *args, **kwargs)
return cv
cls.__new__ = __new__o
class A(object):
__metaclass__ = SingleMeta
a1 = A()  # what`s the fuck

之前用这种方法给 

__getattribute__

class TraceAttribute(type):
def __init__(cls, name, bases, dict):
__getattribute__o = cls.__getattribute__
def __getattribute__(self, *args, **kwargs):
print('__getattribute__:', args, kwargs)
return __getattribute__o(self, *args, **kwargs)
cls.__getattribute__ = __getattribute__
class A(object):  # Python 3 是 class A(object,metaclass=TraceAttribute):
__metaclass__ = TraceAttribute
a = 1
b = 2
a = A()
a.a
# output: __getattribute__:('a',){}
a.b

试解释为什么给 getattribute 打补丁成功，而 new 打补丁失败。
如果我坚持使用元类给 new 打补丁来实现单例模式，应该怎么修改？

答案

其实这是最气人的一点，类里的 

__new__

staticmethod

staticmethod

class SingleMeta(type):
def __init__(cls, name, bases, dict):
cls._instance = None
__new__o = cls.__new__
@staticmethod
def __new__(cls, *args, **kwargs):
if cls._instance:
return cls._instance
cls._instance = cv = __new__o(cls, *args, **kwargs)
return cv
cls.__new__ = __new__o
class A(object):
__metaclass__ = SingleMeta
print(A() is A())  # output: True

##结语

说实话 Python 的动态特性可以让其用众多 

black magic