Python 作为一门面向对象编程语言,罕用的面向对象常识怎么能不分明呢,明天就来分享一波
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[TOC]
在 Python 中创立一个类及其对象
class Employee:
salary = 10000
name = "John Doe"
emp1 = Employee()
print(emp1.salary)
print(emp1.name)
Output:
10000
John Doe
在 Python 中创立一个空类
class Employee:
pass
e1 = Employee()
print(e1)
e1.name = "John Doe"
print(e1.name)
Output:
<__main__.Employee object at 0x0000000002DA51D0>
John Doe
在 Python 中应用 Type 创立类
e1 = type('Employee', (), {})()
print(e1)
e1.name = "John Doe"
print(e1.name)
Output:
<__main__.Employee object at 0x0000000002DCC780>
John Doe
在 Python 中创立和调用类的办法
class Employee:
salary = 10000
name = "John Doe"
def tax(self):
print(self.salary * 0.10)
emp1 = Employee()
print(emp1.salary)
print(emp1.name)
emp1.tax()
Output:
10000
John Doe
1000.0
应用 __init__() 办法为数据属性赋值
class Employee:
def __init__(self, salary, name):
self.salary = salary
self.name = name
emp1 = Employee(10000, "John Doe")
print(emp1.salary)
print(emp1.name)
Output:
10000
John Doe
在 Python 中更新对象属性
class Employee:
def __init__(self, salary, name):
self.salary = salary
self.name = name
emp1 = Employee(10000, "John Doe")
print(emp1.salary)
emp1.salary = 20000
print(emp1.salary)
Output:
10000
20000
在 Python 中删除对象属性和对象
class Employee:
def __init__(self, salary, name):
self.salary = salary
self.name = name
emp1 = Employee(10000, "John Doe")
del emp1.salary # Delete object property
del emp1 # Delete object
Output:
哈哈
在 Python 中检查和比拟对象的类型
class Test(object):
pass
print(type(Test))
obj1 = Test()
print(type(obj1))
obj2 = Test()
print(type(obj1) is type(obj2))
Output:
< class 'type' >
< class '__main__.Test' >
True
在 Python 中将对象的所有属性复制到另一个对象
class MyClass(object):
def __init__(self):
super(MyClass, self).__init__()
self.foo = 1
self.bar = 2
obj1 = MyClass()
obj2 = MyClass()
obj1.foo = 25
obj2.__dict__.update(obj1.__dict__)
print(obj1.foo)
print(obj2.foo)
Output:
25
25
在 Python 中迭代对象属性
class A():
m = 1
n = 2
def __int__(self, x=1, y=2, z=3):
self.x = x
self._y = y
self.__z__ = z
def xyz(self):
print(x, y, z)
obj = A()
print(dir(obj))
print([a for a in dir(obj) if not a.startswith('__')])
Output:
['__class__', '__delattr__', '__dict__', '__dir__', '__doc__', '__eq__', '__format__', '__ge__', '__getattribute__', '__gt__', '__hash__', '__init__', '__int__', '__le__', '__lt__', '__module__', '__ne__', '__new__', '__reduce__', '__reduce_ex__', '__repr__', '__setattr__', '__sizeof__', '__str__', '__subclasshook__', '__weakref__', 'm', 'n', 'xyz']
['m', 'n', 'xyz']
在 Python 中打印对象的所有属性
class Animal(object):
def __init__(self):
self.eyes = 2
self.name = 'Dog'
self.color= 'Spotted'
self.legs= 4
self.age = 10
self.kids = 0
animal = Animal()
animal.tail = 1
temp = vars(animal)
for item in temp:
print(item, ':', temp[item])
Output:
kids : 0
eyes : 2
name : Dog
color : Spotted
tail : 1
legs : 4
age : 10
在 python 中在运行时创立类的数据属性
class Employee:
pass
emp1 = Employee()
setattr(emp1, 'Salary', 12000)
emp2 = Employee()
setattr(emp2, 'Age', 25)
print(emp1.Salary)
print(emp2.Age)
Output:
12000
25
在函数中将对象的实例作为参数传递
class Vehicle:
def __init__(self):
self.trucks = []
def add_truck(self, truck):
self.trucks.append(truck)
class Truck:
def __init__(self, color):
self.color = color
def __repr__(self):
return "{}".format(self.color)
def main():
v = Vehicle()
for t in 'Red Blue Black'.split():
t = Truck(t)
v.add_truck(t)
print(v.trucks)
if __name__ == "__main__":
main()
Output:
[Red, Blue, Black]
在 Python 中创立和应用自定义 Self 参数
class Employee:
def __init__(person, salary, name):
person.salary = salary
person.name = name
def print_details(emp):
print(str(emp.salary) + ':' + emp.name)
emp1 = Employee(10000, 'John Doe')
emp1.print_details()
Output:
10000 : John Doe
应用 self 参数来保护对象的状态
class State(object):
def __init__(self):
self.field = 5.0
def add(self, x):
self.field += x
def mul(self, x):
self.field *= x
def div(self, x):
self.field /= x
def sub(self, x):
self.field -= x
s = State()
print(s.field)
s.add(2) # Self is implicitly passed.
print(s.field)
s.mul(2) # Self is implicitly passed.
print(s.field)
s.div(2) # Self is implicitly passed.
print(s.field)
s.sub(2) # Self is implicitly passed.
print(s.field)
Output:
5.0
7.0
14.0
7.0
5.0
在 Python 中创立和应用动态类变量
class Employee:
age = 25
print(Employee.age)
e = Employee()
print(e.age)
e.age = 30
print(Employee.age) # 25
print(e.age) # 30
Output:
25
25
25
30
在 Python 中的一个函数上应用多个装璜器
def my_decorator(func):
def wrapper():
print("Step - 1")
func()
print("Step - 3")
return wrapper
def repeat(func):
def wrapper():
func()
func()
func()
return wrapper
@my_decorator
@repeat
def start_steps():
print("Step - 2")
start_steps()
Output:
Step - 1
Step - 2
Step - 2
Step - 2
Step - 3
在 Python 中的办法中同时拜访 cls 和 self
class MyClass:
__var2 = 'var2'
var3 = 'var3'
def __init__(self):
self.__var1 = 'var1'
def normal_method(self):
print(self.__var1)
@classmethod
def class_method(cls):
print(cls.__var2)
def my_method(self):
print(self.__var1)
print(self.__var2)
print(self.__class__.__var2)
if __name__ == '__main__':
print(MyClass.__dict__['var3'])
clzz = MyClass()
clzz.my_method()
Output:
var3
var1
var2
var2
从装璜器拜访实例办法的类
class Decorator(object):
def __init__(self, decoratee_enclosing_class):
self.decoratee_enclosing_class = decoratee_enclosing_class
def __call__(self, original_func):
def new_function(*args, **kwargs):
print('decorating function in', self.decoratee_enclosing_class)
original_func(*args, **kwargs)
return new_function
class Bar(object):
@Decorator('Bar')
def foo(self):
print('in foo')
class Baz(object):
@Decorator('Baz')
def foo(self):
print('in foo')
print('before instantiating Bar()')
b = Bar()
print('calling b.foo()')
b.foo()
Output:
before instantiating Bar()
calling b.foo()
decorating function in Bar
in foo
应用给定的装璜器获取 Python 类的所有办法
import inspect
def deco(func):
return func
def deco2():
def wrapper(func):
pass
return wrapper
class Test(object):
@deco
def method(self):
pass
@deco2()
def method2(self):
pass
def methodsWithDecorator(cls, decoratorName):
sourcelines = inspect.getsourcelines(cls)[0]
for i, line in enumerate(sourcelines):
line = line.strip()
if line.split('(')[0].strip() == '@' + decoratorName: # leaving a bit out
nextLine = sourcelines[i + 1]
name = nextLine.split('def')[1].split('(')[0].strip()
yield(name)
print(list(methodsWithDecorator(Test, 'deco')))
print(list(methodsWithDecorator(Test, 'deco2')))
Output:
['method']
['method2']
装璜一个 class
from functools import wraps
def dec(msg='default'):
def decorator(klass):
old_foo = klass.foo
@wraps(klass.foo)
def decorated_foo(self, *args, **kwargs):
print('@decorator pre %s' % msg)
old_foo(self, *args, **kwargs)
print('@decorator post %s' % msg)
klass.foo = decorated_foo
return klass
return decorator
@dec('foo decorator')
class Foo(object):
def foo(self, *args, **kwargs):
print('foo.foo()')
@dec('subfoo decorator')
class SubFoo(Foo):
def foo(self, *args, **kwargs):
print('subfoo.foo() pre')
super(SubFoo, self).foo(*args, **kwargs)
print('subfoo.foo() post')
@dec('subsubfoo decorator')
class SubSubFoo(SubFoo):
def foo(self, *args, **kwargs):
print('subsubfoo.foo() pre')
super(SubSubFoo, self).foo(*args, **kwargs)
print('subsubfoo.foo() post')
SubSubFoo().foo()
Output:
@decorator pre subsubfoo decorator
subsubfoo.foo() pre
@decorator pre subfoo decorator
subfoo.foo() pre
@decorator pre foo decorator
foo.foo()
@decorator post foo decorator
subfoo.foo() post
@decorator post subfoo decorator
subsubfoo.foo() post
@decorator post subsubfoo decorator
将类字段作为参数传递给类办法上的装璜器
import functools
# imagine this is at some different place and cannot be changed
def check_authorization(some_attr, url):
def decorator(func):
@functools.wraps(func)
def wrapper(*args, **kwargs):
print(f"Welcome Message:'{url}'...")
return func(*args, **kwargs)
return wrapper
return decorator
# another dummy function to make the example work
def do_work():
print("work is done...")
def custom_check_authorization(some_attr):
def decorator(func):
# assuming this will be used only on this particular class
@functools.wraps(func)
def wrapper(self, *args, **kwargs):
# get url
url = self.url
# decorate function with original decorator, pass url
return check_authorization(some_attr, url)(func)(self, *args, **kwargs)
return wrapper
return decorator
class Client(object):
def __init__(self, url):
self.url = url
@custom_check_authorization("some_attr")
def get(self):
do_work()
# create object
client = Client('Hello World')
# call decorated function
client.get()
Output:
Welcome Message: 'Hello World'...
work is done...
在 Python 中创立多个传入参数列表的类变量
class Employee(object):
def __init__(self, **kwargs):
for key in kwargs:
setattr(self, key, kwargs[key])
emp = Employee(age=25, name="John Doe")
print(emp.age)
print(emp.name)
Output:
25
John Doe
Python 中的 wraps 装璜器
from functools import wraps
def decorator_func_with_args(arg1, arg2):
def decorator(f):
@wraps(f)
def wrapper(*args, **kwargs):
print("Before orginal function with decorator args:", arg1, arg2)
result = f(*args, **kwargs)
print("Ran after the orginal function")
return result
return wrapper
return decorator
@decorator_func_with_args("test1", "test2")
def hello(name):
"""A function which prints a greeting to the name provided."""
print('Hello', name)
return 25
print("Starting script..")
x = hello('John')
print("The value of x is:", x)
print("The wrapped functions docstring is:", hello.__doc__)
print("The wrapped functions name is:", hello.__name__)
Output:
Starting script..
Before orginal function with decorator args: test1 test2
Hello John
Ran after the orginal function
The value of x is: 25
The wrapped functions docstring is: A function which prints a greeting to the name provided.
The wrapped functions name is: hello
应用可选参数构建装璜器
def d(arg):
if callable(arg): # Assumes optional argument isn't.
def newfn():
print('my default message')
return arg()
return newfn
else:
def d2(fn):
def newfn():
print(arg)
return fn()
return newfn
return d2
@d('This is working')
def hello():
print('hello world !')
@d # No explicit arguments will result in default message.
def hello2():
print('hello2 world !')
@d('Applying it twice')
@d('Would also work')
def hello3():
print('hello3 world !')
hello()
hello2()
hello3()
Output:
This is working
hello world !
my default message
hello2 world !
Applying it twice
Would also work
hello3 world !
在 Python 中将参数传递给装璜器
def decorator_maker_with_arguments(decorator_arg1, decorator_arg2, decorator_arg3):
def decorator(func):
def wrapper(function_arg1, function_arg2, function_arg3):
print("The wrapper can access all the variables\n"
"\t- from the decorator maker: {0} {1} {2}\n"
"\t- from the function call: {3} {4} {5}\n"
"and pass them to the decorated function"
.format(decorator_arg1, decorator_arg2, decorator_arg3,
function_arg1, function_arg2, function_arg3))
return func(function_arg1, function_arg2, function_arg3)
return wrapper
return decorator
@decorator_maker_with_arguments("canada", "us", "brazil")
def decorated_function_with_arguments(function_arg1, function_arg2, function_arg3):
print("This is the decorated function and it only knows about its arguments: {0}"
"{1}" "{2}".format(function_arg1, function_arg2, function_arg3))
decorated_function_with_arguments("france", "germany", "uk")
Output:
The wrapper can access all the variables
- from the decorator maker: canada us brazil
- from the function call: france germany uk
and pass them to the decorated function
This is the decorated function and it only knows about its arguments: france germany uk
@property 装璜器
class Currency:
def __init__(self, dollars, cents):
self.total_cents = dollars * 100 + cents
@property
def dollars(self):
return self.total_cents // 100
@dollars.setter
def dollars(self, new_dollars):
self.total_cents = 100 * new_dollars + self.cents
@property
def cents(self):
return self.total_cents % 100
@cents.setter
def cents(self, new_cents):
self.total_cents = 100 * self.dollars + new_cents
currency = Currency(10, 20)
print(currency.dollars, currency.cents, currency.total_cents)
currency.dollars += 5
print(currency.dollars, currency.cents, currency.total_cents)
currency.cents += 15
print(currency.dollars, currency.cents, currency.total_cents)
Output:
10 20 1020
15 20 1520
15 35 1535
类和函数的装璜器
from functools import wraps
def decorator(func):
@wraps(func)
def wrapper(*args, **kwargs):
print('sth to log: %s : %s' % (func.__name__, args))
return func(*args, **kwargs)
return wrapper
class Class_test(object):
@decorator
def sum_func(self, a, b):
print('class sum: %s' % (a + b))
return a + b
print(Class_test.sum_func(1, 5, 16))
Output:
sth to log: sum_func : (1, 5, 16)
class sum: 21
21
Python 中带参数和返回值的装璜器
def calculation(func):
def wrapper(*args, **kwargs):
print("Inside the calculation function")
num_sum = func(*args, **kwargs)
print("Before return from calculation function")
return num_sum
return wrapper
@calculation
def addition(a, b):
print("Inside the addition function")
return a + b
print("Sum =", addition(5, 10))
Output:
Inside the calculation function
Inside the addition function
Before return from calculation function
Sum = 15
Python 应用参数 wraps 装璜器
from functools import wraps
def decorator_func_with_args(arg1, arg2):
def decorator(f):
@wraps(f)
def wrapper(*args, **kwargs):
print("Before orginal function with decorator args:", arg1, arg2)
result = f(*args, **kwargs)
print("Ran after the orginal function")
return result
return wrapper
return decorator
@decorator_func_with_args("test1", "test2")
def hello(name):
"""A function which prints a greeting to the name provided."""
print('Hello', name)
return 25
print("Starting script..")
x = hello('John')
print("The value of x is:", x)
print("The wrapped functions docstring is:", hello.__doc__)
print("The wrapped functions name is:", hello.__name__)
Output:
Starting script..
Before orginal function with decorator args: test1 test2
Hello John
Ran after the orginal function
The value of x is: 25
The wrapped functions docstring is: A function which prints a greeting to the name provided.
The wrapped functions name is: hello
Python 装璜器获取类名
def print_name(*args):
def _print_name(fn):
def wrapper(*args, **kwargs):
print('{}.{}'.format(fn.__module__, fn.__qualname__))
return fn(*args, **kwargs)
return wrapper
return _print_name
class A():
@print_name()
def a():
print('Hi from A.a')
@print_name()
def b():
print('Hi from b')
A.a()
b()
Output:
__main__.A.a
Hi from A.a
__main__.b
Hi from b
简略装璜器示例
def my_decorator(func):
def wrapper():
print("Step - 1")
func()
print("Step - 3")
return wrapper
@my_decorator
def start_steps():
print("Step - 2")
start_steps()
Output:
Step - 1
Step - 2
Step - 3
在 Python 中应用 print() 打印类的实例
class Element:
def __init__(self, name, city, population):
self.name = name
self.city = city
self.population = population
def __str__(self):
return str(self.__class__) + '\n' + '\n'.join(('{} = {}'.format(item, self.__dict__[item]) for item in self.__dict__))
elem = Element('canada', 'tokyo', 321345)
print(elem)
Output:
name = canada
city = tokyo
population = 321345
在 Python 中的类中将装璜器定义为办法
class myclass:
def __init__(self):
self.cnt = 0
def counter(self, function):
"""this method counts the number of runtime of a function"""
def wrapper(**args):
function(self, **args)
self.cnt += 1
print('Counter inside wrapper:', self.cnt)
return wrapper
global counter_object
counter_object = myclass()
@counter_object.counter
def somefunc(self):
print("Somefunc called")
somefunc()
print(counter_object.cnt)
somefunc()
print(counter_object.cnt)
somefunc()
print(counter_object.cnt)
Output:
Somefunc called
Counter inside wrapper: 1
1
Somefunc called
Counter inside wrapper: 2
2
Somefunc called
Counter inside wrapper: 3
3
获取在 Python 中润饰的给定类的所有办法
class awesome(object):
def __init__(self, method):
self._method = method
def __call__(self, obj, *args, **kwargs):
return self._method(obj, *args, **kwargs)
@classmethod
def methods(cls, subject):
def g():
for name in dir(subject):
method = getattr(subject, name)
if isinstance(method, awesome):
yield name, method
return {name: method for name, method in g()}
class Robot(object):
@awesome
def think(self):
return 0
@awesome
def walk(self):
return 0
def irritate(self, other):
return 0
print(awesome.methods(Robot))
Output:
{'think': <__main__.awesome object at 0x00000213C052AAC0>, 'walk': <__main__.awesome object at 0x00000213C0E33FA0>}
带参数和不带参数的 Python 装璜器
def someDecorator(arg=None):
def decorator(func):
def wrapper(*a, **ka):
if not callable(arg):
print(arg)
return func(*a, **ka)
else:
return 'xxxxx'
return wrapper
if callable(arg):
return decorator(arg) # return 'wrapper'
else:
return decorator # ... or 'decorator'
@someDecorator(arg=1)
def my_func():
print('my_func')
@someDecorator
def my_func1():
print('my_func1')
if __name__ == "__main__":
my_func()
my_func1()
Output:
1
my_func
Python 中带有 self 参数的类办法装璜器
def check_authorization(f):
def wrapper(*args):
print('Inside wrapper function argement passed :', args[0].url)
return f(*args)
return wrapper
class Client(object):
def __init__(self, url):
self.url = url
@check_authorization
def get(self):
print('Inside get function argement passed :', self.url)
Client('Canada').get()
Output:
Inside wrapper function argement passed : Canada
Inside get function argement passed : Canada
在 Python 中的另一个类中应用暗藏的装璜器
class TestA(object):
def _decorator(foo):
def magic(self):
print("Start magic")
foo(self)
print("End magic")
return magic
@_decorator
def bar(self):
print("Normal call")
_decorator = staticmethod(_decorator)
class TestB(TestA):
@TestA._decorator
def bar(self):
print("Override bar in")
super(TestB, self).bar()
print("Override bar out")
print("Normal:")
test = TestA()
test.bar()
print('-' * 10)
print("Inherited:")
b = TestB()
b.bar()
Output:
Normal:
Start magic
Normal call
End magic
----------
Inherited:
Start magic
Override bar in
Start magic
Normal call
End magic
Override bar out
End magic
装璜器外部的 self 对象
import random
def only_registered_users(func):
def wrapper(handler):
print('Checking if user is logged in')
if random.randint(0, 1):
print('User is logged in. Calling the original function.')
func(handler)
else:
print('User is NOT logged in. Redirecting...')
return wrapper
class MyHandler(object):
@only_registered_users
def get(self):
print('Get function called')
m = MyHandler()
m.get()
Output:
Checking if user is logged in
User is logged in. Calling the original function.
Get function called
在 Python 中将多个装璜器利用于单个函数
def multiplication(func):
def wrapper(*args, **kwargs):
num_sum = func(*args, **kwargs)
print("Inside the multiplication function", num_sum)
return num_sum * num_sum
return wrapper
def addition(func):
def wrapper(*args, **kwargs):
num_sum = func(*args, **kwargs)
print("Inside the addition function", num_sum)
return num_sum + num_sum
return wrapper
@addition
@multiplication
def calculation(a):
print("Inside the calculation function", a)
return a
print("Sum =", calculation(5))
Output:
Inside the calculation function 5
Inside the multiplication function 5
Inside the addition function 25
Sum = 50
Python 装璜器获取类实例
class MySerial():
def __init__(self):
pass # I have to have an __init__
def write(self, *args):
print(args[0])
pass # write to buffer
def read(self):
pass # read to buffer
@staticmethod
def decorator(func):
def func_wrap(cls, *args, **kwargs):
cls.ser.write(func(cls, *args, **kwargs))
return cls.ser.read()
return func_wrap
class App():
def __init__(self):
self.ser = MySerial()
@MySerial.decorator
def myfunc(self):
self = 100
return ['canada', 'australia']
App().myfunc()
Output:
['canada', 'australia']
init 和 call 有什么区别
class Counter:
def __init__(self):
self._weights = []
for i in range(0, 2):
self._weights.append(1)
print(str(self._weights[-2]) + "No. from __init__")
def __call__(self, t):
self._weights = [self._weights[-1], self._weights[-1]
+ self._weights[-1]]
print(str(self._weights[-1]) + "No. from __call__")
num_count = Counter()
for i in range(0, 4):
num_count(i)
Output:
1 No. from __init__
2 No. from __call__
4 No. from __call__
8 No. from __call__
16 No. from __call__
在 Python 中应用 new 和 init
class Shape:
def __new__(cls, sides, *args, **kwargs):
if sides == 3:
return Triangle(*args, **kwargs)
else:
return Square(*args, **kwargs)
class Triangle:
def __init__(self, base, height):
self.base = base
self.height = height
def area(self):
return (self.base * self.height) / 2
class Square:
def __init__(self, length):
self.length = length
def area(self):
return self.length*self.length
a = Shape(sides=3, base=2, height=12)
b = Shape(sides=4, length=2)
print(str(a.__class__))
print(a.area())
print(str(b.__class__))
print(b.area())
Output:
class '__main__.Triangle'
12.0
class '__main__.Square'
4
Python 中的迭代重载办法
class Counter:
def __init__(self, low, high):
self.current = low
self.high = high
def __iter__(self):
return self
def __next__(self):
if self.current > self.high:
raise StopIteration
else:
self.current += 1
return self.current - 1
for num in Counter(5, 15):
print(num)
Output:
5
6
..
..
15
在 Python 中应用迭代器反转字符串
class Reverse:
def __init__(self, data):
self.data = data
self.index = len(data)
def __iter__(self):
return self
def __next__(self):
if self.index == 0:
raise StopIteration
self.index = self.index - 1
return self.data[self.index]
test = Reverse('Python')
for char in test:
print(char)
Output:
n
o
h
t
y
P
Python 中 reversed 魔术办法
class Count:
def __init__(self, start, end):
self.start = start
self.end = end
self.current = None
def __iter__(self):
self.current = self.start
while self.current < self.end:
yield self.current
self.current += 1
def __next__(self):
if self.current is None:
self.current = self.start
if self.current > self.end:
raise StopIteration
else:
self.current += 1
return self.current-1
def __reversed__(self):
self.current = self.end
while self.current >= self.start:
yield self.current
self.current -= 1
obj1 = Count(0, 5)
for i in obj1:
print(i)
obj2 = reversed(obj1)
for i in obj2:
print(i)
Output:
0
1
2
....
2
1
0
Python 中的 getitem 和 setitem
class Counter(object):
def __init__(self, floors):
self._floors = [None]*floors
def __setitem__(self, floor_number, data):
self._floors[floor_number] = data
def __getitem__(self, floor_number):
return self._floors[floor_number]
index = Counter(4)
index[0] = 'ABCD'
index[1] = 'EFGH'
index[2] = 'IJKL'
index[3] = 'MNOP'
print(index[2])
Output:
IJKL
在 Python 中应用 getattr 和 setattr 进行属性赋值
class Employee(object):
def __init__(self, data):
super().__setattr__('data', dict())
self.data = data
def __getattr__(self, name):
if name in self.data:
return self.data[name]
else:
return 0
def __setattr__(self, key, value):
if key in self.data:
self.data[key] = value
else:
super().__setattr__(key, value)
emp = Employee({'age': 23, 'name': 'John'})
print(emp.age)
print(emp.name)
print(emp.data)
print(emp.salary)
emp.salary = 50000
print(emp.salary)
Output:
23
John
{'age': 23, 'name': 'John'}
0
50000
什么是 del 办法以及如何调用它
class Employee():
def __init__(self, name='John Doe'):
print('Hello' + name)
self.name = name
def developer(self):
print(self.name)
def __del__(self):
print('Good Bye' + self.name)
emp = Employee('Mark')
print(emp)
emp = 'Rocky'
print(emp)
Output:
Hello Mark
<__main__.Employee object at 0x00000000012498D0>
Good Bye Mark
Rocky
创立类的公有成员
class Test(object):
__private_var = 100
public_var = 200
def __private_func(self):
print('Private Function')
def public_func(self):
print('Public Function')
print(self.public_var)
def call_private(self):
self.__private_func()
print(self.__private_var)
t = Test()
print(t.call_private())
print(t.public_func())
Output:
Private Function
100
None
Public Function
200
None
一个 Python 封装的例子
class Encapsulation:
__name = None
def __init__(self, name):
self.__name = name
def get_name(self):
return self.__name
pobj = Encapsulation('Rocky')
print(pobj.get_name())
Output:
Rocky
一个 Python 组合的例子
class Salary:
def __init__(self, pay):
self.pay = pay
def get_total(self):
return (self.pay*12)
class Employee:
def __init__(self, pay, bonus):
self.pay = pay
self.bonus = bonus
self.obj_salary = Salary(self.pay)
def annual_salary(self):
return "Total:" + str(self.obj_salary.get_total() + self.bonus)
obj_emp = Employee(600, 500)
print(obj_emp.annual_salary())
Output:
Total: 7700
一个 Python 聚合的例子
class Salary:
def __init__(self, pay):
self.pay = pay
def get_total(self):
return (self.pay*12)
class Employee:
def __init__(self, pay, bonus):
self.pay = pay
self.bonus = bonus
def annual_salary(self):
return "Total:" + str(self.pay.get_total() + self.bonus)
obj_sal = Salary(600)
obj_emp = Employee(obj_sal, 500)
print(obj_emp.annual_salary())
Output:
Total: 7700
Python 中的单级、多级和多级继承
# Single inheritence
class Apple:
manufacturer = 'Apple Inc'
contact_website = 'www.apple.com/contact'
name = 'Apple'
def contact_details(self):
print('Contact us at', self.contact_website)
class MacBook(Apple):
def __init__(self):
self.year_of_manufacture = 2018
def manufacture_details(self):
print('This MacBook was manufactured in {0}, by {1}.'
.format(self.year_of_manufacture, self.manufacturer))
macbook = MacBook()
macbook.manufacture_details()
# Multiple inheritence
class OperatingSystem:
multitasking = True
name = 'Mac OS'
class MacTower(OperatingSystem, Apple):
def __init__(self):
if self.multitasking is True:
print('Multitasking system')
# if there are two superclasses with the sae attribute name
# the attribute of the first inherited superclass will be called
# the order of inhertence matters
print('Name: {}'.format(self.name))
mactower = MacTower()
# Multilevel inheritence
class MusicalInstrument:
num_of_major_keys = 12
class StringInstrument(MusicalInstrument):
type_of_wood = 'Tonewood'
class Guitar(StringInstrument):
def __init__(self):
self.num_of_strings = 6
print('The guitar consists of {0} strings,' +
'it is made of {1} and can play {2} keys.'
.format(self.num_of_strings,
self.type_of_wood, self.num_of_major_keys))
guitar = Guitar()
Output:
This MacBook was manufactured in 2018, by Apple Inc.
Multitasking system
Name: Mac OS
The guitar consists of 6 strings, it is made of Tonewood and can play 12 keys.
在 Python 中获取一个类的父类
class A(object):
pass
class B(object):
pass
class C(A, B):
pass
print(C.__bases__)
Output:
(< class '__main__.A' >, < class '__main__.B' >)
Python 中的多态性
# Creating a shape Class
class Shape:
width = 0
height = 0
# Creating area method
def area(self):
print("Parent class Area ...")
# Creating a Rectangle Class
class Rectangle(Shape):
def __init__(self, w, h):
self.width = w
self.height = h
# Overridding area method
def area(self):
print("Area of the Rectangle is :", self.width*self.height)
# Creating a Triangle Class
class Triangle(Shape):
def __init__(self, w, h):
self.width = w
self.height = h
# Overridding area method
def area(self):
print("Area of the Triangle is :", (self.width*self.height)/2)
rectangle = Rectangle(10, 20)
triangle = Triangle(2, 10)
rectangle.area()
triangle.area()
Output:
Area of the Rectangle is : 200
Area of the Triangle is : 10.0
拜访 Child 类中的公有成员
class Human():
# Private var
__privateVar = "this is __private variable"
# Constructor method
def __init__(self):
self.className = "Human class constructor"
self.__privateVar = "this is redefined __private variable"
# Public method
def showName(self, name):
self.name = name
return self.__privateVar + " " + name
# Private method
def __privateMethod(self):
return "Private method"
# Public method that returns a private variable
def showPrivate(self):
return self.__privateMethod()
def showProtecded(self):
return self._protectedMethod()
class Male(Human):
def showClassName(self):
return "Male"
def showPrivate(self):
return self.__privateMethod()
def showProtected(self):
return self._protectedMethod()
class Female(Human):
def showClassName(self):
return "Female"
def showPrivate(self):
return self.__privateMethod()
human = Human()
print(human.className)
print(human.showName("Vasya"))
print(human.showPrivate())
male = Male()
print(male.className)
print(male.showClassName())
female = Female()
print(female.className)
print(female.showClassName())
Output:
Human class constructor
this is redefined __private variable Vasya
Private method
Human class constructor
Male
Human class constructor
Female
Python 中的抽象类
from abc import ABC, abstractmethod
class AbstractClass(ABC):
def __init__(self, value):
self.value = value
super().__init__()
@abstractmethod
def eat(self):
pass
class Parents(AbstractClass):
def eat(self):
return "Eat solid food" + str(self.value) + "times each day."
class Babies(AbstractClass):
def eat(self):
return "Milk only" + str(self.value) + "times or more each day."
food = 3
adult = Parents(food)
print('Adult')
print(adult.eat())
infant = Babies(food)
print('Infants')
print(infant.eat())
Output:
Adult
Eat solid food 3 times each day.
Infants
Milk only 3 times or more each day.
创立一个抽象类来笼罩 Python 中的默认构造函数
from abc import ABCMeta, abstractmethod
class AbstractClass(object, metaclass=ABCMeta):
@abstractmethod
def __init__(self, n):
self.n = n
class Employee(AbstractClass):
def __init__(self, salary, name):
self.salary = salary
self.name = name
emp1 = Employee(10000, "John Doe")
print(emp1.salary)
print(emp1.name)
Output:
10000
John Doe
使一个抽象类继承另一个抽象类
from abc import ABC, abstractmethod
class A(ABC):
def __init__(self, username):
self.username = username
super().__init__()
@abstractmethod
def name(self):
pass
class B(A):
@abstractmethod
def age(self):
pass
class C(B):
def name(self):
print(self.username)
def age(self):
return
c = C('Test1234')
c.name()
Output:
Test1234
Python 中的 super 是做什么的
class A(object):
def __init__(self, profession):
print(profession)
class B(A):
def __init__(self):
print('John Doe')
super().__init__('Developer')
b = B()
Output:
John Doe
Developer
super() 如何在多重继承中与 __init__() 办法一起工作
class F:
def __init__(self):
print('F%s' % super().__init__)
super().__init__()
class G:
def __init__(self):
print('G%s' % super().__init__)
super().__init__()
class H:
def __init__(self):
print('H%s' % super().__init__)
super().__init__()
class E(G, H):
def __init__(self):
print('E%s' % super().__init__)
super().__init__()
class D(E, F):
def __init__(self):
print('D%s' % super().__init__)
super().__init__()
class C(E, G):
def __init__(self):
print('C%s' % super().__init__)
super().__init__()
class B(C, H):
def __init__(self):
print('B%s' % super().__init__)
super().__init__()
class A(D, B, E):
def __init__(self):
print('A%s' % super().__init__)
super().__init__()
a = A()
print(a)
Output:
A bound method D.__init__ of __main__.A object at 0x000000000369CFD0
D bound method B.__init__ of __main__.A object at 0x000000000369CFD0
B bound method C.__init__ of __main__.A object at 0x000000000369CFD0
C bound method E.__init__ of __main__.A object at 0x000000000369CFD0
E bound method G.__init__ of __main__.A object at 0x000000000369CFD0
G bound method H.__init__ of __main__.A object at 0x000000000369CFD0
H bound method F.__init__ of __main__.A object at 0x000000000369CFD0
F method-wrapper '__init__' of A object at 0x000000000369CFD0
__main__.A object at 0x000000000369CFD0
将 super 与类办法一起应用
class A(object):
@classmethod
def name(self, employee):
print('Employee Name:', employee)
class B(A):
@classmethod
def name(self, employee):
super(B, self).name(employee)
B.name('John Doe')
Output:
Employee Name: John Doe
mro 是做什么的
class A(object):
def dothis(self):
print('From A class')
class B1(A):
def dothis(self):
print('From B1 class')
pass
class B2(object):
def dothis(self):
print('From B2 class')
pass
class B3(A):
def dothis(self):
print('From B3 class')
# Diamond inheritance
class D1(B1, B3):
pass
class D2(B1, B2):
pass
d1_instance = D1()
d1_instance.dothis()
print(D1.__mro__)
d2_instance = D2()
d2_instance.dothis()
print(D2.__mro__)
Output:
From B1 class
(class '__main__.D1', class '__main__.B1',)
From B1 class
(class '__main__.D2', class '__main__.B1', , class '__main__.B2', class 'object')
Python 中的元类是什么
def _addMethod(fldName, clsName, verb, methodMaker, dict):
compiledName = _getCompiledName(fldName, clsName)
methodName = _getMethodName(fldName, verb)
dict[methodName] = methodMaker(compiledName)
def _getCompiledName(fldName, clsName):
if fldName[:2] == "__" and fldName[-2:] != "__":
return "_%s%s" % (clsName, fldName)
else:
return fldName
def _getMethodName(fldName, verb):
s = fldName.lstrip("_")
return verb + s.capitalize()
def _makeGetter(compiledName):
return lambda self: self.__dict__[compiledName]
def _makeSetter(compiledName):
return lambda self, value: setattr(self, compiledName, value)
class Accessors(type):
def __new__(cls, clsName, bases, dict):
for fldName in dict.get("_READ", []) + dict.get("_READ_WRITE", []):
_addMethod(fldName, clsName, "get", _makeGetter, dict)
for fldName in dict.get("_WRITE", []) + dict.get("_READ_WRITE", []):
_addMethod(fldName, clsName, "set", _makeSetter, dict)
return type.__new__(cls, clsName, bases, dict)
class Employee(object, metaclass=Accessors):
_READ_WRITE = ['name', 'salary', 'title', 'bonus']
def __init__(self, name, salary, title, bonus=0):
self.name = name
self.salary = salary
self.title = title
self.bonus = bonus
b = Employee('John Doe', 25000, 'Developer', 5000)
print('Name:', b.getName())
print('Salary:', b.getSalary())
print('Title:', b.getTitle())
print('Bonus:', b.getBonus())
Output:
Name: John Doe
Salary: 25000
Title: Developer
Bonus: 5000
元类的具体案例
class UpperAttrNameMetaClass(type):
def __new__(cls, clsname, bases, attrdict, *args, **kwargs):
print('1. Create a new type, from' +
'UpperAttrNameMetaClass.__new__')
new_attrs = dict()
for attr, value in attrdict.items():
if not callable(value) and not str(attr).startswith('__'):
new_attrs[attr.upper()] = value
else:
new_attrs[attr] = value
cls_obj = super().__new__(cls, clsname, bases, new_attrs,
*args, **kwargs)
return cls_obj
def __init__(self, clsname, bases, attrdict):
self.test = 'test'
super().__init__(clsname, bases, attrdict)
print('2. Initialize new type, increase test attribute,' +
'from UpperAttrNameMetaClass.__init__')
def __call__(self, *args, **kwargs):
print('3. Instantiate the new class,' +
'from UpperAttrNameMetaClass.__call__')
new_obj = self.__new__(self, *args, **kwargs)
new_obj.__init__(*args, **kwargs)
return new_obj
class ObjectNoInitMetaClass(type):
def __call__(cls, *args, **kwargs):
if len(args):
raise TypeError('Must use keyword argument' +
'for key function')
new_obj = cls.__new__(cls)
for k, v in kwargs.items():
setattr(new_obj, k.upper(), v)
return new_obj
class Pig(object, metaclass=UpperAttrNameMetaClass):
size = 'Big'
def __new__(cls, *args, **kwargs):
print('4. Call __new__ in the __call__ of the metaclass,' +
'from Pig.__new__')
obj = object.__new__(cls)
return obj
def __init__(self):
print('5. After the new object is instantiated in' +
'the __call__ of the metaclass,the object is promoted,' +
'from Pig.__init__')
self.name = 'Mark'
def talk(self):
print(self.name)
Pig().talk()
print(Pig.__dict__)
print(Pig.SIZE)
class AnyOne(metaclass=ObjectNoInitMetaClass):
pass
foo = AnyOne(name='John', age=28)
print(foo.NAME, foo.AGE)
print(foo.__dict__)
Output:
1. Create a new type, from UpperAttrNameMetaClass.__new__
2. Initialize new type, increase test attribute,from UpperAttrNameMetaClass.__init__
3. Instantiate the new class, from UpperAttrNameMetaClass.__call__
4. Call __new__ in the __call__ of the metaclass, from Pig.__new__
5. After the new object is instantiated in the __call__ of the metaclass,the object is promoted, from Pig.__init__
Mark
{'__doc__': None, 'test': 'test', '__weakref__': , 'SIZE': 'Big', '__init__': , '__dict__': , '__module__': '__main__', '__new__': , 'talk':}
Big
John 28
{'AGE': 28, 'NAME': 'John'}
在 Python 中应用元类的单例类
class SingleInstanceMetaClass(type):
def __init__(self, name, bases, dic):
self.__single_instance = None
super().__init__(name, bases, dic)
def __call__(cls, *args, **kwargs):
if cls.__single_instance:
return cls.__single_instance
single_obj = cls.__new__(cls)
single_obj.__init__(*args, **kwargs)
cls.__single_instance = single_obj
return single_obj
class Setting(metaclass=SingleInstanceMetaClass):
def __init__(self):
self.db = 'MySQL'
self.port = 3306
bar1 = Setting()
bar2 = Setting()
print(bar1 is bar2)
print(bar1.db, bar1.port)
bar1.db = 'ORACLE'
print(bar2.db, bar2.port)
Output:
True
MySQL 3306
ORACLE 3306
@staticmethod 和 @classmethod 有什么区别
class Employee:
@classmethod
def classmthd(*args):
return args
@staticmethod
def staticmthd(*args):
return args
print(Employee.classmthd())
print(Employee.classmthd('test'))
print(Employee.staticmthd())
print(Employee.staticmthd('test'))
Output:
(class '__main__.Employee',)
(class '__main__.Employee', 'test')
()
('test',)
Python 中的装璜器是什么
def message(param1, param2):
def wrapper(wrapped):
class WrappedClass(wrapped):
def __init__(self):
self.param1 = param1
self.param2 = param2
super(WrappedClass, self).__init__()
def get_message(self):
return "message %s %s" % (self.param1, self.param2)
return WrappedClass
return wrapper
@message("param1", "param2")
class Pizza(object):
def __init__(self):
pass
pizza_with_message = Pizza()
print(pizza_with_message.get_message())
Output:
message param1 param2
制作函数装璜器链
def benchmark(func):
"""
A decorator that prints the time a function takes
to execute.
"""
import time
def wrapper(*args, **kwargs):
t = time.clock()
res = func(*args, **kwargs)
print("{0} {1}".format(func.__name__, time.clock()-t))
return res
return wrapper
def logging(func):
"""
A decorator that logs the activity of the script.
(it actually just prints it, but it could be logging!)
"""
def wrapper(*args, **kwargs):
res = func(*args, **kwargs)
print("{0} {1} {2}".format(func.__name__, args, kwargs))
return res
return wrapper
def counter(func):
"""
A decorator that counts and prints the number of times a
function has been executed
"""
def wrapper(*args, **kwargs):
wrapper.count = wrapper.count + 1
res = func(*args, **kwargs)
print("{0} has been used: {1}x".format(func.__name__, wrapper.count))
return res
wrapper.count = 0
return wrapper
@counter
@benchmark
@logging
def letter_range(start, stop, step=1):
start = ord(start.lower())
stop = ord(stop.lower())
for str_lst in range(start, stop, step):
yield chr(str_lst)
print(list(letter_range("a", "f")))
print('\n')
print(list(letter_range("m", "z", 2)))
Output:
letter_range ('a', 'f') {}
wrapper 0.0009437184107374183
wrapper has been used: 1x
['a', 'b', 'c', 'd', 'e']
letter_range ('m', 'z', 2) {}
wrapper 3.131164480070134e-05
wrapper has been used: 2x
['m', 'o', 'q', 's', 'u', 'w', 'y']
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