Py3 oop

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2024

类(Class)与对象(Object)

class Student:
    def __init__(self,name,score):
        self.name = name 
        self.score = score 

    def show(self):
        print("Name: {}. Score: {}".format(self.name,self.score))

student1 = Student("evan",100)
print(student1)
student1.show()

# ➜  tmp py3  clas.py
# <__main__.Student object at 0x7f007c9e9890>
# Name: evan. Score: 100

类变量(class variables)与实例变量(instance variables)

class Student:

    # number属于类变量,定义在方法外,不属于具体实例
    number =0
    def __init__(self,name,score):
        self.name = name 
        self.score = score 

        # number = number + 1
        ## number属于类变量,定义在方法外,不属于具体实例

        Student.number = Student.number + 1

    def show(self):
        print("Name: {}. Score: {}".format(self.name,self.score))

student1 = Student("evan",100)
print(student1)
student1.show()

print(Student.number)
print(student1.__class__.number)

# ➜  tmp py3  clas.py
# <__main__.Student object at 0x7fb907ed9890>
# Name: evan. Score: 100
# 1
# 1


类方法(Class method)

class Student:

    # number属于类变量,定义在方法外,不属于具体实例
    number =0
    def __init__(self,name,score):
        self.name = name 
        self.score = score 

        # number = number + 1
        ## number属于类变量,定义在方法外,不属于具体实例

        Student.number = Student.number + 1

    def show(self):
        print("Name: {}. Score: {}".format(self.name,self.score))

    # 定义类方法,打印学生的数量 属于类的方法不使用self参数, 而使用参数cls,代表类本身。另外习惯上对类方法我们会加上@classmethod的修饰符做说明
    @classmethod 
    def total(cls):
        print("Total: {0}".format(cls.number))

student1 = Student("evan",100)
Student.total() # Total: 1

类的私有属性(private attribute)和私有方法(private method)

class Student:

    # number属于类变量,定义在方法外,不属于具体实例
    number =0
    def __init__(self,name,score):
        self.name = name 
        self.__score = score 

        # number = number + 1
        ## number属于类变量,定义在方法外,不属于具体实例

        # Student.number = Student.number + 1

    def show(self):
        print("Name: {}. Score: {}".format(self.name,self.__score))

    # 定义类方法,打印学生的数量 属于类的方法不使用self参数, 而使用参数cls,代表类本身。另外习惯上对类方法我们会加上@classmethod的修饰符做说明
    # @classmethod 
    # def total(cls):
    #     print("Total: {0}".format(cls.number))



student1 = Student("evan",100)

student1.show() # Name: evan. Score: 100
student1.__score  ## 打印出错,该属性不能从外部访问


class Student:

    # number属于类变量,定义在方法外,不属于具体实例
    number =0
    def __init__(self,name,score):
        self.name = name 
        self.__score = score 

    # 利用property装饰器把函数伪装成属性
    @property
    def score(self):
        print("Name: {}. Score: {}".format(self.name,self.__score))

    # 定义类方法,打印学生的数量 属于类的方法不使用self参数, 而使用参数cls,代表类本身。另外习惯上对类方法我们会加上@classmethod的修饰符做说明
    # @classmethod 
    # def total(cls):
    #     print("Total: {0}".format(cls.number))



student1 = Student("evan",100)
#注意: 一旦给函数加上一个装饰器@property,调用函数的时候不用加括号就可以直接调用函数了

student1.score # Name: evan. Score: 100



类的继承(Inheritance)

class SchoolMember:
    def __init__(self, name, age):
        self.name = name
        self.age = age

    def tell(self):
        print("Name: {}, Age: {}".format(self.name, self.age),end="")

class Teacher(SchoolMember):
    def __init__(self,name,age,salary):
        SchoolMember.__init__(self,name,age)# 利用父类进行初始化
        self.salary = salary 

    def tell(self):
        SchoolMember.tell(self)
        print("Salary: {}".format(self.salary))

class Student(SchoolMember):

    def __init__(self,name,age,score):
        SchoolMember.__init__(self,name,age)
        self.__score = score 

    def tell(self):
        SchoolMember.tell(self)
        print(", Score: {}".format(self.__score))


teacher1 = Teacher("Alice",25,30000)

student1 = Student("evan",30,100)

teacher1.tell()
student1.tell()


# ➜  tmp py3  clas.py
# Name: Alice, Age: 25Salary: 30000
# Name: evan, Age: 30, Score: 100
# ➜  tmp 

super()关键字调用父类方法

# 创建子类学生Student
class Student(SchoolMember):

    def __init__(self, name, age, score):
        super().__init__(name, age)
        self.score = score
    
    def tell(self):
        super().tell() # 等同于 SchoolMember.tell(self)
        print('score: {}'.format(self.score))

静态变量(static variable)和静态方法(static method)

class Student:
    number = 0 
    def __init__(self, nmae,score):
        self.name = nmae 
        self.score = score 

        Student.number += 1 

    def show(self):
        print("Name: {}. Score: {}".format(self.name, self.score))

   # 静态方法无法使用cls和self参数访问类或实例的变量
    @staticmethod 
    def func1():
        print("this is a static method")

多进程编程与multiprocess

import time  
import os 

def long_time_task():
    print('当前里程id {0}'.format(os.getpid()))
    time.sleep(2)
    print("结果:{}".format(8 ** 20))

if __name__ == '__main__':
    print('当前mothe 进程: {}'.format(os.getpid()))
    start = time.time()
    for i in range(2):
        long_time_task()

    end = time.time()
    print('总共耗时: {}'.format(end - start))

#     ➜  tmp py3  mul.py 
# 当前mothe 进程: 36016
# 当前里程id 36016
# 结果:1152921504606846976
# 当前里程id 36016
# 结果:1152921504606846976
# 总共耗时: 4.000534772872925


from multiprocessing import Process 
import time  
import os 

def long_time_task(i):
    print('子进程 {} - 任务{}'.format(os.getpid(),i))
    time.sleep(2)
    print("结果:{}".format(8 ** 20))

if __name__ == '__main__':
    print('当前mothe 进程: {}'.format(os.getpid()))
    start = time.time()
    p1 = Process(target=long_time_task,args=(1,))
    p2 = Process(target=long_time_task,args=(2,))
    print('等所有子进程完成')
    p1.start()
    p2.start()
    p1.join()
    p2.join()
    end = time.time()
    print('总共耗时: {}'.format(end - start))

# ➜  tmp py3 mul2.py
# 当前mothe 进程: 37124
# 等所有子进程完成
# 子进程 37126 - 任务1
# 子进程 37127 - 任务2
# 结果:1152921504606846976
# 结果:1152921504606846976
# 总共耗时: 2.0068671703338623


#AI解说不错
#     创建子进程
#         p1 = Process(target=long_time_task,args=(1,))和p2 = Process(target=long_time_task,args=(2,))
#             这里使用Process类(假设是multiprocessing模块中的Process类)创建了两个子进程。
#             target参数指定了子进程要执行的函数,这里是long_time_task函数。
#             args参数是一个元组,指定了传递给long_time_task函数的参数,这里分别传递了1和2作为任务编号相关的参数。
#     启动和等待子进程
#         p1.start()和p2.start()分别启动两个子进程,使它们开始执行long_time_task函数。
#         p1.join()和p2.join()使主进程等待两个子进程完成。join方法会阻塞主进程,直到对应的子进程执行完毕。
#     记录结束时间和打印总耗时
#         end = time.time()记录当前时间,作为任务结束的时间点。
#         print('总共耗时: {}'.format(end - start))计算并打印从任务开始到结束所花费的时间。


# 这段代码的主要目的是创建两个子进程,让它们并行执行long_time_task函数,然后等待子进程完成,并计算整个过程所花费的时间。


multiprocess模块的Pool类创建多进程

from multiprocessing import Pool,cpu_count 
import time  
import os 

def long_time_task(i):
    print('子进程 {} - 任务{}'.format(os.getpid(),i))
    time.sleep(2)
    print("结果:{}".format(8 ** 20))

if __name__ == '__main__':
    print('cpu core num: {}'.format(cpu_count()))
    print('当前mothe 进程: {}'.format(os.getpid()))
    start = time.time()
    p = Pool(12)
    for i in range(5):
        p.apply_async(long_time_task,args=(i,))
    print('等所有子进程完成')
    p.close()
    p.join()
    end = time.time()
    print('总共耗时: {}'.format(end - start))

# cpu core num: 12
# 当前mothe 进程: 40772
# 等所有子进程完成
# 子进程 40776 - 任务0
# 子进程 40777 - 任务1
# 子进程 40778 - 任务2
# 子进程 40779 - 任务3
# 子进程 40780 - 任务4
# 结果:1152921504606846976结果:1152921504606846976

# 结果:1152921504606846976
# 结果:1152921504606846976
# 结果:1152921504606846976
# 总共耗时: 2.0383548736572266

多进程间的数据共享与通信

from multiprocessing import Process, Queue
import os, time, random

# 写数据进程执行的代码:
def write(q):
    print('Process to write: {}'.format(os.getpid()))
    for value in ['A', 'B', 'C']:
        print('Put %s to queue...' % value)
        q.put(value)
        time.sleep(random.random())

# 读数据进程执行的代码:
def read(q):
    print('Process to read:{}'.format(os.getpid()))
    while True:
        value = q.get(True)
        print('Get %s from queue.' % value)

if __name__=='__main__':
    # 父进程创建Queue,并传给各个子进程:
    q = Queue()
    pw = Process(target=write, args=(q,))
    pr = Process(target=read, args=(q,))
    # 启动子进程pw,写入:
    pw.start()
    # 启动子进程pr,读取:
    pr.start()
    # 等待pw结束:
    pw.join()
    # pr进程里是死循环,无法等待其结束,只能强行终止:
    pr.terminate()

Process to write: 3036
Put A to queue...
Process to read:9408
Get A from queue.
Put B to queue...
Get B from queue.
Put C to queue...
Get C from queue.

Python的多线程编程与threading模块


threading比较高级 不像thread 太底层,要做太多事

import threading
import time


def long_time_task(i):
    print('当前子线程: {} 任务{}'.format(threading.current_thread().name, i))
    time.sleep(2)
    print("结果: {}".format(8 ** 20))


if __name__=='__main__':
    start = time.time()
    print('这是主线程:{}'.format(threading.current_thread().name))
    thread_list = []
    for i in range(1, 3):
        t = threading.Thread(target=long_time_task, args=(i, ))
        thread_list.append(t)

    for t in thread_list:
        t.start()

    for t in thread_list:
        t.join()

    end = time.time()
    print("总共用时{}秒".format((end - start)))

这是主线程:MainThread
当前子线程: Thread - 1 任务1
当前子线程: Thread - 2 任务2
结果: 1152921504606846976
结果: 1152921504606846976
总共用时2.0166890621185303秒

➜  tmp py3 threading.py 
Traceback (most recent call last):
  File "/home/evan/data/python/tmp/threading.py", line 10, in <module>
    print('当前主线程 {}'.format(threading.current_thread().name))
                            ^^^^^^^^^^^^^^^^^^^^^^^^
AttributeError: module 'threading' has no attribute 'current_thread'
Exception ignored in: <module 'threading' from '/home/evan/data/python/tmp/threading.py'>
AttributeError: module 'threading' has no attribute '_shutdown'
➜  tmp 


import threading

def say_hi():
    print('Hello world')

if __name__ == '__main__':
    for i in range(3):
        t = threading.Thread(target=say_hi)
        t.start() #启动工作线程 target()

# Hello world
# Hello world
# Hello world


import threading

def say_hi(word):
    print('Hello %s' % world)

if __name__ == '__main__':
    for i in range(3):
        t = threading.Thread(target=say_hi,args=('mydu',))
        t.start() #启动工作线程 target()

类对象


#!/usr/bin/python3
 
class MyClass:
    """一个简单的类实例"""
    i = 12345
    def f(self):
        return 'hello world'
 
# 实例化类
x = MyClass()
 
# 访问类的属性和方法
print("MyClass 类的属性 i 为:", x.i)
print("MyClass 类的方法 f 输出为:", x.f())


#
以上创建了一个新的类实例并将该对象赋给局部变量 x,x 为空的对象。

执行以上程序输出结果为:

MyClass 类的属性 i 为: 12345
MyClass 类的方法 f 输出为: hello world

see also

Python3 面向对象

__init__() 的特殊方法(构造方法)

类有一个名为 __init__() 的特殊方法(构造方法),该方法在类实例化时会自动调用


#!/usr/bin/python3
 
class Complex:
    def __init__(self, realpart, imagpart):
        self.r = realpart
        self.i = imagpart
x = Complex(3.0, -4.5)
print(x.r, x.i)   # 输出结果:3.0 -4.5