Python 备忘单是 Python 3 编程语言的单页参考表
>>> print("Hello, World!")
Hello, World!
著名的“Hello World”程序在 Python 中的实现
age = 18 # 年龄是 int 类型
name = "John" # 名字现在是 str 类型
print(name)
序列指一批有序的元素,集合指一批无序且不重复的元素
| :- | :- |
|---|---|
str | 文本/字符串(Text) |
int, float, complex | 数值(Numeric) |
dict | 映射/键值对(Mapping) |
list, tuple, range | 序列(Sequence) |
set, frozenset | 集合(Set) |
bool | 布尔值/逻辑值(Boolean) |
bytes, bytearray, memoryview | 二进制数据(Binary) |
查看: 数据类型
>>> msg = "Hello, World!"
>>> print(msg[2:5])
llo
查看: 字符串
mylist = []
mylist.append(1)
mylist.append(2)
for item in mylist:
print(item) # 打印输出 1,2
查看: 列表
num = 200
if num > 0:
print("num is greater than 0")
else:
print("num is not greater than 0")
查看: 判断
for item in range(6):
if item == 3: break
print(item)
else:
print("Finally finished!")
查看: 循环
>>> def my_function():
... print("来自函数的你好")
...
>>> my_function()
来自函数的你好
查看: 函数
with open("myfile.txt", "r", encoding='utf8') as file:
for line in file:
print(line)
查看: 文件处理
result = 10 + 30 # => 40
result = 40 - 10 # => 30
result = 50 * 5 # => 250
result = 16 / 4 # => 4.0 (Float Division)
result = 16 // 4 # => 4 (Integer Division)
result = 25 % 2 # => 1
result = 5 ** 3 # => 125
/ 表示 x 和 y 的商,// 表示 x 和 y 的底商,另见 StackOverflow
counter = 0
counter += 10 # => 10
counter = 0
counter = counter + 10 # => 10
message = "Part 1."
# => Part 1.Part 2.
message += "Part 2."
>>> website = 'Quick Reference'
>>> f"Hello, {website}"
"Hello, Quick Reference"
>>> num = 10
>>> f'{num} + 10 = {num + 10}'
'10 + 10 = 20'
查看: f-字符串
hello = "Hello World"
hello = 'Hello World'
multi_string = """Multiline Strings
Lorem ipsum dolor sit amet,
consectetur adipiscing elit """
查看: 字符串
x = 1 # 整数
y = 2.8 # 浮点小数
z = 1j # 复数
>>> print(type(x))
<class 'int'>
只要内存足够,可以容纳无限大(小)的数值
my_bool = True
my_bool = False
bool(0) # => False
bool(1) # => True
bool 是 int 的子类
list1 = ["apple", "banana", "cherry"]
list2 = [True, False, False]
list3 = [1, 5, 7, 9, 3]
list4 = list((1, 5, 7, 9, 3))
查看: 列表
my_tuple = (1, 2, 3)
my_tuple = tuple((1, 2, 3))
类似列表,但自身不可变
set1 = {"a", "b", "c"}
set2 = set(("a", "b", "c"))
类似列表,但里面的元素是无序而不重复的
>>> empty_dict = {}
>>> a = {"one": 1, "two": 2, "three": 3}
>>> a["one"]
1
>>> a.keys()
dict_keys(['one', 'two', 'three'])
>>> a.values()
dict_values([1, 2, 3])
>>> a.update({"four": 4})
>>> a.keys()
dict_keys(['one', 'two', 'three', 'four'])
>>> a['four']
4
键-值对,一种像 JSON 那样对象
x = int(1) # 得到 1
y = int(2.8) # 得到 2
z = int("3") # 得到 3
x = float(1) # 得到 1.0
y = float(2.8) # 得到 2.8
z = float("3") # 得到 3.0
w = float("4.2") # 得到 4.2
x = str("s1") # 得到 "s1"
y = str(2) # 得到 "2"
z = str(3.0) # 得到 "3.0"
>>> hello = "Hello, World"
>>> print(hello[1]) # 获取第二个字符
e
>>> print(hello[-1]) # 获取倒数第一个字符
d
>>> print(type(hello[-1])) # 得到的还是字符串
<class 'str'>
>>> for char in "foo":
... print(char)
f
o
o
对字符串 for-in 可以得到每个字符(类型还是字符串)
┌───┬───┬───┬───┬───┬───┬───┐
| m | y | b | a | c | o | n |
└───┴───┴───┴───┴───┴───┴───┘
0 1 2 3 4 5 6 7
-7 -6 -5 -4 -3 -2 -1
>>> s = 'mybacon'
>>> s[2:5]
'bac'
>>> s[0:2]
'my'
>>> s = 'mybacon'
>>> s[:2]
'my'
>>> s[2:]
'bacon'
>>> s[:2] + s[2:]
'mybacon'
>>> s[:]
'mybacon'
>>> s = 'mybacon'
>>> s[-5:-1]
'baco'
>>> s[2:6]
'baco'
>>> s = '12345' * 5
>>> s
'1234512345123451234512345'
>>> s[::5]
'11111'
>>> s[4::5]
'55555'
>>> s[::-5]
'55555'
>>> s[::-1]
'5432154321543215432154321'
>>> hello = "Hello, World!"
>>> print(len(hello))
13
len() 函数返回字符串的长度
>>> s = '===+'
>>> n = 8
>>> s * n
'===+===+===+===+===+===+===+===+'
>>> s = 'spam'
>>> s in 'I saw spamalot!'
True
>>> s not in 'I saw The Holy Grail!'
True
判断 "spam" 这个字符串是否在其它字符串里
>>> s = 'spam'
>>> t = 'egg'
>>> s + t # 可以使用加号进行拼接
'spamegg'
>>> 'spam' 'egg' # 两个字符串之间可以省略加号
'spamegg'
name = "John"
print("Hello, %s!" % name)
name = "John"
age = 23
print("%s is %d years old." % (name, age))
txt1 = "My name is {fname}, I'm {age}".format(fname="John", age=36)
txt2 = "My name is {0}, I'm {1}".format("John", 36)
txt3 = "My name is {}, I'm {}".format("John", 36)
| 转义符号 | 对应的操作 |
|---|---|
\\ | 输出反斜杠 |
\' | 输出单引号 |
\" | 输出双引号 |
\n | 换行 |
\t | 水平制表符 |
\r | 光标回到首位 |
\b | 退格 |
>>> name = input("Enter your name: ")
Enter your name: Tom
>>> name
'Tom'
从控制台获取输入数据
>>> # 是否以 H 开头
>>> "Hello, world!".startswith("H")
True
>>> # 是否以 h 开头
>>> "Hello, world!".startswith("h")
False
>>> # 是否以 ! 结尾
>>> "Hello, world!".endswith("!")
True
>>> "、".join(["John", "Peter", "Vicky"])
'John、Peter、Vicky'
>>> website = 'Reference'
>>> f"Hello, {website}"
"Hello, Reference"
>>> num = 10
>>> f'{num} + 10 = {num + 10}'
'10 + 10 = 20'
>>> f"""He said {"I'm John"}"""
"He said I'm John"
>>> f'5 {"{stars}"}'
'5 {stars}'
>>> f'{{5}} {"stars"}'
'{5} stars'
>>> name = 'Eric'
>>> age = 27
>>> f"""Hello!
... I'm {name}.
... I'm {age}."""
"Hello!\n I'm Eric.\n I'm 27."
它从 Python 3.6 开始可用,另见: 格式字符串字面值
>>> f'{"text":10}' # 使用空格填充到指定长度
'text '
>>> f'{"test":*>10}' # 向左填充
'******test'
>>> f'{"test":*<10}' # 向右填充
'test******'
>>> f'{"test":*^10}' # 居中填充
'***test***'
>>> f'{12345:0>10}' # 使用数字填充
'0000012345'
>>> f'{10:b}' # 输出二进制数值
'1010'
>>> f'{10:o}' # 输出八进制数值
'12'
>>> f'{200:x}' # 输出十六进制数值
'c8'
>>> f'{200:X}'
'C8'
>>> f'{345600000000:e}' # 科学计数法
'3.456000e+11'
>>> f'{65:c}' # 将整数转化为一个字符后输出
'A'
>>> f'{10:#b}' # [类型] 带符号(基础)
'0b1010'
>>> f'{10:#o}'
'0o12'
>>> f'{10:#x}'
'0xa'
>>> f'{12345:+}' # 显示正数的正号
'+12345'
>>> f'{-12345:+}' # 显示负数的负号
'-12345'
>>> f'{-12345:+10}' # 显示负号,并使用空格填充,直到长度为 10
' -12345'
>>> f'{-12345:+010}' # 显示负号,并使用0填充,直到长度为 10
'-000012345'
>>> f'{-12345:0=10}' # 负数
'-000012345'
>>> f'{12345:010}' # [0] 快捷方式(不对齐)
'0000012345'
>>> f'{-12345:010}'
'-000012345'
>>> import math # [.precision]
>>> math.pi
3.141592653589793
>>> f'{math.pi:.2f}'
'3.14'
>>> f'{1000000:,.2f}' # [分组选项]
'1,000,000.00'
>>> f'{1000000:_.2f}'
'1_000_000.00'
>>> f'{0.25:0%}' # 百分比
'25.000000%'
>>> f'{0.25:.0%}'
'25%'
>>> li1 = []
>>> li1
[]
>>> li2 = [4, 5, 6]
>>> li2
[4, 5, 6]
>>> li3 = list((1, 2, 3))
>>> li3
[1, 2, 3]
>>> li4 = list(range(1, 11))
>>> li4
[1, 2, 3, 4, 5, 6, 7, 8, 9, 10]
>>> list(filter(lambda x : x % 2 == 1, range(1, 20)))
[1, 3, 5, 7, 9, 11, 13, 15, 17, 19]
>>> [x ** 2 for x in range (1, 11) if x % 2 == 1]
[1, 9, 25, 49, 81]
>>> [x for x in [3, 4, 5, 6, 7] if x > 5]
[6, 7]
>>> list(filter(lambda x: x > 5, [3, 4, 5, 6, 7]))
[6, 7]
>>> li = []
>>> li.append(1)
>>> li
[1]
>>> li.append(2)
>>> li
[1, 2]
>>> li.append(4)
>>> li
[1, 2, 4]
>>> li.append(3)
>>> li
[1, 2, 4, 3]
列表切片的语法:
a_list[start:end]
a_list[start:end:step]
>>> a = ['spam', 'egg', 'bacon', 'tomato', 'ham', 'lobster']
>>> a[2:5]
['bacon', 'tomato', 'ham']
>>> a[-5:-2]
['egg', 'bacon', 'tomato']
>>> a[1:4]
['egg', 'bacon', 'tomato']
>>> a[:4]
['spam', 'egg', 'bacon', 'tomato']
>>> a[0:4]
['spam', 'egg', 'bacon', 'tomato']
>>> a[2:]
['bacon', 'tomato', 'ham', 'lobster']
>>> a[2:len(a)]
['bacon', 'tomato', 'ham', 'lobster']
>>> a
['spam', 'egg', 'bacon', 'tomato', 'ham', 'lobster']
>>> a[:]
['spam', 'egg', 'bacon', 'tomato', 'ham', 'lobster']
['spam', 'egg', 'bacon', 'tomato', 'ham', 'lobster']
>>> a[0:6:2]
['spam', 'bacon', 'ham']
>>> a[1:6:2]
['egg', 'tomato', 'lobster']
>>> a[6:0:-2]
['lobster', 'tomato', 'egg']
>>> a
['spam', 'egg', 'bacon', 'tomato', 'ham', 'lobster']
>>> a[::-1]
['lobster', 'ham', 'tomato', 'bacon', 'egg', 'spam']
>>> li = ['bread', 'butter', 'milk']
>>> li.pop()
'milk'
>>> li
['bread', 'butter']
>>> del li[0]
>>> li
['butter']
>>> li.remove('butter')
>>> li
[]
>>> li = ['a', 'b', 'c', 'd']
>>> li[0]
'a'
>>> li[-1]
'd'
>>> li[4]
Traceback (most recent call last):
File "<stdin>", line 1, in <module>
IndexError: list index out of range
>>> odd = [1, 3, 5]
>>> odd.extend([9, 11, 13])
>>> odd
[1, 3, 5, 9, 11, 13]
>>> odd = [1, 3, 5]
>>> odd + [9, 11, 13]
[1, 3, 5, 9, 11, 13]
>>> li = [3, 1, 3, 2, 5]
>>> li.sort()
>>> li
[1, 2, 3, 3, 5]
>>> li.reverse()
>>> li
[5, 3, 3, 2, 1]
>>> li = [3, 1, 3, 2, 5]
>>> li.count(3)
2
>>> li = ["re"] * 3
>>> li
['re', 're', 're']
>>> nums = [40, 36, 89, 2, 36, 100, 7, -20.5, -999]
>>> nums.index(2)
3
>>> nums.index(100, 3, 7) # 搜索3-7之间的元素
5
>>> nums.index(7, 4) # 搜索4之后的元素
6
当寻找一个不存在的值时,抛出ValueError。
number = int(input('输入一个整数:'))
if number < 0:
print("您输入了一个负数。")
else:
print("您输入了一个非负整数。")
number = int(input('输入一个整数:'))
if number < 0:
print("您输入了一个负数。")
elif number == 0:
print("您输入了一个 0 。")
else:
print("您输入了一个正数。")
scope = int(input('输入百分制成绩:'))
line = 60
tip = "及格" if scope >= line else "不及格"
# 相当于 scope >= line ? "及格" : "不及格"
print(tip)
注意条件是放在中间的
primes = [2, 3, 5, 7]
for prime in primes:
print(prime)
animals = ["dog", "cat", "mouse"]
for i, value in enumerate(animals):
print(i, value)
x = 0
while x < 4:
print(x)
x += 1 # Shorthand for x = x + 1
x = 0
for index in range(10):
x = index * 10
if index == 5:
break
print(x)
for index in range(3, 8):
x = index * 10
if index == 5:
continue
print(x)
for i in range(4):
print(i) # Prints: 0 1 2 3
for i in range(4, 8):
print(i) # Prints: 4 5 6 7
for i in range(4, 10, 2):
print(i) # Prints: 4 6 8
name = ['Pete', 'John', 'Elizabeth']
age = [6, 23, 44]
for n, a in zip(name, age):
print('%s is %d years old' %(n, a))
result = [x**2 for x in range(10) if x % 2 == 0]
print(result)
# [0, 4, 16, 36, 64]
def hello_world():
print('Hello, World!')
def add(x, y):
print("x is %s, y is %s" %(x, y))
return x + y
add(5, 6) # => 11
def varargs(*args):
return args
varargs(1, 2, 3) # => (1, 2, 3)
args 的类型是 tuple
def keyword_args(**kwargs):
return kwargs
# => {"big": "foot", "loch": "ness"}
keyword_args(big="foot", loch="ness")
kwargs 的类型是 dict
def swap(x, y):
return y, x
x = 1
y = 2
x, y = swap(x, y) # => x = 2, y = 1
def add(x, y=10):
return x + y
add(5) # => 15
add(5, 20) # => 25
# => True
(lambda x: x > 2)(3)
# => 5
(lambda x, y: x ** 2 + y ** 2)(2, 1)
ip, port = "127.0.0.1", 80
print(ip) # -> "127.0.0.1"
print(port) # -> 80
# 与以下代码等价
ip, port = ("127.0.0.1", 80)
# 与以下代码效果相同
ip, port = ["127.0.0.1", 80]
ip, _, port = "127.0.0.1:80".rpartition(":")
print(ip) # -> "127.0.0.1"
print(port) # -> "80"
# _ 这个变量此刻的值是 ":" ,但一般不再使用。
_ 也是一个单一变量,不允许解包多个元素,因此变量与值必须一一对应。
major, minor, *_ = "3.10.2.beta".split(".")
print(major) # -> "3"
print(minor) # -> "10"
major, *_, level = "3.10.2.beta".split(".")
print(major) # -> "3"
print(level) # -> "beta"
*_, micro, level = "3.10.2.beta".split(".")
print(micro) # -> "2"
print(level) # -> "beta"
a, b, *_ = {3, 2, 1}
print(a) # -> 1
print(b) # -> 2
print(_) # -> [3]
集合 中的元素是无序的,因此解包结果不能轻易确定。
a, b, *_ = range(3)
print(a) # -> 0
print(b) # -> 1
print(_) # -> [2]
支持 迭代器 协议的对象也可被解包。
a, b, *_ = dict(a=1, b=2, c=3)
print(a) # -> "a"
print(_) # -> ["c"]
a, b, *_ = dict(a=1, b=2, c=3).values()
print(a) # -> 1
print(_) # -> [3]
chars = (*"abc", *"def", "g", "h")
# -> ("a", "b", "c", "d", "e", "f", "g", "h")
digits = [*range(10), *"abcdef"]
# -> [0, 1, 2, 3, 4, 5, 6, 7, 8, 9,
# "a", "b", "c", "d", "e", "f"]
part = {"小明": 18, "小亮": 22}
summary = {"小花": 16, **part}
print(summary)
# -> {"小花": 16, "小明": 18, "小亮": 22}
***students = [
("小明", 18),
("小亮", 22),
]
for k, v in students:
print(k) # -> "小明"、"小亮"
print(v) # -> 18、22
students = [
(0, ("小明", 18)),
(1, ("小亮", 22)),
]
for i, (k, v) in students:
print(i) # -> 0、1
print(k) # -> "小明"、"小亮"
print(v) # -> 18、22
def version(major, minor, *parts):
print(major) # -> "3"
print(minor) # -> "10"
print(parts) # -> ("2", "beta", "0")
version("3", "10", "2", "beta", "0")
# 过程类似于
major, minor, *parts = ("3", "10", "2", "beta", "0")
def version():
parts = "3.10.2.beta.0".split(".")
return *parts, "x64"
print(version())
# -> ("3", "10", "2", "beta", "0", "x64")
import math
print(math.sqrt(16)) # => 4.0
from math import ceil, floor
print(ceil(3.7)) # => 4.0
print(floor(3.7)) # => 3.0
from math import *
import math as m
# => True
math.sqrt(16) == m.sqrt(16)
import math
dir(math)
with open("myfile.txt") as file:
for line in file:
print(line)
file = open('myfile.txt', 'r')
for i, line in enumerate(file, start=1):
print("Number %s: %s" % (i, line))
contents = {"aa": 12, "bb": 21}
with open("myfile1.txt", "w+") as file:
file.write(str(contents))
with open('myfile1.txt', "r+") as file:
contents = file.read()
print(contents)
contents = {"aa": 12, "bb": 21}
with open("myfile2.txt", "w+") as file:
file.write(json.dumps(contents))
with open('myfile2.txt', "r+") as file:
contents = json.load(file)
print(contents)
import os
os.remove("myfile.txt")
import os
if os.path.exists("myfile.txt"):
os.remove("myfile.txt")
else:
print("The file does not exist")
import os
os.rmdir("myfolder")
class MyNewClass:
pass
# 类的实例化
my = MyNewClass()
class Animal:
def __init__(self, voice):
self.voice = voice
cat = Animal('Meow')
print(cat.voice) # => Meow
dog = Animal('Woof')
print(dog.voice) # => Woof
class Dog:
# 类的方法
def bark(self):
print("Ham-Ham")
charlie = Dog()
charlie.bark() # => "Ham-Ham"
class MyClass:
class_variable = "A class variable!"
# => 一个类变量!
print(MyClass.class_variable)
x = MyClass()
# => 一个类变量!
print(x.class_variable)
class ParentClass:
def print_test(self):
print("Parent Method")
class ChildClass(ParentClass):
def print_test(self):
print("Child Method")
# 调用父级的 print_test()
super().print_test()
>>> child_instance = ChildClass()
>>> child_instance.print_test()
Child Method
Parent Method
class Employee:
def __init__(self, name):
self.name = name
def __repr__(self):
return self.name
john = Employee('John')
print(john) # => John
class CustomError(Exception):
pass
class ParentClass:
def print_self(self):
print('A')
class ChildClass(ParentClass):
def print_self(self):
print('B')
obj_A = ParentClass()
obj_B = ChildClass()
obj_A.print_self() # => A
obj_B.print_self() # => B
class ParentClass:
def print_self(self):
print("Parent")
class ChildClass(ParentClass):
def print_self(self):
print("Child")
child_instance = ChildClass()
child_instance.print_self() # => Child
class Animal:
def __init__(self, name, legs):
self.name = name
self.legs = legs
class Dog(Animal):
def sound(self):
print("Woof!")
Yoki = Dog("Yoki", 4)
print(Yoki.name) # => YOKI
print(Yoki.legs) # => 4
Yoki.sound() # => Woof!
参见 自定义类创建 。
from typing import Any
class Object:
def __new__(cls, *args, **kwargs) -> "self":
# new 和 init 声明的参数必须一致
# 或者用 *args 和 **kwargs 进行兼容
return object.__new__(cls)
def __init__(self, *args, **kwargs):
# 初始化方法没有返回值,也不能返回值。
pass
def __call__(self, *args, **kwargs) -> Any:
pass
# 依次调用了 new 和 init,所以如果
# 手动调用 new,那么别忘了调用 init
obj = Object()
# 触发 __call__ 方法,要给什么参数取决于声明
obj()
参见 上下文管理器 。
from typing import Any
class Object:
def __enter__(self) -> Optional[Any]:
# with 语句会将返回值绑定到 as 子句中的变量,如果有的话。
return
def __exit__(self, exc_type, exc_value, traceback):
# 若 with 内没有发生异常,则三个参数都是 None 。
# 不应该重新引发传入的异常,这是调用者的责任。
pass
with Object() as alias:
# 进入 with 之前调用 obj.__enter__() 并得到 alias(如果有返回的话)
pass
# 离开 with 后调用 obj.__exit__() ,不管是正常结束还是因异常抛出而离开。
# 当需要获取 Object 的对象时可以这样写
obj = Object()
with obj as alias:
pass
下表使用 -> * 代表返回值类型是任意的,或者需要视情况而定,实际上并不存在这种写法。
诸如 -> str 仅表示绝大多数情况下应当返回 str 类型,或者推荐返回 str 类型。
没有 -> 的方法一般没有返回值。
参见 https://docs.python.org/zh-cn/3/reference/datamodel.html
| 语句 | 特殊方法 | 备注 | |
|---|---|---|---|
repr(obj) | __repr__(self) -> str | 详见 repr() 。 | |
str(obj) | __str__(self) -> str | 详见 str 类型 。 | |
bytes(obj) | __bytes__(self) -> bytes | 详见 bytes() 。 | |
format(obj, spec) | __format__(self, spec) -> str | 详见 format()、格式化字符串字面值、格式规格迷你语言 。 | |
hash(obj) | __hash__(self) -> int | 详见 hash() 。 | |
bool(obj) | __bool__(self) -> bool | 未定义时调用 obj.__len__() != 0 ,若 __len__() 也未定义,则所有对象都被视为 True 。另见 bool() 。 | |
dir(obj) | __dir__(self) -> list | 返回值必须是一个序列,dir() 会把返回的序列转换为列表并对其排序。 | |
Object[key] | __class_getitem__(cls, key) -> * | 不建议用于除了 模拟泛型类型 以外的用途,避免 IDE 误判。 |
| 语句 | 特殊方法 | 备注 | |
|---|---|---|---|
isinstance(instance, class) | class.__instancecheck__(self, instance) -> bool | 如果 instance 应被视为 class 的一个(直接或间接)实例则返回真值。 | |
issubclass(subclass, class) | class.__subclasscheck__(self, subclass) -> bool | 如果 subclass 应被视为 class 的一个(直接或间接)子类则返回真值。 |
| 语句 | 特殊方法 | 备注 | |
|---|---|---|---|
obj < other | __lt__(self, other) -> bool | ||
obj <= other | __le__(self, other) -> bool | ||
obj == other | __eq__(self, other) -> bool | 默认返回 obj is other ,如果结果为 False ,则会返回 NotImplemented 。 | |
obj != other | __ne__(self, other) -> bool | 默认返回 not obj.__eq__(other) 。 | |
obj > other | __gt__(self, other) -> bool | ||
obj >= other | __ge__(self, other) -> bool |
| 语句 | 特殊方法 | 备注 | |
|---|---|---|---|
obj.name | __getattr__(self, name) -> * | 优先调用。当抛出 AttributeError 时转向调用 __getattribute__() 。 | |
obj.name | __getattribute__(self, name) -> * | 参见 自定义属性访问 避免无限递归。 | |
obj.name = value | __setattr__(self, name, value) | ||
del obj.name | __delattr__(self, name) | 仅在 del obj.name 对于该对象有意义时才应该被实现。 |
| 语句 | 特殊方法 | 备注 | |
|---|---|---|---|
len(obj) | __len__(self) -> int | ||
op.length_hint(obj) | __length_hint__(self) -> int | 在使用标准库 operator 的 length_hint() 时会被调用(Python 3.4+)。 | |
obj[key] | __getitem__(self, key) -> * | 需要抛出 IndexError 以便正确地结束 for 循环。 | |
obj[key] | __missing__(self, key) -> * | 仅在 dict 的子类找不到键时被调用(不能重写 __getitem__ 方法)。 | |
obj[key] = value | __setitem__(self, key, value) | a[1:2] = b 实际上是 a[slice(1, 2, None)] = b ,其它情形及在其余方法中同理。详见 slice() 。 | |
del obj[key] | __delitem__(self, key) | ||
| 调用途径有很多 | __iter__(self) -> Iterator | 在需要创建一个 迭代器 时被调用,例如使用 iter() 、 for 循环 。最好返回一个新对象,因为迭代器在语义上是一次性的。若返回 self ,则必须实现 __next__() 方法。 | |
reversed(obj) | __reversed__(self) -> * | 详见 reversed() 。 | |
item in obj | __contains__(self, item) -> bool | 对于未定义该方法的对象在 in 和 not in 时,参考 成员检测运算 。 |
| 语句 | 特殊方法 | 备注 | |
|---|---|---|---|
+obj | __neg__(self) -> * | ||
-obj | __pos__(self) -> * | ||
~obj | __invert__(self) -> * | ||
abs(obj) | __abs__(self) -> * | ||
int(obj) | __int__(self) -> * | ||
float(obj) | __float__(self) -> * | ||
complex(obj) | __complex__(self) -> * | ||
round(obj) | __round__(self) -> int | 详见 round() 。 | |
round(obj) | __round__(self, ndigits) -> * | 详见 round() 。 | |
math.ceil(obj) | __ceil__(self) -> int | 详见标准库 math 的 ceil() 。 | |
math.floor(obj) | __floor__(self) -> int | 详见标准库 math 的 floor() 。 | |
math.trunc(obj) | __trunc__(self) -> int | 详见标准库 math 的 trunc() 。 | |
__index__(self) -> int | 需要无损地将数值转换为整数的时候会被调用。详见 这里 。 | ||
obj + other | __add__(self, other) -> * | ||
obj - other | __sub__(self, other) -> * | ||
obj * other | __mul__(self, other) -> * | ||
obj @ other | __matmul__(self, other) -> * | 为第三方库而生的矩阵乘法运算符,这里提了一嘴。(Python 3.5+) | |
obj / other | __truediv__(self, other) -> * | ||
obj // other | __floordiv__(self, other) -> * | ||
obj % other | __mod__(self, other) -> * | ||
divmod(obj, other) | __divmod__(self, other) -> tuple | divmod(a, b) 返回一个元组 (a // b, a % b) ,详见 divmod() 。 | |
obj ** exp | __pow__(self, exp) -> * | ||
pow(obj, exp, mod) | __pow__(self, exp, mod) -> * | pow(base, exp, mod) 比 pow(base, exp) % mod 更高效。 | |
obj << other | __lshift__(self, other) -> * | ||
obj >> other | __rshift__(self, other) -> * | ||
obj & other | __and__(self, other) -> * | ||
obj ^ other | __xor__(self, other) -> * | ||
obj | other | __or__(self, other) -> * | ||
other + obj | __radd__(self, obj) -> * | 仅当 obj 未定义 __add__() 或其返回 NotImplemented ,且与 other 互相都没有继承关系时,调用 other 的 __radd__() 。详见 这里 。 | |
other - obj | __rsub__(self, obj) -> * | 以下,如此类推。 | |
other * obj | __rmul__(self, obj) -> * | ||
other @ obj | __rmatmul__(self, obj) -> * | ||
other / obj | __rtruediv__(self, obj) -> * | ||
other // obj | __rfloordiv__(self, obj) -> * | ||
other % obj | __rmod__(self, obj) -> * | ||
divmod(other, obj) | __rdivmod__(self, obj) -> tuple | ||
other ** obj | __rpow__(self, obj) -> * | ||
__rpow__(self, obj, mod) -> * | pow(obj, other, mod) 不会尝试调用 other.__rpow__(obj, mod) ,因为强制转换规则会太过复杂。 | ||
other << obj | __rlshift__(self, obj) -> * | ||
other >> obj | __rrshift__(self, obj) -> * | ||
other & obj | __rand__(self, obj) -> * | ||
other ^ obj | __rxor__(self, obj) -> * | ||
other | obj | __ror__(self, obj) -> * | ||
obj += other | __iadd__(self, other) -> * | 若方法已定义,则 a += b 等价于 a.__iadd(b) ;若未定义,则回退到 a + b 选择 x.__add__(y) 和 y.__radd__(x) 。 | |
obj -= other | __isub__(self, other) -> * | 以下,如此类推。 | |
obj *= other | __imul__(self, other) -> * | ||
obj @= other | __imatmul__(self, other) -> * | ||
obj /= other | __itruediv__(self, other) -> * | ||
obj //= other | __ifloordiv__(self, other) -> * | ||
obj %= other | __imod__(self, other) -> * | ||
obj **= exp | __ipow__(self, other) -> * | ||
obj <<= other | __ilshift__(self, other) -> * | ||
obj >>= other | __irshift__(self, other) -> * | ||
obj &= other | __iand__(self, other) -> * | ||
obj ^= other | __ixor__(self, other) -> * | ||
obj |= other | __ior__(self, other) -> * |
string: str = "ha"
times: int = 3
print(string * times) # => hahaha
result: str = 1 + 2
print(result) # => 3
错误的类型标注不会影响正常运行,也不会报错
def say(name: str, start: str = "Hi"):
return start + ", " + name
print(say("Python")) # => Hi, Python
def calc_summary(*args: int):
return sum(args)
print(calc_summary(3, 1, 4)) # => 8
表示 args 的所有元素都是 int 类型的。
def say_hello(name) -> str:
return "Hello, " + name
var = "Python"
print(say_hello(var)) # => Hello, Python
from typing import Union
def resp200(meaningful) -> Union[int, str]:
return "OK" if meaningful else 200
表示返回值可能是 int,也可能是 str 。
def calc_summary(**kwargs: int):
return sum(kwargs.values())
print(calc_summary(a=1, b=2)) # => 3
表示 kwargs 的所有值都是 int 类型的。
def resp200() -> (int, str):
return 200, "OK"
def resp200(meaningful) -> int | str:
return "OK" if meaningful else 200
自 Python 3.10 起可用。
class Employee:
name: str
age: int
def __init__(self, name, age):
self.name = name
self.age = age
self.graduated: bool = False
class Employee:
name: str
age: int
def set_name(self, name) -> "Employee":
self.name = name
return self
这里表示 set_name() 返回了一个 Employee 对象。
from typing import Self
class Employee:
name: str
age: int
def set_name(self: Self, name) -> Self:
self.name = name
return self
from typing import TypeVar, Type
T = TypeVar("T")
# "mapper" 的值是一个像 int、str、MyClass 这样的类型
# "default" 是一个 T 类型的值,比如 314、"string"、MyClass()
# 函数的返回值也是一个 T 类型的值
def converter(raw, mapper: Type[T], default: T) -> T:
try:
return mapper(raw)
except:
return default
raw: str = input("请输入一个整数:")
result: int = converter(raw, mapper=int, default=0)
from typing import TypeVar, Callable, Any
T = TypeVar("T")
def converter(raw, mapper: Callable[[Any], T], default: T) -> T:
try:
return mapper(raw)
except:
return default
# Callable[[Any], T] 表示值是一个像这样声明的函数:
# def anynomous(arg: Any) -> T:
# pass
def is_success(value) -> bool:
return value in (0, "OK", True, "success")
resp = dict(code=0, message="OK", data=[])
successed: bool = converter(resp.message, mapper=is_success, default=False)
# 这是单行注释
""" 可以写多行字符串
使用三个",并且经常使用
作为文档。
"""
''' 可以写多行字符串
使用三个',并且经常使用
作为文档。
'''
def double_numbers(iterable):
for i in iterable:
yield i + i
生成器可帮助您编写惰性代码
values = (-x for x in [1,2,3,4,5])
gen_to_list = list(values)
# => [-1, -2, -3, -4, -5]
print(gen_to_list)
try:
# 使用“raise”来引发错误
raise IndexError("这是一个索引错误")
except IndexError as e:
pass # pass只是一个空操作。 通常你会在这里做恢复。
except (TypeError, NameError):
pass # 如果需要,可以一起处理多个异常。
else: # try/except 块的可选子句。 必须遵循除块之外的所有内容
print("All good!") # 仅当 try 中的代码未引发异常时运行
finally: # 在所有情况下执行
print("我们可以在这里清理资源")