Swift---Swift5基本语法
Swift5 https://docs.swift.org/swift-book/GuidedTour/GuidedTour.html
import UIKit
var str = "Hello, playground"
//介绍swift5相关的语法
//********************常量和变量
/*
1.常量定义时必须赋初值,
2.变量定义时必须加 “!” or “?”
3.可以在一行中声明多个常量或者多个变量,用逗号隔开:
*/
let maximumNumberOfLoginAttempts = 10
var currentLoginAttempt = 0
var x = 0.0, y = 0.0, z = 0.0
var sgfdfd:Int?
var welcomeMessage: String!
var welcomeMessageInt: Int?
var optionalString: String? = "Hello"
print(optionalString == nil)
// Prints "false"
var optionalName: String? = "John Appleseed"
var greeting = "Hello!"
if let name = optionalName {
greeting = "Hello, \(name)"
}
//********************条件语句
//Switch
let vegetable = "red pepper"
switch vegetable {
case "celery":
print("Add some raisins and make ants on a log.")
case "cucumber", "watercress":
print("That would make a good tea sandwich.")
case let x where x.hasSuffix("pepper"):
print("Is it a spicy \(x)?")
default:
print("Everything tastes good in soup.")
}
// Prints "Is it a spicy red pepper?"
//for-in
//字典是无序的!!!
let interestingNumbers = [
"Prime": [2, 3, 5, 7, 11, 13],
"Fibonacci": [1, 1, 2, 3, 5, 8],
"Square": [1, 4, 9, 16, 25],
]
var largest = 0
for (kind, numbers) in interestingNumbers {
print(kind)
for number in numbers {
if number > largest {
largest = number
}
}
}
print(largest)
//while-repeat
var n = 2
while n < 100 {
n *= 2
}
print(n)
// Prints "128"
var m = 2
repeat {
m *= 2
} while m < 100
print(m)
// Prints "128"
//You can keep an index in a loop by using ..< to make a range of indexes.
var total = 0
for i in 0..<4 {
total += i
}
print(total)
//********************数组和字典
//创建方式一
var shoppingList = ["catfish", "water", "tulips"]
shoppingList[1] = "bottle of water"
var occupations = [
"Malcolm": "Captain",
"Kaylee": "Mechanic",
]
occupations["Jayne"] = "Public Relations"
shoppingList.append("blue paint")
print(shoppingList)
//创建方式二
let emptyArray = [String]()
let emptyDictionary = [String: Float]()
let individualScores = [75, 43, 103, 87, 12]
//注意if 语句的使用
var teamScore = 0
for score in individualScores {
if score > 50 {
teamScore += 3
} else {
teamScore += 1
}
}
print(teamScore)
// Prints "11"
//********************Functions and Closures
/*
函数实际上是闭包的一种特殊情况:
方法名可以一样,但是方法里的参数设置不能一样,否则报错
*/
///简单方法
func greet(person: String, day: String) -> String {
return "Hello \(person), today is \(day)."
}
func greet(_ person: String, on day: String) -> String {
return "Hello \(person), today is \(day)."
}
func greet(_ person: String, ooon day: String) -> Int {
return 15
}
greet(person: "Bob", day: "Tuesday")
greet("John", on: "Wednesday")
greet("Bill", ooon: "TOne")
///返回多个参数的方法[通过tuple 实现]
func calculateStatistics(scores: [Int]) -> (min: Int, max: Int, sum: Int) {
var min = scores[0]
var max = scores[0]
var sum = 0
for score in scores {
if score > max {
max = score
} else if score < min {
min = score
}
sum += score
}
return (min, max, sum)
}
let statistics = calculateStatistics(scores: [5, 3, 100, 3, 9])
print(statistics.sum)
// Prints "120"
print(statistics.2)
// Prints "120"
///函数可以嵌套。嵌套函数可以访问在外部函数中声明的变量。可以使用嵌套函数在长函数或复杂函数中组织代码。
func returnFifteen() -> Int {
var y = 10
func add() {
y += 5
}
add()
return y
}
returnFifteen()
///函数可以返回另一个函数作为它的值。
func makeIncrementer() -> ((Int) -> Int) {
func addOne(number: Int) -> Int {
return 1 + number
}
return addOne
}
var increment = makeIncrementer()
increment(7)
///一个函数可以接受另一个函数作为它的参数之一。
func hasAnyMatches(list: [Int], condition: (Int) -> Bool) -> Bool {
for item in list {
if condition(item) {
return true
}
}
return false
}
func lessThanTen(number: Int) -> Bool {
return number < 10
}
var numbers = [20, 19, 7, 12]
hasAnyMatches(list: numbers, condition: lessThanTen)
///函数实际上是闭包的一种特殊情况:
numbers.map({ (number: Int) -> Int in
let result = 3 * number
return result
})
///您有几个选项可以更简洁地编写闭包。当闭包的类型已知时,例如委托的回调,您可以省略它的参数类型、返回类型,或者两者都省略。单个语句闭包隐式地返回它们唯一语句的值。
let mappedNumbers = numbers.map({ number in 3 * number })
print(mappedNumbers)
// Prints "[60, 57, 21, 36]"
//********************Objects and Classes
//一个简单的类
class Shape {
var numberOfSides = 0
func simpleDescription() -> String {
return "A shape with \(numberOfSides) sides."
}
}
var shape = Shape()
shape.numberOfSides = 7
var shapeDescription = shape.simpleDescription()
//一个有init 的类
class NamedShape {
var numberOfSides: Int = 0
var name: String
init(name: String) {
self.name = name
}
func simpleDescription() -> String {
return "A shape with \(numberOfSides) sides."
}
}
//实现继承的类
class Square: NamedShape {
var sideLength: Double
init(sideLength: Double, name: String) {
self.sideLength = sideLength
super.init(name: name)
numberOfSides = 4
}
func area() -> Double {
return sideLength * sideLength
}
override func simpleDescription() -> String {
return "A square with sides of length \(sideLength)."
}
}
let test = Square(sideLength: 5.2, name: "my test square")
test.area()
test.simpleDescription()
///除了存储的简单属性外,属性还可以有getter和setter。
class EquilateralTriangle: NamedShape {
var sideLength: Double = 0.0
init(sideLength: Double, name: String) {
self.sideLength = sideLength
super.init(name: name)
numberOfSides = 3
}
var perimeter: Double {
get {
return 3.0 * sideLength
}
set {
sideLength = newValue / 3.0
}
}
override func simpleDescription() -> String {
return "An equilateral triangle with sides of length \(sideLength)."
}
}
var triangle = EquilateralTriangle(sideLength: 3.1, name: "a triangle")
print(triangle.perimeter)
// Prints "9.3"
triangle.perimeter = 9.9
print(triangle.sideLength)
// Prints "3.3000000000000003"
///如果您不需要计算属性,但仍然需要提供在设置新值之前和之后运行的代码,那么使用willSet和didSet。只要值在初始化器之外发生更改,就会运行您提供的代码。例如,下面的类确保三角形的边长总是与其正方形的边长相同。
class TriangleAndSquare {
var triangle: EquilateralTriangle {
willSet {
square.sideLength = newValue.sideLength
}
}
var square: Square {
willSet {
triangle.sideLength = newValue.sideLength
}
}
init(size: Double, name: String) {
square = Square(sideLength: size, name: name)
triangle = EquilateralTriangle(sideLength: size, name: name)
}
}
var triangleAndSquare = TriangleAndSquare(size: 10, name: "another test shape")
print(triangleAndSquare.square.sideLength)
// Prints "10.0"
print(triangleAndSquare.triangle.sideLength)
// Prints "10.0"
triangleAndSquare.square = Square(sideLength: 50, name: "larger square")
print(triangleAndSquare.triangle.sideLength)
// Prints "50.0"
///当处理可选值时,您可以编写?在方法、属性和下标等操作之前。如果之前的值是?是nil吗?被忽略,整个表达式的值为nil。否则,可选值将被打开,并且在?作用于打开的值。在这两种情况下,整个表达式的值都是一个可选值。
let optionalSquare: Square? = Square(sideLength: 2.5, name: "optional square")
let sideLength = optionalSquare?.sideLength
//********************Enumerations and Structures
//使用枚举创建枚举。与类和所有其他命名类型一样,枚举可以具有与其关联的方法。
enum Rank: Int {
case ace = 1
case two, three, four, five, six, seven, eight, nine, ten
case jack, queen, king
func simpleDescription() -> String {
switch self {
case .ace:
return "ace"
case .jack:
return "jack"
case .queen:
return "queen"
case .king:
return "king"
default:
return String(self.rawValue)
}
}
}
let ace = Rank.ace
let aceRawValue = ace.rawValue
//使用init?(rawValue:)初始化器从原始值生成枚举的实例。如果没有匹配的秩,则返回匹配原始值的枚举用例或nil。
if let convertedRank = Rank(rawValue: 3) {
let threeDescription = convertedRank.simpleDescription()
}
//枚举的大小写值是实际值,而不仅仅是编写原始值的另一种方式。事实上,在没有有意义的原始值的情况下,您不需要提供一个。
enum Suit {
case spades, hearts, diamonds, clubs
func simpleDescription() -> String {
switch self {
case .spades:
return "spades"
case .hearts:
return "hearts"
case .diamonds:
return "diamonds"
case .clubs:
return "clubs"
}
}
}
let hearts = Suit.hearts
let heartsDescription = hearts.simpleDescription()
//如果枚举具有原始值,这些值将作为声明的一部分确定,这意味着特定枚举用例的每个实例始终具有相同的原始值。枚举用例的另一个选择是拥有与该用例相关联的值——这些值是在创建实例时确定的,并且对于枚举用例的每个实例,它们可以是不同的。可以将关联值视为枚举用例实例的存储属性。例如,考虑从服务器请求日出和日落时间的情况。服务器要么响应所请求的信息,要么响应错误的描述。
enum ServerResponse {
case result(String, String)
case failure(String)
}
let success = ServerResponse.result("6:00 am", "8:09 pm")
let failure = ServerResponse.failure("Out of cheese.")
switch success {
case let .result(sunrise, sunset):
print("Sunrise is at \(sunrise) and sunset is at \(sunset).")
case let .failure(message):
print("Failure... \(message)")
}
// Prints "Sunrise is at 6:00 am and sunset is at 8:09 pm."
//使用struct创建结构。结构支持许多与类相同的行为,包括方法和初始化器。结构和类之间最重要的区别之一是,结构在代码中传递时总是被复制,但是类是通过引用传递的。
struct Card {
var rank: Rank
var suit: Suit
func simpleDescription() -> String {
return "The \(rank.simpleDescription()) of \(suit.simpleDescription())"
}
}
let threeOfSpades = Card(rank: .three, suit: .spades)
let threeOfSpadesDescription = threeOfSpades.simpleDescription()
//********************Protocols and Extensions
//使用协议声明协议。
//使用 mutating 关键字修饰方法是为了能在该方法中修改 struct 或是 enum 的变量,在设计接口的时候,也要考虑到使用者程序的扩展性。所以要多考虑使用mutating来修饰方法。
//注意,在SimpleStructure声明中使用mutating关键字来标记修改结构的方法。SimpleClass的声明不需要任何标记为mutating的方法,因为类上的方法总是可以修改该类。
protocol ExampleProtocol {
var simpleDescription: String { get }
mutating func adjust()
}
class SimpleClass: ExampleProtocol {
var simpleDescription: String = "A very simple class."
var anotherProperty: Int = 69105
func adjust() {
simpleDescription += " Now 100% adjusted."
}
}
var a = SimpleClass()
a.adjust()
let aDescription = a.simpleDescription
struct SimpleStructure: ExampleProtocol {
var simpleDescription: String = "A simple structure"
mutating func adjust() {
simpleDescription += " (adjusted)"
}
}
var b = SimpleStructure()
b.adjust()
let bDescription = b.simpleDescription
//使用扩展向现有类型添加功能,如新方法和计算属性。您可以使用扩展将协议一致性添加到在其他地方声明的类型,甚至添加到从库或框架导入的类型。
extension Int: ExampleProtocol {
var simpleDescription: String {
return "The number \(self)"
}
mutating func adjust() {
self += 42
}
}
print(7.simpleDescription)
// Prints "The number 7"
//您可以像使用任何其他命名类型一样使用协议名称—例如,创建具有不同类型但都符合单个协议的对象集合。当处理类型为协议类型的值时,不能使用协议定义之外的方法。
let protocolValue: ExampleProtocol = a
print(protocolValue.simpleDescription)
// Prints "A very simple class. Now 100% adjusted."
// print(protocolValue.anotherProperty) // Uncomment to see the error
//即使变量protocolValue有一个SimpleClass的运行时类型,编译器仍然将它视为给定类型的ExampleProtocol。这意味着除了协议一致性之外,您不能意外地访问类实现的方法或属性。
//********************Error Handling
//使用采用错误协议的任何类型表示错误。
enum PrinterError: Error {
case outOfPaper
case noToner
case onFire
}
//使用throw来抛出错误,并使用throw来标记可能抛出错误的函数。如果在函数中抛出错误,函数将立即返回,调用该函数的代码将处理该错误。
func send(job: Int, toPrinter printerName: String) throws -> String {
if printerName == "Never Has Toner" {
throw PrinterError.noToner
}
return "Job sent"
}
//有几种方法可以处理错误。一种方法是使用do-catch。在do块内部,您可以通过在其前面编写try来标记可能抛出错误的代码。在catch块内部,除非您给它一个不同的名称,否则错误会自动给出名称错误。
do {
let printerResponse = try send(job: 1040, toPrinter: "Bi Sheng")
print(printerResponse)
} catch {
print(error)
}
// Prints "Job sent"
//您可以提供多个catch块来处理特定的错误。在catch之后编写模式,就像在开关的case之后一样。
do {
let printerResponse = try send(job: 1440, toPrinter: "Gutenberg")
print(printerResponse)
} catch PrinterError.onFire {
print("I'll just put this over here, with the rest of the fire.")
} catch let printerError as PrinterError {
print("Printer error: \(printerError).")
} catch {
print(error)
}
// Prints "Job sent"
//另一种处理错误的方法是使用try?将结果转换为可选的。如果函数抛出错误,则丢弃特定的错误,结果为nil。否则,结果是一个可选的,包含函数返回的值。
let printerSuccess = try? send(job: 1884, toPrinter: "Mergenthaler")
let printerFailure = try? send(job: 1885, toPrinter: "Never Has Toner")
//使用defer编写一个代码块,该代码块在函数中所有其他代码之后,即函数返回之前执行。无论函数是否抛出错误,都会执行代码。您可以使用defer互相编写安装和清理代码,即使它们需要在不同的时间执行。
var fridgeIsOpen = false
let fridgeContent = ["milk", "eggs", "leftovers"]
func fridgeContains(_ food: String) -> Bool {
fridgeIsOpen = true
defer {
fridgeIsOpen = false
}
let result = fridgeContent.contains(food)
return result
}
fridgeContains("banana")
print(fridgeIsOpen)
// Prints "false"
//********************泛型
//在尖括号内编写一个名称,使其成为泛型函数或类型。
func makeArray<Item>(repeating item: Item, numberOfTimes: Int) -> [Item] {
var result = [Item]()
for _ in 0..<numberOfTimes {
result.append(item)
}
return result
}
makeArray(repeating: "knock", numberOfTimes: 4)
//您可以创建函数和方法的通用形式,以及类、枚举和结构。
// Reimplement the Swift standard library's optional type
enum OptionalValue<Wrapped> {
case none
case some(Wrapped)
}
var possibleInteger: OptionalValue<Int> = .none
possibleInteger = .some(100)
//在正文前面指定需求列表的位置使用—例如,要求类型实现协议,要求两种类型相同,或者要求类具有特定的超类。
//sequence 是一个协议
//在 Swift 4 中可以在 associatedtype 后面声明的类型后追加 where 语句
func anyCommonElements<T: Sequence, U: Sequence>(_ lhs: T, _ rhs: U) -> Bool
where T.Element: Equatable, T.Element == U.Element
{
for lhsItem in lhs {
for rhsItem in rhs {
if lhsItem == rhsItem {
return true
}
}
}
return false
}
anyCommonElements([1, 2, 3], [3])
//上面这个假定函数有两个类型参数。第一个类型参数T,有一个需要T必须遵循Sequence协议的类型约束;第二个类型参数U,有一个需要U必须遵循Sequence协议的类型约束。
print("end")