Apple Swift编程语言入门教程（英文版）

Swift教程中文版：http://blog.csdn.net/mushitaotao/article/details/28679879

Apple Swift编程语言入门教程（英文版）

A Swift Tour

Tradition suggests that the first program in a new language should print the words “Hello, world” on the screen. In Swift, this can be done in a single line:

• println("Hello, world")

If you have written code in C or Objective-C, this syntax looks familiar to you—in Swift, this line of code is a complete program. You don’t need to import a separate library for functionality like input/output or string handling. Code written at global scope is used as the entry point for the program, so you don’t need a mainfunction. You also don’t need to write semicolons at the end of every statement.

This tour gives you enough information to start writing code in Swift by showing you how to accomplish a variety of programming tasks. Don’t worry if you don’t understand something—everything introduced in this tour is explained in detail in the rest of this book.

NOTE

For the best experience, open this chapter as a playground in Xcode. Playgrounds allow you to edit the code listings and see the result immediately.

Open Playground

Simple Values

Use let to make a constant and var to make a variable. The value of a constant doesn’t need to be known at compile time, but you must assign it a value exactly once. This means you can use constants to name a value that you determine once but use in many places.

• varmyVariable = 42
• myVariable = 50
• letmyConstant = 42

A constant or variable must have the same type as the value you want to assign to it. However, you don’t always have to write the type explicitly. Providing a value when you create a constant or variable lets the compiler infer its type. In the example above, the compiler infers that myVariable is an integer because its initial value is a integer.

If the initial value doesn’t provide enough information (or if there is no initial value), specify the type by writing it after the variable, separated by a colon.

• letimplicitInteger = 70
• letimplicitDouble = 70.0
• letexplicitDouble: Double = 70

EXPERIMENT

Create a constant with an explicit type of Float and a value of 4.

Values are never implicitly converted to another type. If you need to convert a value to a different type, explicitly make an instance of the desired type.

• letlabel = "The width is "
• letwidth = 94
• letwidthLabel = label + String(width)

EXPERIMENT

Try removing the conversion to String from the last line. What error do you get?

There’s an even simpler way to include values in strings: Write the value in parentheses, and write a backslash (\) before the parentheses. For example:

• letapples = 3
• letoranges = 5
• letappleSummary = "I have \(apples) apples."
• letfruitSummary = "I have \(apples +oranges) pieces of fruit."

EXPERIMENT

Use \() to include a floating-point calculation in a string and to include someone’s name in a greeting.

Create arrays and dictionaries using brackets ([]), and access their elements by writing the index or key in brackets.

• varshoppingList = ["catfish","water", "tulips", "blue paint"]
• shoppingList[1] = "bottle of water"
• varoccupations = [
• "Malcolm":"Captain",
• "Kaylee":"Mechanic",
• ]
• occupations["Jayne"] = "Public Relations"

To create an empty array or dictionary, use the initializer syntax.

• letemptyArray = String[]()
• letemptyDictionary = Dictionary<String,Float>()

If type information can be inferred, you can write an empty array as [] and an empty dictionary as [:]—for example, when you set a new value for a variable or pass an argument to a function.

• shoppingList = [] // Went shopping and bought everything.

Control Flow

Use if and switch to make conditionals, and use for-in, for, while, and do-while to make loops. Parentheses around the condition or loop variable are optional. Braces around the body are required.

• letindividualScores = [75,43, 103, 87, 12]
• varteamScore = 0
• forscore in individualScores {
• ifscore > 50 {
• teamScore += 3
• }else {
• teamScore += 1
• }
• }
• teamScore

In an if statement, the conditional must be a Boolean expression—this means that code such as if score { ... } is an error, not an implicit comparison to zero.

You can use if and let together to work with values that might be missing. These values are represented as optionals. An optional value either contains a value or contains nil to indicate that the value is missing. Write a question mark (?) after the type of a value to mark the value as optional.

• varoptionalString: String? = "Hello"
• optionalString == nil
• varoptionalName: String? = "John Appleseed"
• vargreeting = "Hello!"
• iflet name = optionalName {
• greeting = "Hello, \(name)"
• }

EXPERIMENT

Change optionalName to nil. What greeting do you get? Add an else clause that sets a different greeting ifoptionalName is nil.

If the optional value is nil, the conditional is false and the code in braces is skipped. Otherwise, the optional value is unwrapped and assigned to the constant after let, which makes the unwrapped value available inside the block of code.

Switches support any kind of data and a wide variety of comparison operations—they aren’t limited to integers and tests for equality.

• letvegetable = "red pepper"
• switchvegetable {
• case"celery":
• letvegetableComment = "Add some raisins and make ants on a log."
• case"cucumber", "watercress":
• letvegetableComment = "That would make a good tea sandwich."
• caselet x where x.hasSuffix("pepper"):
• letvegetableComment = "Is it a spicy \(x)?"
• default:
• letvegetableComment = "Everything tastes good in soup."
• }

EXPERIMENT

Try removing the default case. What error do you get?

After executing the code inside the switch case that matched, the program exits from the switch statement. Execution doesn’t continue to the next case, so there is no need to explicitly break out of the switch at the end of each case’s code.

You use for-in to iterate over items in a dictionary by providing a pair of names to use for each key-value pair.

• letinterestingNumbers = [
• "Prime": [2,3, 5, 7, 11, 13],
• "Fibonacci": [1,1, 2, 3, 5, 8],
• "Square": [1,4, 9, 16, 25],
• ]
• varlargest = 0
• for (kind,numbers) in interestingNumbers {
• fornumber in numbers {
• ifnumber > largest {
• largest = number
• }
• }
• }
• largest

EXPERIMENT

Add another variable to keep track of which kind of number was the largest, as well as what that largest number was.

Use while to repeat a block of code until a condition changes. The condition of a loop can be at the end instead, ensuring that the loop is run at least once.

• varn = 2
• whilen < 100 {
• n = n * 2
• }
• n
• varm = 2
• do {
• m = m * 2
• }while m < 100
• m

You can keep an index in a loop—either by using .. to make a range of indexes or by writing an explicit initialization, condition, and increment. These two loops do the same thing:

• varfirstForLoop = 0
• fori in 0..3 {
• firstForLoop += i
• }
• firstForLoop
• varsecondForLoop = 0
• forvar i = 0; i < 3; ++i {
• secondForLoop += 1
• }
• secondForLoop

Use .. to make a range that omits its upper value, and use ... to make a range that includes both values.

Functions and Closures

Use func to declare a function. Call a function by following its name with a list of arguments in parentheses. Use -> to separate the parameter names and types from the function’s return type.

• funcgreet(name:String, day: String) -> String {
• return"Hello \(name), today is \(day)."
• }
• greet("Bob","Tuesday")

EXPERIMENT

Remove the day parameter. Add a parameter to include today’s lunch special in the greeting.

Use a tuple to return multiple values from a function.

• funcgetGasPrices() -> (Double,Double, Double) {
• return (3.59,3.69, 3.79)
• }
• getGasPrices()

Functions can also take a variable number of arguments, collecting them into an array.

• funcsumOf(numbers:Int...) -> Int {
• varsum = 0
• fornumber in numbers {
• sum += number
• }
• returnsum
• }
• sumOf()
• sumOf(42,597, 12)

EXPERIMENT

Write a function that calculates the average of its arguments.

Functions can be nested. Nested functions have access to variables that were declared in the outer function. You can use nested functions to organize the code in a function that is long or complex.

• funcreturnFifteen() -> Int {
• vary = 10
• funcadd() {
• y += 5
• }
• add()
• returny
• }
• returnFifteen()

Functions are a first-class type. This means that a function can return another function as its value.

• funcmakeIncrementer() -> (Int ->Int) {
• funcaddOne(number:Int) -> Int {
• return1 + number
• }
• returnaddOne
• }
• varincrement = makeIncrementer()
• increment(7)

A function can take another function as one of its arguments.

• funchasAnyMatches(list:Int[], condition: Int -> Bool) -> Bool {
• foritem in list {
• ifcondition(item) {
• returntrue
• }
• }
• returnfalse
• }
• funclessThanTen(number:Int) -> Bool {
• returnnumber < 10
• }
• varnumbers = [20,19, 7, 12]
• hasAnyMatches(numbers,lessThanTen)

Functions are actually a special case of closures. You can write a closure without a name by surrounding code with braces ({}). Use in to separate the arguments and return type from the body.

• numbers.map({
• (number:Int) -> Int in
• letresult = 3 * number
• returnresult
• })

EXPERIMENT

Rewrite the closure to return zero for all odd numbers.

You have several options for writing closures more concisely. When a closure’s type is already known, such as the callback for a delegate, you can omit the type of its parameters, its return type, or both. Single statement closures implicitly return the value of their only statement.

• numbers.map({number in 3 * number })

You can refer to parameters by number instead of by name—this approach is especially useful in very short closures. A closure passed as the last argument to a function can appear immediately after the parentheses.

• sort([1,5, 3, 12, 2]) { $0 > $1 }

Objects and Classes

Use class followed by the class’s name to create a class. A property declaration in a class is written the same way as a constant or variable declaration, except that it is in the context of a class. Likewise, method and function declarations are written the same way.

• classShape {
• varnumberOfSides = 0
• funcsimpleDescription() -> String {
• return"A shape with \(numberOfSides) sides."
• }
• }

EXPERIMENT

Add a constant property with let, and add another method that takes an argument.

Create an instance of a class by putting parentheses after the class name. Use dot syntax to access the properties and methods of the instance.

• varshape = Shape()
• shape.numberOfSides = 7
• varshapeDescription = shape.simpleDescription()

This version of the Shape class is missing something important: an initializer to set up the class when an instance is created. Use init to create one.

• classNamedShape {
• varnumberOfSides: Int = 0
• varname: String
• init(name:String) {
• self.name = name
• }
• funcsimpleDescription() -> String {
• return"A shape with \(numberOfSides) sides."
• }
• }

Notice how self is used to distinguish the name property from the name argument to the initializer. The arguments to the initializer are passed like a function call when you create an instance of the class. Every property needs a value assigned—either in its declaration (as with numberOfSides) or in the initializer (as withname).

Use deinit to create a deinitializer if you need to perform some cleanup before the object is deallocated.

Subclasses include their superclass name after their class name, separated by a colon. There is no requirement for classes to subclass any standard root class, so you can include or omit a superclass as needed.

Methods on a subclass that override the superclass’s implementation are marked with override—overriding a method by accident, without override, is detected by the compiler as an error. The compiler also detects methods with override that don’t actually override any method in the superclass.

• classSquare: NamedShape {
• varsideLength: Double
• init(sideLength:Double, name: String) {
• self.sideLength = sideLength
• super.init(name:name)
• numberOfSides = 4
• }
• funcarea() -> Double {
• returnsideLength * sideLength
• }
• overridefunc simpleDescription() -> String {
• return"A square with sides of length \(sideLength)."
• }
• }
• lettest = Square(sideLength:5.2, name: "my test square")
• test.area()
• test.simpleDescription()

EXPERIMENT

Make another subclass of NamedShape called Circle that takes a radius and a name as arguments to its initializer. Implement an area and a describe method on the Circle class.

In addition to simple properties that are stored, properties can have a getter and a setter.

• classEquilateralTriangle: NamedShape {
• varsideLength: Double = 0.0
• init(sideLength:Double, name: String) {
• self.sideLength = sideLength
• super.init(name:name)
• numberOfSides = 3
• }
• varperimeter: Double {
• get {
• return3.0 * sideLength
• }
• set {
• sideLength = newValue / 3.0
• }
• }
• overridefunc simpleDescription() -> String {
• return"An equilateral triagle with sides of length \(sideLength)."
• }
• }
• vartriangle = EquilateralTriangle(sideLength:3.1, name: "a triangle")
• triangle.perimeter
• triangle.perimeter = 9.9
• triangle.sideLength

In the setter for perimeter, the new value has the implicit name newValue. You can provide an explicit name in parentheses after set.

Notice that the initializer for the EquilateralTriangle class has three different steps:

1. Setting the value of properties that the subclass declares.

2. Calling the superclass’s initializer.

3. Changing the value of properties defined by the superclass. Any additional setup work that uses methods, getters, or setters can also be done at this point.

If you don’t need to compute the property but still need to provide code that is run before and after setting a new value, use willSet and didSet. For example, the class below ensures that the side length of its triangle is always the same as the side length of its square.

• classTriangleAndSquare {
• vartriangle: EquilateralTriangle {
• willSet {
• square.sideLength = newValue.sideLength
• }
• }
• varsquare: Square {
• willSet {
• triangle.sideLength = newValue.sideLength
• }
• }
• init(size:Double, name: String) {
• square = Square(sideLength:size, name: name)
• triangle = EquilateralTriangle(sideLength:size, name: name)
• }
• }
• vartriangleAndSquare = TriangleAndSquare(size:10, name: "another test shape")
• triangleAndSquare.square.sideLength
• triangleAndSquare.triangle.sideLength
• triangleAndSquare.square = Square(sideLength:50, name: "larger square")
• triangleAndSquare.triangle.sideLength

Methods on classes have one important difference from functions. Parameter names in functions are used only within the function, but parameters names in methods are also used when you call the method (except for the first parameter). By default, a method has the same name for its parameters when you call it and within the method itself. You can specify a second name, which is used inside the method.

• classCounter {
• varcount: Int = 0
• funcincrementBy(amount:Int, numberOfTimes times: Int) {
• count += amount * times
• }
• }
• varcounter = Counter()
• counter.incrementBy(2,numberOfTimes: 7)

When working with optional values, you can write ? before operations like methods, properties, and subscripting. If the value before the ? is nil, everything after the ? is ignored and the value of the whole expression is nil. Otherwise, the optional value is unwrapped, and everything after the ? acts on the unwrapped value. In both cases, the value of the whole expression is an optional value.

• letoptionalSquare: Square? = Square(sideLength:2.5, name: "optional square")
• letsideLength = optionalSquare?.sideLength

Enumerations and Structures

Use enum to create an enumeration. Like classes and all other named types, enumerations can have methods associated with them.

• enumRank: Int {
• caseAce = 1
• caseTwo, Three, Four, Five, Six, Seven, Eight, Nine, Ten
• caseJack, Queen, King
• funcsimpleDescription() -> String {
• switchself {
• case .Ace:
• return"ace"
• case .Jack:
• return"jack"
• case .Queen:
• return"queen"
• case .King:
• return"king"
• default:
• returnString(self.toRaw())
• }
• }
• }
• letace = Rank.Ace
• letaceRawValue = ace.toRaw()

EXPERIMENT

Write a function that compares two Rank values by comparing their raw values.

In the example above, the raw value type of the enumeration is Int, so you only have to specify the first raw value. The rest of the raw values are assigned in order. You can also use strings or floating-point numbers as the raw type of an enumeration.

Use the toRaw and fromRaw functions to convert between the raw value and the enumeration value.

• iflet convertedRank = Rank.fromRaw(3) {
• letthreeDescription = convertedRank.simpleDescription()
• }

The member values of an enumeration are actual values, not just another way of writing their raw values. In fact, in cases where there isn’t a meaningful raw value, you don’t have to provide one.

• enumSuit {
• caseSpades, Hearts, Diamonds, Clubs
• funcsimpleDescription() -> String {
• switchself {
• case .Spades:
• return"spades"
• case .Hearts:
• return"hearts"
• case .Diamonds:
• return"diamonds"
• case .Clubs:
• return"clubs"
• }
• }
• }
• lethearts = Suit.Hearts
• letheartsDescription = hearts.simpleDescription()

EXPERIMENT

Add a color method to Suit that returns “black” for spades and clubs, and returns “red” for hearts and diamonds.

Notice the two ways that the Hearts member of the enumeration is referred to above: When assigning a value to the hearts constant, the enumeration member Suit.Hearts is referred to by its full name because the constant doesn’t have an explicit type specified. Inside the switch, the enumeration is referred to by the abbreviated form .Hearts because the value of self is already known to be a suit. You can use the abbreviated form anytime the value’s type is already known.

Use struct to create a structure. Structures support many of the same behaviors as classes, including methods and initializers. One of the most important differences between structures and classes is that structures are always copied when they are passed around in your code, but classes are passed by reference.

• structCard {
• varrank: Rank
• varsuit: Suit
• funcsimpleDescription() -> String {
• return"The \(rank.simpleDescription()) of \(suit.simpleDescription())"
• }
• }
• letthreeOfSpades = Card(rank: .Three,suit: .Spades)
• letthreeOfSpadesDescription = threeOfSpades.simpleDescription()

EXPERIMENT

Add a method to Card that creates a full deck of cards, with one card of each combination of rank and suit.

An instance of an enumeration member can have values associated with the instance. Instances of the same enumeration member can have different values associated with them. You provide the associated values when you create the instance. Associated values and raw values are different: The raw value of an enumeration member is the same for all of its instances, and you provide the raw value when you define the enumeration.

For example, consider the case of requesting the sunrise and sunset time from a server. The server either responds with the information or it responds with some error information.

• enumServerResponse {
• caseResult(String,String)
• caseError(String)
• }
• letsuccess = ServerResponse.Result("6:00 am", "8:09 pm")
• letfailure = ServerResponse.Error("Out of cheese.")
• switchsuccess {
• caselet .Result(sunrise,sunset):
• letserverResponse = "Sunrise is at \(sunrise) and sunset is at \(sunset)."
• caselet .Error(error):
• letserverResponse = "Failure... \(error)"
• }

EXPERIMENT

Add a third case to ServerResponse and to the switch.

Notice how the sunrise and sunset times are extracted from the ServerResponse value as part of matching the value against the switch cases.

Protocols and Extensions

Use protocol to declare a protocol.

• protocolExampleProtocol {
• varsimpleDescription: String { get }
• mutatingfunc adjust()
• }

Classes, enumerations, and structs can all adopt protocols.

• classSimpleClass: ExampleProtocol {
• varsimpleDescription: String = "A very simple class."
• varanotherProperty: Int = 69105
• funcadjust() {
• simpleDescription += " Now 100% adjusted."
• }
• }
• vara = SimpleClass()
• a.adjust()
• letaDescription = a.simpleDescription
• structSimpleStructure: ExampleProtocol {
• varsimpleDescription: String = "A simple structure"
• mutatingfunc adjust() {
• simpleDescription += " (adjusted)"
• }
• }
• varb = SimpleStructure()
• b.adjust()
• letbDescription = b.simpleDescription

EXPERIMENT

Write an enumeration that conforms to this protocol.

Notice the use of the mutating keyword in the declaration of SimpleStructure to mark a method that modifies the structure. The declaration of SimpleClass doesn’t need any of its methods marked as mutating because methods on a class can always modify the class.

Use extension to add functionality to an existing type, such as new methods and computed properties. You can use an extension to add protocol conformance to a type that is declared elsewhere, or even to a type that you imported from a library or framework.

• extensionInt: ExampleProtocol {
• varsimpleDescription: String {
• return"The number \(self)"
• }
• mutatingfunc adjust() {
• self += 42
• }
• }
• 7.simpleDescription

EXPERIMENT

Write an extension for the Double type that adds an absoluteValue property.

You can use a protocol name just like any other named type—for example, to create a collection of objects that have different types but that all conform to a single protocol. When you work with values whose type is a protocol type, methods outside the protocol definition are not available.

• letprotocolValue: ExampleProtocol = a
• protocolValue.simpleDescription
• // protocolValue.anotherProperty // Uncomment to see the error

Even though the variable protocolValue has a runtime type of SimpleClass, the compiler treats it as the given type of ExampleProtocol. This means that you can’t accidentally access methods or properties that the class implements in addition to its protocol conformance.

Generics

Write a name inside angle brackets to make a generic function or type.

• funcrepeat<ItemType>(item:ItemType, times: Int) -> ItemType[] {
• varresult = ItemType[]()
• fori in 0..times {
• result += item
• }
• returnresult
• }
• repeat("knock",4)

You can make generic forms of functions and methods, as well as classes, enumerations, and structures.

• // Reimplement the Swift standard library's optional type
• enumOptionalValue<T> {
• caseNone
• caseSome(T)
• }
• varpossibleInteger: OptionalValue<Int> = .None
• possibleInteger = .Some(100)

Use where after the type name to specify a list of requirements—for example, to require the type to implement a protocol, to require two types to be the same, or to require a class to have a particular superclass.

• funcanyCommonElements <T,U where T: Sequence, U: Sequence, T.GeneratorType.Element:Equatable, T.GeneratorType.Element == U.GeneratorType.Element> (lhs:T, rhs: U) -> Bool {
• forlhsItem in lhs {
• forrhsItem in rhs {
• iflhsItem == rhsItem {
• returntrue
• }
• }
• }
• returnfalse
• }
• anyCommonElements([1,2, 3], [3])

EXPERIMENT

Modify the anyCommonElements function to make a function that returns an array of the elements that any two sequences have in common.

In the simple cases, you can omit where and simply write the protocol or class name after a colon. Writing <T: Equatable> is the same as writing <T where T: Equatable>.