面向对象编程之类
//定义一个简单的类
scala> :paste
// Entering paste mode (ctrl-D to finish)
//类默认public的
class HelloWorld{
private var name = "leo"
def sayHello(){print("Hello,"+name)}
def getName = name
}
// Exiting paste mode, now interpreting.
defined class HelloWorld
scala> var helloWorld = new HelloWorld
helloWorld: HelloWorld = HelloWorld@74f143e1
scala> helloWorld.sayHello()
Hello,leo
scala> print(helloWorld.getName) //也可以不加括号,如果定义方法时不带括号,则用方法时也不能带括号
leo
//getter与setter
//定义不带private的var field,JVM会自动定义为private,并提供public的getter和setter方法
//如果定义private 修饰field,则生成getter和setter也是private的
//如果定义val filed,则只会生成getter方法
//如果不希望生成setter和getter方法,则将field声明为private[this]
自定义getter与setter
scala> :paste
// Entering paste mode (ctrl-D to finish)
class Student{
private var myName = "leo"
def name = "your name is" + myName
def name_=(newValue:String){
print("you cannot edit your name!!")
}
}
// Exiting paste mode, now interpreting.
defined class Student
scala> val leo = new Student //()可有可无
leo: Student = Student@4064c13a
scala> print(leo.name)
your name isleo
scala> leo.name = "leo1" //相当于setter方法
you cannot edit your name!!leo.name: String = your name isleo
仅暴露field的getter方法
scala> :paste
// Entering paste mode (ctrl-D to finish)
class Student{
private var myName = "leo" //private修饰,不暴露getter和setter方法,因此可以自定义
def updateName(newName:String){
if(newName == "leo1") myName = newName
else print("not accpet this new name!!")
}
def name = "your name is "+myName
}
// Exiting paste mode, now interpreting.
defined class Student
scala> val s = new Student()
s: Student = Student@6ff347a9
scala> s.name
res30: String = your name is leo
scala> s.updateName("tom")
not accpet this new name!!
scala> s.updateName("leo1")
scala> s.name
res33: String = your name is leo1
private[this]的使用
scala> :paste
// Entering paste mode (ctrl-D to finish)
class Student{
private var myAge = 0
def age_=(newValue:Int){
if(newValue > 0) myAge = newValue
else print("illegal age!")
}
def age = myAge
def older(s:Student)={ //用private[this]修饰的话会报错
myAge > s.myAge
}
}
// Exiting paste mode, now interpreting.
defined class Student
scala> val s1 = new Student
s1: Student = Student@1c437904
scala> s1.age = 20
s1.age: Int = 20
scala> val s2 = new Student
s2: Student = Student@400f0e8e
scala> s2.age = 25
s2.age: Int = 25
scala> s1.older(s2)
res34: Boolean = false
java风格的getter和setter
// 在Scala 2.10.0之后已被废弃
// 使用scala.beans.BeanProperty代替
scala> import scala.beans.BeanProperty
import scala.beans.BeanProperty
scala> :paste
// Entering paste mode (ctrl-D to finish)
class Student{
@BeanProperty var name:String = _
}
// Exiting paste mode, now interpreting.
defined class Student
scala> val s = new Student
s: Student = Student@1166c9c5
scala> s.setName("leo")
scala> s.get
getClass getName
scala> s.getName
res39: String = leo
辅助构造函数constructor
scala> :paste
// Entering paste mode (ctrl-D to finish)
class Student{
private var name = ""
private var age = 0
def this(name:String){
this()
this.name = name
}
def this(name:String,age:Int){
this(name)
this.age = age
}
}
// Exiting paste mode, now interpreting.
defined class Student
scala> var s1 = new Student()
s1: Student = Student@51c959a4
scala> val s2 = new Student("leo")
s2: Student = Student@51a18b21
scala> val s3 = new Student("leo",30)
s3: Student = Student@40ef0af8
主构造函数constructor
//主constructor与类名放在一起,与java不同
//类中没有定义在任何方法或者代码块中的代码,就是主constructor的代码
scala> :paste
// Entering paste mode (ctrl-D to finish)
class Student(val name:String,val age:Int){
println("your name is "+name +",your age is "+age)
}
// Exiting paste mode, now interpreting.
defined class Student
scala> val s = new Student
<console>:12: error: not enough arguments for constructor Student: (name: String, age: Int)Student.
Unspecified value parameters name, age.
val s = new Student
^
scala> val s = new Student("jom",23)
your name is jom,your age is 23
s: Student = Student@2d70f312
//给默认值
scala> :paste
// Entering paste mode (ctrl-D to finish)
class Student(val name:String="leo",val age:Int=30){ // 如果主constructor传入的参数什么修饰都没有,比如name:String ,那么如果类内部方法使用到了,则会声明为private[this] name;否则没有该field,就只能被constructor代码使用而已
println(name+" "+age)
}
// Exiting paste mode, now interpreting.
defined class Student
scala> val s1 = new Student
leo 30
s1: Student = Student@cf10c92
内部类
scala> import scala.collection.mutable.ArrayBuffer
import scala.collection.mutable.ArrayBuffer
scala> :paste
// Entering paste mode (ctrl-D to finish)
class Class{
class Student(val name:String){}
val students = new ArrayBuffer[Student]
def getStudent(name:String)={
new Student(name)
}
}
// Exiting paste mode, now interpreting.
defined class Class
scala> val c1 = new Class
c1: Class = Class@539bb233
scala> val s1 = c1.getStudent("leo")
s1: c1.Student = Class$Student@48b01607
scala> c1.students += s1
res0: c1.students.type = ArrayBuffer(Class$Student@48b01607)
scala> val c2 = new Class
c2: Class = Class@475fb7
scala> val s2 = c2.getStudent("leo")
s2: c2.Student = Class$Student@5f9f1886
scala> c1.students += s2
<console>:15: error: type mismatch;
found : c2.Student
required: c1.Student
c1.students += s2
^
面向对象编程之对象
- object,相当于class的单个实例,通常在里面放一些静态的field或者method
- 第一次调用object的方法时,就会执行object的constructor,也就是object内部不在method中的代码;但是object不能定义接收参数的constructor
- 注意,object的constructor只会在第一次被调用时执行一次,以后再调用不会再次执行constructor
- object通常用于作为单例模式的实现,或者放class的静态成员,比如工具方法
scala> :paste
// Entering paste mode (ctrl-D to finish)
object Person{
private var eyeNum=2
println("this Person object!")
def getEyeNum = eyeNum
}
scala> Person.getEyeNum
this Person object!
res3: Int = 2
伴生对象
- 如果有一个class,还有一个与class同名的object,那么就称这个object是class的伴生对象,class是object的伴生类
- 伴生对象伴生类和伴生对象必须放在一个.scala文件之中
- 伴生类和伴生对象,最大的特点就在于,互相可以访问private field
scala> :paste
// Entering paste mode (ctrl-D to finish)
class Person(val name:String,val age:Int){
def sayHello = println("Hi,"+name+",I guess you are "+age+"years old!"+Person.eyeNum)
}
object Person{
private val eyeNum = 2
def getEyeNum = eyeNum
}
scala> val p = new Person("TOM",30)
p: Person = Person@101f2ca2
scala> p.sayHello
Hi,TOM,I guess you are 30years old!2
让object继承抽象类
- object的功能其实和class类似,除了不能定义接收参数的constructor之外
- object也可以继承抽象类,并覆盖抽象类中的方法
scala> :paste
// Entering paste mode (ctrl-D to finish)
abstract class Hello(val message:String){
def sayHello(name:String):Unit
}
object HelloImpl extends Hello("hello"){
override def sayHello(name:String)={
println(message+","+name)
}
}
scala> HelloImpl.sayHello("world")
hello,world
apply方法
- object中非常重要的一个特殊方法,就是apply方法
- 通常在伴生对象中实现apply方法,并在其中实现构造伴生类的对象的功能
- 而创建伴生类的对象时,通常不会使用new Class的方式,而是使用Class()的方式,隐式地调用伴生对象的apply方法,这样会让对象创建更加简洁
- 比如,Array类的伴生对象的apply方法就实现了接收可变数量的参数,并创建一个Array对象的功能
- val a = Array(1,2,3,4,5)
scala> :paste
// Entering paste mode (ctrl-D to finish)
class Person(val name: String)
object Person{
def apply(name:String)=new Person(name)
}
// Exiting paste mode, now interpreting.
defined class Person
defined object Person
scala> val p1 = new Person("leo")
p1: Person = Person@7698b7a4
scala> val p2 = Person("leo")
p2: Person = Person@374c40ba
main方法
- 方法入口
- scala中main方法定义为def main(args:Array[String]),而且必须定义在object中
object HelloWorld{
def main(args:Array[String]){
println("Hello World!!")
}
}
- 除了自己实现main方法之外,还可以继承App Trait,然后将需要在main方法中运行的代码,直接作为object的constructor代码;而且用args可以接受传入的参数
object HelloWorld extends App{
if(args.length > 0) println("hello," + args(0))
else println("Hello World!!")
}
- 运行上述代码,需要放入.scala文件中,然后使用scalac编译,再用scala运行class文件 scala -Dscala.time HelloWorld
- App Trait的工作原理为:App Trait继承自DelayedInit Trait,scalac命令进行编译时,会把继承App Trait的object的constructor代码都放到DelayedInit Trait的delayedInit方法中执行
用object来实现枚举功能
- scala没有直接提供类似于java中的Enum这样的枚举特性,如果要实现枚举,则需要用object继承Enumeration类,并且调用Value方法来初始化枚举值
object Season extends Enumeration{
val SPRING,SUMMER,AUTUMN,WINTER = Value
}
scala> Season.SPRING
res0: Season.Value = SPRING
- 还可以通过Value传入枚举值的id和name,通过id和toString可以获取,还可以通过id和name来查找枚举值
scala> :paste
// Entering paste mode (ctrl-D to finish)
object Season extends Enumeration{
val SPRING = Value(0,"spring")
val SUMMER = Value(1,"summer")
val AUTUMN = Value(2,"autumn")
val WINTER = Value(3,"winter")
}
// Exiting paste mode, now interpreting.
defined object Season
scala> Season(0)
res0: Season.Value = spring
scala> Season.withName("spring")
res1: Season.Value = spring
scala> for(ele <- Season.values) println(ele)
spring
summer
autumn
winter
面向对象编程之继承
- 让子类继承父类,与java一样,也是使用extends关键字
- 继承就代表,子类可以从父类继承父类的field和method;然后子类可以在自己内部放入父类所没有,子类特有的field和method;使用继承可以有效复用代码
- 子类可以覆盖父类的filed和method;但是如果父类用final修饰,field和method用final修饰,则该类是无法被继承的,field和method是无法被覆盖的
scala> :paste
// Entering paste mode (ctrl-D to finish)
class Person{
private var name = "leo"
def getName = name
}
class Student extends Person{
private var score = "A"
def getScore = score
}
// Exiting paste mode, now interpreting.
defined class Person
defined class Student
scala> val s1 = new Student()
s1: Student = Student@1530d0f2
scala> s1.getScore
res3: String = A
scala> s1.getName
res4: String = leo
override和super
- 如果子类要覆盖一个父类中的非抽象方法,则必须使用override关键字
- override关键字可以帮组我们尽早的发现代码里的错误,覆写方法错了就会报错
- 在子类覆盖父类方法之后,如果我们在子类中就是要调用父类的被覆盖的方法,那就可以使用super关键字,显式地指定要调用父类的方法
scala> :paste
// Entering paste mode (ctrl-D to finish)
class Person{
private var name="leo"
def getName = name
}
class Student extends Person{
private var score = "A"
def getScore = score
override def getName = "Hi,I'm "+ super.getName
}
// Exiting paste mode, now interpreting.
defined class Person
defined class Student
scala> val st = new Student
st: Student = Student@445c693
scala> st.getName
res5: String = Hi,I'm leo
isInstanceOf和asInstanceOf
- 如果我们创建了子类的对象,但是又将其赋予了父类类型的变量,则在后续的程序中,我们又需要将父类类型的变量转换为子类类型的变量
- 使用isInstanceOf判断对象是否是指定类的对象,如果是的话,则可以使用asInstanceOf将对象转换为指定类型
- 注意,如果对象是null,则isInstanceOf一定返回false,asInstanceOf一定返回null
- 注意,如果没有用isInstanceOf先判断对象是否为指定类的实例,就直接用asInstanceOf转换,则可能会抛出异常
scala> :paste
// Entering paste mode (ctrl-D to finish)
class Person
class Student extends Person
val p:Person = new Student
var s:Student = null
if(p.isInstanceOf[Student]) s = p.asInstanceOf[Student]
// Exiting paste mode, now interpreting.
defined class Person
defined class Student
p: Person = Student@2d7e6c8c
s: Student = Student@2d7e6c8c
scala> s
res9: Student = Student@2d7e6c8c
getClass和classOf
- isInstanceOf只能判断对象是否是指定类以及其子类的对象,而不能精确判断出,对象就是指定类的对象
- 如果要求精确地判断对象就是指定类的对象,那么就只能使用getClass和classOf了
- 对象.getClass可以精确获取对象的类,classOf[类]可以精确获取类,然后使用==操作符即可判断
scala> :paste
class Person
class Student extends Person
val p:Person = new Student
p.isInstanceOf[Person]
// Exiting paste mode, now interpreting.
defined class Person
defined class Student
p: Person = Student@5b95557f
res11: Boolean = true
scala> p.getClass == classOf[Person]
res12: Boolean = false
scala> p.getClass == classOf[Student]
使用模式匹配进行类型判断
- 在实际开发中,比如spark的源码中,大量的地方使用模式匹配的方式来进行类型的判断
- 功能性上来说,与isInstanceOf一样,判断主要是该类以及该类的子类的对象即可,不是精准判断的
scala> :paste
// Entering paste mode (ctrl-D to finish)
class Person
class Student extends Person
val p:Person = new Student
p match{
case per:Person => println("its Person object")
case _ => println("unkonwn type")
}
// Exiting paste mode, now interpreting.
its Person object
defined class Person
defined class Student
p: Person = Student@7f4596d0
protected
- 跟java一样,使用protected关键字修饰的filed和method,在子类中就不需要super关键字,直接就可以访问field和method
- 还可以使用protected[this],则只能在当前子类对象中访问父类的field和method,无法通过其他子类对象访问父类的field和mehtod
scala> :paste
// Entering paste mode (ctrl-D to finish)
class Person{
protected var name:String="leo"
protected[this] var hobby:String = "game"
}
class Student extends Person{
def sayHello = println("Hello,"+name)
def makeFriends(s:Student){
println("my hobby is "+hobby + ",your hobby is " +s.hobby)
}
}
// Exiting paste mode, now interpreting.
<pastie>:20: error: value hobby is not a member of Student
println("my hobby is "+hobby + ",your hobby is " +s.hobby)
调用父类的constructor
- 每个类可以有一个主constructor和任意多个辅助constructor,而每个辅助constructor的第一行都必须是调用其他辅助constructor或者是主constructor;因此子类的辅助constructor是一定不可能直接调用父类的constructor的
- 只能在子类的主constrctor中调用父类的constructor
scala> :paste
// Entering paste mode (ctrl-D to finish)
class Person(val name:String,val age:Int)
class Student(name:String,age:Int,var score:Double) extends Person(name,age){
def this(name:String){
this(name,0,0)
}
def this(age:Int){
this("leo",age,0)
}
}
// Exiting paste mode, now interpreting.
defined class Person
defined class Student
匿名内部类
- 在scala中匿名子类非常常见,相当于java匿名内部类
- 定义一个类没有名称的子类,并直接创建其对象,然后将对象的引用赋予一个变量,之后甚至可以将该匿名子类的对象传递给其他函数
scala> :paste
// Entering paste mode (ctrl-D to finish)
class Person(protected val name:String){
def sayHello = "Hello,I'm " + name
}
val p = new Person("leo"){
override def sayHello = "Hi,I'm "+name
}
def greeting(p:Person{def sayHello:String}){
println(p.sayHello)
}
// Exiting paste mode, now interpreting.
defined class Person
p: Person = $anon$1@628b9af5
greeting: (p: Person{def sayHello: String})Unit
scala> p.sayHello
res5: String = Hi,I'm leo
scala> greeting(p)
Hi,I'm leo
抽象类
- 和java同样的原理
scala> :paste
// Entering paste mode (ctrl-D to finish)
abstract class Person(val name:String){
def sayHello:Unit
}
class Student(name:String) extends Person(name){
def sayHello:Unit = println("Hello, "+name) //可以省略override
}
// Exiting paste mode, now interpreting.
defined class Person
defined class Student
scala> val s = new Student("jike")
s: Student = Student@49bcd90d
scala> s.sayHello
Hello, jike
抽象field
- 如果在父类中,定义了field,但是没有给出初始值,则此field为抽象field
- 抽象filed意味着,scala会根据自己的规则,为var或val类型的field生成对应的getter和setter方法,但是父类中没有该field的
- 子类必须覆盖field,以定义自己的具体field,并且覆盖抽象field,不需要使用override关键字
abstract class Person{
val name :String
}
class Student extends Person{
val name :String = "leo"
}
scala> val s = new Student
s: Student = Student@48c2391
scala> s.name
res9: String = leo