简述: 今天带来的是Kotlin浅谈系列第七弹,上篇博客我们聊到关于Kotlin中的lambda表达式的一些语法规则和基本使用。然而我们并没有聊到Kotlin的lambda表达式的本质是什么?我们都知道使用Kotlin来开发Android,最终都会编译成字节码文件.class,然后字节码文件run到JVM上,最后整个应用跑起来。
- 1、为什么需要去对lambda表达式字节码分析?(why)
- 2、lambda表达式实质原理是什么?(what)
- 3、lambda表达式字节码查看工具的使用
- 4、kotlin中@Metadata注解详解
- 5、如何去分析lambda表达式字节码(how)
- 6、使用lambda表达式时的性能优化
- 7、使用lambda表达式需要注意哪些问题
一、为什么需要去对lambda表达式字节码分析?
Kotlin中的lambda表达式给使用者的感知它就是一个很简洁的语法糖,但是在简洁语法糖背后内容你有所了解吗?学会分析lambda表达式编译成字节码的整个过程,会对高效率地去使用lambda表达式会有很大帮助,否则就会很容出现lambda表达式滥用的情况,这种情况非常影响程序性能。所以需要从真正本质上去完全理解lambda是什么?以及它是如何编译成对应class。
二、lambda表达式实质原理
Kotlin中的lambda表达式实际上最后会编译为一个class类,这个类会去继承Kotlin中Lambda的抽象类(在kotlin.jvm.internal包中)并且实现一个FunctionN(在kotlin.jvm.functions包中)的接口(这个N是根据lambda表达式传入参数的个数决定的,目前接口N的取值为 0 <= N <= 22,也就是lambda表达式中函数传入的参数最多也只能是22个),这个Lambda抽象类是实现了FunctionBase接口,该接口中有两个方法一个是getArity()获取lambda参数的元数,toString()实际上就是打印出Lambda表达式类型字符串,获取Lambda表达式类型字符串是通过Java中Reflection类反射来实现的。FunctionBase接口继承了Function,Serializable接口。来看一个简单的lambda例子
package com.mikyou.kotlin.lambda.simple
typealias Sum = (Int, Int, Int) -> Int
fun main(args: Array<String>) {
val sum: Sum = { a, b, c ->//定义一个很简单的三个数求和的lambda表达式
a + b + c
}
println(sum.invoke(1, 2, 3))
}
lambda调用处反编译后的代码
package com.mikyou.kotlin.lambda.simple;
import kotlin.Metadata;
import kotlin.jvm.functions.Function3;
import kotlin.jvm.internal.Intrinsics;
import org.jetbrains.annotations.NotNull;
@Metadata(
mv = {1, 1, 10},
bv = {1, 0, 2},
k = 2,
d1 = {"\u0000\u001e\n\u0000\n\u0002\u0010\u0002\n\u0000\n\u0002\u0010\u0011\n\u0002\u0010\u000e\n\u0002\b\u0002\n\u0002\u0018\u0002\n\u0002\u0010\b\n\u0000\u001a\u0019\u0010\u0000\u001a\u00020\u00012\f\u0010\u0002\u001a\b\u0012\u0004\u0012\u00020\u00040\u0003¢\u0006\u0002\u0010\u0005*:\u0010\u0006\"\u001a\u0012\u0004\u0012\u00020\b\u0012\u0004\u0012\u00020\b\u0012\u0004\u0012\u00020\b\u0012\u0004\u0012\u00020\b0\u00072\u001a\u0012\u0004\u0012\u00020\b\u0012\u0004\u0012\u00020\b\u0012\u0004\u0012\u00020\b\u0012\u0004\u0012\u00020\b0\u0007¨\u0006\t"},
d2 = {"main", "", "args", "", "", "([Ljava/lang/String;)V", "Sum", "Lkotlin/Function3;", "", "production sources for module Lambda_main"}
)
public final class SumLambdaKt {
public static final void main(@NotNull String[] args) {
Intrinsics.checkParameterIsNotNull(args, "args");
Function3 sum = (Function3)null.INSTANCE;//实例化的是FunctionN接口中Function3,因为有三个参数
int var2 = ((Number)sum.invoke(1, 2, 3)).intValue();
System.out.println(var2);
}
}
lambda反编译后的代码
package com.mikyou.kotlin.lambda.simple;
import kotlin.jvm.internal.Lambda;
@kotlin.Metadata(mv = {1, 1, 10}, bv = {1, 0, 2}, k = 3, d1 = {"\000\n\n\000\n\002\020\b\n\002\b\004\020\000\032\0020\0012\006\020\002\032\0020\0012\006\020\003\032\0020\0012\006\020\004\032\0020\001H\n¢\006\002\b\005"}, d2 = {"<anonymous>", "", "a", "b", "c", "invoke"})
final class SumLambdaKt$main$sum$1 extends Lambda implements kotlin.jvm.functions.Function3<Integer, Integer, Integer, Integer> {
public final int invoke(int a, int b, int c) {
return a + b + c;
}
public static final SumLambdaKt$main$sum$1 INSTANCE =new SumLambdaKt$main$sum$1();
SumLambdaKt$main$sum$1() {
super(3);//这个super传入3,也就是前面getArity获得参数的元数和函数参数个数一致
}
}
三、lambda表达式字节码查看工具的使用
既然是分析字节码class文件,所以必须得有个字节码查看工具,你可以使用JD-GUI或者其他的,我这里使用的是BytecodeViewer,它核心实现也是基于JD-GUI的。任意选择一款字节码查看工具都可以,这里是BytecodeViewer的下载地址有需要可以去下载,它的使用也是非常简单的。
- 1、下载完毕后,打开主界面(界面有点粗糙,这个可以忽略)
- 2、然后,只需要把相应的.class文件拖入文件选择区,就可以查看相应反编译的Java代码和字节码
四、kotlin中@Metadata注解详解
从刚刚反编译的代码,有个@Metadata注解很是引入注意,它到底是个啥?每个Kotlin代码反编译成Java代码都会有这个@Metadata注解。为了更好地去理解这个字节码生成的过程,我觉得有必要去了解一下,它们每一个的含义。
1、@Metadata注解介绍及生成流程
kotlin中的@Metadata注解是一个很特殊的注解,它记录了Kotlin代码中的一些信息,比如 class 的可见性,function 的返回值,参数类型,property 的 lateinit,nullable 的属性,typealias类型别名声明等。我们都知道Kotlin代码最终都要转化成Java的字节码的,然后运行JVM上。但是Kotlin代码和Java代码差别还是很大的,一些Kotlin特殊语言特性是独有的(比如lateinit, nullable, typealias),所以需要记录一些信息来标识Kotlin中的一些特殊语法信息。最终这些信息都是有kotlinc编译器生成,并以注解的形式存在于字节码文件中。
2、@Metadata注解的状态
通过上面转化图可得知,@Metadata注解会一直保存在class字节码中,也就是这个注解是一个运行时的注解,在RunTime的时候会一直保留,那么可以通过反射可以拿到,并且这个@Metadata注解是Kotlin独有的,也就是Java是不会生成这样的注解存在于.class文件中,也就是从另一方面可以通过反射可以得知这个类是不是Kotlin的class.
3、@Metadata注解源码中每个参数的含义
@Metadata注解源码
package kotlin
/**
* This annotation is present on any class file produced by the Kotlin compiler and is read by the compiler and reflection.
* Parameters have very short names on purpose: these names appear in the generated class files, and we'd like to reduce their size.
*/
@Retention(AnnotationRetention.RUNTIME)
@Target(AnnotationTarget.CLASS)
internal annotation class Metadata(
/**
* A kind of the metadata this annotation encodes. Kotlin compiler recognizes the following kinds (see KotlinClassHeader.Kind):
*
* 1 Class
* 2 File
* 3 Synthetic class
* 4 Multi-file class facade
* 5 Multi-file class part
*
* The class file with a kind not listed here is treated as a non-Kotlin file.
*/
val k: Int = 1,
/**
* The version of the metadata provided in the arguments of this annotation.
*/
val mv: IntArray = intArrayOf(),
/**
* The version of the bytecode interface (naming conventions, signatures) of the class file annotated with this annotation.
*/
val bv: IntArray = intArrayOf(),
/**
* Metadata in a custom format. The format may be different (or even absent) for different kinds.
*/
val d1: Array<String> = arrayOf(),
/**
* An addition to [d1]: array of strings which occur in metadata, written in plain text so that strings already present
* in the constant pool are reused. These strings may be then indexed in the metadata by an integer index in this array.
*/
val d2: Array<String> = arrayOf(),
/**
* An extra string. For a multi-file part class, internal name of the facade class.
*/
val xs: String = "",
/**
* Fully qualified name of the package this class is located in, from Kotlin's point of view, or empty string if this name
* does not differ from the JVM's package FQ name. These names can be different in case the [JvmPackageName] annotation is used.
* Note that this information is also stored in the corresponding module's `.kotlin_module` file.
*/
val pn: String = "",
/**
* An extra int. Bits of this number represent the following flags:
*
* 0 - this is a multi-file class facade or part, compiled with `-Xmultifile-parts-inherit`.
* 1 - this class file is compiled by a pre-release version of Kotlin and is not visible to release versions.
* 2 - this class file is a compiled Kotlin script source file (.kts).
*/
@SinceKotlin("1.1")
val xi: Int = 0
)
注意: @Metadata注解中的k,mv,d1,d2..都是简写,为什么要这样做呢?说白了就是为了class文件的大小,尽可能做到精简。
参数简写名称 | 参数全称 | 参数类型 | 参数取值 | 参数含义 |
---|---|---|---|---|
k | kind | Int | 1: class,表示这个kotlin文件是一个类或者接口 2: file,表示这个kotin文件是一个.kt结尾的文件 3: Synthetic class,表示这个kotlin文件是一个合成类 4(Multi-file class facade) 5(Multi-file class part) |
表示当前metadata注解编码种类 |
mv | metadata version | IntArray | - | metadata版本号 |
bv | bytecode version | IntArray | - | 字节码版本号 |
d1 | data1 | Array<String> | - | 主要记录Kotlin语法信息 |
d2 | data2 | Array<String> | - | 主要记录Kotlin语法信息 |
xs | extra String | String | - | 主要是为多文件的类(Multi-file class)预留的名称 |
xi | extra Int | Int | 0 (表示一个多文件的类Multi-file class facade或者多文件类的部分Multi-file class part编译成-Xmultifile-parts-inherit) 1 (表示此类文件由Kotlin的预发行版本编译,并且对于发行版本不可见) 2 (表示这个类文件是一个编译的Kotlin脚本源文件) |
- |
pn | fully qualified name of package | String | - | 主要记录kotlin类完整的包名 |
4、实例分析@Metadata注解
kotlin源码,定义的是一个.kt结尾文件
package com.mikyou.kotlin.lambda.simple
typealias Sum = (Int, Int, Int) -> Int//typealias关键字声明lambda表达式类型别名
fun main(args: Array<String>) {
val sum: Sum = { a, b, c ->//定义一个很简单的三个数求和的lambda表达式
a + b + c
}
println(sum.invoke(1, 2, 3))
}
反编译后Java代码
package com.mikyou.kotlin.lambda.simple;
import kotlin.Metadata;
import kotlin.jvm.functions.Function3;
import kotlin.jvm.internal.Intrinsics;
import org.jetbrains.annotations.NotNull;
@Metadata(
mv = {1, 1, 10},
bv = {1, 0, 2},
k = 2,
d1 = {"\u0000\u001e\n\u0000\n\u0002\u0010\u0002\n\u0000\n\u0002\u0010\u0011\n\u0002\u0010\u000e\n\u0002\b\u0002\n\u0002\u0018\u0002\n\u0002\u0010\b\n\u0000\u001a\u0019\u0010\u0000\u001a\u00020\u00012\f\u0010\u0002\u001a\b\u0012\u0004\u0012\u00020\u00040\u0003¢\u0006\u0002\u0010\u0005*:\u0010\u0006\"\u001a\u0012\u0004\u0012\u00020\b\u0012\u0004\u0012\u00020\b\u0012\u0004\u0012\u00020\b\u0012\u0004\u0012\u00020\b0\u00072\u001a\u0012\u0004\u0012\u00020\b\u0012\u0004\u0012\u00020\b\u0012\u0004\u0012\u00020\b\u0012\u0004\u0012\u00020\b0\u0007¨\u0006\t"},
d2 = {"main", "", "args", "", "", "([Ljava/lang/String;)V", "Sum", "Lkotlin/Function3;", "", "production sources for module Lambda_main"}
)
public final class SumLambdaKt {
public static final void main(@NotNull String[] args) {
Intrinsics.checkParameterIsNotNull(args, "args");
Function3 sum = (Function3)SumLambdaKt$main$sum$1.INSTANCE;
int var2 = ((Number)sum.invoke(1, 2, 3)).intValue();
System.out.println(var2);
}
}
- k = 2 表示的是这是一个.kt结尾的kotlin文件
- mv = {1,1,10} 表示metadata版本号是1.1.10
- bv = {1,0,2} 表示bytecode版本号是1.0.2
- d1 = {...} 里面的信息是经过了 protobuf 编码的二进制流 具体可见详细描述
- d2 = {"main", "", "args", "", "", "([Ljava/lang/String;)V", "Sum", "Lkotlin/Function3;", "", "production sources for module Lambda_main"}表示记录有main函数,已经main函数参数名称args,Sum就是通过typealias取lambda表达式类型别名,Lkotlin/Function3声明的是Lambda表达式中生成的这个类是实现了FunctionN中Function3接口,因为它对应只有三个参数
kotlin中定义一个类源码
package com.mikyou.kotlin.lambda
/**
* Created by mikyou on 2018/3/27.
*/
data class Person(val name: String, val age: Int)
反编译后Java代码
package com.mikyou.kotlin.lambda;
import kotlin.Metadata;
import kotlin.jvm.internal.Intrinsics;
import org.jetbrains.annotations.NotNull;
@Metadata(
mv = {1, 1, 10},
bv = {1, 0, 2},
k = 1,//kind就是变成了1,表示这是一个kotlin的class类
d1 = {"\u0000 \n\u0002\u0018\u0002\n\u0002\u0010\u0000\n\u0000\n\u0002\u0010\u000e\n\u0000\n\u0002\u0010\b\n\u0002\b\t\n\u0002\u0010\u000b\n\u0002\b\u0004\b\u0086\b\u0018\u00002\u00020\u0001B\u0015\u0012\u0006\u0010\u0002\u001a\u00020\u0003\u0012\u0006\u0010\u0004\u001a\u00020\u0005¢\u0006\u0002\u0010\u0006J\t\u0010\u000b\u001a\u00020\u0003HÆ\u0003J\t\u0010\f\u001a\u00020\u0005HÆ\u0003J\u001d\u0010\r\u001a\u00020\u00002\b\b\u0002\u0010\u0002\u001a\u00020\u00032\b\b\u0002\u0010\u0004\u001a\u00020\u0005HÆ\u0001J\u0013\u0010\u000e\u001a\u00020\u000f2\b\u0010\u0010\u001a\u0004\u0018\u00010\u0001HÖ\u0003J\t\u0010\u0011\u001a\u00020\u0005HÖ\u0001J\t\u0010\u0012\u001a\u00020\u0003HÖ\u0001R\u0011\u0010\u0004\u001a\u00020\u0005¢\u0006\b\n\u0000\u001a\u0004\b\u0007\u0010\bR\u0011\u0010\u0002\u001a\u00020\u0003¢\u0006\b\n\u0000\u001a\u0004\b\t\u0010\n¨\u0006\u0013"},
d2 = {"Lcom/mikyou/kotlin/lambda/Person;", "", "name", "", "age", "", "(Ljava/lang/String;I)V", "getAge", "()I", "getName", "()Ljava/lang/String;", "component1", "component2", "copy", "equals", "", "other", "hashCode", "toString", "production sources for module Lambda_main"}
)
public final class Person {
@NotNull
private final String name;
private final int age;
@NotNull
public final String getName() {
return this.name;
}
public final int getAge() {
return this.age;
}
public Person(@NotNull String name, int age) {
Intrinsics.checkParameterIsNotNull(name, "name");
super();
this.name = name;
this.age = age;
}
@NotNull
public final String component1() {
return this.name;
}
public final int component2() {
return this.age;
}
@NotNull
public final Person copy(@NotNull String name, int age) {
Intrinsics.checkParameterIsNotNull(name, "name");
return new Person(name, age);
}
// $FF: synthetic method
@NotNull
public static Person copy$default(Person var0, String var1, int var2, int var3, Object var4) {
if ((var3 & 1) != 0) {
var1 = var0.name;
}
if ((var3 & 2) != 0) {
var2 = var0.age;
}
return var0.copy(var1, var2);
}
public String toString() {
return "Person(name=" + this.name + ", age=" + this.age + ")";
}
public int hashCode() {
return (this.name != null ? this.name.hashCode() : 0) * 31 + this.age;
}
public boolean equals(Object var1) {
if (this != var1) {
if (var1 instanceof Person) {
Person var2 = (Person)var1;
if (Intrinsics.areEqual(this.name, var2.name) && this.age == var2.age) {
return true;
}
}
return false;
} else {
return true;
}
}
}
5、@Metadata注解需要注意的问题
我们知道了@Metadata注解是会一直保留至运行时,而且在配置混淆一定需要注意,@Metadata注解保存的信息是会被proguard给干掉的,所以不能让proguard干掉,否则一些重要的信息就会丢失,那么这个.class文件就是无效的,run在JVM上是会抛异常的。
五、如何去分析lambda表达式字节码
- 1、从Kotlin源码出发定义了一个三个数求和lambda表达式最后通过invoke()方法传入三个参数完成lambda表达式的调用。
package com.mikyou.kotlin.lambda.simple
typealias Sum = (Int, Int, Int) -> Int //给类型取个别名
fun main(args: Array<String>) {
val sum: Sum = { a, b, c ->//定义一个很简单的三个数求和的lambda表达式
a + b + c
}
println(sum.invoke(1, 2, 3))//invoke方法实现lambda表达式的调用
}
- 2、然后再重点介绍几个类和接口。
Lambda抽象类:
/*
* Copyright 2010-2015 JetBrains s.r.o.
*
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
package kotlin.jvm.internal
public abstract class Lambda(private val arity: Int) : FunctionBase {
override fun getArity() = arity//实现FunctionBase接口中的抽象方法getArity(),并通过构造器把元数传给它
override fun toString() = Reflection.renderLambdaToString(this)//toString()方法重写
}
FunctionBase接口,继承了Function<R>接口和Serializable序列化接口(这是一个Java接口):
/*
* Copyright 2010-2016 JetBrains s.r.o.
*
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
package kotlin.jvm.internal;
import kotlin.Function;
import java.io.Serializable;
public interface FunctionBase extends Function, Serializable {
int getArity();//抽象方法getArity
}
FunctionN系列的接口( 0 <= N <= 22)也继承了Function<R>接口,也就是目前支持的lambda表达式类型接收参数的个数不能超过22个,是不是突然感觉kotlin居然还有这种操作。并且每个接口中都有一个invoke抽象方法,用于外部调用lambda表达式。
/*
* Copyright 2010-2018 JetBrains s.r.o.
*
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
// Auto-generated file. DO NOT EDIT!
package kotlin.jvm.functions
/** A function that takes 0 arguments. */
public interface Function0<out R> : Function<R> {
/** Invokes the function. */
public operator fun invoke(): R
}
/** A function that takes 1 argument. */
public interface Function1<in P1, out R> : Function<R> {
/** Invokes the function with the specified argument. */
public operator fun invoke(p1: P1): R
}
/** A function that takes 2 arguments. */
public interface Function2<in P1, in P2, out R> : Function<R> {
/** Invokes the function with the specified arguments. */
public operator fun invoke(p1: P1, p2: P2): R
}
/** A function that takes 3 arguments. */
public interface Function3<in P1, in P2, in P3, out R> : Function<R> {
/** Invokes the function with the specified arguments. */
public operator fun invoke(p1: P1, p2: P2, p3: P3): R
}
/** A function that takes 4 arguments. */
public interface Function4<in P1, in P2, in P3, in P4, out R> : Function<R> {
/** Invokes the function with the specified arguments. */
public operator fun invoke(p1: P1, p2: P2, p3: P3, p4: P4): R
}
/** A function that takes 5 arguments. */
public interface Function5<in P1, in P2, in P3, in P4, in P5, out R> : Function<R> {
/** Invokes the function with the specified arguments. */
public operator fun invoke(p1: P1, p2: P2, p3: P3, p4: P4, p5: P5): R
}
/** A function that takes 6 arguments. */
public interface Function6<in P1, in P2, in P3, in P4, in P5, in P6, out R> : Function<R> {
/** Invokes the function with the specified arguments. */
public operator fun invoke(p1: P1, p2: P2, p3: P3, p4: P4, p5: P5, p6: P6): R
}
/** A function that takes 7 arguments. */
public interface Function7<in P1, in P2, in P3, in P4, in P5, in P6, in P7, out R> : Function<R> {
/** Invokes the function with the specified arguments. */
public operator fun invoke(p1: P1, p2: P2, p3: P3, p4: P4, p5: P5, p6: P6, p7: P7): R
}
/** A function that takes 8 arguments. */
public interface Function8<in P1, in P2, in P3, in P4, in P5, in P6, in P7, in P8, out R> : Function<R> {
/** Invokes the function with the specified arguments. */
public operator fun invoke(p1: P1, p2: P2, p3: P3, p4: P4, p5: P5, p6: P6, p7: P7, p8: P8): R
}
/** A function that takes 9 arguments. */
public interface Function9<in P1, in P2, in P3, in P4, in P5, in P6, in P7, in P8, in P9, out R> : Function<R> {
/** Invokes the function with the specified arguments. */
public operator fun invoke(p1: P1, p2: P2, p3: P3, p4: P4, p5: P5, p6: P6, p7: P7, p8: P8, p9: P9): R
}
/** A function that takes 10 arguments. */
public interface Function10<in P1, in P2, in P3, in P4, in P5, in P6, in P7, in P8, in P9, in P10, out R> : Function<R> {
/** Invokes the function with the specified arguments. */
public operator fun invoke(p1: P1, p2: P2, p3: P3, p4: P4, p5: P5, p6: P6, p7: P7, p8: P8, p9: P9, p10: P10): R
}
/** A function that takes 11 arguments. */
public interface Function11<in P1, in P2, in P3, in P4, in P5, in P6, in P7, in P8, in P9, in P10, in P11, out R> : Function<R> {
/** Invokes the function with the specified arguments. */
public operator fun invoke(p1: P1, p2: P2, p3: P3, p4: P4, p5: P5, p6: P6, p7: P7, p8: P8, p9: P9, p10: P10, p11: P11): R
}
/** A function that takes 12 arguments. */
public interface Function12<in P1, in P2, in P3, in P4, in P5, in P6, in P7, in P8, in P9, in P10, in P11, in P12, out R> : Function<R> {
/** Invokes the function with the specified arguments. */
public operator fun invoke(p1: P1, p2: P2, p3: P3, p4: P4, p5: P5, p6: P6, p7: P7, p8: P8, p9: P9, p10: P10, p11: P11, p12: P12): R
}
/** A function that takes 13 arguments. */
public interface Function13<in P1, in P2, in P3, in P4, in P5, in P6, in P7, in P8, in P9, in P10, in P11, in P12, in P13, out R> : Function<R> {
/** Invokes the function with the specified arguments. */
public operator fun invoke(p1: P1, p2: P2, p3: P3, p4: P4, p5: P5, p6: P6, p7: P7, p8: P8, p9: P9, p10: P10, p11: P11, p12: P12, p13: P13): R
}
/** A function that takes 14 arguments. */
public interface Function14<in P1, in P2, in P3, in P4, in P5, in P6, in P7, in P8, in P9, in P10, in P11, in P12, in P13, in P14, out R> : Function<R> {
/** Invokes the function with the specified arguments. */
public operator fun invoke(p1: P1, p2: P2, p3: P3, p4: P4, p5: P5, p6: P6, p7: P7, p8: P8, p9: P9, p10: P10, p11: P11, p12: P12, p13: P13, p14: P14): R
}
/** A function that takes 15 arguments. */
public interface Function15<in P1, in P2, in P3, in P4, in P5, in P6, in P7, in P8, in P9, in P10, in P11, in P12, in P13, in P14, in P15, out R> : Function<R> {
/** Invokes the function with the specified arguments. */
public operator fun invoke(p1: P1, p2: P2, p3: P3, p4: P4, p5: P5, p6: P6, p7: P7, p8: P8, p9: P9, p10: P10, p11: P11, p12: P12, p13: P13, p14: P14, p15: P15): R
}
/** A function that takes 16 arguments. */
public interface Function16<in P1, in P2, in P3, in P4, in P5, in P6, in P7, in P8, in P9, in P10, in P11, in P12, in P13, in P14, in P15, in P16, out R> : Function<R> {
/** Invokes the function with the specified arguments. */
public operator fun invoke(p1: P1, p2: P2, p3: P3, p4: P4, p5: P5, p6: P6, p7: P7, p8: P8, p9: P9, p10: P10, p11: P11, p12: P12, p13: P13, p14: P14, p15: P15, p16: P16): R
}
/** A function that takes 17 arguments. */
public interface Function17<in P1, in P2, in P3, in P4, in P5, in P6, in P7, in P8, in P9, in P10, in P11, in P12, in P13, in P14, in P15, in P16, in P17, out R> : Function<R> {
/** Invokes the function with the specified arguments. */
public operator fun invoke(p1: P1, p2: P2, p3: P3, p4: P4, p5: P5, p6: P6, p7: P7, p8: P8, p9: P9, p10: P10, p11: P11, p12: P12, p13: P13, p14: P14, p15: P15, p16: P16, p17: P17): R
}
/** A function that takes 18 arguments. */
public interface Function18<in P1, in P2, in P3, in P4, in P5, in P6, in P7, in P8, in P9, in P10, in P11, in P12, in P13, in P14, in P15, in P16, in P17, in P18, out R> : Function<R> {
/** Invokes the function with the specified arguments. */
public operator fun invoke(p1: P1, p2: P2, p3: P3, p4: P4, p5: P5, p6: P6, p7: P7, p8: P8, p9: P9, p10: P10, p11: P11, p12: P12, p13: P13, p14: P14, p15: P15, p16: P16, p17: P17, p18: P18): R
}
/** A function that takes 19 arguments. */
public interface Function19<in P1, in P2, in P3, in P4, in P5, in P6, in P7, in P8, in P9, in P10, in P11, in P12, in P13, in P14, in P15, in P16, in P17, in P18, in P19, out R> : Function<R> {
/** Invokes the function with the specified arguments. */
public operator fun invoke(p1: P1, p2: P2, p3: P3, p4: P4, p5: P5, p6: P6, p7: P7, p8: P8, p9: P9, p10: P10, p11: P11, p12: P12, p13: P13, p14: P14, p15: P15, p16: P16, p17: P17, p18: P18, p19: P19): R
}
/** A function that takes 20 arguments. */
public interface Function20<in P1, in P2, in P3, in P4, in P5, in P6, in P7, in P8, in P9, in P10, in P11, in P12, in P13, in P14, in P15, in P16, in P17, in P18, in P19, in P20, out R> : Function<R> {
/** Invokes the function with the specified arguments. */
public operator fun invoke(p1: P1, p2: P2, p3: P3, p4: P4, p5: P5, p6: P6, p7: P7, p8: P8, p9: P9, p10: P10, p11: P11, p12: P12, p13: P13, p14: P14, p15: P15, p16: P16, p17: P17, p18: P18, p19: P19, p20: P20): R
}
/** A function that takes 21 arguments. */
public interface Function21<in P1, in P2, in P3, in P4, in P5, in P6, in P7, in P8, in P9, in P10, in P11, in P12, in P13, in P14, in P15, in P16, in P17, in P18, in P19, in P20, in P21, out R> : Function<R> {
/** Invokes the function with the specified arguments. */
public operator fun invoke(p1: P1, p2: P2, p3: P3, p4: P4, p5: P5, p6: P6, p7: P7, p8: P8, p9: P9, p10: P10, p11: P11, p12: P12, p13: P13, p14: P14, p15: P15, p16: P16, p17: P17, p18: P18, p19: P19, p20: P20, p21: P21): R
}
/** A function that takes 22 arguments. */
public interface Function22<in P1, in P2, in P3, in P4, in P5, in P6, in P7, in P8, in P9, in P10, in P11, in P12, in P13, in P14, in P15, in P16, in P17, in P18, in P19, in P20, in P21, in P22, out R> : Function<R> {
/** Invokes the function with the specified arguments. */
public operator fun invoke(p1: P1, p2: P2, p3: P3, p4: P4, p5: P5, p6: P6, p7: P7, p8: P8, p9: P9, p10: P10, p11: P11, p12: P12, p13: P13, p14: P14, p15: P15, p16: P16, p17: P17, p18: P18, p19: P19, p20: P20, p21: P21, p22: P22): R
}
Function<R>接口,我们都知道在kotlin中是可以把函数当做值来看待的,那么这个函数值也是有类型的,也就是函数类型,这个Function就是lambda、匿名函数、普通命名函数的函数引用类型。
/*
* Copyright 2010-2015 JetBrains s.r.o.
*
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
package kotlin
/**
* Represents a value of a functional type, such as a lambda, an anonymous function or a function reference.
*
* @param R return type of the function.
*/
public interface Function<out R>
lambda编译后生成的class,通过生成字节码中的类可以看出,
生成唯一的类名是这个lambda表达式声明处于哪个顶层文件(它生成规则之前博客有提到),哪个方法中,以及最终lambda表达式的名字组成, SumLambdaKt$main$sum$1, SumLambdaKt顶层文件名,在main函数声明的,lambda表达式名为sum,由于Kotlin中的lambda只有三个参数,那么这个Lambda类的arity元数也就是3,可以看到生成的类中构造器super(3)。然后就去实现了对应FunctionN接口也就是N=3,实现了Function3接口,重写了invoke方法。
package com.mikyou.kotlin.lambda.simple;
import kotlin.jvm.internal.Lambda;
@kotlin.Metadata(mv = {1, 1, 10}, bv = {1, 0, 2}, k = 3, d1 = {"\000\n\n\000\n\002\020\b\n\002\b\004\020\000\032\0020\0012\006\020\002\032\0020\0012\006\020\003\032\0020\0012\006\020\004\032\0020\001H\n¢\006\002\b\005"}, d2 = {"<anonymous>", "", "a", "b", "c", "invoke"})
final class SumLambdaKt$main$sum$1 extends Lambda implements kotlin.jvm.functions.Function3<Integer, Integer, Integer, Integer> {
public final int invoke(int a, int b, int c) {
return a + b + c;
}
public static final SumLambdaKt$main$sum$1 INSTANCE =new SumLambdaKt$main$sum$1();//静态SumLambdaKt$main$sum$1的实例INSTANCE供外部调用
SumLambdaKt$main$sum$1() {
super(3);//这个super传入3,也就是前面getArity获得参数的元数和函数参数个数一致
}
}
为了清晰表达类与类之间关系请看下面这张类图
调用处反编译的Java代码
package com.mikyou.kotlin.lambda.simple;
import kotlin.Metadata;
import kotlin.jvm.functions.Function3;
import kotlin.jvm.internal.Intrinsics;
import org.jetbrains.annotations.NotNull;
@Metadata(
mv = {1, 1, 10},
bv = {1, 0, 2},
k = 2,
d1 = {"\u0000\u001e\n\u0000\n\u0002\u0010\u0002\n\u0000\n\u0002\u0010\u0011\n\u0002\u0010\u000e\n\u0002\b\u0002\n\u0002\u0018\u0002\n\u0002\u0010\b\n\u0000\u001a\u0019\u0010\u0000\u001a\u00020\u00012\f\u0010\u0002\u001a\b\u0012\u0004\u0012\u00020\u00040\u0003¢\u0006\u0002\u0010\u0005*:\u0010\u0006\"\u001a\u0012\u0004\u0012\u00020\b\u0012\u0004\u0012\u00020\b\u0012\u0004\u0012\u00020\b\u0012\u0004\u0012\u00020\b0\u00072\u001a\u0012\u0004\u0012\u00020\b\u0012\u0004\u0012\u00020\b\u0012\u0004\u0012\u00020\b\u0012\u0004\u0012\u00020\b0\u0007¨\u0006\t"},
d2 = {"main", "", "args", "", "", "([Ljava/lang/String;)V", "Sum", "Lkotlin/Function3;", "", "production sources for module Lambda_main"}
)
public final class SumLambdaKt {
public static final void main(@NotNull String[] args) {
Intrinsics.checkParameterIsNotNull(args, "args");
Function3 sum = (Function3)SumLambdaKt$main$sum$1.INSTANCE;//调用静态SumLambdaKt$main$sum$1的实例INSTANCE,强转成Function3类型。
int var2 = ((Number)sum.invoke(1, 2, 3)).intValue();//然后用这个sum对象实例去调用Function3中三个参数的invoke方法
System.out.println(var2);
}
}
最后我们再梳理一下整个编译的流程:
首先,定义好的Kotlin Lambda表达式,通过Lambda表达式的类型,可以得到参数的个数以及参数的类型,也就是向Lambda抽象类的构造器传递arity元数,Lambda抽象类又把arity传递给FunctionBase,在编译时期会根据这个arity元数动态确定需要实现FunctionN接口,然后通过实现了相应的FunctionN接口中的invoke方法,最后lambda表达式函数体内代码逻辑将会在invoke方法体内。整个编译的流程完毕,也就在本地目录会生成一个.class字节码文件。从调用处反编译的代码就会直接调用.class字节码中已经生成的类中的INSTANCE静态实例对象,最后通过这个实例去调用invoke方法。
六、使用lambda表达式时的性能优化
我们都知道lambda表达式可以作为一个参数传入到另一个函数中,这个也称为高阶函数。在使用高阶函数的时候我们需要注意尽量把我们的高阶函数声明成inline内联函数,因为通过上面的字节码分析的编译过程知道lambda最终会被编译成一个FunctionN类,然后调用的地方是使用这个FunctionN的实例去调用相应invoke方法。如果声明成内联函数的话,那么将不会去生成这个类并且在函数调用处是不需要实例化这个FunctionN的实例,而是在调用的时把调用的方法给替换上去,可以降低很大的性能开销。一起来看个例子
没有设置inline函数的case:
package com.mikyou.kotlin.lambda.high
typealias SumAlias = (Int, Int) -> Int
fun printSum(a: Int, b: Int, block: SumAlias) {//没有设置inline关键字
println(block.invoke(a, b))
}
fun main(args: Array<String>) {
printSum(4, 5) { a, b ->
a + b
}
}
编译生成.clas文件目录,一个是调用处生成的字节码,另一处则是声明Lambda表达式字节码:
函数调用处生成的字节码
package com.mikyou.kotlin.lambda.high;
import kotlin.Metadata;
import kotlin.jvm.functions.Function2;
import kotlin.jvm.internal.Intrinsics;
import org.jetbrains.annotations.NotNull;
@Metadata(
mv = {1, 1, 10},
bv = {1, 0, 2},
k = 2,
d1 = {"\u0000(\n\u0000\n\u0002\u0010\u0002\n\u0000\n\u0002\u0010\u0011\n\u0002\u0010\u000e\n\u0002\b\u0003\n\u0002\u0010\b\n\u0002\b\u0002\n\u0002\u0018\u0002\n\u0002\u0018\u0002\n\u0002\b\u0002\u001a\u0019\u0010\u0000\u001a\u00020\u00012\f\u0010\u0002\u001a\b\u0012\u0004\u0012\u00020\u00040\u0003¢\u0006\u0002\u0010\u0005\u001a4\u0010\u0006\u001a\u00020\u00012\u0006\u0010\u0007\u001a\u00020\b2\u0006\u0010\t\u001a\u00020\b2\u001c\u0010\n\u001a\u0018\u0012\u0004\u0012\u00020\b\u0012\u0004\u0012\u00020\b\u0012\u0004\u0012\u00020\b0\u000bj\u0002`\f*.\u0010\r\"\u0014\u0012\u0004\u0012\u00020\b\u0012\u0004\u0012\u00020\b\u0012\u0004\u0012\u00020\b0\u000b2\u0014\u0012\u0004\u0012\u00020\b\u0012\u0004\u0012\u00020\b\u0012\u0004\u0012\u00020\b0\u000b¨\u0006\u000e"},
d2 = {"main", "", "args", "", "", "([Ljava/lang/String;)V", "printSum", "a", "", "b", "block", "Lkotlin/Function2;", "Lcom/mikyou/kotlin/lambda/high/SumAlias;", "SumAlias", "production sources for module Lambda_main"}
)
public final class SumHighFuntionKt {
public static final void printSum(int a, int b, @NotNull Function2 block) {
Intrinsics.checkParameterIsNotNull(block, "block");
int var3 = ((Number)block.invoke(a, b)).intValue();
System.out.println(var3);
}
public static final void main(@NotNull String[] args) {
Intrinsics.checkParameterIsNotNull(args, "args");
printSum(4, 5, (Function2)null.INSTANCE);//传入了Function2类型INSTANCE实例到printSum函数中
}
}
lambda声明处反编译的代码
package com.mikyou.kotlin.lambda.high;
import kotlin.jvm.internal.Lambda;
@kotlin.Metadata(mv = {1, 1, 10}, bv = {1, 0, 2}, k = 3, d1 = {"\000\n\n\000\n\002\020\b\n\002\b\003\020\000\032\0020\0012\006\020\002\032\0020\0012\006\020\003\032\0020\001H\n¢\006\002\b\004"}, d2 = {"<anonymous>", "", "a", "b", "invoke"})
final class SumHighFuntionKt$main$1 extends Lambda implements kotlin.jvm.functions.Function2<Integer, Integer, Integer> {
public static final 1INSTANCE =new 1();
public final int invoke(int a, int b) {
return a + b;
}
SumHighFuntionKt$main$1() {
super(2);
}
}
设置inline函数的case:
package com.mikyou.kotlin.lambda.high
typealias SumAlias = (Int, Int) -> Int
inline fun printSum(a: Int, b: Int, block: SumAlias) {//设置inline,printSum为内联函数
println(block.invoke(a, b))
}
fun main(args: Array<String>) {
printSum(4, 5) { a, b ->
a + b
}
}
编译生成.clas文件目录,只有一个调用处生成的字节码:
函数调用处生成的字节码
package com.mikyou.kotlin.lambda.high;
import kotlin.Metadata;
import kotlin.jvm.functions.Function2;
import kotlin.jvm.internal.Intrinsics;
import org.jetbrains.annotations.NotNull;
@Metadata(
mv = {1, 1, 10},
bv = {1, 0, 2},
k = 2,
d1 = {"\u0000(\n\u0000\n\u0002\u0010\u0002\n\u0000\n\u0002\u0010\u0011\n\u0002\u0010\u000e\n\u0002\b\u0003\n\u0002\u0010\b\n\u0002\b\u0002\n\u0002\u0018\u0002\n\u0002\u0018\u0002\n\u0002\b\u0002\u001a\u0019\u0010\u0000\u001a\u00020\u00012\f\u0010\u0002\u001a\b\u0012\u0004\u0012\u00020\u00040\u0003¢\u0006\u0002\u0010\u0005\u001a7\u0010\u0006\u001a\u00020\u00012\u0006\u0010\u0007\u001a\u00020\b2\u0006\u0010\t\u001a\u00020\b2\u001c\u0010\n\u001a\u0018\u0012\u0004\u0012\u00020\b\u0012\u0004\u0012\u00020\b\u0012\u0004\u0012\u00020\b0\u000bj\u0002`\fH\u0086\b*.\u0010\r\"\u0014\u0012\u0004\u0012\u00020\b\u0012\u0004\u0012\u00020\b\u0012\u0004\u0012\u00020\b0\u000b2\u0014\u0012\u0004\u0012\u00020\b\u0012\u0004\u0012\u00020\b\u0012\u0004\u0012\u00020\b0\u000b¨\u0006\u000e"},
d2 = {"main", "", "args", "", "", "([Ljava/lang/String;)V", "printSum", "a", "", "b", "block", "Lkotlin/Function2;", "Lcom/mikyou/kotlin/lambda/high/SumAlias;", "SumAlias", "production sources for module Lambda_main"}
)
public final class SumHighFuntionKt {
public static final void printSum(int a, int b, @NotNull Function2 block) {
Intrinsics.checkParameterIsNotNull(block, "block");
int var4 = ((Number)block.invoke(a, b)).intValue();
System.out.println(var4);
}
public static final void main(@NotNull String[] args) {
Intrinsics.checkParameterIsNotNull(args, "args");
//下面调用地方直接是把传入block替换到该调用处执行,根本就不需要了Function2实例对象,这样会降低类创建和生成的开销。
byte a$iv = 4;
int b$iv = 5;
int var4 = a$iv + b$iv;
System.out.println(var4);
}
}
七、使用lambda表达式需要注意哪些问题
- 1、在使用proguard的时候需要注意不要将@Metadata注解中信息给混淆了,否则会有异常抛出。
- 2、在使用高阶函数时,尽量去使用inline函数,降低类生成和类的实例创建的开销。关于内联函数,我们会在接下来博客一一详细介绍。
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