java中通用的方法和准则
1.不要让常量和变量中出现易混淆的字母
比如: long i = 1l;
别人很难一下子看清楚是11还是1l,所以应该这样写1L。
命名规范:
1.包名全部小写
2.类名首字母大写
3.方法名称,首字母小写,后面单词首字母大写
4.常量要用大写,并且用下划线隔开
5.变量要用小写
2.莫让常量蜕变成变量
interface Const {
public static final int RANDOM_NUM = new Random().nextInt(10);
}
for (int j = 0; j < 5; j++) {
Log.i("clp", "num =" + Const.RANDOM_NUM);
}上面的代码,每次运行值都会不一样。
RE:只有在值固定的时候,才考虑用final。否则轻易不要用。 static有时候在临时保存数据的时候会用到。
3.三元操作符的类型务必一致
int i = 80;
String s1 = String.valueOf(i < 100 ? 90 : 100);
String s2 = String.valueOf(i < 100 ? 90 : 100.0);
Log.i("clp", "s1=" + s1);
Log.i("clp", "s2=" + s2);
I/clp: s1=90
I/clp: s2=90.0 规则:
1.如果2个类型不能相互转换,就返回Object类型
2.如果是明确类型的表达式(比如变量),则int类型转为long,long类型转为float
…还有其他规则
4.避免带有边长参数的方法重载
public int getCount(int type, int i, int j) {
return i + j;
}
public int getCount(int type, int... value) {
int count = 0;
for (int i : value) {
count *= i;
}
return count;
}
Log.i("clp", "count=" + getCount(1, 3, 4)); 上面的代码,很容易搞混,可能不分析具体原因,不知道会调用那个。
RE:其实会调用int参数的那个,因为编译器从最简单的开始。
I/clp: count=7
5.不要让null或者空值影响到边长方法
public void methodA(String name, Integer... value) {
}
public void methodA(String name, String... value) {
}
methodA("a", 1, 2);
methodA("b", "e", "e");
methodA("c");//编译器报错
methodA("c", null);//编译器报错 上面解决的办法是传入空的String。
RE:我感觉最好的办法是,避免这种写法,遇到这种情况,不要去重载。
基本类型
27.谨慎包装类型的大小比较
Integer i = new Integer(2);
Integer j = new Integer(2);
//比较封装对象的大小,只能使用i.compareTo(j)。
//i==j,i>j,j<j都返回false。 i==j是返回对象的引用地址。i>j,j<j是值的比较。28.优先使用整形池
int input = 127;//128 555
Integer ii = new Integer(input);
Integer jj = new Integer(input);
Log.i("clp", "new 产生的对象:" + (ii == jj));//都为false
ii = input;
jj = input;
Log.i("clp", "基本类型产生的对象" + (ii == jj));//127为true,128 555为false
ii = Integer.valueOf(input);
jj = Integer.valueOf(input);
Log.i("clp", "valueOf 产生的对象" + (ii == jj));//127为true,128 555为false 1.new产生的对象比较,肯定为false
2.自动装箱和Integer.valueOf一样(装箱时通过valueOf实现)
3.valueOf的实现方式,在-128和127之间,使用的是缓冲。超过的话,直接new
public static Integer valueOf(int i) {
final int offset = 128;
if (i > -128 && i < 127) {
return IntegerCache.cache[i + offset];
}
return new Integer(i);
}- 7
29.优先使用基本类型
int i = 14;
f(i);
f(Integer.valueOf(i));
public static void f(long i) {
Log.i("clp", "基本类型的方法被调用");
}
public static void f(Long i) {
Log.i("clp", "包装的方法被调用");
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输出结果:
Log.i(“clp”, “基本类型的方法被调用”);
Log.i(“clp”, “基本类型的方法被调用”);
解析:1.自动装箱只有在赋值时才有关系,重载可以编译通过
2.f(i)不会报错,因为编辑器会自动把i加宽,变为long
3.f(Integer.valueOf(i))不会报错:基本类型,可以先加宽在包装。但是不能直接包装。所以1.先转变为Integer对象,然后调用方法的时候发现没有,自动转换为int基本类型 3.发现没有,自动加宽变为long
4.如果把f(long i)方法给注释掉,代码是编译不通过的
30.不要随便设置随机种子
Random random = new Random(1000);
for (int i = 0; i < 4; i++) {
CldLog.i("clp", "第" + i + "次的随机数为:" + random.nextInt());
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RE:按照上面的代码写,每次运行都会得到想通的随机数。通过Random random = new Random(),则不能固定范围
04-15 11:35:44.565 15244-15244/cld.navi.mainframe I/clp: 第0次的随机数为:-1244746321 @initControls:CldModeA.Java(72)
04-15 11:35:44.565 15244-15244/cld.navi.mainframe I/clp: 第1次的随机数为:1060493871 @initControls:CldModeA.java(72)
04-15 11:35:44.565 15244-15244/cld.navi.mainframe I/clp: 第2次的随机数为:-1826063944 @initControls:CldModeA.java(72)
04-15 11:35:44.565 15244-15244/cld.navi.mainframe I/clp: 第3次的随机数为:1976922248 @initControls:CldModeA.java(72)
正确写法如下:
Random random = new Random();
for (int i = 0; i < 4; i++) {
CldLog.i("clp", "第" + i + "次的随机数为:" + random.nextInt(20));
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类、对象及方法
31.接口中不要存在实现代码
RE:这个都知道
32.静态变量一定要先声明后赋值
static {
i = 100;
}
public static int i = 1;
//输出结果,i等于1
public static int i = 1;
static {
i = 100;
}
//输出结果,i等于100- 1
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1.静态变量是类加载的时候分配到存储区的
2.静态变量在类初始化的时候首先被加载,分配地址空间,还没赋值
3.按照静态类和静态块的先后顺序赋值,所以谁的位置在后面,谁有最终的决定权
33.不要复写静态方法
public class Base {
public static void doBaseStatic() {
Log.i("clp", "doBaseStatic");
}
public void doBase() {
Log.i("clp", "doBase No Static");
}
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public class Sub extends Base {
public static void doBaseStatic() {
Log.i("clp", "do Sub Static");
}
public void doBase() {
Log.i("clp", "do Sub No Static");
}
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Base mBase = new Sub();
mBase.doBase();//do Sub No Static
Base.doBaseStatic();//doBaseStatic
mBase.doBaseStatic();//doBaseStatic
//Android Studio用上面的写法会提示
Sub.doBaseStatic();//do Sub Static- 1
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1.mBase.doBaseStatic()实际上调用的是父类的方法。因为静态方法不依赖实例对象,是通过类名访问的
34.构造函数尽量简化
public abstract class Server {
public static int DEFAULT_PORT = 4000;
public Server() {
Log.i("clp", "Server");
int port = getPort();
Log.i("clp", "port=" + port);
// Log.i();
}
protected abstract int getPort();
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public class ServerIml extends Server {
public int port = 100;
public ServerIml(int port) {
Log.i("clp", "ServerIml");
this.port = port;
}
@Override
protected int getPort() {
// return port;//值为0
return DEFAULT_PORT;//返回值4000
}
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ServerIml serverIml = new ServerIml(80);- 1
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这个跟构造方法的执行顺序有关。
04-15 14:35:54.027 7381-7381/com.example.demo I/clp: Server
04-15 14:35:54.027 7381-7381/com.example.demo I/clp: port=4000
04-15 14:35:54.027 7381-7381/com.example.demo I/clp: ServerIml
执行顺序如下:
1.子类的构造函数接收int类型的参数(没有赋值)
2.父类初始化常量,也就是DEFAULT_PORT,并赋值为4000
3.执行父类无参的构造方法
4.调用int port = getPort();获取端口号 ,调用子类端口号的实现方法。此时DEFAULT_PORT已经有值,但是port子类的
构造函数还没有执行,所以没有赋值,返回0
5.父类初始化完毕,开始初始化子类
6.子类被赋值为100
7.执行子类的构造函数,重新赋值为80
35.避免在构造函数中初始化其他类
public class Son extends Father {
public void doSomeThing() {
Log.i("clp", "doSomeThing");
}
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public class Father {
Father() {
new Other();
}
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public class Other {
Other() {
new Son();
}
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Son son = new Son();
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上面的代码,直接回导致程序死掉。陷入死循环。
36.使用构造代码块精炼程序
代码块:
1.使用static{}的静态代码块。类创建的时候加载
2.方法后面{}的普通代码块,必须通过调用方法名称使用
3.synchronize修饰的同步代码块
4.构造代码块,在类中没有任何修饰,直接使用{}
public class CldGouzaoUtil {
{
Log.i("clp", "构造代码块");
}
public CldGouzaoUtil() {
Log.i("clp", "构造方法");
}
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04-15 14:59:55.597 22529-22529/com.example.demo I/clp: 构造代码块
04-15 14:59:55.597 22529-22529/com.example.demo I/clp: 构造方法
构造代码块,不同于static代码块,它是依赖于构造方法执行。所以用途主要为
1.初始化实例变量
2.初始化实例环境
RE:2个都是在构造方法执行前执行一些初始化、检测的操作。
37.构造代码块会想你所想
public class CldGouzaoUtil {
protected static int numOfNew = 0;
{
numOfNew++;
}
public CldGouzaoUtil() {
}
public CldGouzaoUtil(String mDes) {
this();
}
public static int getNumOfNew() {
return numOfNew;
}
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new CldGouzaoUtil();
new CldGouzaoUtil("haha");
new CldGouzaoUtil("haha");
Log.i("clp", "初始化的次数为:" + CldGouzaoUtil.getNumOfNew());- 1
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04-15 15:31:37.737 19985-19985/com.example.demo I/clp: 初始化的次数为:3
new CldGouzaoUtil(“haha”)这种构造函数调用this的,构造代码块也只会执行一次。而且只要不杀死程序,次数会一直保留。
38.使用静态内部类提高封装性
//使用静态内部类加强类的封装性和提高代码的可读性
public class CldInnerStatic {
//提高封装性-比如这个代表home是外部类的子行为
//提高代码的可读性
//形似内部,神似外部---可以脱离外部存在
String name;
public Home home;
private static int outer = 100;
public CldInnerStatic(String name) {
this.name = name;
}
public void setHome(Home home) {
this.home = home;
}
//不持有外部类的引用
//静态内部类不依赖外部类
public static class Home {//静态内部类
public String addr;//地址
public int tel;//家庭电话
public Home(String addr, int tel) {
this.addr = addr;
this.tel = tel;
// name = "哈哈";//报错-不能访问外部类的变量
outer = 80;//静态内部类可以访问外部类static的变量
}
}
public class Company {
// public static int comAddr = "";//报错-普通内部类不能声明static的方法和变量
//报错
// public static void setComName() {//普通内部类不能声明static的方法和变量
//
// }
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CldInnerStatic innerStatic = new CldInnerStatic("张三");
innerStatic.setHome(new CldInnerStatic.Home("上海", 02166666666));- 1
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39.使用匿名内部类的构造函数
List<String> mList = new ArrayList<>();
List<String> mList2 = new ArrayList<>() {
};
List<String> mList3 = new ArrayList<>() {
{//代码块
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第二种和第三种都是相当于匿名内部类List mlist2 = new Sub();
40.匿名类的构造函数很特殊
public class CldCalculator {
{//在这里,计算出来的值就为0,在使用的地方就是正确的
setOperator();
Log.i("clp", "setOperator");
}
private int i, j, result;
public CldCalculator() {
}
public CldCalculator(int i, int j) {
Log.i("clp", "CldCalculator");
this.i = i;
this.j = j;
}
protected void setOperator() {
result = i + j;
}
public int getResult() {
return result;
}
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public class SubCal extends CldCalculator {
{//在这里,计算出来的值就为0,在使用的地方就是正确的
setOperator();
Log.i("clp", "setOperator");
}
public SubCal(int i, int j) {
}
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CldCalculator calculator = new CldCalculator(1, 2) {
// {
// setOperator();//这里使用,值是正确的
// Log.i("clp", "setOperator");
// }
};
Log.i("clp", "result=" + calculator.getResult());
CldCalculator calculator1 = new SubCal(1, 2);
Log.i("clp", "calculator1=" + calculator.getResult());//结果为0- 1
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两个结果不一样,因为匿名内部类的特殊处理机制。一般的类都是默认调用父类的无参构造。但是匿名类没有名字,直接由
构造代码块代替,直接调用了父类的同参构造方法。然后再调用自己的构造代码块。
41.让多继承成为现实
使用内部类,巧妙的实现多继承
public interface Father {
int Strong();//强壮指数
}
public interface Mother {
int kind();//温柔指数
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public class FatherIml implements Father {
@Override
public int Strong() {
return 8;
}
}
public class MotherIml implements Mother {
@Override
public int kind() {
return 8;
}
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public class Son extends FatherIml implements Mother {
@Override
public int Strong() {
return super.Strong() + 2;//比付清还要强壮
}
@Override
public int kind() {
return new MotherIml() {
@Override
public int kind() {
return super.kind() - 2;//温柔比母亲少了2个点
}
}.kind();
}
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Son son = new Son();
Log.i("clp", "strong =" + son.Strong() + ";kind=" + son.kind());
//结果:04-15 17:32:13.267 14610-14610/? I/clp: strong =10;kind=6- 1
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42.让工具类不可实例化
工具类的正确构建方式:1.不能实例化 2.不能继承
public final class CldUtil {
private CldUtil() {
throw new Error("不要实例化我");
}
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43.避免对象的浅拷贝
public class Person implements Cloneable {
//名称
private String name;
//父亲
private Person father;
public Person(String name) {
this.name = name;
}
public Person(String name, Person father) {
this.name = name;
this.father = father;
}
public void setName(String name) {
this.name = name;
}
public void setFather(Person father) {
this.father = father;
}
public String getName() {
return name;
}
public Person getFather() {
return father;
}
@Override
public Person clone() {//对象的拷贝
Person p = null;
try {
p = (Person) super.clone();
p.setFather(new Person(p.getFather().getName()));//如果没有这句话,就是浅拷贝,加了这句话,就是深拷贝
} catch (CloneNotSupportedException e) {
e.printStackTrace();
}
return p;
}
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Person father = new Person("父亲");
Person p1 = new Person("大儿子", father);
Person p2 = p1.clone();
p2.setName("小儿子");
// p2.setFather(new Person("干爹"));
p2.getFather().setName("干爹");
Log.i("clp", "fist name=" + p1.getName() + ";father =" + p1.getFather().getName());
Log.i("clp", "sec name=" + p2.getName() + ";father =" + p2.getFather().getName());- 1
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使用浅拷贝
04-15 17:55:30.827 2810-2810/com.example.demo I/clp: fist name=大儿子;father =干爹
04-15 17:55:30.827 2810-2810/com.example.demo I/clp: sec name=小儿子;father =干爹
使用p2.setFather(new Person(“干爹”));或者深拷贝
04-15 17:58:27.197 2810-2810/com.example.demo I/clp: fist name=大儿子;father =父亲
04-15 17:58:27.197 2810-2810/com.example.demo I/clp: sec name=小儿子;father =干爹
44.推荐使用序列化实现对象的拷贝
public class Person implements Serializable {
private static final long serialVersionUID = 201704161112L;
//名称
public String name;
//父亲
public Person person;
public Person(String name) {
this.name = name;
}
public Person(String name, Person person) {
this.name = name;
this.person = person;
}
public String getName() {
return name;
}
public void setName(String name) {
this.name = name;
}
public Person getPerson() {
return person;
}
public void setPerson(Person person) {
this.person = person;
}
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//使用字节流实现对象的拷贝
public static <T extends Serializable> T clone(T obj) {
//final和static的序列化问题会被引入到对象的拷贝中???
//transient变量也会影响到拷贝的结果???
T cloneObj = null;
try {
ByteArrayOutputStream byteArrayOutputStream = new ByteArrayOutputStream();
ObjectOutputStream objectOutputStream = new ObjectOutputStream(byteArrayOutputStream);
objectOutputStream.writeObject(obj);//如果不实现序列化,则会抛出序列化异常
objectOutputStream.close();
ByteArrayInputStream byteArrayInputStream = new ByteArrayInputStream(byteArrayOutputStream.toByteArray());
ObjectInputStream objectInputStream = new ObjectInputStream(byteArrayInputStream);
cloneObj = (T) objectInputStream.readObject();
objectInputStream.close();
} catch (Exception e) {
e.printStackTrace();
}
return cloneObj;
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01-04 19:27:44.620 17104-17104/old.pkg.com.myapplicati I/clp: 名称:小儿子;父亲为:父亲
01-04 19:27:44.620 17104-17104/old.pkg.com.myapplicati I/clp: 名称:大儿子;父亲为:干爹
45.复写equals方法时不要识别不出自己
public class Person {
//名称
public String name;
public Person(String name) {
this.name = name;
}
public String getName() {
return name;
}
public void setName(String name) {
this.name = name;
}
@Override
public boolean equals(Object obj) {
if (obj instanceof Person) {
Person person = (Person) obj;
//equalsIgnoreCase为忽略大小写
return name.equalsIgnoreCase(person.getName());
// return name.equalsIgnoreCase(person.getName().trim());
// 01-04 19:41:01.360 30991-30991/old.pkg.com.myapplicati I/clp: p1 is equals =false
//
// return name.equalsIgnoreCase(person.getName());
// 01-04 19:41:48.420 32459-32459/old.pkg.com.myapplicati I/clp: p1 is equals =true
}
return super.equals(obj);
}
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Person p1 = new Person("张三 ");
Log.i("clp", "p1 is equals =" + p1.equals(p1));- 1
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使用:
return name.equalsIgnoreCase(person.getName().trim());
01-04 19:41:01.360 30991-30991/old.pkg.com.myapplicati I/clp: p1 is equals =false
return name.equalsIgnoreCase(person.getName());
01-04 19:41:48.420 32459-32459/old.pkg.com.myapplicati I/clp: p1 is equals =true
46.equals应该考虑null值情景
接上面的例子,如果按照下面的方式判断,就会报错
Person p1 = new Person("张三 ");
Person p2 = new Person(null);
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所以,应该按照下面的写:
@Override
public boolean equals(Object obj) {
if (obj instanceof Person) {
Person person = (Person) obj;
if (person.getName() == null || name == null) {
return false;
}
//equalsIgnoreCase为忽略大小写
return name.equalsIgnoreCase(person.getName());
// return name.equalsIgnoreCase(person.getName().trim());
// 01-04 19:41:01.360 30991-30991/old.pkg.com.myapplicati I/clp: p1 is equals =false
//
// return name.equalsIgnoreCase(person.getName());
// 01-04 19:41:48.420 32459-32459/old.pkg.com.myapplicati I/clp: p1 is equals =true
}
return super.equals(obj);
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47.在equals中使用getClass进行类型判断
接上面例子,如果有一个子类,代码如下:
public class ManPerson extends Person {
public int id;
public ManPerson(String name, int id) {
this.name = name;
this.id = id;
}
@Override
public boolean equals(Object obj) {
if (obj instanceof ManPerson) {
ManPerson person = (ManPerson) obj;
return super.equals(obj) && person.id == id;
}
return super.equals(obj);
}
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然后进行判断:
Person p1 = new Person("张三");
ManPerson manPerson = new ManPerson("张三", 100);
Log.i("clp", "p1 manPerson is equals =" + p1.equals(manPerson));- 1
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结果是true。
这是因为p1为父类,所以使用了父类的equals方法进行判断。关键就是equals方法中使用了instanceof。故修改如下:
@Override
public boolean equals(Object obj) {
if (obj.getClass() != null && obj.getClass() == this.getClass()) {
Person person = (Person) obj;
if (person.getName() == null || name == null) {
return false;
}
//equalsIgnoreCase为忽略大小写
return name.equalsIgnoreCase(person.getName());
// return name.equalsIgnoreCase(person.getName().trim());
// 01-04 19:41:01.360 30991-30991/old.pkg.com.myapplicati I/clp: p1 is equals =false
//
// return name.equalsIgnoreCase(person.getName());
// 01-04 19:41:48.420 32459-32459/old.pkg.com.myapplicati I/clp: p1 is equals =true
}
return super.equals(obj);
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48.覆写equals方法必须覆写hashCode方法
Map<Person, Object> map = new HashMap<Person, Object>() {
{
put(new Person("张三"), new Object());
}
};
Log.i("clp", "map has key=" + map.containsKey(new Person("张三")));- 1
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上面方法,如果不覆写hashCode,会返回false。
因为map是根据hashCode值决定数组的下标(HashMap底层是通过数组保存的)。如果不覆写,每一个对象都有一个hasCode,自然会找不到
所以Person类中添加如下方法:
@Override
public int hashCode() {
return name.hashCode();
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49.推荐覆写toString()
原因是本身,此此方法返回的是对象引用的地址值。
01-04 21:29:51.320 27893-27893/old.pkg.com.myapplicati I/clp: person =newpkg.pkg.com.myapplication2.algorithm.Person@bd2e9
Person person = new Person("张三");
Log.i("clp", "person =" + person.toString());- 1
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01-04 21:29:12.490 26591-26591/old.pkg.com.myapplicati I/clp: person =name =张三
50.使用package-info类为包服务
作用:
1.声明友好类和包内访问常量
2.为在包上标注注解提供便利
3.提供包的整体注释说明
51.不要主动进行垃圾回收
因为System.gc会停止所有的相应,去进行检测内存中是否有可回收的对象。可能会比较耗时,10S或者20S也说不准。
字符串
52.推荐使用String直接量赋值
String s1 = "张三";
String s2 = " 张三 ";
String s3 = new String("张三");
String s4 = s3.intern();
Log.i("clp", " s1 s2 is equals=" + (s1 == s2));
Log.i("clp", " s1 s3 is equals=" + (s1 == s3));
Log.i("clp", " s1 s4 is equals=" + (s1 == s4));- 1
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01-04 21:51:49.220 19875-19875/old.pkg.com.myapplicati I/clp: s1 s2 is equals=false
01-04 21:51:49.220 19875-19875/old.pkg.com.myapplicati I/clp: s1 s3 is equals=false
01-04 21:51:49.220 19875-19875/old.pkg.com.myapplicati I/clp: s1 s4 is equals=true
Java为了避免产生大量的对象,内部有一个字符串池。创建字符串时,会先判断池子中是否有这个字符串,有就直接返回,
如果没有,就创建一个,丢到池子当中,并返回。
使用new 创建,肯定是新建了一个对象。
intern方法会检查当前的对象,在池子中是否有字面值相等的引用对象,如果有就返回池子中的对象,没有就放置到池子中,并返回。
会不会有线程安全问题?
String是一个不可变对象。
1.不可能有子类
2.String中提供的方法中的返回值,都会新建一个对象,不会对原对象进行修改。
要不要考虑垃圾回收?
字符串池,是保存子JVM的常量池当中,不会进行垃圾回收。
53.注意参数中传递的参数要求
//删除字符串
public static String remove(String orgin, String sub) {
return orgin.replaceAll(sub, "");
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Log.i("clp", "result =" + CldStringUtil.remove("好是好", "好"));
Log.i("clp", "result =" + CldStringUtil.remove("$是$", "$"));- 1
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结果:
01-04 22:08:33.220 6359-6359/old.pkg.com.myapplicati I/clp: result =是
01-04 22:08:33.220 6359-6359/old.pkg.com.myapplicati I/clp: result =是
replaceAll要求第一个参数是正则表达式。$这个符号在正则表达式中是字符串的结束位置。
修改如下:
//删除字符串
public static String remove(String orgin, String sub) {
while (orgin.contains(sub)) {
orgin = orgin.replace(sub, "");
}
return orgin;
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54.正确使用String、StringBuffer、StringBuilder
1.String一旦创建,不可变
2.StringBuffer是线程安全的,StringBuilder是线程不安全的。
所以StringBuffer的性能要比StringBuilder低。
3.性能方法,因为String每次都会新建,所以会远慢于StringBuffer和StringBuilder
55.注意字符串的位置
String s1 = 1 + 2 + "abc";
String s2 = "abc" + 1 + 2;
Log.i("clp", "s1=" + s1);
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01-05 06:40:30.540 28819-28819/old.pkg.com.myapplicati I/clp: s1=3abc
01-05 06:40:30.540 28819-28819/old.pkg.com.myapplicati I/clp: s2=abc12
1.从左到右依次拼接
2.只要遇到String,则所有数据都转换为String类进行拼接
3.如果是原始数据,则直接进行拼接,如果是对象,则调用toString()
4.在+表达式中,String具有最高的优先级
56.自由选择字符串拼接方法
String s = "";
long time = System.currentTimeMillis();
for (int i = 0; i < 5000; i++) {
s += "a";
}
long timeend = System.currentTimeMillis() - time;
Log.i("clp", "time1 =" + timeend);
String a = "";
long time2 = System.currentTimeMillis();
for (int i = 0; i < 5000; i++) {
s = s.concat("a");
}
long timeend2 = System.currentTimeMillis() - time2;
Log.i("clp", "time1 =" + timeend2);
StringBuilder b = new StringBuilder();
long time3 = System.currentTimeMillis();
for (int i = 0; i < 5000; i++) {
b.append("a");
}
long timeend3 = System.currentTimeMillis() - time3;
Log.i("clp", "time1 =" + timeend3);
StringBuffer c = new StringBuffer();
long time4 = System.currentTimeMillis();
for (int i = 0; i < 5000; i++) {
c.append("a");
}
long timeend4 = System.currentTimeMillis() - time4;
Log.i("clp", "time1 =" + timeend4); 01-05 06:53:02.410 3080-3080/old.pkg.com.myapplicati I/clp: time1 =1160
01-05 06:53:04.070 3080-3080/old.pkg.com.myapplicati I/clp: time1 =1668
01-05 06:53:04.080 3080-3080/old.pkg.com.myapplicati I/clp: time1 =5
01-05 06:53:04.090 3080-3080/old.pkg.com.myapplicati I/clp: time1 =8
书上说concat执行时间比直接添加少一倍。但是在我手机上测试为啥还要高???
57.推荐在复杂字符串操作中使用正则表达式
//使用正则表达式计算单词的数量
public static int getCount(String word) {
//正在表达式
Pattern pattern = Pattern.compile("\\b\\w+\\b");
Matcher matcher = pattern.matcher(word);
int count = 0;
while (matcher.find()) {
count++;
}
return count;
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String s = "How are you !Good!";
Log.i("clp", "count=" + CldStringUtil.getCount(s));- 1
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58.强烈建议使用UTF编码
文件格式为UTF-8
try {
String s = "张三";
byte[] b = s.getBytes("GBK");
Log.i("clp", "string is =" + new String(b));
Log.i("clp", "string is =" + new String(b, "GBK"));
} catch (Exception e) {
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输出结果:
01-05 07:20:10.370 11249-11249/old.pkg.com.myapplicati I/clp: string is =����
01-05 07:20:10.370 11249-11249/old.pkg.com.myapplicati I/clp: string is =张三
59.对字符串排序持一种宽容的态度
1.使用Arrays.sort肯定不行,它是根据UNICODE代码表来排序的。
2.使用Collator,但是只能包含常用的7000多个汉字。
String[] sortName = {"张三", "李四", "王五"};
Comparator c = Collator.getInstance(Locale.CHINA);
Arrays.sort(sortName, c);
for (String str : sortName) {
Log.i("clp", "name =" + str);
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原因:java使用UNICODE编码。
GB2312->GB18030->UNICODE
数组和集合
60.性能考虑,数组是首选
//基本类型是在栈内操作的。而对象是在堆内操作的。
//栈的特点是:速度快、容量小 堆的特点是:速度慢,容量大。
public static int getCountArray(int[] list) {
int sum = 0;
long time = System.currentTimeMillis();
for (int i = 0; i < list.length; i++) {
sum += list[i];
}
long timeend = System.currentTimeMillis() - time;
Log.i("clp", "array time is =" + timeend);
return sum;
}
public static int getCountList(List<Integer> list) {
int sum = 0;
long time = System.currentTimeMillis();
for (int i = 0; i < list.size(); i++) {
sum += list.get(i);//做了一次拆箱操作。Integer通过intValue方法自动转换为了int基本类型
}
long timeend = System.currentTimeMillis() - time;
Log.i("clp", "data time is =" + timeend);
return sum;
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int[] data = new int[100000];
for (int i = 0; i < data.length; i++) {
data[i] = 2;
}
CldArrayUtil.getCountArray(data);
List<Integer> list = new ArrayList<Integer>();
for (int j = 0; j < 100000; j++) {
list.add(2);
}
CldArrayUtil.getCountList(list);- 1
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01-05 08:13:19.740 21326-21326/old.pkg.com.myapplicati I/clp: array time is =4
01-05 08:13:19.880 21326-21326/old.pkg.com.myapplicati I/clp: data time is =35
数组的效率是集合的10倍。这个说法是对的。
61.若有必要,使用变长数组
public static int[] expandArray(int[] data, int length) {//指定新的数组长度
if (length < 0) {
length = 0;
}
return Arrays.copyOf(data, length);
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int[] data = new int[20];
for (int i = 0; i < data.length; i++) {
data[i] = 2;
}
data = CldArrayUtil.expandArray(data, 50);
Log.i("clp", "length =" + data.length);
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01-05 08:26:57.310 23679-23679/old.pkg.com.myapplicati I/clp: length =50
01-05 08:26:57.310 23679-23679/old.pkg.com.myapplicati I/clp: data[2]=2
62.警惕数组的浅拷贝
Arrays.copyOf为数组的浅拷贝,如果是基本类型,直接拷贝值。如果是对象,拷贝的是引用地址。
所以如果改变拷贝后的对象的值,拷贝前的值也会发生变化。
解决方式:重新生成对象。
63.在明确的场景下,为集合指定初始容量
1.例如ArrayList,如果不指定,初始容量为10.每次如果长度不够,就自动扩容到1.5倍。
所以,如果要指定一个长度为50的List,最好直接指定容量
List<String> mlist = new ArrayList<>(50);
for (int i = 0; i < 60; i++) {//列表长度为50,添加60个元素
mlist.add("2");
}
Log.i("clp", "list size =" + mlist.size());- 1
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01-05 19:23:08.320 4367-4367/old.pkg.com.myapplicati I/clp: list size =60
Vector、HashMap、Stack类似。
64.多种最值算法,适时选择
int[] data = new int[100000];
for (int i = 0; i < data.length; i++) {
data[i] = new Random().nextInt(10000);
}
//使用数组排序
int max = data[0];
long time = System.currentTimeMillis();
for (int i : data) {
max = max > data[i] ? max : data[i];
}
long timeEnd = System.currentTimeMillis() - time;
Log.i("clp", "timeEnd=" + timeEnd);
Log.i("clp", "max data = " + max);- 1
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01-05 19:35:47.690 8007-8007/old.pkg.com.myapplicati I/clp: timeEnd=6
01-05 19:35:47.690 8007-8007/old.pkg.com.myapplicati I/clp: max data = 9999
int[] data = new int[100000];
for (int i = 0; i < data.length; i++) {
data[i] = new Random().nextInt(10000);
}
//使用Arrays排序
int max = data[0];
long time = System.currentTimeMillis();
Arrays.sort(data.clone());
long timeEnd = System.currentTimeMillis() - time;
Log.i("clp", "timeEnd=" + timeEnd);
Log.i("clp", "max data = " + data[data.length - 1]);- 1
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01-05 19:37:36.810 9440-9440/old.pkg.com.myapplicati I/clp: timeEnd=172
01-05 19:37:36.810 9440-9440/old.pkg.com.myapplicati I/clp: max data = 9281
排序10万个数据,才有细微的差别。所以,小数据性能影响不大。用Arrays.sort排序代码可读性高一点。
求第二大元素,正常通过数据循环查找可以搞定,下面使用TreeSet实现(过滤掉相同数据).
long time = System.currentTimeMillis();
List<Integer> mList = Arrays.asList(data);
TreeSet<Integer> ts = new TreeSet<Integer>(mList);
int max = ts.lower(ts.last());
long timeEnd = System.currentTimeMillis() - time;
Log.i("clp", "timeEnd=" + timeEnd);
Log.i("clp", "sec max data = " + max);- 1
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01-05 19:42:18.750 10551-10551/old.pkg.com.myapplicati I/clp: timeEnd=1092
01-05 19:42:18.750 10551-10551/old.pkg.com.myapplicati I/clp: sec max data = 9998
65.避开基本类型数组转换列表陷进
int[] data = new int[100000];
for (int i = 0; i < data.length; i++) {
data[i] = new Random().nextInt(10000);
}
List mList = Arrays.asList(data);
Log.i("clp", "list size =" + mList.size());- 1
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01-05 19:50:27.710 13585-13585/old.pkg.com.myapplicati I/clp: list size =1
asList需要输入一个泛型化的边长参数,基本类型是不能泛型化的,但是数组可以。所以上面就把数组泛型化为只有一个数组的。
mList.get(0)数据如下:
其他7个基本类型也有这个问题,所以如果要用,请使用包装类型。
66.asList方法产生的List对象不可更改
Integer[] data = new Integer[5];
for (int i = 0; i < 5; i++) {
data[i] = new Random().nextInt(10);
}
List<Integer> mList = Arrays.asList(data);
mList.add(2);- 1
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java.lang.RuntimeException: Unable to start activity ComponentInfo
{old.pkg.com.myapplicati/newpkg.pkg.com.myapplication2.MainActivity}: java.lang.UnsupportedOperationException
at android.app.ActivityThread.performLaunchActivity(ActivityThread.java:2279)
at android.app.ActivityThread.handleLaunchActivity(ActivityThread.java:2329)
at android.app.ActivityThread.access$1100(ActivityThread.java:141)
at android.app.ActivityThread$H.handleMessage(ActivityThread.java:1242)- 1
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因为通过asList产生的List不同于正常使用的List,不能使用add remove方法。
只有size toArray get set contains五个方法可以用。
List mList = Arrays.asList(1, 2, 3);这种方式生成数组有巨大的隐患。
67.不同的列表选择不同的遍历方法
new Thread(new Runnable() {
@Override
public void run() {
List<Integer> mList = new ArrayList<>();
for (int i = 0; i < 80 * 100; i++) {
mList.add(new Random().nextInt(200));
}
long start = System.currentTimeMillis();
int average = CldArrayUtil.average(mList);
Log.i("clp", "time =" + (System.currentTimeMillis() - start) + "ms");
Log.i("clp", "average=" + average);
List<Integer> mList2 = new LinkedList<>();
for (int i = 0; i < 80 * 100; i++) {
mList2.add(new Random().nextInt(200));
}
long start2 = System.currentTimeMillis();
int average2 = CldArrayUtil.average(mList2);
Log.i("clp", "time2 =" + (System.currentTimeMillis() - start2) + "ms");
Log.i("clp", "average2=" + average2);
}
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使用fori循环
//求平局数
public static int average(List<Integer> list) {
int sum = 0;
for (int i = 0; i < list.size(); i++) {
sum += list.get(i);
}
return sum / list.size();
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01-05 21:07:22.310 2140-2188/old.pkg.com.myapplicati I/clp: time =8ms
01-05 21:07:22.310 2140-2188/old.pkg.com.myapplicati I/clp: average=98
01-05 21:07:23.280 2140-2188/old.pkg.com.myapplicati I/clp: time2 =929ms
01-05 21:07:23.280 2140-2188/old.pkg.com.myapplicati I/clp: average2=98
8000个就是快1S,80万个就是100S!!!!
//求平局数
public static int average(List<Integer> list) {
int sum = 0;
// for (int i = 0; i < list.size(); i++) {
// sum += list.get(i);
// }
for (Integer i : list) {
sum += i;
}
return sum / list.size();
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01-05 21:09:06.990 3137-3185/old.pkg.com.myapplicati I/clp: time =5ms
01-05 21:09:06.990 3137-3185/old.pkg.com.myapplicati I/clp: average=99
01-05 21:09:07.030 3137-3185/old.pkg.com.myapplicati I/clp: time2 =9ms
01-05 21:09:07.030 3137-3185/old.pkg.com.myapplicati I/clp: average2=98
在手机上测试,使用foreach方法,消耗的时间差不多???
ArrayList实现了随机读取(RandomAcess),而LinkedList实现了迭代器。
书上建议通过判断是否有RandomAcess
//求平局数
public static int average(List<Integer> list) {
int sum = 0;
if (list instanceof RandomAccess) {//针对ArrayList可以随机读取的
for (int i = 0; i < list.size(); i++) {
sum += list.get(i);
}
} else {//针对LinkedList这种
for (Integer i : list) {
sum += i;
}
}
return sum / list.size();
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01-05 21:11:53.070 4250-4304/old.pkg.com.myapplicati I/clp: time =4ms
01-05 21:11:53.070 4250-4304/old.pkg.com.myapplicati I/clp: average=98
01-05 21:11:53.130 4250-4304/old.pkg.com.myapplicati I/clp: time2 =12ms
01-05 21:11:53.130 4250-4304/old.pkg.com.myapplicati I/clp: average2=98
68.频繁插入和删除时用LinkedList
ArrayList和LinkedList性能比较
添加:
new Thread(new Runnable() {
@Override
public void run() {
List<String> mArrayList = new ArrayList<String>();
for (int i = 0; i < 10; i++) {
mArrayList.add("a");
}
long start = System.currentTimeMillis();
for (int i = 0; i < 100000; i++) {
mArrayList.add(2, "a");
}
Log.i("clp", "array list time =" + (System.currentTimeMillis() - start) + "ms");
List<String> mLinkedList = new LinkedList<String>();
for (int i = 0; i < 10; i++) {
mLinkedList.add("a");
}
long start2 = System.currentTimeMillis();
for (int i = 0; i < 100000; i++) {
mLinkedList.add(2, "a");
}
Log.i("clp", "linked list time =" + (System.currentTimeMillis() - start2) + "ms");
}
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01-05 21:34:13.060 10127-10170/old.pkg.com.myapplicati I/clp: array list time =15847ms
01-05 21:34:13.170 10127-10170/old.pkg.com.myapplicati I/clp: linked list time =116ms
10万个数据的话,相差100倍。
删除:
new Thread(new Runnable() {
@Override
public void run() {
List<String> mArrayList = new ArrayList<String>();
for (int i = 0; i < 10 * 10000; i++) {
mArrayList.add("a");
}
long start = System.currentTimeMillis();
while (mArrayList.size() > 0){
mArrayList.remove(0);
}
Log.i("clp", "array list time =" + (System.currentTimeMillis() - start) + "ms");
List<String> mLinkedList = new LinkedList<String>();
for (int i = 0; i < 10 * 10000; i++) {
mLinkedList.add("a");
}
long start2 = System.currentTimeMillis();
while (mLinkedList.size() > 0) {
mLinkedList.remove(0);
}
Log.i("clp", "linked list time =" + (System.currentTimeMillis() - start2) + "ms");
}
}).start();- 1
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01-05 21:37:58.600 11330-11372/old.pkg.com.myapplicati I/clp: array list time =15108ms
01-05 21:37:58.700 11330-11372/old.pkg.com.myapplicati I/clp: linked list time =13ms
删除,性能相差1000倍。
修改:
new Thread(new Runnable() {
@Override
public void run() {
List<String> mArrayList = new ArrayList<String>();
for (int i = 0; i < 10 * 10000; i++) {
mArrayList.add("a");
}
long start = System.currentTimeMillis();
for (int i = 0; i < 10 * 10000; i++) {
mArrayList.set(10000, "b");
}
Log.i("clp", "array list time =" + (System.currentTimeMillis() - start) + "ms");
List<String> mLinkedList = new LinkedList<String>();
for (int i = 0; i < 10 * 10000; i++) {
mLinkedList.add("a");
}
long start2 = System.currentTimeMillis();
for (int i = 0; i < 10 * 10000; i++) {
mLinkedList.set(10000, "b");
}
Log.i("clp", "linked list time =" + (System.currentTimeMillis() - start2) + "ms");
}
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01-05 21:40:26.700 12467-12523/old.pkg.com.myapplicati I/clp: array list time =28ms
01-05 21:40:55.580 12467-12523/old.pkg.com.myapplicati I/clp: linked list time =28672ms
总结:频繁的删除和插入,使用LinkedList。 如果频繁的获取和修改。使用ArrayList
69.列表相等只需关系元素数据
判断集合是否相等时,只需要判断元素是否相等即可。
ArrayList<String> mList = new ArrayList<String>();
mList.add("a");
Vector<String> mVList = new Vector<String>();
mVList.add("a");
Log.i("clp", "is equals =" + mList.equals(mVList));- 1
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01-06 06:56:50.610 25692-25692/old.pkg.com.myapplicati I/clp: is equals =true
equals是在AbstractList中实现的,代码如下:
public boolean equals(Object o) {
if (o == this)
return true;
if (!(o instanceof List))
return false;
ListIterator<E> e1 = listIterator();
ListIterator e2 = ((List) o).listIterator();
while (e1.hasNext() && e2.hasNext()) {
E o1 = e1.next();
Object o2 = e2.next();
if (!(o1==null ? o2==null : o1.equals(o2)))
return false;
}
return !(e1.hasNext() || e2.hasNext());
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70.子列表只是原列表的一个视图
List<String> mlist = new ArrayList<String>();
mlist.add("A");
mlist.add("B");
ArrayList<String> mBList = new ArrayList<>(mlist);
List<String> mCList = mlist.subList(0, mlist.size());
mCList.add("C");
Log.i("clp", "mlist mBlist is equals =" + mlist.equals(mBList));
Log.i("clp", "mlist mCList is equals =" + mlist.equals(mCList));- 1
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01-06 07:18:39.990 29976-29976/old.pkg.com.myapplicati I/clp: mlist mBlist is equals =false
01-06 07:18:39.990 29976-29976/old.pkg.com.myapplicati I/clp: mlist mCList is equals =true
subList是在原数组上进行操作。
71.推荐使用subList处理局部列表
List<String> mList = new ArrayList<String>();
for (int i = 0; i < 100; i++) {
mList.add("a");
}
//删除第20~30之间的元素
mList.subList(20, 30).clear();
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01-06 07:28:51.470 32234-32234/old.pkg.com.myapplicati I/clp: mList size =90
72.生成子列表之后不要再操作原列表
List<String> mList = new ArrayList<String>();
for (int i = 0; i < 100; i++) {
mList.add("a");
}
List<String> mSubList = mList.subList(20, 30);
mList.add("d");
Log.i("clp", "mlist size =" + mList.size());
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java.lang.RuntimeException: Unable to start activity ComponentInfo
{old.pkg.com.myapplicati/newpkg.pkg.com.myapplication2.MainActivity}:
java.util.ConcurrentModificationException
操作子列表也有可能导致报错,如下:
List<String> mList = new ArrayList<String>();
for (int i = 0; i < 100; i++) {
mList.add("a");
}
List<String> mSubList = mList.subList(20, 30);
List<String> mSubList2 = mList.subList(10, 30);
mSubList.add("d");
// mSubList2.add("e");
Log.i("clp", "mlist size =" + mList.size());
Log.i("clp", "mSubList size =" + mSubList.size());
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73.使用Comparator进行排序
public class Person implements Comparable<Person> {
public int id;
public String name;
public Person(int id, String name) {
this.id = id;
this.name = name;
}
@Override
public int compareTo(Person person) {
if (person == null) {
return -1;
}
return Integer.valueOf(id).compareTo(Integer.valueOf(person.id));
}
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List<Person> mList = new ArrayList<Person>();
mList.add(new Person(2, "张二"));
mList.add(new Person(1, "张一"));
mList.add(new Person(4, "张四"));
mList.add(new Person(3, "张三"));
Collections.sort(mList);
for (int i = 0; i < mList.size(); i++) {
Log.i("clp", "index =" + i + ";name =" + mList.get(i).name);
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使用Comparator可以拓展排序。
List<Person> mList = new ArrayList<Person>();
mList.add(new Person(2, 440300, "张二"));
mList.add(new Person(1, 440322, "张一"));
mList.add(new Person(4, 440310, "张四"));
mList.add(new Person(3, 440200, "张三"));
mList.add(new Person(6, 440200, "张六"));
mList.add(new Person(5, 440200, "张五"));
Collections.sort(mList, new PerComparator());
for (int i = 0; i < mList.size(); i++) {
Log.i("clp", "index =" + i + ";cityId=" + mList.get(i).cityId + ";name =" + mList.get(i).name);
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//先按照cityId进行排序,如果相等,就按照id排序
public class PerComparator implements Comparator<Person> {
@Override
public int compare(Person person, Person t1) {
if (person.cityId > t1.cityId) {//1的画,是排后面
return 1;
} else if (person.cityId == t1.cityId) {//如果城市相等,按照id排序
if (person.id > t1.id) {
return 1;
} else if (person.id == t1.id) {
return 0;
} else {
return -1;
}
} else {
return -1;
}
}
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如果想实现倒序,直接使用:
Collections.sort(mList, Collections.reverseOrder(new PerComparator()));
Collections.reverse(mList);---对排序之后的,进行倒序Comparable实现默认排序。Comparator可以实现拓展排序。
74.不推荐使用binarySearch对列表进行检索
1.indexOf是通过for循环进行排序查找第一个符合条件的
2.binarySearch是通过二分查找,但是前提也是必须先排序
所以,如果已经排序的,使用binarySearch性能会高很多。
75.集合中的元素必须做到compartTo和equals同步
public class Person implements Comparable<Person> {
public int id;
public String name;
public Person(int id, String name) {
this.id = id;
this.name = name;
}
@Override
public int compareTo(Person person) {
if (person == null) {
return -1;
}
return person.name.compareTo(this.name);
}
@Override
public boolean equals(Object o) {
if (o == null) {
return false;
}
if (o == this) {
return true;
}
if (this.getClass() != o.getClass()) {
return false;
}
Person p = (Person) o;
return Integer.valueOf(id).compareTo(Integer.valueOf(p.id)) == 0;
}
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List<Person> mList = new ArrayList<Person>();
mList.add(new Person(1, "张二"));
mList.add(new Person(1, "张一"));
Person p = new Person(1, "张一");
int index1 = mList.indexOf(p);
int index2 = Collections.binarySearch(mList, p);
Log.i("clp", "index1=" + index1);
Log.i("clp", "index2=" + index2);- 1
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04-18 11:51:12.192 12423-12423/com.example.demo I/clp: index1=0
04-18 11:51:12.192 12423-12423/com.example.demo I/clp: index2=1
indexOf是通过对象中的equals来判断是否相等,
binarySearch是通过compartTo来判断是否相等。所以2个方法应该同步。
76.集合运算中使用更优雅的方式
List<String> mList1 = new ArrayList<String>();
mList1.add("a");
mList1.add("b");
List<String> mList2 = new ArrayList<String>();
mList2.add("a");
mList2.add("c");
//并集
// mList1.addAll(mList2);
// Log.i("clp", "并集 size=" + mList1.size());
// //04-18 12:07:46.552 12423-12423/com.example.demo I/clp: 并集 size=4
//交集
// mList1.retainAll(mList2);
// Log.i("clp", "交集 size=" + mList1.size());
//04-18 12:08:55.022 12423-12423/com.example.demo I/clp: 交集 size=1
//差集
// mList1.removeAll(mList2);
// Log.i("clp", "差集 size=" + mList1.size());
//04-18 12:09:44.782 12423-12423/com.example.demo I/clp: 差集 size=1
//无重复的并集
mList2.removeAll(mList1);
mList1.addAll(mList2);
Log.i("clp", "无重复的并集 size=" + mList1.size());
// 04-18 12:10:34.862 12423-12423/com.example.demo I/clp: 无重复的并集 size=3- 1
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无重复的并集,不能使用HashSet,因为会把本来重复的元素合并掉。
77.使用shuffle打乱列表
int count = 10;
List<String> mList = new ArrayList<>(10);
for (int i = 0; i < 10; i++) {
mList.add(i + "");
}
// for (int i = 0; i < 10; i++) {
// int random = new Random().nextInt(10);
// Collections.swap(mList, i, random);
// }
Collections.shuffle(mList);//打乱顺序
for (int i = 0; i < 10; i++) {
Log.i("clp", "value" + mList.get(i));
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78.减少HashMap中元素的数量
1.比ArrayList多了Entry对象,如果有40万个数据,就是多了40万个对象
2.扩容机制不一样,HashMap是2倍扩容,ArrayList是1.5倍
3.HashMap有一个加载因子,意思是到达容量的0.75就开始扩容了
所以大量数据的时候,HashMap比ArrayList先内存溢出。
79.集合中的哈希码尽量不要重复
HashMap是通过哈希值,实现比ArrayList快速的查找,如果哈希码是一样的,性能就和链表的性能是一样的。
80.多线程使用Vector和HashTable
final Vector<String> mVList = new Vector<String>();
for (int i = 0; i < 10000; i++) {
mVList.add("火车票" + i);
}
for (int i = 0; i < 10; i++) {
new Thread(new Runnable() {
@Override
public void run() {
while (true) {
String mR = mVList.remove(0);
Log.i("clp", "cur thread id=" + Thread.currentThread().getId() + ";remove =" + mR);
}
}
}).start();
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多个线程同步,但是不能实现,一个线程读的时候,另一个线程在写。
81.非稳定序列推荐使用List
SortedSet<Person> sortSet = new TreeSet<Person>();
sortSet.add(new Person(15, "张三"));
sortSet.add(new Person(10, "张四"));
for (Person per : sortSet) {
Log.i("clp", "id=" + per.id + ";name=" + per.name);
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04-18 15:44:55.202 31018-31018/com.example.demo I/clp: id=10;name=张四
04-18 15:44:55.202 31018-31018/com.example.demo I/clp: id=15;name=张三
SortedSet<Person> sortSet = new TreeSet<Person>();
sortSet.add(new Person(15, "张三"));
sortSet.add(new Person(10, "张四"));
sortSet.first().id = 20;
for (Person per : sortSet) {
Log.i("clp", "id=" + per.id + ";name=" + per.name);
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04-18 15:45:49.532 31018-31018/com.example.demo I/clp: id=20;name=张四
04-18 15:45:49.532 31018-31018/com.example.demo I/clp: id=15;name=张三
SortedSet只有在插入的时候,进行排序。
sortSet = new TreeSet<Person>(new ArrayList<Person>(sortSet));可以通过new 重新构建。
基本类型,建议使用SortedSet,如果是自己创建的对象,可以使用Colletions.sort
82.集合大家族
一、List
实现List的接口主要有:ArrayList-动态数组 LinkedList-双向链表 Vector-线程安全的动态数组 Stack-对象栈,先进后出
二、Set-不包含重复元素的集合:
EnumSet-枚举类型的专用Set,所有的元素都是枚举类型
HashSet-以哈希码决定元素位置的Set,与HashMap类似,提供快速的插入和查找
TreeSet-自动排序的Set,实现了SortedSet接口
三、Map-分为排序的Map和非排序Map
TreeMap-根据Key值自动排序
HashMap
HashTable
Properties:HashTable的子类,主要从Property文件中加载数据,并提供方便的读写。
EnumMap
WeakHashMap:可以被垃圾回收的HashMap
四、Queue队列-分为阻塞和非阻塞队列
五、数组
所有的集合底层存储的都是数组,数据可以存储基本类型,集合不行。
六、工具类
数组的工具类:Array和Arrays
集合的工具类:Collections
如果需要精确排序,则需要使用开源项目。如pinyin4j。
枚举和注解
83.推荐使用枚举定义常亮
public enum SeaSon {
Sping, Summer, Autumn, Winner;
public static SeaSon getCommonSeason() {
return Sping;
}
}
for (SeaSon s : SeaSon.values()) {
Log.i("clp", "s values =" + s);
}
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04-19 10:26:24.608 14196-14196/com.example.demo I/clp: s values =Sping
04-19 10:26:24.608 14196-14196/com.example.demo I/clp: s values =Summer
04-19 10:26:24.608 14196-14196/com.example.demo I/clp: s values =Autumn
04-19 10:26:24.608 14196-14196/com.example.demo I/clp: s values =Winner
04-19 10:26:24.608 14196-14196/com.example.demo I/clp: common =Sping
84.使用构造函数协助描述枚举项
public enum SeaSon {
Sping("春"), Summer("夏"), Autumn("秋"), Winner("冬");
private String desc;
SeaSon(String desc) {
this.desc = desc;
}
public String getDesc() {
return desc;
}
public static SeaSon getCommonSeason() {
return Sping;
}
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for (SeaSon s : SeaSon.values()) {
Log.i("clp", "s values =" + s.getDesc());
}
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构造函数还可以比这个更复杂,传递对象等。
85.小心switch带来的空值异常
public void doSwSeaSon(SeaSon seaSon) {
switch (seaSon) {
case Sping:
Log.i("clp", "Sping");
break;
default:
Log.i("clp", "其他类型");
break;
}
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doSwSeaSon(null);- 1
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java.lang.NullPointerException: Attempt to invoke virtual method ‘int com.cp.demo.java.SeaSon.ordinal()’ on a null object reference
case的其实是:SeaSon.Sping.ordinal(),所以要做对象的空值判断。
86.在switch的default代码块中增加AssertionError错误
因为枚举类型和case没有强制关系,如果后续增加了一个,没有case,就会导致switch漏掉这个枚举项。
87.枚举使用valueOf前必须进行校验
否则会抛出异常
List<String> mList = Arrays.asList("Sping", "sss");
for (int i = 0; i < mList.size(); i++) {
SeaSon sea = SeaSon.valueOf(mList.get(i));
if (sea == null) {
Log.i("clp", "没有此枚举值");
} else {
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}
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java.lang.IllegalArgumentException: sss is not a constant in com.cp.demo.java.SeaSon
两种方案:
1.捕获异常
List<String> mList = Arrays.asList("Sping", "sss");
for (int i = 0; i < mList.size(); i++) {
try {
SeaSon sea = SeaSon.valueOf(mList.get(i));
Log.i("clp", "有值");
} catch (IllegalArgumentException e) {
Log.i("clp", "没有此枚举值");
}
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04-19 11:35:20.148 13538-13538/com.example.demo I/clp: 有值
04-19 11:35:20.148 13538-13538/com.example.demo I/clp: 没有此枚举值
2.拓展枚举类
public static boolean contains(String name) {
for (SeaSon sen : values()) {
if (sen.name().equals(name)) {
return true;
}
}
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List<String> mList = Arrays.asList("Sping", "sss");
for (int i = 0; i < mList.size(); i++) {
boolean sea = SeaSon.contains(mList.get(i));
if (sea) {
Log.i("clp", "有值");
} else {
Log.i("clp", "没有此枚举值");
}
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88.用枚举实现工厂方法模式更简洁
1.非静态方法实现。
public interface Car {
public void drive();
}
public class FortCar implements Car {
@Override
public void drive() {
Log.i("clp", "fort drive");
}
}
public class BuickCar implements Car {
@Override
public void drive() {
Log.i("clp", "buick drive");
}
}
public enum CarFactory {
FortCar, BuickCar;
public Car create() {
switch (this) {
case FortCar:
return new FortCar();
case BuickCar:
return new BuickCar();
default:
Log.i("clp", "无效参数");
}
return null;
}
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04-19 11:55:34.988 1940-1940/com.example.demo I/clp: fort drive
2.通过抽象方法生成
public enum CarFactory {
FortCar {
@Override
public Car create() {
return new FortCar();
}
}, BuickCar {
@Override
public Car create() {
return new BuickCar();
}
};
public abstract Car create();
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89.枚举项的数量限制的64个以内
long e = -1L >>> -65;//value=1
long e = -1L >>> -1;//value=1
long e = -1L >>> 63;//value=1
long e = -1L >>> 1;//9223372036854775807
long e = -1L >>> 62;//value=3
int e = -1 >>> 31;//value=1
int e = -1 >>> 1;//2147483647- 1
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小于等于64和大于64处理的机制是不一样的。
Enum[] universe = getUniverse(elementType);
if (universe == null)
throw new ClassCastException(elementType + " not an enum");
if (universe.length <= 64)
return new RegularEnumSet<>(elementType, universe);
else
return new JumboEnumSet<>(elementType, universe);
RegularEnumSet:
void addAll() {
if (universe.length != 0)
elements = -1L >>> -universe.length;
}
JumboEnumSet:
void addAll() {
for (int i = 0; i < elements.length; i++)
elements[i] = -1;
elements[elements.length - 1] >>>= -universe.length;
size = universe.length;
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所以内部是以64位拆分进行分组。
90.小心注解继承
91.枚举和注解结合使用威力很大
92.注意@Overrig不同版本的区别
如果是Java1.6版本的程序移植到1.5版本环境中,就需要删除实现接口方法上的@Override注解
泛型和反射
93.Java的泛型是类型擦除的
编译期:源码->class文件的过程
运行期:在JVM中运行的过程
public void initList(List<Integer> mList) {
}
public void initList(List<String> mList) {
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按照上面这种方式写,报错。
initList(List)’ clashes with ‘initList(List)’; both methods have same erasure
List<String> mList = new ArrayList<String>();
List<Integer> mIList = new ArrayList<Integer>();
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04-25 15:49:13.356 2760-2760/old.pkg.com.myapplicati I/clp: is equals=true
他们擦除后的类型都是List
Java泛型-类型擦除:
94.不能初始化泛型参数和数组
T t = new T();//报错
T[] mTArray = new T[];//报错
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以上3个写法,在AS上面都报错,需要在运行期指定T类型。
95.强制声明泛型的实际类型
List<Integer> mList = CldCalMiniUtil.asList();//正确
List<Integer> mList = CldCalMiniUtil.<Integer>asList();//正确
List<Number> mList2 = CldCalMiniUtil.asList(1, 2.2);//报错
List<Number> mList2 = CldCalMiniUtil.<Number>asList(1, 2.2);//正确--这里使用了强制声明
