java常用类解析七:java异常机制、异常栈、异常处理方式、异常链、异常丢失
1、java标准异常概述
Throwable表示任何可以作为异常被抛出的类,有两个子类Error和Exception。从这两个类的源代码中可以看出,这两个类并没有添加新的方法,Throwable提供了所以方法的实现。Error表示编译时和系统错误。Exception是可以被抛出的异常类。RuntimeException继承自Exception(如NullPointerException),表示运行时异常,JVM会自动抛出.
2、自定义异常类
自定义异常类方法: 通过继承Throwable或Exception。异常类的所有实现都是基类Throwable实现的,所以构造自定义异常类完全可以参考Exception和Error类。我们只要添加上自定义异常类的构造方法就可以了
package demo.others;
/**
* 自定义异常类方法
* 1、通过继承Throwable
* 2、通过继承Exception
*
* @author Touch
*/
public class MyExceptionDemo extends Exception {
private static final long serialVersionUID = 1L;
public MyExceptionDemo() {
super();
}
public MyExceptionDemo(String message) {
super(message);
}
public MyExceptionDemo(String message, Throwable cause) {
super(message, cause);
}
public MyExceptionDemo(Throwable cause) {
super(cause);
}
}
3、异常栈及异常处理方式
可以通过try、catch来捕获异常。捕获到的异常。下面的示例演示了几种常用异常处理方式
package demo.others;
import mine.util.exception.MyException;
public class ExceptionDemo1 {
public void f() throws MyException {
throw new MyException("自定义异常");
}
public void g() throws MyException {
f();
}
public void h() throws MyException {
try {
g();
} catch (MyException e) {
//1、通过获取栈轨迹中的元素数组来显示异常抛出的轨迹
for (StackTraceElement ste : e.getStackTrace())
System.out.println(ste.getMethodName());
//2、直接将异常栈信息输出至标准错误流或标准输出流
e.printStackTrace();//输出到标准错误流
e.printStackTrace(System.err);
e.printStackTrace(System.out);
//3、将异常信息输出到文件中
//e.printStackTrace(new PrintStream("file/exception.txt"));
//4、重新抛出异常,如果直接抛出那么栈路径是完整的,如果用fillInStackTrace()
//那么将会从这个方法(当前是h()方法)作为异常发生的原点。
//throw e;
throw (MyException)e.fillInStackTrace();
}
}
public static void main(String[] args) {
try {
new ExceptionDemo1().h();
} catch (MyException e) {
// TODO Auto-generated catch block
e.printStackTrace();
}
}
}
运行结果:
f
g
h
main
mine.util.exception.MyException: 自定义异常
at demo.others.ExceptionDemo1.f(ExceptionDemo1.java:7)
at demo.others.ExceptionDemo1.g(ExceptionDemo1.java:11)
at demo.others.ExceptionDemo1.h(ExceptionDemo1.java:16)
at demo.others.ExceptionDemo1.main(ExceptionDemo1.java:35)
mine.util.exception.MyException: 自定义异常
at demo.others.ExceptionDemo1.f(ExceptionDemo1.java:7)
at demo.others.ExceptionDemo1.g(ExceptionDemo1.java:11)
at demo.others.ExceptionDemo1.h(ExceptionDemo1.java:16)
at demo.others.ExceptionDemo1.main(ExceptionDemo1.java:35)
mine.util.exception.MyException: 自定义异常
at demo.others.ExceptionDemo1.f(ExceptionDemo1.java:7)
at demo.others.ExceptionDemo1.g(ExceptionDemo1.java:11)
at demo.others.ExceptionDemo1.h(ExceptionDemo1.java:16)
at demo.others.ExceptionDemo1.main(ExceptionDemo1.java:35)
mine.util.exception.MyException: 自定义异常
at demo.others.ExceptionDemo1.h(ExceptionDemo1.java:30)
at demo.others.ExceptionDemo1.main(ExceptionDemo1.java:35)
分析上面的程序,首先main函数被调用,然后是调用h函数,再g函数、f函数,f函数抛出异常,并在h函数捕获,这时将依次从栈顶到栈底输出异常栈路径。
4、异常链
有时候我们会捕获一个异常后在抛出另一个异常,如下代码所示:
package demo.others;
import java.io.IOException;
import mine.util.exception.MyException;
public class ExceptionDemo2 {
public void f() throws MyException {
throw new MyException("自定义异常");
}
public void g() throws Exception {
try {
f();
} catch (MyException e) {
e.printStackTrace();
throw new Exception("重新抛出的异常1");
}
}
public void h() throws IOException {
try {
g();
} catch (Exception e) {
// TODO Auto-generated catch block
e.printStackTrace();
throw new IOException("重新抛出异常2");
}
}
public static void main(String[] args) {
try {
new ExceptionDemo2().h();
} catch (IOException e) {
// TODO Auto-generated catch block
e.printStackTrace();
}
}
}
运行结果:
mine.util.exception.MyException: 自定义异常
at demo.others.ExceptionDemo2.f(ExceptionDemo2.java:9)
at demo.others.ExceptionDemo2.g(ExceptionDemo2.java:14)
at demo.others.ExceptionDemo2.h(ExceptionDemo2.java:23)
at demo.others.ExceptionDemo2.main(ExceptionDemo2.java:32)
java.lang.Exception: 重新抛出的异常1
at demo.others.ExceptionDemo2.g(ExceptionDemo2.java:17)
at demo.others.ExceptionDemo2.h(ExceptionDemo2.java:23)
at demo.others.ExceptionDemo2.main(ExceptionDemo2.java:32)
java.io.IOException: 重新抛出异常2
at demo.others.ExceptionDemo2.h(ExceptionDemo2.java:27)
at demo.others.ExceptionDemo2.main(ExceptionDemo2.java:32)
从结果中我们可以看出,异常栈变小了。也就是说丢失了最原始的异常信息。怎样保存最原始的异常信息呢?Throwable类中有个Throwable cause属性,表示原始异常。通过接收cause参数的构造器可以把原始异常传递给新异常,或者通过initCause()方法。如下示例:
package demo.others;
import java.io.IOException;
import mine.util.exception.MyException;
public class ExceptionDemo2 {
public void f() throws MyException {
throw new MyException("自定义异常");
}
public void g() throws Exception {
try {
f();
} catch (MyException e) {
e.printStackTrace();
throw new Exception("重新抛出的异常1",e);
}
}
public void h() throws IOException {
try {
g();
} catch (Exception e) {
// TODO Auto-generated catch block
e.printStackTrace();
IOException io=new IOException("重新抛出异常2");
io.initCause(e);
throw io;
}
}
public static void main(String[] args) {
try {
new ExceptionDemo2().h();
} catch (IOException e) {
// TODO Auto-generated catch block
e.printStackTrace();
}
}
}
结果:
mine.util.exception.MyException: 自定义异常
at demo.others.ExceptionDemo2.f(ExceptionDemo2.java:9)
at demo.others.ExceptionDemo2.g(ExceptionDemo2.java:14)
at demo.others.ExceptionDemo2.h(ExceptionDemo2.java:23)
at demo.others.ExceptionDemo2.main(ExceptionDemo2.java:34)
java.lang.Exception: 重新抛出的异常1
at demo.others.ExceptionDemo2.g(ExceptionDemo2.java:17)
at demo.others.ExceptionDemo2.h(ExceptionDemo2.java:23)
at demo.others.ExceptionDemo2.main(ExceptionDemo2.java:34)
Caused by: mine.util.exception.MyException: 自定义异常
at demo.others.ExceptionDemo2.f(ExceptionDemo2.java:9)
at demo.others.ExceptionDemo2.g(ExceptionDemo2.java:14)
... 2 more
java.io.IOException: 重新抛出异常2
at demo.others.ExceptionDemo2.h(ExceptionDemo2.java:27)
at demo.others.ExceptionDemo2.main(ExceptionDemo2.java:34)
Caused by: java.lang.Exception: 重新抛出的异常1
at demo.others.ExceptionDemo2.g(ExceptionDemo2.java:17)
at demo.others.ExceptionDemo2.h(ExceptionDemo2.java:23)
... 1 more
Caused by: mine.util.exception.MyException: 自定义异常
at demo.others.ExceptionDemo2.f(ExceptionDemo2.java:9)
at demo.others.ExceptionDemo2.g(ExceptionDemo2.java:14)
... 2 more
从结果中看出当获取到“重新抛出异常2的时候,同时可以输出原始异常“重新抛出的异常1“和原始异常”自定义异常,这就是异常链。
5、finally的使用
finally子句总是执行的,通常用来做一些清理工作,如关闭文件,关闭连接等
下面举几个finally的例子:
// 读取指定路径文本文件
public static String read(String filePath) {
StringBuilder str = new StringBuilder();
BufferedReader in = null;
try {
in = new BufferedReader(new FileReader(filePath));
String s;
try {
while ((s = in.readLine()) != null)
str.append(s + '\n');
} finally {
in.close();
}
} catch (IOException e) {
// TODO Auto-generated catch block
e.printStackTrace();
}
return str.toString();
}分析:如果调用in = new BufferedReader(new FileReader(filePath));时发生异常,这时是一个文件路径不存在的异常,也就是说并没有打开文件,这时将会直接跳到catch块,而不会执行try...finally块(并不是finally子句)里面的语句in.close();此时不需要关闭文件。
再看一个例子,会导致异常的丢失
package demo.others;
import mine.util.exception.MyException;
public class ExceptionDemo3 {
public void f() throws MyException {
throw new MyException("异常1");
}
public void g() throws MyException {
throw new MyException("异常2");
}
public static void main(String[] args) {
try {
ExceptionDemo3 ex = new ExceptionDemo3();
try {
ex.f();
} finally {
ex.g();//此时捕获g方法抛出的异常,f方法抛出的异常丢失了
}
} catch (MyException e) {
System.out.println(e);
}
}
}
结果:mine.util.exception.MyException: 异常2
此时异常1就丢失了
或者这样写:
package demo.others;
import mine.util.exception.MyException;
public class ExceptionDemo3 {
public void g() throws MyException {
throw new MyException("异常2");
}
public static void main(String[] args) {
ExceptionDemo3 ex = new ExceptionDemo3();
try {
ex.g();
} finally {
//直接return会丢失所以抛出的异常
return;
}
}
}
6、异常的限制
(1)当覆盖方法时,只能抛出在基类方法的异常说明里列出的那些异常,有些基类的方法声明抛出异常其实并没有抛出异常,这是因为可能在其子类的覆盖方法中会抛出异常
(2)构造器可以抛出任何异常而不必理会基类构造器所抛出的异常,派生类构造器异常说明必须包含基类构造器异常说明,因为构造派生类对象时会调用基类构造器。此外,派生类构造器不能捕获基类构造器抛出的异常。