通过反序列化生成对象的过程主要由以下几个步骤:
1、创建一个对象输入流,它可以包装一个其他类型的源输入流,如文件输入流;
2、 通过对象输入流的readObject()方法读取对象。
其中正是readObject方法返回了一个对象,这个对象就是根据序列化生成的文件而创建的对象,所以反序列化如何创建对象关键就在于readObject方法的实现,那就来探析一下它的实现,它的源码如下:
public final Object readObject() throws IOException, ClassNotFoundException { if (enableOverride) { return readObjectOverride(); } // if nested read, passHandle contains handle of enclosing object int outerHandle = passHandle; try { Object obj = readObject0(false); handles.markDependency(outerHandle, passHandle); ClassNotFoundException ex = handles.lookupException(passHandle); if (ex != null) { throw ex; } if (depth == 0) { vlist.doCallbacks(); } return obj; } finally { passHandle = outerHandle; if (closed && depth == 0) { clear(); } } }
由于该方法返回值就是一个Object类型,所以我们重点看实际返回的obj这个对象是怎么创建,可以看出它是通过另一个方法创建,继续查看readObject0方法的源码:
private Object readObject0(boolean unshared) throws IOException { boolean oldMode = bin.getBlockDataMode(); if (oldMode) { int remain = bin.currentBlockRemaining(); if (remain > 0) { throw new OptionalDataException(remain); } else if (defaultDataEnd) { /* * Fix for 4360508: stream is currently at the end of a field * value block written via default serialization; since there * is no terminating TC_ENDBLOCKDATA tag, simulate * end-of-custom-data behavior explicitly. */ throw new OptionalDataException(true); } bin.setBlockDataMode(false); } byte tc; while ((tc = bin.peekByte()) == TC_RESET) { bin.readByte(); handleReset(); } depth++; totalObjectRefs++; try { switch (tc) { case TC_NULL: return readNull(); case TC_REFERENCE: return readHandle(unshared); case TC_CLASS: return readClass(unshared); case TC_CLASSDESC: case TC_PROXYCLASSDESC: return readClassDesc(unshared); case TC_STRING: case TC_LONGSTRING: return checkResolve(readString(unshared)); case TC_ARRAY: return checkResolve(readArray(unshared)); case TC_ENUM: return checkResolve(readEnum(unshared)); case TC_OBJECT: return checkResolve(readOrdinaryObject(unshared)); case TC_EXCEPTION: IOException ex = readFatalException(); throw new WriteAbortedException("writing aborted", ex); case TC_BLOCKDATA: case TC_BLOCKDATALONG: if (oldMode) { bin.setBlockDataMode(true); bin.peek(); // force header read throw new OptionalDataException( bin.currentBlockRemaining()); } else { throw new StreamCorruptedException( "unexpected block data"); } case TC_ENDBLOCKDATA: if (oldMode) { throw new OptionalDataException(true); } else { throw new StreamCorruptedException( "unexpected end of block data"); } default: throw new StreamCorruptedException( String.format("invalid type code: %02X", tc)); } } finally { depth--; bin.setBlockDataMode(oldMode); } }
这个方法是readObject方法的底层实现,由于它的返回值类型也是对象类型,所以我们重点看返回的实际对象是哪个,通过观察和debug发现,开关语句执行时下面这行代码,checkResolve方法接收的参数类型是对象类型,返回值类型也是对象类型。
case TC_OBJECT: return checkResolve(readOrdinaryObject(unshared));
那我们来查看readOrdinaryObject对象:
private Object readOrdinaryObject(boolean unshared) throws IOException { if (bin.readByte() != TC_OBJECT) { throw new InternalError(); } ObjectStreamClass desc = readClassDesc(false); desc.checkDeserialize(); Class<?> cl = desc.forClass(); if (cl == String.class || cl == Class.class || cl == ObjectStreamClass.class) { throw new InvalidClassException("invalid class descriptor"); } Object obj; try { obj = desc.isInstantiable() ? desc.newInstance() : null; } catch (Exception ex) { throw (IOException) new InvalidClassException( desc.forClass().getName(), "unable to create instance").initCause(ex); } passHandle = handles.assign(unshared ? unsharedMarker : obj); ClassNotFoundException resolveEx = desc.getResolveException(); if (resolveEx != null) { handles.markException(passHandle, resolveEx); } if (desc.isExternalizable()) { readExternalData((Externalizable) obj, desc); } else { readSerialData(obj, desc); } handles.finish(passHandle); if (obj != null && handles.lookupException(passHandle) == null && desc.hasReadResolveMethod()) { Object rep = desc.invokeReadResolve(obj); if (unshared && rep.getClass().isArray()) { rep = cloneArray(rep); } if (rep != obj) { // Filter the replacement object if (rep != null) { if (rep.getClass().isArray()) { filterCheck(rep.getClass(), Array.getLength(rep)); } else { filterCheck(rep.getClass(), -1); } } handles.setObject(passHandle, obj = rep); } } return obj; }
此处我们重点看的还应该是产生实际返回值的地方,也就是这块:
obj = desc.isInstantiable() ? desc.newInstance() : null;
所以这就是为什么通过反序列化创建对象的时候,并不会执行被序列化对象的构造方法。
对于实现Serializable接口的类,并不要求该类具有一个无参的构造方法, 因为在反序列化的过程中实际上是去其继承树上找到一个没有实现Serializable接口的父类(最终会找到Object),然后构造该类的对象,再逐层往下的去设置各个可以反序列化的属性(也就是没有被transient修饰的非静态属性)。
我们通过一个具体的案例就可以看出来:
import java.io.Serializable; public class Users implements Serializable { private String username; private int age; private String sex; public Users() { System.out.println("调用了构造方法"); } /*
get和set方法
*/
…………
}
创建一个测试类:
import java.io.*; public class TestUsers { public static void main(String[] args) { try { System.out.println("开始序列化。。。。。"); Users users = new Users(); users.setUsername("fym"); users.setAge(23); users.setSex("nan"); FileOutputStream fs = new FileOutputStream("users.ser"); ObjectOutputStream os = new ObjectOutputStream(fs); os.writeObject(users); os.close(); fs.close(); System.out.println("开始反序列化。。。。。"); FileInputStream fileInputStream = new FileInputStream("users.ser"); ObjectInputStream objectInputStream = new ObjectInputStream(fileInputStream); Users o = (Users)objectInputStream.readObject(); System.out.println(o); fileInputStream.close(); objectInputStream.close(); } catch (Exception e) { e.printStackTrace(); } } }
输出结果:
开始序列化。。。。。
调用了构造方法
开始反序列化。。。。。
Users{username='fym', age=23, sex='nan'}
我们将其改造一下,让User类继承一个没有序列化的父类:
class ParentsUser{ public ParentsUser(){ System.out.println("调用了父类构造方法"); } } public class Users extends ParentsUser implements Serializable { …… }
再一次执行上面的测试类,输出结果如下:
开始序列化。。。。。
调用了父类构造方法
调用了构造方法
开始反序列化。。。。。
调用了父类构造方法
Users{username='fym', age=23, sex='nan'}
发现,反序列化创建对象的时候,果然调用了离User类最近的没有序列化的超类的无参构造函数。