A tool for tracing use of the JNI in Android apps
A Frida module to trace use of the JNI API in Android apps.
Native libraries contained within Android Apps often make use of the JNI API to
utilize the Android Runtime. Tracking those calls through
manual reverse engineering can be a slow and painful process.
as a dynamic analysis tracing tool similar to frida-trace or strace but for
The easiest way to get running with
jnitrace is to install using pip:
pip install jnitrace
- arm, arm64, x86, or x64 Android device
- Frida installed on the Android device
- Frida support > 12
- Linux, Mac, or Windows Host with Python 3 and pip
After a pip install it is easy to run
jnitrace -l libnative-lib.so -b accurate -d -p com.example.myapplication
jnitrace requires a minimum of two parameters to run a trace:
-l- is used to specify the libraries to trace. This can be a list of libraries or
*if you want to trace all libraries.
-p- is used to specify the process to trace. It needs to be given in the form of an Android package.
Optional arguments are listed below:
-i <spawn|attach>- is used to specify the Frida attach mechanism to use. It can either be spawn or attach. Spawn is the default option.
-b <fuzzy|accurate>- is used to control backtrace output. Fuzzy will use the Frida FUZZY Backtracer, whereas accurate will use the Frida ACCURATE Backtracer.
-d- is used to control whether the trace output should show any additional data for the method arguments. This will include buffers passed to a function or strings.
Remember frida-server must be running before running
jnitrace. If the default
instructions for installing frida have been followed, the following command will start the server ready for
adb shell /data/local/tmp/frida-server
jnitrace from source requires that
node first be installed.
node, the following commands need to be run:
npm install frida-compile
frida-compile main.js -o ../build/jnitrace.js -w
frida-compile will run in the background compiling the source to the output
jnitrace.js. By using the
-w command with
changes to the source file trigger
frida-compile to update the output.
jnitrace.py loads from build/jnitrace.js by default, so no other
changes are required to run the updates.
Like frida-trace, output is colored based on the API call thread.
Immediately below the thread ID in the display is the JNI API method name.
Method names match exactly with those seen in the
jni.h header file.
Subsequent lines contain a list of arguments indicated by a
|-. After the
|- characters are the argument type followed by the argument value. For
jmethods, jfields and jclasses the Java type will be displayed in curly
braces. This is dependent on
jnitrace having seen the original method,
field, or class lookup. For any methods passing buffers,
extract the buffers from the arguments and display it as a hexdump below the
Return values are displayed at the bottom of the list as
|= and will not
be present for void methods.
If the backtrace is enabled, a Frida backtrace will be displayed below the method call. Please be aware, as per the Frida docs, the fuzzy backtrace is not always accurate and the accurate backtrace may provide limited results.
The goal of this project was to create a tool that could trace JNI API calls efficiently for most Android applications.
Unfortunately, the simplest approach of attaching to all function pointers in
the JNIEnv structure overloads the application. It causes a crash based on the
sheer number of function calls made by other unrelated libraries also using
the same functions in
To deal with that performance barrier,
jnitrace creates a shadow JNIEnv that
it can supply to libraries it wants to track. That JNIEnv contains a series
of function trampolines that bounce the JNI API calls through some custom
Frida NativeCallbacks to track the input and output of those functions.
The generic Frida API does a great job of providing a platform to build those function trampolines with minimal effort. However, that simple approach does not work for all of the JNIEnv API. The key problem with tracing all of the methods is the use of variadic arguments in the API. It is not possible to create the NativeCallback for these functions ahead of time, as it is not known beforehand all the different combinations of Java methods that will be called.
The solution is to monitor the process for calls to
GetStaticMethodID, used to look up method identifiers from the runtime.
jnitrace sees a
jmethodID lookup it has a known mapping of
ID to method signature. Later, when a JNI Java method call is made, an initial
NativeCallback is used to extract the method ID in the call. That method
signature is then parsed to extract the method arguments. Once
extracted the arguments in the method, it can dynamically create a
NativeCallback for that method. That new NativeCallback is returned and a
little bit of architecture specific shellcode deals with setting up the stack
and registers to allow that call to run successfully. Those NativeCallbacks
for specific methods are cached to allow the callback to run more efficiently
if a method if called multiple times.
The other place where a simple NativeCallback is not sufficient for
extracting the arguments from a method call, is for calls using a
va_args pointer as the final argument. In this case
jnitrace uses some code
to extract the arguments from the pointer provided. Again this is architecture
All data traced in these function calls is sent to the python console application that formats and displays it to the user.
Most testing of this tool has been done on an Android x86_64 emulator running Marshmallow. Any issues experienced running on another device, please file an issue, but also, if possible, it is recommended to try running on a similar emulator.
For any issues experienced running
jnitrace please create an issue on
GitHub. Please include the following information in the filed issue:
- Device you were running on
- Version of Frida you were using
- Application you were running against
- Any displayed error messages
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