With this project, we aim to create a management toolchain for fuzzing. Unlike other toolchains and frameworks, we want to be modular in such a way that you can use those parts of FuzzManager that seem interesting to you without forcing a process upon you that does not fit your requirements.
CrashManager is the part of FuzzManager responsible for managing crash results submitted to the server. The main features are:
-
Store crash information gathered from various sources. See FTB.
-
Bucket crashes using flexible, human-readable signatures that can match a large number of symptoms of a crash, are proposed by the server but can be altered and tuned by the user. The server also includes semi-automatic optimization of signatures that helps you group duplicates into one bucket.
-
Report bugs directly to a bug tracker using the best testcase available. We support only Bugzilla as a bugtracker right now, but again the API is designed to be extendable.
FTB (Fuzzing Tool Box) is the underlying library that contains classes for parsing crash output from various tools (CrashInfo), bucketing crashes (CrashSignature), and parsing assertions (AssertionHelper). This can be used locally without having a running FuzzManager server instance to support crash logging and bucketing. FTB already supports a variety of tools like GDB, ASan and Minidumps but can be extended to support any form of crash information you would like.
Collector is a command-line utility or a Python class that can be used to communicate with a CrashManager server. Collector provides an easy client interface that allows your clients to submit crashes as well as download and match existing signatures to avoid reporting frequent issues repeatedly.
EC2SpotManager is another (optional) part of FuzzManager that allows you to manage large pools of spot instances in the Amazon Cloud. It supports hierarchical configurations to avoid configuration duplication and ensures that your instances are always running in the desired quantity as well as in the cheapest zone.
Please send any questions regarding the project to choller-at-mozilla-dot-com.
The client portion of FuzzManager (FTB and Collector) can be installed with
pip install FuzzManager
. This is all you need if you just need to talk to a
FuzzManager server instance or use FTB locally.
The server part of FuzzManager is a Django application. Please note that it requires the full repository to be checked out, not just the server directory.
Dependency constraints are listed in requirements.txt. You can ask pip to respect these contraints by installing FuzzManager using:
pip install -c requirements.txt '.[server]'
A Redis server is also required for EC2SpotManager, and can be installed on a Debian-based Linux with:
sudo apt-get install redis-server
You can set the server up just like any other Django project. The Django
configuration file is found at server/server/settings.py
. The default will
work, but for a production setup, you should at least review the database
settings.
Afterward, you should run the following commands
$ cd server
$ python manage.py migrate
$ cd frontend
$ npm install
$ npm run build
$ cd ..
Create the fuzzmanager user.
$ python manage.py create_user --username fuzzmanager --email fuzzmanager@internal.com
Get fuzzmanager authorization token
$ python manage.py get_auth_token fuzzmanager
4a253efa90f514bd89ae9a86d1dc264aa3133945
It is important that you edit FuzzManager/server/settings.py and adjust the following variables according to your needs.
ALLOWED_HOSTS = ['host']
CSRF_TRUSTED_ORIGINS = ['scheme://host']
See ALLOWED_HOSTS and CSRF_TRUSTED_ORIGINS documentation.
You may also want to increase the maximum size in bytes allowed in a request body. The default of 2.5MB may not be enough in some cases by adding the following variable.
DATA_UPLOAD_MAX_MEMORY_SIZE = <YOUR VALUE HERE>
See DATA_UPLOAD_MAX_MEMORY_SIZE
For local testing, you can use the builtin debug webserver:
python manage.py runserver
For a production setup, see the docker-compose.yml for an example of the processes required.
Use the following command to get an authentication token for a Django user:
python manage.py get_auth_token username
A docker image is available by building the Dockerfile
.
You can easily run a local server (and MySQL database server) by using docker-composer:
docker compose up
On a first run, you must execute the database migrations:
docker compose exec backend python manage.py migrate
And create a superuser to be able to log in on http://localhost:8000
docker compose exec backend python manage.py create_user --username user --email user@example.com
docker compose exec backend python manage.py changepassword user
By default, the docker image uses Django settings set in Python module server.settings_docker
, with the following settings:
DEBUG = False
to enable production modeALLOWED_HOSTS = ["localhost", ]
to allow development usage onhttp://localhost:8000
You can customize settings by mounting a file from your host into the container:
volumes:
- "./settings_docker.py:/src/server/server/settings_docker.py:ro"
In order to talk to FuzzManager, your fuzzer should use the client interface provided, called the Collector. It can be used as a standalone command line tool or directly as a Python class in case your fuzzer is written in Python.
We'll first describe how to use the class interface directly from Python. If you want to use the command line interface instead, I still suggest that you read on because the command line interface is very similar to the class interface in terms of functionality and configuration.
For simple cases where you can just (re)run a command with a testcase that produces a crash, we also provide an easy report class that runs your command and figures out all the crash information on its own. You will find the description of this mode at the end of this section as it still requires configuration files to be setup properly, but tl;dr, it can be as easy as:
$ python Collector.py --autosubmit mybadprogram --someopt yourtest
And you're done submitting everything, crash information as well as program information.
The Collector constructor takes various arguments that are required for later operations. These arguments include a directory for signatures, server data such as hostname, port, etc. as well as authentication data and a client name. However, the preferred way to pass these options is not through the constructor, but through a configuration file. The constructor will try to read the configuration file located at ~/.fuzzmanagerconf and use any parameters from there if it hasn't been explicitly specified in the constructor call. This makes deployment very easy and saves time. An example configuration could look like this:
[Main]
sigdir = /home/example/signatures
serverhost = 127.0.0.1
serverport = 8000
serverproto = http
serverauthtoken = 4a253efa90f514bd89ae9a86d1dc264aa3133945
With this file present and readable, instantiating the Collector doesn't require any further arguments.
Several methods of the collector work with the CrashInfo
class. This class stores all the necessary data about a crash. In order to get a CrashInfo instance, you need:
- A variable containing the stdout output of your program
- A variable containing the stderr output of your program
- A variable containing crash information as outputted by GDB or AddressSanitizer
- A ProgramConfiguration instance
The first three sets of data are typically already available in a fuzzer. Note that for GDB traces, the trace should contain first the stack trace, then a dump of all registers and then a dissassembly of the program counter (see also the FTB/Running/AutoRunner.py file which demonstrates how to output all information properly for FuzzManager).
The last thing required is the ProgramConfiguration
. This class is largely a container class storing various properties of the program, e.g. product name, the platform, version and runtime options. Instead of instantiating the class and providing all the data manually, it is again recommended to use the configuration file support. Assuming your binary is located at /home/example/foo then creating a configuration file at /home/example/foo.fuzzmanagerconf with the necessary data is recommended. Such a file could look like this:
[Main]
platform = x86
product = mozilla-central
product_version = 70de2960aa87
os = linux
[Metadata]
pathPrefix = /srv/repos/mozilla-central/
buildFlags = --enable-optimize --enable-posix-nspr-emulation --enable-valgrind --enable-gczeal --target=i686-pc-linux-gnu --disable-tests --enable-debug
Once this file is present, you can call ProgramConfiguration.fromBinary
with your binary path and the configuration will be created from the file. You can add program arguments and environment variables through the provided addProgramArguments
and addEnvironmentVariables
methods afterward. Finally, call CrashInfo.fromRawCrashData
with all the described data. Here's a simple example:
# Note: This could fail and return None when the configuration is missing or throw if misconfigured
configuration = ProgramConfiguration.fromBinary(opts.binary)
configuration.addEnvironmentVariables(env)
configuration.addProgramArguments(args)
crashInfo = CrashInfo.fromRawCrashData(stdout, stderr, configuration, auxCrashData=crashdata)
Calling the refresh
method of our Collector instance will download a zipfile from the server, containing the signatures and metadata exported by the server. Once the download is complete, the Collector will first delete all signatures including their metadata from the signature directory. Then the downloaded zipfile is extracted.
The search
method is the first of a few methods requiring a crashInfo
variable. Create it as described above and the Collector will search inside the signature directory for any matching signatures. Upon match, it will return a tuple containing the filename of the signature matching as well as a metadata object corresponding to that signature.
The submit
method can be used to send a crash report to the FuzzManager server. Again the crashInfo
parameter works as described above. In addition, you can provide a file containing a test and an optional "quality" indicator of the test (the best quality is 0). The use of this quality indicator largely depends on how your fuzzer/reducer works. The server will prefer better qualities when proposing test cases for filing bugs. Finally, the method accepts an additional metadata parameter which can contain arbitrary information that is stored with the crash on the server. Note that this metadata is combined with the metadata found in the ProgramConfiguration
of the crashInfo
. When using binary configuration files, this means that the metadata supplied in that configuration file is automatically submitted with the crash to the server.
Further methods of the Collector include generate
for generating signatures locally and download
for downloading testcases from the server. Both methods work as documented in the source code and are only useful in special cases depending on the application scenario.a
If your crashes can be reproduced on the command line by just running a command with your testcase, then you can use the automated submit method (--autosubmit
in the command line client) and just pass the failing command line to the client. The client will automatically run the target program, gather crash and program configuration and submit it to the server. Of course this mode requires that both the global configuration file and the binary configuration file are present.
TBD