OSS-Fuzz-AIxCC: AIxCC AFC Competition fork of OSS-Fuzz (v1.2.0)
Changes in v1.2.0:
base-builder-jvmhas been updated to use the lastest aixcc-jazzer ref, adjusting the OsCmdInjection sanitizer.- This adjustment adds some safety measures around OsCmdInjection to reduce risk and reduce potential unintentional crash-state explosion when dealing with such vulnerabilities.
helper.pycommandsbuild_image,build_fuzzers, andshellhave added optional flags to control docker image tags.- Adds the flag
--docker_image_tag TAGto the commands. This is entirely optional and backwards compatible, but can allow control over the project-image docker tag, enabling easier parallel processing.
- Adds the flag
helper.py reproducehas an added optional flag to reproduce with docker running in non-privileged mode.helper.py reproducehas an added optional flag to timeout when the reproduce subprocess hangs.- This enables crash detection to handle cases where sanitizers are hit, yet for various reasons the
reproduce subprocess does not resolve and hangs indefinitely. If
timeoutis set, when the reproduce subprocess does not resolve withintimeoutseconds, reproduce will end the subprocess and return with code 124.
- This enables crash detection to handle cases where sanitizers are hit, yet for various reasons the
reproduce subprocess does not resolve and hangs indefinitely. If
Changes in v1.1.0:
- The state of oss-fuzz-aixcc has been synced with upstream changes at 162f2ab818f5992b66486a4d06cb0e3c88c37773.
helper.py build_fuzzerswith local source now matches behavior of non-local source, keeping the build state clean between runs.base-imagehas been updated to default its locale to C.UTF-8 instead of POSIX.
This is a competition fork of oss-fuzz which is guaranteed to be compatible with the AFC challenges. This fork is designed to remain fully backwards compatible with the public/upstream oss-fuzz, and thus competition challenges will reflect realistic real-world repositories.
Other than base-image changes, the projects files have not been touched in this repository. The list of projects in the projects directory does not reflect which projects will be used in any AFC round.
Competitors are recommended to test their CRS against public repositories using this competition fork. Competitors are recommended to view the [example-crs-architecture] repository's example-challenge-evaluation scripts to see details on how this fuzz tooling is used during competition.
Example basic usage of the helper script is below. Note: When working with local source, you must pass the local source repository into the scripts as detailed below.
# Build the project image and pull AFC base images
infra/helper.py build_image --pull <project_name>
# Build the fuzzer harnesses for the project, using local source
infra/helper.py build_fuzzers --clean --sanitizer <sanitizer> --engine <engine> <project_name> <path-to-local-src>
# Check all fuzzer harnesses for build
infra/helper.py check_build --sanitizer <sanitizer> --engine <engine> <project_name>
# Reproduce the testcase
# optionally use --propagate_exit_codes
infra/helper.py reproduce <project_name> <harness_name> <path-to-data-blob>
OSS-Fuzz: Continuous Fuzzing for Open Source Software
Fuzz testing is a well-known technique for uncovering programming errors in software. Many of these detectable errors, like buffer overflow, can have serious security implications. Google has found thousands of security vulnerabilities and stability bugs by deploying guided in-process fuzzing of Chrome components, and we now want to share that service with the open source community.
In cooperation with the Core Infrastructure Initiative and the OpenSSF, OSS-Fuzz aims to make common open source software more secure and stable by combining modern fuzzing techniques with scalable, distributed execution. Projects that do not qualify for OSS-Fuzz (e.g. closed source) can run their own instances of ClusterFuzz or ClusterFuzzLite.
We support the libFuzzer, AFL++, and Honggfuzz fuzzing engines in combination with Sanitizers, as well as ClusterFuzz, a distributed fuzzer execution environment and reporting tool.
Currently, OSS-Fuzz supports C/C++, Rust, Go, Python, Java/JVM, and JavaScript code. Other languages supported by LLVM may work too. OSS-Fuzz supports fuzzing x86_64 and i386 builds.
Overview
Documentation
Read our detailed documentation to learn how to use OSS-Fuzz.
Trophies
As of August 2023, OSS-Fuzz has helped identify and fix over 10,000 vulnerabilities and 36,000 bugs across 1,000 projects.
Blog posts
- 2023-08-16 - AI-Powered Fuzzing: Breaking the Bug Hunting Barrier
- 2023-02-01 - Taking the next step: OSS-Fuzz in 2023
- 2022-09-08 - Fuzzing beyond memory corruption: Finding broader classes of vulnerabilities automatically
- 2021-12-16 - Improving OSS-Fuzz and Jazzer to catch Log4Shell
- 2021-03-10 - Fuzzing Java in OSS-Fuzz
- 2020-12-07 - Improving open source security during the Google summer internship program
- 2020-10-09 - Fuzzing internships for Open Source Software
- 2018-11-06 - A New Chapter for OSS-Fuzz
- 2017-05-08 - OSS-Fuzz: Five months later, and rewarding projects
- 2016-12-01 - Announcing OSS-Fuzz: Continuous fuzzing for open source software