- Coverage-guided fuzz testing process
- Supported fuzzing engines and languages
- Confirm status of coverage-guided fuzz testing
- Enable coverage-guided fuzz testing
- Output
- Corpus registry
- Coverage-guided fuzz testing report
- Duration of coverage-guided fuzz testing
- FIPS-enabled binary
- Offline environment
- Interacting with the vulnerabilities
- Troubleshooting
Coverage-guided fuzz testing
Coverage-guided fuzz testing sends random inputs to an instrumented version of your application in an effort to cause unexpected behavior. Such behavior indicates a bug that you should address. GitLab allows you to add coverage-guided fuzz testing to your pipelines. This helps you discover bugs and potential security issues that other QA processes may miss.
We recommend that you use fuzz testing in addition to the other security scanners in GitLab Secure and your own test processes. If you’re using GitLab CI/CD, you can run your coverage-guided fuzz testing as part your CI/CD workflow.
For an overview, see Coverage Fuzzing.
Coverage-guided fuzz testing process
The fuzz testing process:
- Compiles the target application.
- Runs the instrumented application, using the
gitlab-cov-fuzz
tool. - Parses and analyzes the exception information output by the fuzzer.
- Downloads the corpus from either:
- The previous pipelines.
- If
COVFUZZ_USE_REGISTRY
is set totrue
, the corpus registry.
- Downloads crash events from previous pipeline.
- Outputs the parsed crash events and data to the
gl-coverage-fuzzing-report.json
file. - Updates the corpus, either:
- In the job’s pipeline.
- If
COVFUZZ_USE_REGISTRY
is set totrue
, in the corpus registry.
The results of the coverage-guided fuzz testing are available in the CI/CD pipeline.
Supported fuzzing engines and languages
You can use the following fuzzing engines to test the specified languages.
Language | Fuzzing Engine | Example |
---|---|---|
C/C++ | libFuzzer | c-cpp-example |
Go | go-fuzz (libFuzzer support) | go-fuzzing-example |
Swift | libFuzzer | swift-fuzzing-example |
Rust | cargo-fuzz (libFuzzer support) | rust-fuzzing-example |
Java (Maven only)1 | Javafuzz (recommended) | javafuzz-fuzzing-example |
Java | JQF (not preferred) | jqf-fuzzing-example |
JavaScript |
jsfuzz
|
jsfuzz-fuzzing-example |
Python |
pythonfuzz
|
pythonfuzz-fuzzing-example |
AFL (any language that works on top of AFL) | AFL | afl-fuzzing-example |
- Support for Gradle is planned in issue 409764.
Confirm status of coverage-guided fuzz testing
To confirm the status of coverage-guided fuzz testing:
- On the left sidebar, select Search or go to and find your project.
- Select Secure > Security configuration.
- In the Coverage Fuzzing section the status is:
- Not configured
- Enabled
- A prompt to upgrade to GitLab Ultimate.
Enable coverage-guided fuzz testing
To enable coverage-guided fuzz testing, edit .gitlab-ci.yml
:
-
Add the
fuzz
stage to the list of stages. -
If your application is not written in Go, provide a Docker image using the matching fuzzing engine. For example:
image: python:latest
-
Include the
Coverage-Fuzzing.gitlab-ci.yml
template provided as part of your GitLab installation. -
Customize the
my_fuzz_target
job to meet your requirements.
Example extract of coverage-guided fuzzing configuration
stages:
- fuzz
include:
- template: Coverage-Fuzzing.gitlab-ci.yml
my_fuzz_target:
extends: .fuzz_base
script:
# Build your fuzz target binary in these steps, then run it with gitlab-cov-fuzz
# See our example repos for how you could do this with any of our supported languages
- ./gitlab-cov-fuzz run --regression=$REGRESSION -- <your fuzz target>
The Coverage-Fuzzing
template includes the hidden job
.fuzz_base
, which you must extend for each of your fuzzing
targets. Each fuzzing target must have a separate job. For example, the
go-fuzzing-example project
contains one job that extends .fuzz_base
for its single fuzzing target.
The hidden job .fuzz_base
uses several YAML keys that you must not override in your own
job. If you include these keys in your own job, you must copy their original content:
-
before_script
-
artifacts
-
rules
Available CI/CD variables
Use the following variables to configure coverage-guided fuzz testing in your CI/CD pipeline.
CI/CD variable | Description |
---|---|
COVFUZZ_ADDITIONAL_ARGS
|
Arguments passed to gitlab-cov-fuzz . Used to customize the behavior of the underlying fuzzing engine. Read the fuzzing engine’s documentation for a complete list of arguments.
|
COVFUZZ_BRANCH
|
The branch on which long-running fuzzing jobs are to be run. On all other branches, only fuzzing regression tests are run. Default: Repository’s default branch. |
COVFUZZ_SEED_CORPUS
|
Path to a seed corpus directory. Default: empty. |
COVFUZZ_URL_PREFIX
|
Path to the gitlab-cov-fuzz repository cloned for use with an offline environment. You should only change this value when using an offline environment. Default: https://gitlab.com/gitlab-org/security-products/analyzers/gitlab-cov-fuzz/-/raw .
|
COVFUZZ_USE_REGISTRY
|
Set to true to have the corpus stored in the GitLab corpus registry. The variables COVFUZZ_CORPUS_NAME and COVFUZZ_GITLAB_TOKEN are required if this variable is set to true . Default: false .
|
COVFUZZ_CORPUS_NAME
|
Name of the corpus to be used in the job. |
COVFUZZ_GITLAB_TOKEN
|
Environment variable configured with personal access token or project access token with API read/write access. |
Seed corpus
Files in the seed corpus must be updated manually. They are not updated or overwritten by the coverage-guide fuzz testing job.
Output
Each fuzzing step outputs these artifacts:
-
gl-coverage-fuzzing-report.json
: A report containing details of the coverage-guided fuzz testing and its results. -
artifacts.zip
: This file contains two directories:-
corpus
: Contains all test cases generated by the current and all previous jobs. -
crashes
: Contains all crash events the current job found and those not fixed in previous jobs.
-
You can download the JSON report file from the CI/CD pipelines page. For more information, see Downloading artifacts.
Corpus registry
The corpus registry is a library of corpuses. Corpuses in a project’s registry are available to all jobs in that project. A project-wide registry is a more efficient way to manage corpuses than the default option of one corpus per job.
The corpus registry uses the package registry to store the project’s corpuses. Corpuses stored in the registry are hidden to ensure data integrity.
When you download a corpus, the file is named artifacts.zip
, regardless of the filename used when
the corpus was initially uploaded. This file contains only the corpus, which is different to the
artifacts files you can download from the CI/CD pipeline. Also, a project member with a Reporter or above privilege can download the corpus using the direct download link.
View details of the corpus registry
To view details of the corpus registry:
- On the left sidebar, select Search or go to and find your project.
- Select Secure > Security configuration.
- In the Coverage Fuzzing section, select Manage corpus.
Create a corpus in the corpus registry
To create a corpus in the corpus registry, either:
- Create a corpus in a pipeline
- Upload an existing corpus file
Create a corpus in a pipeline
To create a corpus in a pipeline:
- In the
.gitlab-ci.yml
file, edit themy_fuzz_target
job. - Set the following variables:
- Set
COVFUZZ_USE_REGISTRY
totrue
. - Set
COVFUZZ_CORPUS_NAME
to name the corpus. - Set
COVFUZZ_GITLAB_TOKEN
to the value of the personal access token.
- Set
After the my_fuzz_target
job runs, the corpus is stored in the corpus registry, with the name
provided by the COVFUZZ_CORPUS_NAME
variable. The corpus is updated on every pipeline run.
Upload a corpus file
To upload an existing corpus file:
- On the left sidebar, select Search or go to and find your project.
- Select Secure > Security configuration.
- In the Coverage Fuzzing section, select Manage corpus.
- Select New corpus.
- Complete the fields.
- Select Upload file.
- Select Add.
You can now reference the corpus in the .gitlab-ci.yml
file. Ensure the value used in the
COVFUZZ_CORPUS_NAME
variable matches exactly the name given to the uploaded corpus file.
Use a corpus stored in the corpus registry
To use a corpus stored in the corpus registry, you must reference it by its name. To confirm the name of the relevant corpus, view details of the corpus registry.
Prerequisites:
- Enable coverage-guide fuzz testing in the project.
- Set the following variables in the
.gitlab-ci.yml
file:- Set
COVFUZZ_USE_REGISTRY
totrue
. - Set
COVFUZZ_CORPUS_NAME
to the name of the corpus. - Set
COVFUZZ_GITLAB_TOKEN
to the value of the personal access token.
- Set
Coverage-guided fuzz testing report
For detailed information about the gl-coverage-fuzzing-report.json
file’s format, read the
schema.
Example coverage-guided fuzzing report:
{
"version": "v1.0.8",
"regression": false,
"exit_code": -1,
"vulnerabilities": [
{
"category": "coverage_fuzzing",
"message": "Heap-buffer-overflow\nREAD 1",
"description": "Heap-buffer-overflow\nREAD 1",
"severity": "Critical",
"stacktrace_snippet": "INFO: Seed: 3415817494\nINFO: Loaded 1 modules (7 inline 8-bit counters): 7 [0x10eee2470, 0x10eee2477), \nINFO: Loaded 1 PC tables (7 PCs): 7 [0x10eee2478,0x10eee24e8), \nINFO: 5 files found in corpus\nINFO: -max_len is not provided; libFuzzer will not generate inputs larger than 4096 bytes\nINFO: seed corpus: files: 5 min: 1b max: 4b total: 14b rss: 26Mb\n#6\tINITED cov: 7 ft: 7 corp: 5/14b exec/s: 0 rss: 26Mb\n=================================================================\n==43405==ERROR: AddressSanitizer: heap-buffer-overflow on address 0x602000001573 at pc 0x00010eea205a bp 0x7ffee0d5e090 sp 0x7ffee0d5e088\nREAD of size 1 at 0x602000001573 thread T0\n #0 0x10eea2059 in FuzzMe(unsigned char const*, unsigned long) fuzz_me.cc:9\n #1 0x10eea20ba in LLVMFuzzerTestOneInput fuzz_me.cc:13\n #2 0x10eebe020 in fuzzer::Fuzzer::ExecuteCallback(unsigned char const*, unsigned long) FuzzerLoop.cpp:556\n #3 0x10eebd765 in fuzzer::Fuzzer::RunOne(unsigned char const*, unsigned long, bool, fuzzer::InputInfo*, bool*) FuzzerLoop.cpp:470\n #4 0x10eebf966 in fuzzer::Fuzzer::MutateAndTestOne() FuzzerLoop.cpp:698\n #5 0x10eec0665 in fuzzer::Fuzzer::Loop(std::__1::vector\u003cfuzzer::SizedFile, fuzzer::fuzzer_allocator\u003cfuzzer::SizedFile\u003e \u003e\u0026) FuzzerLoop.cpp:830\n #6 0x10eead0cd in fuzzer::FuzzerDriver(int*, char***, int (*)(unsigned char const*, unsigned long)) FuzzerDriver.cpp:829\n #7 0x10eedaf82 in main FuzzerMain.cpp:19\n #8 0x7fff684fecc8 in start+0x0 (libdyld.dylib:x86_64+0x1acc8)\n\n0x602000001573 is located 0 bytes to the right of 3-byte region [0x602000001570,0x602000001573)\nallocated by thread T0 here:\n #0 0x10ef92cfd in wrap__Znam+0x7d (libclang_rt.asan_osx_dynamic.dylib:x86_64+0x50cfd)\n #1 0x10eebdf31 in fuzzer::Fuzzer::ExecuteCallback(unsigned char const*, unsigned long) FuzzerLoop.cpp:541\n #2 0x10eebd765 in fuzzer::Fuzzer::RunOne(unsigned char const*, unsigned long, bool, fuzzer::InputInfo*, bool*) FuzzerLoop.cpp:470\n #3 0x10eebf966 in fuzzer::Fuzzer::MutateAndTestOne() FuzzerLoop.cpp:698\n #4 0x10eec0665 in fuzzer::Fuzzer::Loop(std::__1::vector\u003cfuzzer::SizedFile, fuzzer::fuzzer_allocator\u003cfuzzer::SizedFile\u003e \u003e\u0026) FuzzerLoop.cpp:830\n #5 0x10eead0cd in fuzzer::FuzzerDriver(int*, char***, int (*)(unsigned char const*, unsigned long)) FuzzerDriver.cpp:829\n #6 0x10eedaf82 in main FuzzerMain.cpp:19\n #7 0x7fff684fecc8 in start+0x0 (libdyld.dylib:x86_64+0x1acc8)\n\nSUMMARY: AddressSanitizer: heap-buffer-overflow fuzz_me.cc:9 in FuzzMe(unsigned char const*, unsigned long)\nShadow bytes around the buggy address:\n 0x1c0400000250: fa fa fd fa fa fa fd fa fa fa fd fa fa fa fd fa\n 0x1c0400000260: fa fa fd fa fa fa fd fa fa fa fd fa fa fa fd fa\n 0x1c0400000270: fa fa fd fa fa fa fd fa fa fa fd fa fa fa fd fa\n 0x1c0400000280: fa fa fd fa fa fa fd fa fa fa fd fa fa fa fd fa\n 0x1c0400000290: fa fa fd fa fa fa fd fa fa fa fd fa fa fa fd fa\n=\u003e0x1c04000002a0: fa fa fd fa fa fa fd fa fa fa fd fa fa fa[03]fa\n 0x1c04000002b0: fa fa fa fa fa fa fa fa fa fa fa fa fa fa fa fa\n 0x1c04000002c0: fa fa fa fa fa fa fa fa fa fa fa fa fa fa fa fa\n 0x1c04000002d0: fa fa fa fa fa fa fa fa fa fa fa fa fa fa fa fa\n 0x1c04000002e0: fa fa fa fa fa fa fa fa fa fa fa fa fa fa fa fa\n 0x1c04000002f0: fa fa fa fa fa fa fa fa fa fa fa fa fa fa fa fa\nShadow byte legend (one shadow byte represents 8 application bytes):\n Addressable: 00\n Partially addressable: 01 02 03 04 05 06 07 \n Heap left redzone: fa\n Freed heap region: fd\n Stack left redzone: f1\n Stack mid redzone: f2\n Stack right redzone: f3\n Stack after return: f5\n Stack use after scope: f8\n Global redzone: f9\n Global init order: f6\n Poisoned by user: f7\n Container overflow: fc\n Array cookie: ac\n Intra object redzone: bb\n ASan internal: fe\n Left alloca redzone: ca\n Right alloca redzone: cb\n Shadow gap: cc\n==43405==ABORTING\nMS: 1 EraseBytes-; base unit: de3a753d4f1def197604865d76dba888d6aefc71\n0x46,0x55,0x5a,\nFUZ\nartifact_prefix='./crashes/'; Test unit written to ./crashes/crash-0eb8e4ed029b774d80f2b66408203801cb982a60\nBase64: RlVa\nstat::number_of_executed_units: 122\nstat::average_exec_per_sec: 0\nstat::new_units_added: 0\nstat::slowest_unit_time_sec: 0\nstat::peak_rss_mb: 28",
"scanner": {
"id": "libFuzzer",
"name": "libFuzzer"
},
"location": {
"crash_address": "0x602000001573",
"crash_state": "FuzzMe\nstart\nstart+0x0\n\n",
"crash_type": "Heap-buffer-overflow\nREAD 1"
},
"tool": "libFuzzer"
}
]
}
Duration of coverage-guided fuzz testing
The available durations for coverage-guided fuzz testing are:
- 10-minute duration (default): Recommended for the default branch.
- 60-minute duration: Recommended for the development branch and merge requests. The longer duration provides greater coverage.
In the
COVFUZZ_ADDITIONAL_ARGS
variable set the value--regression=true
.
For a complete example, read the Go coverage-guided fuzzing example.
Continuous coverage-guided fuzz testing
It’s also possible to run the coverage-guided fuzzing jobs longer and without blocking your main pipeline. This configuration uses the GitLab parent-child pipelines.
The suggested workflow in this scenario is to have long-running, asynchronous fuzzing jobs on the main or development branch, and short synchronous fuzzing jobs on all other branches and MRs. This balances the needs of completing the per-commit pipeline complete quickly, while also giving the fuzzer a large amount of time to fully explore and test the app. Long-running fuzzing jobs are usually necessary for the coverage-guided fuzzer to find deeper bugs in your codebase.
The following is an extract of the .gitlab-ci.yml
file for this
workflow. For the full example, see the Go fuzzing example’s repository:
sync_fuzzing:
variables:
COVFUZZ_ADDITIONAL_ARGS: '-max_total_time=300'
trigger:
include: .covfuzz-ci.yml
strategy: depend
rules:
- if: $CI_COMMIT_BRANCH != 'continuous_fuzzing' && $CI_PIPELINE_SOURCE != 'merge_request_event'
async_fuzzing:
variables:
COVFUZZ_ADDITIONAL_ARGS: '-max_total_time=3600'
trigger:
include: .covfuzz-ci.yml
rules:
- if: $CI_COMMIT_BRANCH == 'continuous_fuzzing' && $CI_PIPELINE_SOURCE != 'merge_request_event'
This creates two jobs:
-
sync_fuzzing
: Runs all your fuzz targets for a short period of time in a blocking configuration. This finds simple bugs and allows you to be confident that your MRs aren’t introducing new bugs or causing old bugs to reappear. -
async_fuzzing
: Runs on your branch and finds deep bugs in your code without blocking your development cycle and MRs.
The covfuzz-ci.yml
is the same as that in the original synchronous example.
FIPS-enabled binary
Starting in GitLab 15.0 the coverage fuzzing binary is compiled with golang-fips
on Linux x86 and uses OpenSSL as the cryptographic backend. For more details, see FIPS compliance at GitLab with Go.
Offline environment
To use coverage fuzzing in an offline environment:
-
Clone
gitlab-cov-fuzz
to a private repository that your offline GitLab instance can access. -
For each fuzzing step, set
COVFUZZ_URL_PREFIX
to${NEW_URL_GITLAB_COV_FUZ}/-/raw
, whereNEW_URL_GITLAB_COV_FUZ
is the URL of the privategitlab-cov-fuzz
clone that you set up in the first step.
Interacting with the vulnerabilities
After a vulnerability is found, you can address it. The merge request widget lists the vulnerability and contains a button for downloading the fuzzing artifacts. By selecting one of the detected vulnerabilities, you can see its details.
You can also view the vulnerability from the Security Dashboard, which shows an overview of all the security vulnerabilities in your groups, projects, and pipelines.
Selecting the vulnerability opens a modal that provides additional information about the vulnerability:
- Status: The vulnerability’s status. As with any type of vulnerability, a coverage fuzzing vulnerability can be Detected, Confirmed, Dismissed, or Resolved.
- Project: The project in which the vulnerability exists.
- Crash type: The type of crash or weakness in the code. This typically maps to a CWE.
- Crash state: A normalized version of the stack trace, containing the last three functions of the crash (without random addresses).
- Stack trace snippet: The last few lines of the stack trace, which shows details about the crash.
- Identifier: The vulnerability’s identifier. This maps to either a CVE or CWE.
- Severity: The vulnerability’s severity. This can be Critical, High, Medium, Low, Info, or Unknown.
- Scanner: The scanner that detected the vulnerability (for example, Coverage Fuzzing).
- Scanner Provider: The engine that did the scan. For Coverage Fuzzing, this can be any of the engines listed in Supported fuzzing engines and languages.
Troubleshooting
Error Unable to extract corpus folder from artifacts zip file
If you see this error message, and COVFUZZ_USE_REGISTRY
is set to true
, ensure that the uploaded
corpus file extracts into a folder named corpus
.
Error 400 Bad request - Duplicate package is not allowed
If you see this error message when running the fuzzing job with COVFUZZ_USE_REGISTRY
set to true
,
ensure that duplicates are allowed. For more details, see
duplicate Generic packages.