If you wish to deploy in AWS, use this previous release.
A Cisco SecureX Concrete Relay implementation using APIVoid as a third-party Cyber Threat Intelligence service provider.
The Relay itself is just a simple application written in Python that can be easily packaged and deployed. This relay is now Cisco Hosted and no longer requires AWS Lambda.
- We need an application that will translate API requests from SecureX Threat Response to the third-party integration, and vice versa.
- We need an application that can be completely self contained within a virtualized container using Docker.
Open the code folder in your terminal.
cd code
If you want to test the application you will require Docker and several dependencies from the Pipfile file:
pip install --no-cache-dir --upgrade pipenv && pipenv install --dev
You can perform two kinds of testing:
-
Run static code analysis checking for any semantic discrepancies and PEP 8 compliance:
flake8 . -
Run the suite of unit tests and measure the code coverage:
coverage run --source api/ -m pytest --verbose tests/unit/ && coverage report
If you want to test the live Lambda you may use any HTTP client (e.g. Postman),
just make sure to send requests to your Lambda's URL with the Authorization
header set to Bearer <JWT>.
NOTE. If you need input data for testing purposes you can use data from the observables.json file.
In order to build the application, we need to use a Dockerfile.
- Open a terminal. Build the container image using the
docker buildcommand.
docker build -t tr-05-apivoid .
- Once the container is built, and an image is successfully created, start your container using the
docker runcommand and specify the name of the image we have just created. By default, the container will listen for HTTP requests using port 9090.
docker run -dp 9090:9090 --name tr-05-apivoid tr-05-apivoid
- Watch the container logs to ensure it starts correctly.
docker logs tr-05-apivoid
-
Once the container has started correctly, open your web browser to http://localhost:9090. You should see a response from the container.
This application was developed and tested under Python version 3.9.
-
POST /health- Verifies the Authorization Bearer JWT and decodes it to restore the original credentials.
- Authenticates to the underlying external service to check that the provided credentials are valid and the service is available at the moment.
-
POST /observe/observables- Accepts a list of observables and filters out unsupported ones.
- Verifies the Authorization Bearer JWT and decodes it to restore the original credentials.
- Makes a series of requests to the underlying external service to query for some cyber threat intelligence data on each supported observable.
- Maps the fetched data into appropriate CTIM entities.
- Returns a list per each of the following CTIM entities (if any extracted):
Indicator,Sighting,Relationship.
-
POST /version- Returns the current version of the application.
ipdomain
Each response from the APIVoid API for the supported observables generates the following CTIM entities:
-
Sightingfrom each entry in.data.report.blacklists.engineswhere.data.report.blacklists.engines[].detectedistrue:- Value from
.data.report.blacklists.engines[].enginewill map tosource - Value from
.data.report.blacklists.engines[].referencewill map tosource_uri - The query time will map to
.observed_time.start_time
- Value from
-
Indicatorfrom each entry in.data.report.blacklists.engineswhere.data.report.blacklists.engines[].detectedistrue:IndicatorTLP will bewhite- Value from
.data.report.blacklists.engines[].enginewill map toshort_description
-
Relationshiptype betweenSightingandIndicatorismember-ofbecauseSightingsandIndicatorsare based on feeds.