This repository includes Sanskar Gupta's (frontend) and Felix Seifert's (backend) project work of the course Network Programming at KTH Royal Institute of Technology. The project is a small microservices-based application (MSA) which is based on the Quarkus framework.
The idea is that a user can log in and store which places he/she visited from when to when. After a successful login
via the Keycloak application, his/her inputs are sent to the microservice visited-places which
stores it in a PostgreSQL database. The user can then request to see his/her places on a map. The places would be
enriched with the actual coordinates by the microservice coordinate-finder. The
frontend then displays these places with markers whose size depend on the duration the user stayed over
there.
The architecture for a local desktop setup is shown in the following image. How to start the full application, have a look under the section Full Test.
Users call the frontend where they have to identify. The Keycloak application then authenticates them and returns
a token. With this token, the frontend taks to visited-places to operate CRUD operations on the places this user
visited. If places have to be returned, coordinate-finder provides the coordinates for these places.
coordinate-finder checks whether they are in its own database. If the coordinates are not stored in the database,
the HERE Geocoding and Search API is approached.
The infrastructure consists out of a PostgreSQL database container and a Keycloak identity and access management
application. To run both container, you would have to run the docker-compose.yml file.
docker-compose up -dAccording to the database per service pattern, each service receives its own database within the PostgreSQL container.
The credentials of the databases for the different microservices can be seen in the
init-databases.sql file. To access the different databases, use the
following Docker command and adapt it to your needs.
sudo docker exec -it postgres psql -d <database> -U <user> -W
The Keycloak application is automatically initialised with the settings from the file
realm-network-programming-project.json. Currently,
all functions of the backend are available for the role USER. Upon start-up, the user alex with the password alex
and the role USER is created automatically.
The admin console of Keycloak is available under http://localhost:8180/auth/admin/.
The microservices of the backend of the MSA can currently be started only separately. For starting a service, go to its directory and start it either in the Quarkus development mode, like a normal Java application or compile it to a native executable. Alternatively, a microservice can also be started in a Docker container. The startup instructions are all described within the microservice directories. For more information on how to run Quarkus applications, please consult the Quarkus page about Maven tooling.
To start the React frontend, have a look at the description within the frontend folder.
To spin up the full application and use it in the web-browser, run the following steps:
-
Start the infrastructure with Docker Compose.
cd infrastructure && \ sudo docker-compose up -d && \ cd .. -
Insert an API key for the HERE Geocoding and Search API in the
applications.propertiesfile of the microservicecoordinate-finder. -
Start the microservice
coordinate-finderin the Quarkus DEV mode.cd coordinate-finder && \ ./mvnw compile quarkus:dev -
Start the microservice
visited-placesin the Quarkus DEV mode.cd visited-places && \ ./mvnw compile quarkus:dev && -
Run
npm installint the frontend folder, create a.envfile with the necessary content and start the app in DEV mode.cd frontend && \ npm install && \ echo "REACT_APP_MAPBOX_ACCESS_TOKEN='pk.eyJ1Ijoic2Fuc2thcjk1IiwiYSI6ImNraml5dWo5ZDJtZDkydnNjdWtscXZxNm0ifQ.cb8o0SXu2SJY-aqquDCwqw' REACT_APP_AUTH_SERVER_OIDC_TOKEN_URL='http://localhost:8180/auth/realms/network-programming-project/protocol/openid-connect/token' REACT_APP_VISITED_PLACE_URL='http://localhost:8081/api/v1/places'" > .env && \ npm start
To test the identity framework with its authentication and authorisation, start the infrastructure and start the
microservices visited-places and coordinate-finder. Then, query Keycloak to
receive a valid access token (and store it for simplicity).
export access_token=$( \
curl -X POST http://localhost:8180/auth/realms/network-programming-project/protocol/openid-connect/token \
--user frontend: \
-H 'content-type: application/x-www-form-urlencoded' \
-d 'username=alex&password=alex&grant_type=password' | jq --raw-output '.access_token' \
)You should use the credentials of the client frontend because the clients for the backend microservices are not
allowed to request new tokens and can only verify them. Besides the client credentials, which represent a certain
service, you also need the user credentials which identify the actual end-user of the system.
Use this token then as a Bearer token to query the visited-places service which uses the token to check the user's
authorisation and retrieve the user's identity from it.
curl -v -X GET \
http://localhost:8081/api/v1/places \
-H "Authorization: Bearer "$access_tokenAs stored in the database, this endpoint returns the places the user visited and the dates from when to when.
In addition, you can find the longitude and latitude of this place. These details are retrieved from the microservice
coordinate-finder. This microservice gets the coordinates from its own database. If they are not stored in there, it
queries the HERE Geocoding and Search API.
The current solution has some coordinate inaccuracies.
To successfully query the API of Here, you would need to register for a free API key
and enter it in the applications.properties file of the
microservice coordinate-finder.
The frontend is built in JavaScript with React.
The backend microservices are built in Java with Quarkus. The REST endpoints are realised with JAX-RS and the databases are accessed with Hibernate ORM with Panache. The RDBMS PostgreSQL and the identity and access management solution Keycloak for Open ID Connect are used as Docker containers and managed with Docker Compose.