This project is part of Eventuate, which is a microservices collaboration platform.
This application demonstrates two key patterns:
The application consists of three services:
-
Order Service- manages orders -
Customer Service- manages customers -
Order History Service- maintains the order history
All services are implemented using Micronaut, JPA and the Eventuate Tram framework, which provides transactional publish/subscribe.
The Order Service uses a choreography-based saga to enforce the customer’s credit limit when creating orders.
The Order History Service implements a CQRS view and subscribes to domain events published by the Order Service and Customer Service
Sagas are a mechanism for maintaining data consistency in a microservice architecture. A saga is a sequence of transactions, each of which is local to a service.
To learn more about why you need sagas if you are using microservices:
-
Read the Saga pattern
-
Read about sagas in my Microservices patterns book
There are two main ways to coordinate sagas: orchestration and choreography. To learn more about orchestration, please look at the Orchestration-based saga example This example uses choreography-based sagas, which use domain events for coordination. Each step of a saga updates the local database and publishes a domain event. The domain event is processed by an event handler, which performs the next local transaction.
The saga for creating an Order consists of the follow steps:
-
The Order Service creates an
Orderin aPENDINGstate and publishes anOrderCreatedevent -
The
Customer Servicereceives the event attempts to reserve credit for thatOrder. It publishes either aCredit Reservedevent or aCreditLimitExceededevent. -
The
Order Servicereceives the event and changes the state of the order to eitherAPPROVEDorREJECTED.
The CQRS pattern implements queries that retrieves data from multiple services. It maintains a queryable replica of the data by subscribing to domain events published by the services that own the data.
In this example, the Order History Service maintains a CQRS view in MongoDB by subscribing to domain events published by the Order Service and Customer Service.
The CQRS view stores each customer as a MongoDB document that contains information the customer and their orders.
To learn more about why you need CQRS if you are using microservices:
-
Read the CQRS pattern
-
Look at GOTO Chicago 2019 presentation
-
Read about CQRS in my Microservices patterns book
The services uses the Eventuate Tram framework to communicate asynchronously using events. The flow for publishing a domain event using Eventuate Tram is as follows:
-
Eventuate Tram inserts events into the
MESSAGEtable as part of the ACID transaction that updates the JPA entity. -
The Eventuate Tram CDC service tracks inserts into the
MESSAGEtable using the MySQL binlog (or Postgres WAL) and publishes messages to Apache Kafka. -
A service subscribes to the events, updates its database, and possibly publishes more events.
The following diagram shows the architecture of the Customers and Orders application.
The application consists of three services: Customer Service, Order Service, and Order History Service
The Customer Service implements a REST API for managing customers.
The service persists the Customer JPA entity in a MySQL/Postgres database.
Using Eventuate Tram, it publishes Customer domain events that are consumed by the Order Service.
For more information, see the microservice canvas for the Customer Service.
The Order Service implements REST API for managing orders.
The service persists the Order JPA entity in MySQL/Postgres database.
Using Eventuate Tram, it publishes Order domain events that are consumed by the Customer Service.
For more information, see the microservice canvas for the Order Service.
The Order History Service implements REST API for querying a customer’s order history
This service subscribes to events published by the Order Service and Customer Service and updates a MongoDB-based CQRS view.
For more information, see the microservice canvas for the Order History Service.
Note: you do not need to install Gradle since it will be downloaded automatically. You just need to have Java 8 installed.
First, build the application
./gradlew assembleNext, launch the services using Docker Compose:
./gradlew mysqlbinlogComposeBuild
./gradlew mysqlbinlogComposeUpNote:
-
You can also run the Postgres version using
./gradlew postgrespollingComposeUpor./gradlew postgreswalComposeUp -
If the containers aren’t accessible via
localhost- e.g. you are using Docker Toolbox, you will have to use${DOCKER_HOST_IP}instead of localhost. See this guide to settingDOCKER_HOST_IPfor more information.
Once the application has started, you can use the application via the Swagger UI:
-
Customer Service-http://localhost:8082/swagger-ui/index.html -
Order Service-http://localhost:8081/swagger-ui/index.html -
Order History Service-http://localhost:8083/swagger-ui/index.html
You can also use curl to interact with the services.
First, let’s create a customer:
$ curl -X POST --header "Content-Type: application/json" -d '{
"creditLimit": {
"amount": 5
},
"name": "Jane Doe"
}' http://localhost:8082/customers
HTTP/1.1 200
Content-Type: application/json;charset=UTF-8
{
"customerId": 1
}Next, create an order:
$ curl -X POST --header "Content-Type: application/json" -d '{
"customerId": 1,
"orderTotal": {
"amount": 4
}
}' http://localhost:8081/orders
HTTP/1.1 200
Content-Type: application/json;charset=UTF-8
{
"orderId": 1
}Next, check the status of the Order in the Order Service:
$ curl -X GET http://localhost:8081/orders/1
HTTP/1.1 200
Content-Type: application/json;charset=UTF-8
{
"orderId": 1,
"orderState": "APPROVED"
}Finally, look at the customer’s order history in the Order History Service:
$ curl -X GET --header "Accept: */*" "http://localhost:8083/customers/1"
HTTP/1.1 200
Content-Type: application/json;charset=UTF-8
{
"id": 1,
"orders": {
"1": {
"state": "APPROVED",
"orderTotal": {
"amount": 4
}
}
},
"name": "Chris",
"creditLimit": {
"amount": 100
}
}Don’t hesitate to create an issue or see