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Solution Architecture

Edwin van Wijk edited this page Feb 15, 2019 · 3 revisions

I've created a solution architecture diagram which shows all the moving parts in the application. You will probably recognize how the different bounded-contexts in the context-map are represented by the services in this architecture:

Solution Architecture

PitStop Web App

The web application is the front-end for the system. Users can manage customers, vehicles and the planning for the workshop from this front-end. The front-end will only communicate with the different APIs in the system and has no knowledge of the message-broker or any other services.

Customer Management Service

This service offers an API that is used to manage Customers in the system. For now, only CREATE and READ functionality (list and single by unique Id) is implemented.

This service handles the following commands:

  • RegisterCustomer

This service publishes the following events:

  • CustomerRegistered

Vehicle Management Service

This service offers an API that is used to manage Vehicles in the system. For now, only CREATE and READ functionality (list and single by unique Id) is implemented.

This service handles the following commands:

  • RegisterVehicle

This service publishes the following events:

  • VehicleRegistered

Workshop Management Service

This service contains 2 parts: an API for managing the workshop planning and an event-handler that handles events and builds a read-model that is used by the API.

API

This is an API that is used to manage Maintenance Jobs in the system. Because we want to be able to keep Workshop Management up and running even when other services are down, the API also offers functionality to retrieve vehicle and customer information from the read-model. This read-model is filled by the event-handler (described below).

This service handles the following commands:

  • PlanMaintenanceJob
  • FinishMaintenanceJob

This service publishes the following events:

  • WorkshopPlanningCreated
  • MaintenanceJobPlanned
  • MaintenanceJobFinished

Within this bounded-context I've used a DDD approach. The Workshop Planning aggregate handles all commands and yields events that will then be published using the message-broker.

Because this aggregate uses event-sourcing for persisting its state, every command that comes in is first transformed into an event that is handled by the aggregate. This will actually change the internal state of the aggregate. The state is persisted by storing the list of all events that occurred for 1 aggregate instance. When another command comes in for an aggregate instance (identified by its unique Id), all events are replayed and handled by the aggregate to return it to its former state. The aggregate offers a specific constructor that takes a list of events and replays them internally.

Event-handler

The event-handler ingests events containing information about Customers and Vehicles coming from the message-broker. It only handles events from the message-broker and offers no API. As stated above, it builds a read-model that is used by the front-end when scheduling maintenance jobs. This ensures that we can always schedule new maintenance jobs and manage existing jobs even though the Customer Service or Vehicle Service is offline.

This service handles the following events:

  • CustomerRegistered
  • VehicleRegistered
  • MaintenanceJobPlanned
  • MaintenanceJobFinished

Notification Service

The notification service sends a notification to every customer that has a maintenance job planned on the current day. It only handles events from the message-broker and offers no API.

This service handles the following events:

  • CustomerRegistered
  • DayHasPassed
  • MaintenanceJobPlanned
  • MaintenanceJobFinished

Invoice Service

The invoice service creates an invoice for all maintenance jobs that have been finished (and are not yet invoiced). It only handles events from the message-broker and offers no API. The invoice is created as an HTML email message which is emailed to PrestoPrint, a fictitious printing company.

This service handles the following events:

  • CustomerRegistered
  • DayHasPassed
  • MaintenanceJobPlanned
  • MaintenanceJobFinished

Time Service

The Time service is a service that informs other services when a certain time-period has passed. For now only the DayHasPassed event is supported.

I chose this approach to make testing of time-related functionality simple without the need for messing with the system-clock on test-machines. So instead of acting upon time-outs based on the system-time, services act upon events.

This service publishes the following events:

  • DayHasPassed

Auditlog Service

The AuditLog service picks up all events from the message-broker and stores them for later reference. It only handles events from the message-broker and offers no API.