Adopting an event-driven architecture (EDA) to increase scalability and reduce coupling between components/services is relatively common in complex environments.
While this approach solves a number of problems, one of the challenges faced by teams is standardizing events to ensure compatibility between all components. To mitigate this challenge, we can use the CloudEvents project.
The project aims to be a specification for standardizing and describing events, bringing consistency, accessibility, and portability. Another advantage is that the project provides a series of SDKs to accelerate team adoption in addition to being a specification.
In this post, I want to demonstrate the use of the Go SDK (with a special appearance by the Python SDK ) in a fictitious project.
Let's consider an environment composed of two microservices: a user, which manages users (CRUD), and an audit service, which stores important events in the environment for future analysis.
The service code of the user service is as follows:
package main
import (
"context"
"encoding/json"
"log"
"net/http"
"time"
cloudevents "github.com/cloudevents/sdk-go/v2"
"github.com/cloudevents/sdk-go/v2/protocol"
"github.com/go-chi/chi/v5"
"github.com/go-chi/httplog"
"github.com/google/uuid"
)
const auditService = "http://localhost:8080/"
func main() {
logger := httplog.NewLogger("user", httplog.Options{
JSON: true,
})
ctx := context.Background()
ceClient, err := cloudevents.NewClientHTTP()
if err != nil {
log.Fatalf("failed to create client, %v", err)
}
r := chi.NewRouter()
r.Use(httplog.RequestLogger(logger))
r.Post("/v1/user", storeUser(ctx, ceClient))
http.Handle("/", r)
srv := &http.Server{
ReadTimeout: 30 * time.Second,
WriteTimeout: 30 * time.Second,
Addr: ":3000",
Handler: http.DefaultServeMux,
}
err = srv.ListenAndServe()
if err != nil {
logger.Panic().Msg(err.Error())
}
}
type userRequest struct {
ID uuid.UUID
Name string `json:"name"`
Password string `json:"password"`
}
func storeUser(ctx context.Context, ceClient cloudevents.Client) http.HandlerFunc {
return func(w http.ResponseWriter, r *http.Request) {
oplog := httplog.LogEntry(r.Context())
var ur userRequest
err := json.NewDecoder(r.Body).Decode(&ur)
if err != nil {
w.WriteHeader(http.StatusBadRequest)
oplog.Error().Msg(err.Error())
return
}
ur.ID = uuid.New()
//TODO: store user in a database
// Create an Event.
event := cloudevents.NewEvent()
event.SetSource("github.com/eminetto/post-cloudevents")
event.SetType("user.storeUser")
event.SetData(cloudevents.ApplicationJSON, map[string]string{"id": ur.ID.String()})
// Set a target.
ctx := cloudevents.ContextWithTarget(context.Background(), auditService)
// Send that Event.
var result protocol.Result
if result = ceClient.Send(ctx, event); cloudevents.IsUndelivered(result) {
oplog.Error().Msgf("failed to send, %v", result)
w.WriteHeader(http.StatusInternalServerError)
return
}
return
}
}
In the code, you can see the creation of an event and its sending to the audit service, which looks like this:
package main
import (
"context"
"fmt"
"log"
cloudevents "github.com/cloudevents/sdk-go/v2"
)
func receive(event cloudevents.Event) {
// do something with event.
fmt.Printf("%s", event)
}
func main() {
// The default client is HTTP.
c, err := cloudevents.NewClientHTTP()
if err != nil {
log.Fatalf("failed to create client, %v", err)
}
if err = c.StartReceiver(context.Background(), receive); err != nil {
log.Fatalf("failed to start receiver: %v", err)
}
}
By running both services, you can see how they work by sending a request to the user :
curl -X "POST" "http://localhost:3000/v1/user" \
-H 'Accept: application/json' \
-H 'Content-Type: application/json' \
-d $'{
"name": "Ozzy Osbourne",
"password": "12345"
}'
The user output is:
{"level":"info","service":"user","httpRequest":{"proto":"HTTP/1.1","remoteIP":"[::1]:50894","requestID":"Macbook-Air-de-Elton.local/3YUAnzEbis-000001","requestMethod":"POST","requestPath":"/v1/user","requestURL":"http://localhost:3000/v1/user"},"httpRequest":{"header":{"accept":"application/json","content-length":"52","content-type":"application/json","user-agent":"curl/8.7.1"},"proto":"HTTP/1.1","remoteIP":"[::1]:50894","requestID":"Macbook-Air-de-Elton.local/3YUAnzEbis-000001","requestMethod":"POST","requestPath":"/v1/user","requestURL":"http://localhost:3000/v1/user","scheme":"http"},"timestamp":"2024-11-28T15:52:27.947355-03:00","message":"Request: POST /v1/user"}
{"level":"warn","service":"user","httpRequest":{"proto":"HTTP/1.1","remoteIP":"[::1]:50894","requestID":"Macbook-Air-de-Elton.local/3YUAnzEbis-000001","requestMethod":"POST","requestPath":"/v1/user","requestURL":"http://localhost:3000/v1/user"},"httpResponse":{"bytes":0,"elapsed":2.33225,"status":0},"timestamp":"2024-11-28T15:52:27.949877-03:00","message":"Response: 0 Unknown"}
The output of the audit service demonstrates the receipt of the event.
❯ go run main.go
Context Attributes,
specversion: 1.0
type: user.storeUser
source: github.com/eminetto/post-cloudevents
id: 5190bc29-a3d5-4fca-9a88-85fccffc16b6
time: 2024-11-28T18:53:17.474154Z
datacontenttype: application/json
Data,
{
"id": "8aadf8c5-9c4e-4c11-af24-beac2fb9a4b7"
}
To validate the portability goal, I used the Python SDK to implement a version of the audit service:
from flask import Flask, request
from cloudevents.http import from_http
app = Flask(__name__)
# create an endpoint at http://localhost:/3000/
@app.route("/", methods=["POST"])
def home():
# create a CloudEvent
event = from_http(request.headers, request.get_data())
# you can access cloudevent fields as seen below
print(
f"Found {event['id']} from {event['source']} with type "
f"{event['type']} and specversion {event['specversion']}"
)
return "", 204
if __name__ == "__main__":
app.run(port=8080)
The application output shows the receipt of the event without the need for changes to the service user:
(.venv) eminetto@Macbook-Air-de-Elton audit-python % python3 main.py * Serving Flask app 'main' * Debug mode: off WARNING: This is a development server. Do not use it in a production deployment. Use a production WSGI server instead. * Running on http://127.0.0.1:8080 Press CTRL+C to quit Found ce1abe22-dce5-40f0-8c82-12093b707ed7 from github.com/eminetto/post-cloudevents with type user.storeUser and specversion 1.0 127.0.0.1 - - [28/Nov/2024 15:59:31] "POST / HTTP/1.1" 204 -
The previous example introduces the CloudEvents SDKs, but it violates a principle of event-based architectures: loosen coupling. The application user is aware of and tied to the auditing application, which is not a good practice. We can improve this situation by using other CloudEvents features, such as pub/sub, or by adding something like Kafka. The following example uses Kafka to decouple the two applications.
The first step was to create one docker-compose.yaml to use Kafka:
services:
kafka:
image: bitnami/kafka:latest
restart: on-failure
ports:
- 9092:9092
environment:
- KAFKA_CFG_BROKER_ID=1
- KAFKA_CFG_LISTENERS=PLAINTEXT://:9092
- KAFKA_CFG_ADVERTISED_LISTENERS=PLAINTEXT://127.0.0.1:9092
- KAFKA_CFG_ZOOKEEPER_CONNECT=zookeeper:2181
- KAFKA_CFG_NUM_PARTITIONS=3
- ALLOW_PLAINTEXT_LISTENER=yes
depends_on:
- zookeeper
zookeeper:
image: bitnami/zookeeper:latest
ports:
- 2181:2181
environment:
- ALLOW_ANONYMOUS_LOGIN=yes
The following change was in the service user:
package main
import (
"context"
"encoding/json"
"log"
"net/http"
"time"
"github.com/IBM/sarama"
"github.com/cloudevents/sdk-go/protocol/kafka_sarama/v2"
cloudevents "github.com/cloudevents/sdk-go/v2"
"github.com/go-chi/chi/v5"
"github.com/go-chi/httplog"
"github.com/google/uuid"
)
const (
auditService = "127.0.0.1:9092"
auditTopic = "audit"
)
func main() {
logger := httplog.NewLogger("user", httplog.Options{
JSON: true,
})
ctx := context.Background()
saramaConfig := sarama.NewConfig()
saramaConfig.Version = sarama.V2_0_0_0
sender, err := kafka_sarama.NewSender([]string{auditService}, saramaConfig, auditTopic)
if err != nil {
log.Fatalf("failed to create protocol: %s", err.Error())
}
defer sender.Close(context.Background())
ceClient, err := cloudevents.NewClient(sender, cloudevents.WithTimeNow(), cloudevents.WithUUIDs())
if err != nil {
log.Fatalf("failed to create client, %v", err)
}
r := chi.NewRouter()
r.Use(httplog.RequestLogger(logger))
r.Post("/v1/user", storeUser(ctx, ceClient))
http.Handle("/", r)
srv := &http.Server{
ReadTimeout: 30 * time.Second,
WriteTimeout: 30 * time.Second,
Addr: ":3000",
Handler: http.DefaultServeMux,
}
err = srv.ListenAndServe()
if err != nil {
logger.Panic().Msg(err.Error())
}
}
type userRequest struct {
ID uuid.UUID
Name string `json:"name"`
Password string `json:"password"`
}
func storeUser(ctx context.Context, ceClient cloudevents.Client) http.HandlerFunc {
return func(w http.ResponseWriter, r *http.Request) {
oplog := httplog.LogEntry(r.Context())
var ur userRequest
err := json.NewDecoder(r.Body).Decode(&ur)
if err != nil {
w.WriteHeader(http.StatusBadRequest)
oplog.Error().Msg(err.Error())
return
}
ur.ID = uuid.New()
//TODO: store user in a database
// Create an Event.
event := cloudevents.NewEvent()
event.SetID(uuid.New().String())
event.SetSource("github.com/eminetto/post-cloudevents")
event.SetType("user.storeUser")
event.SetData(cloudevents.ApplicationJSON, map[string]string{"id": ur.ID.String()})
// Send that Event.
if result := ceClient.Send(
// Set the producer message key
kafka_sarama.WithMessageKey(context.Background(), sarama.StringEncoder(event.ID())),
event,
); cloudevents.IsUndelivered(result) {
oplog.Error().Msgf("failed to send, %v", result)
w.WriteHeader(http.StatusInternalServerError)
return
}
return
}
}
A few changes were needed, mainly to make a connection with Kafka, but the event itself did not change.
I made a similar change to the audit service:
package main
import (
"context"
"fmt"
"log"
"github.com/IBM/sarama"
"github.com/cloudevents/sdk-go/protocol/kafka_sarama/v2"
cloudevents "github.com/cloudevents/sdk-go/v2"
)
const (
auditService = "127.0.0.1:9092"
auditTopic = "audit"
auditGroupID = "audit-group-id"
)
func receive(event cloudevents.Event) {
// do something with event.
fmt.Printf("%s", event)
}
func main() {
saramaConfig := sarama.NewConfig()
saramaConfig.Version = sarama.V2_0_0_0
receiver, err := kafka_sarama.NewConsumer([]string{auditService}, saramaConfig, auditGroupID, auditTopic)
if err != nil {
log.Fatalf("failed to create protocol: %s", err.Error())
}
defer receiver.Close(context.Background())
c, err := cloudevents.NewClient(receiver)
if err != nil {
log.Fatalf("failed to create client, %v", err)
}
if err = c.StartReceiver(context.Background(), receive); err != nil {
log.Fatalf("failed to start receiver: %v", err)
}
}
The output of the applications stays the same.
With the inclusion of Kafka, we decoupled the applications, no longer violating the principles of EDA while maintaining the advantages provided by CloudEvents.
The goal of this post was to introduce the standard and demonstrate the ease of implementation using the SDKs. I could cover the subject in more depth, but I hope I have achieved the objective and inspired research and use of the technology.
It would be very useful if you already use/have used CloudEvents and wanted to share your experiences in the comments.
You can find the codes I presented in this post in the repository on GitHub.
Originally published at https://eltonminetto.dev on Nov 29, 2024.
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