Latest news about Bitcoin and all cryptocurrencies. Your daily crypto news habit.
How to develop Go gRPC microservices and deploy in Kubernetes
A few month back, I started my journey learning gRPC. This article is to demonstrate how we can use gRPC to develop microservices using Go and deploy them in kubernetes cluster. We will develop two microservice. One microservice will be responsible for calculating summation of two integer and other will serve a public RESTÂ API.
Prerequisites
There are many many way to run kubernetes cluster in local machine. I am going to use Minikube for this article. We also need to install kubectl, Docker and Protobuf Compiler.
To start Minikube you have to run following command with root privileges
$ minikube start [--vm-driver=<driver>]
Define communication protocol
As an underlying transport protocol we will use gRPC. For that we need to write definitions for message types and services in Protocol Buffer’s interface definition language and compile them. In your project root directory create a file named add.proto inside pb directory.
syntax = "proto3";package pb;message AddRequest { uint64 a = 1; uint64 b = 2;}message AddResponse { uint64 result = 1;}service AddService { rpc Compute (AddRequest) returns (AddResponse) {}}
To compile this proto file navigate to pb directory and run the following command
$ protoc -I . --go_out=plugins=grpc:. ./*.proto
After successful compilation it will produce add.pb.go file in the same directory.
Implement summation service
To implement summation service we need to use auto-generated code. Now create main.go file inside add directory and make sure you import correct packages
package mainimport ( "fmt" "golang.org/x/net/context" "google.golang.org/grpc" "google.golang.org/grpc/reflection" "log" "net" // replace this with your own project "github.com/shuza/kubernetes-go-grpc/pd")
Now implement the Compute handler function that will add two integer from using auto-generated pb.AddServiceClient interface.
func (s *server) Compute(cxt context.Context, r *pb.AddRequest) (*pb.AddResponse, error) { result := &pb.AddResponse{} result.Result = r.A + r.B logMessage := fmt.Sprintf("A: %d B: %d sum: %d", r.A, r.B, result.Result) log.Println(logMessage) return result, nil}
Noe in the main function, register a server type which will handle requests. Then start the gRPCÂ server.
type server struct{}func main() { lis, err := net.Listen("tcp", ":3000") if err != nil { log.Fatalf("Failed to listen: %v", err) } s := grpc.NewServer() pb.RegisterAddServiceServer(s, &server{}) reflection.Register(s) if err := s.Serve(lis); err != nil { log.Fatalf("Failed to serve: %v", err) }}
API Service
API service use Gorilla Mux to serve REST API response to the client and route them.Create a client to communicate with the Add Service. To communicate with Add Service we will use service name add-service because later we will deploy our service in kubernetes cluster. Kubernetes has a built-in DNS service, so we can access by service name.
func main() { // Connect to Add service conn, err := grpc.Dial("add-service:3000", grpc.WithInsecure()) if err != nil { log.Fatalf("Dial Failed: %v", err) } addClient := pb.NewAddServiceClient(conn) routes := mux.NewRouter() routes.HandleFunc("/add/{a}/{b}", func(w http.ResponseWriter, r *http.Request) { w.Header().Set("Content-Type", "application/json; charset=UFT-8") vars := mux.Vars(r) a, err := strconv.ParseUint(vars["a"], 10, 64) if err != nil { json.NewEncoder(w).Encode("Invalid parameter A") } b, err := strconv.ParseUint(vars["b"], 10, 64) if err != nil { json.NewEncoder(w).Encode("Invalid parameter B") } ctx, cancel := context.WithTimeout(context.TODO(), time.Minute) defer cancel() req := &pb.AddRequest{A: a, B: b} if resp, err := addClient.Compute(ctx, req); err == nil { msg := fmt.Sprintf("Summation is %d", resp.Result) json.NewEncoder(w).Encode(msg) } else { msg := fmt.Sprintf("Internal server error: %s", err.Error()) json.NewEncoder(w).Encode(msg) } }).Methods("GET") fmt.Println("Application is running on : 8080 .....") http.ListenAndServe(":8080", routes)}
Here I have declared a handler for /add/{a}/{b} endpoint which reads parameters A and B and then call Add Service for summation.
Build Docker Images
Now your services are ready but need to containerize them to deploy in kubernetes cluster. For Add Service create a Dockerfile inside add directory
FROM golangCOPY . /go/src/addWORKDIR /go/src/addRUN go get .ENTRYPOINT go run main.goEXPOSE 3000
To build and push summation-service image in DockerHub navigate to add directory and run following commands
$ docker build . -t shuzasa/summation-service:v1.0$ docker push shuzasa/summation-service:v1.0
For Api Service create Dockerfile inside api directory
FROM golangCOPY . /go/src/apiWORKDIR /go/src/apiRUN go get .ENTRYPOINT go run main.goEXPOSE 8080
To build and push api-service image navigate to api directory and run following commands
$ docker build . -t shuzasa/api-service:v1.0$ docker push shuzasa/api-service:v1.0
Deploying to Kubernetes cluster
For each service we need to configure two object in kubernetes Deployment and Service. Deployment will create poda inside kubernetes cluster and manage desire status of those pods to make sure we have our application running to serve traffic. Service will provide fixed address to access those pods. For Summation service create add-service.yaml file and insert following commands
apiVersion: apps/v1kind: Deploymentmetadata: name: add-deployment labels: app: addspec: selector: matchLabels: app: add replicas: 1 template: metadata: labels: app: add spec: containers: - name: add image: shuzasa/add-service:v1.2 ports: - name: add-service containerPort: 3000---apiVersion: v1kind: Servicemetadata: name: add-servicespec: selector: app: add ports: - port: 3000 targetPort: add-service
For api-service create api-service.yaml file
apiVersion: apps/v1kind: Deploymentmetadata: name: api-deployment labels: app: apispec: selector: matchLabels: app: api replicas: 1 template: metadata: labels: app: api spec: containers: - name: api image: shuzasa/api-service:v1.0 ports: - name: api-service containerPort: 8080---apiVersion: v1kind: Servicemetadata: name: api-servicespec: selector: app: api ports: - name: http port: 8080 nodePort: 30080 type: NodePort
Main difference between two service definition is in api-service we have declared it as NodePort type as it can be accessible from outside of kubernetes cluster. Now create those resources by running following commands
$ kubectl create -f summation-service.yaml$ kubectl create -f api-service.yaml
Wait until all the pods become available or in running state
$ kubectl get pods -wNAME READY STATUS RESTARTS AGEadd-deployment-66df6c78b6-qcj77 1/1 Running 0 2mapi-deployment-577f4965f5-d2bkd 1/1 Running 0 2m
Conclusion
Let’s verify our system. To get URL of our api-service run
$ minikube service api-service --url
Make a request to the service using previously found IPÂ address
curl http://192.168.99.100:30080/add/1/3
And it will show the summation result.
You can find entire source code on GitHub.
Originally published at shuza.ninja on February 2, 2019.
How to develop Go gRPC microservices and deploy in Kubernates was originally published in Hacker Noon on Medium, where people are continuing the conversation by highlighting and responding to this story.
Disclaimer
The views and opinions expressed in this article are solely those of the authors and do not reflect the views of Bitcoin Insider. Every investment and trading move involves risk - this is especially true for cryptocurrencies given their volatility. We strongly advise our readers to conduct their own research when making a decision.