Using Envoy Proxy to load-balance gRPC services on GKE

Last reviewed 2019-05-30 UTC

This tutorial demonstrates how to expose multiple gRPC services deployed on Google Kubernetes Engine (GKE) on a single external IP address by using an external passthrough Network Load Balancer and Envoy Proxy. The tutorial highlights some of the advanced features that Envoy provides for gRPC.

Introduction

gRPC is an open source, language-independent RPC framework based on HTTP/2 that uses protocol buffers for efficient on-the-wire representation and fast serialization. Inspired by Stubby, the internal Google RPC framework, gRPC enables low-latency communication between microservices and between mobile clients and APIs.

gRPC runs over HTTP/2 and offers several advantages over HTTP/1.1, such as efficient binary encoding, multiplexing of requests and responses over a single connection, and automatic flow control. gRPC also offers several options for load balancing. This tutorial focuses on situations where clients are untrusted, such as mobile clients and clients running outside the trust boundary of the service provider. Of the load-balancing options that gRPC provides, you use proxy-based load balancing in this tutorial.

In the tutorial, you deploy a Kubernetes Service of TYPE=LoadBalancer, which is exposed as a transport layer (layer 4) external passthrough Network Load Balancer on Google Cloud. This service provides a single public IP address and passes TCP connections directly to the configured backends. In the tutorial, the backend is a Kubernetes Deployment of Envoy instances.

Envoy is an open source application layer (layer 7) proxy that offers many advanced features. In this tutorial, you use it to terminate TLS connections and route gRPC traffic to the appropriate Kubernetes Service. Compared to other application layer solutions such as Kubernetes Ingress, using Envoy directly provides multiple customization options, like the following:

  • Service discovery
  • Load-balancing algorithms
  • Transforming requests and responses—for instance, to JSON or gRPC-Web
  • Authenticating requests by validating JWT tokens
  • gRPC health checks

By combining an external passthrough Network Load Balancer with Envoy, you can set up an endpoint (external IP address) that forwards traffic to a set of Envoy instances running in a Google Kubernetes Engine cluster. These instances then use application layer information to proxy requests to different gRPC services running in the cluster. The Envoy instances use cluster DNS to identify and load-balance incoming gRPC requests to the healthy and running pods for each service. This means traffic is load-balanced to the pods per RPC request rather than per TCP connection from the client.

Architecture

In this tutorial, you deploy two gRPC services, echo-grpc and reverse-grpc, in a Google Kubernetes Engine (GKE) cluster and expose them to the internet on a public IP address. The following diagram shows the architecture for exposing these two services through a single endpoint:

architecture for exposing `echo-grpc` and `reverse-grpc` through a single endpoint

An external passthrough Network Load Balancer accepts incoming requests from the internet (for example, from mobile clients or service consumers outside your company). The external passthrough Network Load Balancer performs the following tasks:

  • Load-balances incoming connections to the nodes in the pool. Traffic is forwarded to the envoy Kubernetes Service, which is exposed on all nodes in the cluster. The Kubernetes network proxy forwards these connections to pods that are running Envoy.
  • Performs HTTP health checks against the nodes in the cluster.

Envoy performs the following tasks:

  • Terminates TLS connections.
  • Discovers pods running the gRPC services by querying the internal cluster DNS service.
  • Routes and load-balances traffic to the gRPC service pods.
  • Performs health checks of the gRPC services according to the gRPC Health Checking Protocol.
  • Exposes an endpoint for health checking of Envoy instances by the external passthrough Network Load Balancer.

The gRPC services (echo-grpc and reverse-grpc) are exposed as Kubernetes headless Services. This means that no clusterIP address is assigned, and the Kubernetes network proxy doesn't load-balance traffic to the pods. Instead, a DNS A record that contains the pod IP addresses is created in the cluster DNS service. Envoy discovers the pod IP addresses from this DNS entry and load-balances across them according to the policy configured in Envoy.

The following diagram shows the Kubernetes objects involved in this tutorial:

Kubernetes objects used in this tutorial, including services, YAML files, DNS A records, secrets, pods, and proxy entry

Costs

In this document, you use the following billable components of Google Cloud:

To generate a cost estimate based on your projected usage, use the pricing calculator. New Google Cloud users might be eligible for a free trial.

When you finish the tasks that are described in this document, you can avoid continued billing by deleting the resources that you created. For more information, see Clean up.

Before you begin

  1. In the Google Cloud console, on the project selector page, select or create a Google Cloud project.

    Go to project selector

  2. Make sure that billing is enabled for your Google Cloud project.

  3. In the Google Cloud console, activate Cloud Shell.

    Activate Cloud Shell

Prepare the environment

  1. In Cloud Shell, set the Google Cloud project that you want to use for this tutorial:

    gcloud config set project PROJECT_ID

    Replace PROJECT_ID with your Google Cloud project ID.

  2. Enable the Artifact Registry and GKE APIs:

    gcloud services enable artifactregistry.googleapis.com \
        container.googleapis.com
    

Create the GKE cluster

  1. In Cloud Shell, create a GKE cluster for running your gRPC services:

    gcloud container clusters create envoy-grpc-tutorial \
        --enable-ip-alias \
        --release-channel rapid \
        --scopes cloud-platform \
        --workload-pool PROJECT_ID.svc.id.goog \
        --zone us-central1-f
    

    This tutorial uses the us-central1-f zone. You can use a different zone or region.

  2. Verify that the kubectl context has been set up by listing the nodes in your cluster:

    kubectl get nodes --output name
    

    The output looks similar to this:

    node/gke-envoy-grpc-tutorial-default-pool-c9a3c791-1kpt
    node/gke-envoy-grpc-tutorial-default-pool-c9a3c791-qn92
    node/gke-envoy-grpc-tutorial-default-pool-c9a3c791-wf2h
    

Create the Artifact Registry repository

  1. In Cloud Shell, create a new repository to store container images:

    gcloud artifacts repositories create envoy-grpc-tutorial-images \
        --repository-format docker \
        --location us-central1
    

    You create the repository in the same region as the GKE cluster to help optimize latency and network bandwidth when nodes pull container images.

  2. Grant the Artifact Registry Reader role on the repository to the Google service account used by the node VMs of the GKE cluster:

    PROJECT_NUMBER=$(gcloud projects describe PROJECT_ID --format 'value(projectNumber)')
    
    gcloud artifacts repositories add-iam-policy-binding envoy-grpc-tutorial-images \
        --location us-central1 \
        --member serviceAccount:$PROJECT_NUMBER-compute@developer.gserviceaccount.com \
        --role roles/artifactregistry.reader
    
  3. Add a credential helper entry for the repository hostname to the Docker configuration file in your Cloud Shell home directory:

    gcloud auth configure-docker us-central1-docker.pkg.dev
    

    The credential helper entry enables container image tools running in Cloud Shell to authenticate to the Artifact Registry repository location for pulling and pushing images.

Deploy the gRPC services

To route traffic to multiple gRPC services behind one load balancer, you deploy two sample gRPC services: echo-grpc and reverse-grpc. Both services expose a unary method that takes a string in the content request field. echo-grpc responds with the content unaltered, while reverse-grpc responds with the content string reversed.

  1. In Cloud Shell, clone the repository containing the gRPC services and switch to the repository directory:

    git clone https://github.com/GoogleCloudPlatform/kubernetes-engine-samples
    cd kubernetes-engine-samples/networking/grpc-gke-nlb-tutorial/
    
  2. Create a self-signed TLS certificate and private key:

    openssl req -x509 -newkey rsa:4096 -nodes -sha256 -days 365 \
        -keyout privkey.pem -out cert.pem -extensions san \
        -config \
        <(echo "[req]";
          echo distinguished_name=req;
          echo "[san]";
          echo subjectAltName=DNS:grpc.example.com
         ) \
        -subj '/CN=grpc.example.com'
    
  3. Create a Kubernetes Secret called envoy-certs that contains the self-signed TLS certificate and private key:

    kubectl create secret tls envoy-certs \
        --key privkey.pem --cert cert.pem \
        --dry-run=client --output yaml | kubectl apply --filename -
    

    Envoy uses this TLS certificate and private key when it terminates TLS connections.

  4. Build the container images for the sample apps echo-grpc and reverse-grpc, push the images to Artifact Registry, and deploy the apps to the GKE cluster, using Skaffold:

    skaffold run \
        --default-repo=us-central1-docker.pkg.dev/PROJECT_ID/envoy-grpc-tutorial-images \
        --module=echo-grpc,reverse-grpc \
        --skip-tests
    

    Skaffold is an open source tool from Google that automates workflows for developing, building, pushing, and deploying applications as containers.

  5. Deploy Envoy to the GKE cluster using Skaffold:

    skaffold run \
        --digest-source=none \
        --module=envoy \
        --skip-tests
    
  6. Verify that two pods are ready for each deployment:

    kubectl get deployments
    

    The output looks similar to the following. The values for READY should be 2/2 for all deployments.

    NAME           READY   UP-TO-DATE   AVAILABLE   AGE
    echo-grpc      2/2     2            2           1m
    envoy          2/2     2            2           1m
    reverse-grpc   2/2     2            2           1m
    
  7. Verify that echo-grpc, envoy, and reverse-grpc exist as Kubernetes Services:

    kubectl get services --selector skaffold.dev/run-id
    

    The output looks similar to the following. Both echo-grpc and reverse-grpc should have TYPE=ClusterIP and CLUSTER-IP=None.

    NAME           TYPE           CLUSTER-IP    EXTERNAL-IP      PORT(S)         AGE
    echo-grpc      ClusterIP      None          <none>           8081/TCP        2m
    envoy          LoadBalancer   10.40.2.203   203.0.113.1      443:31516/TCP   2m
    reverse-grpc   ClusterIP      None          <none>           8082/TCP        2m
    

Test the gRPC services

To test the services, you use the grpcurl command-line tool.

  1. In Cloud Shell, install grpcurl:

    go install github.com/fullstorydev/grpcurl/cmd/grpcurl@latest
    
  2. Get the external IP address of the envoy Kubernetes Service and store it in an environment variable:

    EXTERNAL_IP=$(kubectl get service envoy \
        --output=jsonpath='{.status.loadBalancer.ingress[0].ip}')
    
  3. Send a request to the echo-grpc sample app:

    grpcurl -v -d '{"content": "echo"}' \
        -proto echo-grpc/api/echo.proto \
        -authority grpc.example.com -cacert cert.pem \
        $EXTERNAL_IP:443 api.Echo/Echo
    

    The output looks similar to this:

    Resolved method descriptor:
    rpc Echo ( .api.EchoRequest ) returns ( .api.EchoResponse );
    
    Request metadata to send:
    (empty)
    
    Response headers received:
    content-type: application/grpc
    date: Wed, 02 Jun 2021 07:18:22 GMT
    hostname: echo-grpc-75947768c9-jkdcw
    server: envoy
    x-envoy-upstream-service-time: 3
    
    Response contents:
    {
      "content": "echo"
    }
    
    Response trailers received:
    (empty)
    Sent 1 request and received 1 response
    

    The hostname response header shows the name of the echo-grpc pod that handled the request. If you repeat the command a few times, you should see two different values for the hostname response header, corresponding to the names of the echo-grpc pods.

  4. Verify the same behavior with the Reverse gRPC service:

    grpcurl -v -d '{"content": "reverse"}' \
        -proto reverse-grpc/api/reverse.proto \
        -authority grpc.example.com -cacert cert.pem \
        $EXTERNAL_IP:443 api.Reverse/Reverse
    

    The output looks similar to this:

    Resolved method descriptor:
    rpc Reverse ( .api.ReverseRequest ) returns ( .api.ReverseResponse );
    
    Request metadata to send:
    (empty)
    
    Response headers received:
    content-type: application/grpc
    date: Wed, 02 Jun 2021 07:20:15 GMT
    hostname: reverse-grpc-5c9b974f54-wlfwt
    server: envoy
    x-envoy-upstream-service-time: 1
    
    Response contents:
    {
      "content": "esrever"
    }
    
    Response trailers received:
    (empty)
    Sent 1 request and received 1 response
    

Envoy configuration

To understand the Envoy configuration better, you can look at the configuration file envoy/k8s/envoy.yaml in the Git repository.

The route_config section specifies how incoming requests are routed to the echo-grpc and reverse-grpc sample apps.

route_config:
  name: local_route
  virtual_hosts:
  - name: local_service
    domains:
    - "*"
    routes:
    - match:
        prefix: "/api.Echo/"
      route:
        cluster: echo-grpc
    - match:
        prefix: "/api.Reverse/"
      route:
        cluster: reverse-grpc

The sample apps are defined as Envoy clusters.

clusters:
- name: echo-grpc
  connect_timeout: 0.5s
  type: STRICT_DNS
  dns_lookup_family: V4_ONLY
  lb_policy: ROUND_ROBIN
  http2_protocol_options: {}
  load_assignment:
    cluster_name: echo-grpc
    endpoints:
    - lb_endpoints:
      - endpoint:
          address:
            socket_address:
              address: echo-grpc.default.svc.cluster.local
              port_value: 8081
  health_checks:
    timeout: 1s
    interval: 10s
    unhealthy_threshold: 2
    healthy_threshold: 2
    grpc_health_check: {}

The type: STRICT_DNS and lb_policy: ROUND_ROBIN fields in the cluster definition specify that Envoy performs DNS lookups of the hostname specified in the address field and load-balances across the IP addresses in the response to the DNS lookup. The response contains multiple IP addresses because the Kubernetes Service objects that define the sample apps specify headless services.

The http2_protocol_options field specifies that Envoy uses the HTTP/2 protocol to the sample apps.

The grpc_health_check field in the health_checks section specifies that Envoy uses the gRPC health checking protocol to determine the health of the sample apps.

Troubleshoot

If you run into problems with this tutorial, we recommend that you review these documents:

You can also explore the Envoy administration interface to diagnose problems with the Envoy configuration.

  1. To open the administration interface, set up port forwarding from Cloud Shell to the admin port of one of the Envoy pods:

    kubectl port-forward \
        $(kubectl get pods -o name | grep envoy | head -n1) 8080:8090
    
  2. Wait until you see this output in the console:

    Forwarding from 127.0.0.1:8080 -> 8090
    
  3. Click the Web preview button in Cloud Shell and select Preview on port 8080. This opens a new browser window showing the administration interface.

    Envoy admin interface with preview selected

  4. When you are done, switch back to Cloud Shell and press Control+C to end port forwarding.

Alternative ways to route gRPC traffic

You can modify this solution in a number of ways to suit your environment.

Alternative application layer load balancers

Some of the application layer functionality that Envoy provides can also be provided by other load-balancing solutions:

  • You can use a global external Application Load Balancer or regional external Application Load Balancer instead of an external passthrough Network Load Balancer and self-managed Envoy. Using an external Application Load Balancer provides several benefits compared to an external passthrough Network Load Balancer, such as advanced traffic management capability, managed TLS certificates, and integration with other Google Cloud products such as Cloud CDN, Google Cloud Armor, and IAP.

    We recommend that you use a global external Application Load Balancer or regional external Application Load Balancer if the traffic management capabilities they offer satisfy your use cases and if you do not need support for client certificate-based authentication, also known as mutual TLS (mTLS) authentication. For more information, see the following documents:

  • If you use Cloud Service Mesh or Istio, you can use their features to route and load-balance gRPC traffic. Both Cloud Service Mesh and Istio provide an ingress gateway that is deployed as an external passthrough Network Load Balancer with an Envoy backend, similar to the architecture in this tutorial. The main difference is that Envoy is configured through Istio's traffic routing objects.

    To make the example services in this tutorial routable in the Cloud Service Mesh or Istio service mesh, you must remove the line clusterIP: None from the Kubernetes Service manifests (echo-service.yaml and reverse-service.yaml). This means using the service discovery and load balancing functionality of Cloud Service Mesh or Istio instead of the similar functionality in Envoy.

    If you already use Cloud Service Mesh or Istio, we recommend using the ingress gateway to route to your gRPC services.

  • You can use NGINX in place of Envoy, either as a Deployment or using the NGINX Ingress Controller for Kubernetes. Envoy is used in this tutorial because it provides more advanced gRPC functionality, such as support for the gRPC health checking protocol.

Internal VPC network connectivity

If you want to expose the services outside your GKE cluster but only inside your VPC network, you can use either an internal passthrough Network Load Balancer or an internal Application Load Balancer.

To use an internal passthrough Network Load Balancer in place of an external passthrough Network Load Balancer, add the annotation cloud.google.com/load-balancer-type: "Internal" to the envoy-service.yaml manifest.

To use an internal Application Load Balancer, consult the documentation on configuring Ingress for internal Application Load Balancers.

Clean up

After you finish the tutorial, you can clean up the resources that you created so that they stop using quota and incurring charges. The following sections describe how to delete or turn off these resources.

Delete the project

  1. In the Google Cloud console, go to the Manage resources page.

    Go to Manage resources

  2. In the project list, select the project that you want to delete, and then click Delete.
  3. In the dialog, type the project ID, and then click Shut down to delete the project.

Delete the resources

If you want to keep the Google Cloud project you used in this tutorial, delete the individual resources:

  1. In Cloud Shell, delete the local Git repository clone:

    cd ; rm -rf kubernetes-engine-samples/networking/grpc-gke-nlb-tutorial/
    
  2. Delete the GKE cluster:

    gcloud container clusters delete envoy-grpc-tutorial \
        --zone us-central1-f --async --quiet
    
  3. Delete the repository in Artifact Registry:

    gcloud artifacts repositories delete envoy-grpc-tutorial-images \
        --location us-central1 --async --quiet
    

What's next