open-consul/website/source/docs/guides/connect-envoy.md
2019-04-01 13:34:48 -07:00

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docs Using Envoy with Connect docs-guides-connect-envoy This guide walks though getting started running Envoy as a Connect Proxy.

Using Connect with Envoy Proxy

Consul Connect has first class support for using Envoy as a proxy. This guide will describe how to setup a development-mode Consul server and two services that use Envoy proxies on a single machine with Docker. The aim of this guide is to demonstrate a minimal working setup and the moving parts involved, it is not intended for production deployments.

For reference documentation on how the integration works and is configured, please see our Envoy documentation.

Setup Overview

We'll start all containers using Docker's host network mode and will have a total of five containers running by the end of this guide.

  1. A single Consul server
  2. An example TCP echo service as a destination
  3. An Envoy sidecar proxy for the echo service
  4. An Envoy sidecar proxy for the client service
  5. An example client service (netcat)

We choose to run in Docker since Envoy is only distributed as a Docker image so it's the quickest way to get a demo running. The same commands used here will work in just the same way outside of Docker if you build an Envoy binary yourself.

Building an Envoy Image

Starting Envoy requires a bootstrap configuration file that points Envoy to the local agent for discovering the rest of it's configuration. The Consul binary includes the consul connect envoy command which can generate the bootstrap configuration for Envoy and optionally run it directly.

Envoy's official Docker image can be used with Connect directly however it requires some additional steps to generate bootstrap configuration and inject it into the container.

Instead, we'll use Docker multi-stage builds (added in version 17.05) to make a local image that has both envoy and consul binaries.

We'll create a local Docker image to use that contains both binaries. First create a Dockerfile containing the following:

FROM consul:latest
FROM envoyproxy/envoy:v1.8.0
COPY --from=0 /bin/consul /bin/consul
ENTRYPOINT ["dumb-init", "consul", "connect", "envoy"]

This takes the Consul binary from the latest release image and copies it into a new image based on the official Envoy image.

This can be built locally with:

docker build -t consul-envoy .

We will use the consul-envoy image we just made to configure and run Envoy processes later.

Deploying a Consul Server

Next we need a Consul server. We'll work with a single Consul server in -dev mode for simplicity.

-> Note: -dev mode enables the gRPC server on port 8502 by default. For a production agent you'll need to explicitly configure the gRPC port.

In order to start a proxy instance, a proxy service definition must exist on the local Consul agent. We'll create one using the sidecar service registration syntax.

Create a configuration file called envoy_demo.hcl containing the following service definitions.

services {
  name = "client"
  port = 8080
  connect {
    sidecar_service {
      proxy {
        upstreams {
          destination_name = "echo"
          local_bind_port = 9191
        }
      }
    }
  }
}
services {
  name = "echo"
  port = 9090
  connect {
    sidecar_service {}
  }
}

The Consul container can now be started with that configuration.

$ docker run --rm -d -v$(pwd)/envoy_demo.hcl:/etc/consul/envoy_demo.hcl \
  --network host --name consul-agent consul:latest \
  agent -dev -config-file /etc/consul/envoy_demo.hcl
1c90f7fcc83f5390332d7a4fdda2f1bf74cf62762de9ea2f67cd5a09c0573641

Running with -d like this puts the container into the background so we can continue in the same terminal. Log output can be seen using the name we gave.

docker logs -f consul-agent

Note that the Consul server has registered two services client and echo, but also registered two proxies client-sidecar-proxy and echo-sidecar-proxy. Next we'll need to run those services and proxies.

Running the Echo Service

Next we'll run the echo service. We can use an existing TCP echo utility image for this.

Start the echo service on port 9090 as registered before.

$ docker run -d --network host abrarov/tcp-echo --port 9090
1a0b0c569016d00aadc4fc2b2954209b32b510966083f2a9e17d3afc6d185d87

Running the Proxies

We can now run "sidecar" proxy instances.

$ docker run --rm -d --network host --name echo-proxy \
  consul-envoy -sidecar-for echo
3f213a3cf9b7583a194dd0507a31e0188a03fc1b6e165b7f9336b0b1bb2baccb
$ docker run --rm -d --network host --name client-proxy \
  consul-envoy -sidecar-for client -admin-bind localhost:19001
d8399b54ee0c1f67d729bc4c8b6e624e86d63d2d9225935971bcb4534233012b

The -admin-bind flag on the second proxy command is needed because both proxies are running on the host network and so can't bind to the same port for their admin API (which cannot be disabled).

Again we can see the output using docker logs. To see more verbose information from Envoy you can add -- -l debug to the end of the commands above. This passes the -l (log level) option directly through to Envoy. With debug level logs you should see the config being delivered to the proxy in the output.

The consul connect envoy command here is connecting to the local agent, getting the proxy configuration from the proxy service registration and generating the required Envoy bootstrap configuration before execing the envoy binary directly to run it with the generated configuration.

Envoy uses the bootstrap configuration to connect to the local agent directly via gRPC and use it's xDS protocol to retrieve the actual configuration for listeners, TLS certificates, upstream service instances and so on. The xDS API allows the Envoy instance to watch for any changes so certificate rotations or changes to the upstream service instances are immediately sent to the proxy.

Running the Client Service

Finally, we can see the connectivity by running a dummy "client" service. Rather than run a full service that itself can listen, we'll simulate the service with a simple netcat process that will only talk to the client-sidecar-proxy Envoy instance.

Recall that we configured the client sidecar with one declared "upstream" dependency (the echo service). In that declaration we also requested that the echo service should be exposed to the client on local port 9191.

This configuration causes the client-sidecar-proxy to start a TCP proxy listening on localhost:9191 and proxying to the echo service. Importantly, the listener will use the correct client service mTLS certificate to authorize the connection. It discovers the IP addresses of instances of the echo service via Consul service discovery.

We can now see this working if we run netcat.

$ docker run -ti --rm --network host gophernet/netcat localhost 9191
Hello World!
Hello World!
^C

Testing Authorization

To demonstrate that Connect is controlling authorization for the echo service, we can add an explicit deny rule.

$ docker run -ti --rm --network host consul:latest intention create -deny client echo
Created: client => echo (deny)

Now, new connections will be denied. Depending on a few factors, netcat may not see the connection being closed but will not get a response from the service.

$ docker run -ti --rm --network host gophernet/netcat localhost 9191
Hello?
Anyone there?
^C

-> Note: Envoy will not currently re-authenticate already established TCP connections so if you still have the netcat terminal open from before, that will still be able to communicate with "echo". New connections should be denied though.

Removing the intention restores connectivity.

$ docker run -ti --rm --network host consul:latest intention delete client echo
Intention deleted.
$ docker run -ti --rm --network host gophernet/netcat localhost 9191
Hello?
Hello?
^C

Summary

In this guide we walked through getting a minimal working example of two plain TCP processes communicating over mTLS using Envoy sidecars configured by Connect.

For more details on how the Envoy integration works, please see the Envoy reference documentation.

To see how to get Consul Connect working in different environments like Kubernetes see the Connect Getting Started overview.