Skip to content

richardbischof/inlets

 
 

Repository files navigation

inlets

Expose your local endpoints to the Internet

Build Status License: MIT Go Report Card Documentation

Intro

inlets combines a reverse proxy and websocket tunnels to expose your internal and development endpoints to the public Internet via an exit-node. An exit-node may be a 5-10 USD VPS or any other computer with an IPv4 IP address.

Why do we need this project? Similar tools such as ngrok or Argo Tunnel from Cloudflare are closed-source, have limits built-in, can work out expensive, and have limited support for arm/arm64. Ngrok is also often banned by corporate firewall policies meaning it can be unusable. Other open-source tunnel tools are designed to only set up a single static tunnel. inlets aims to dynamically bind and discover your local services to DNS entries with automated TLS certificates to a public IP address over a websocket tunnel.

When combined with SSL - inlets can be used with any corporate HTTP proxy which supports CONNECT.

Conceptual diagram for inlets

License & terms

Important

Developers wishing to use inlets within a corporate network are advised to seek approval from their administrators or management before using the tool. By downloading, using, or distributing inlets, you agree to the LICENSE terms & conditions. No warranty or liability is provided.

Who is behind this project?

inlets is brought to you by Alex Ellis. Alex is a CNCF Ambassador and the founder of OpenFaaS.

OpenFaaS® makes it easy for developers to deploy event-driven functions and microservices to Kubernetes without repetitive, boiler-plate coding. Package your code or an existing binary in a Docker image to get a highly scalable endpoint with auto-scaling and metrics. The project has around 19k GitHub stars, over 240 contributors and a growing number of end-users in production.

Become an Insider to receive regular Insider Updates on inlets, and all his other OSS work, blogs and videos via GitHub Sponsors

Backlog & goals

Completed

  • automatically create endpoints on exit-node based upon client definitions
    • multiplex sites on same port and websocket through the use of DNS / host entries
  • link encryption using SSL over websockets (wss://)
  • automatic reconnect
  • authentication using service account or basic auth
  • automatic TLS provisioning for endpoints using cert-magic
    • configure staging or production LetsEncrypt issuer using HTTP01 challenge
  • native multi-arch with ARMHF/ARM64 support
  • Dockerfile and Kubernetes YAML files
  • discover and implement Service type of LoadBalancer for Kubernetes - inlets-operator
  • tunnelling websocket traffic in addition to HTTP(s)
  • get a logo for the project

Stretch goals

  • automatic configuration of DNS / A records
  • configuration to run "exit-node" as serverless container with Azure ACI / AWS Fargate
  • configure staging or production LetsEncrypt issuer using DNS01 challenge

Non-goals

  • tunnelling plain TCP traffic over the websocket

    This use-case is covered by inlets-pro, ask me about early access to inlets-pro.

Status

Unlike HTTP 1.1 which follows a synchronous request/response model websockets use an asynchronous pub/sub model for sending and receiving messages. This presents a challenge for tunneling a synchronous protocol over an asynchronous bus.

inlets 2.0 introduces performance enhancements and leverages parts of the Kubernetes and Rancher API. It uses the same tunnelling packages that enable node-to-node communication in Rancher's k3s project. It is suitable for development and may be useful in production. Before deploying inlets into production, it is advised that you do adequate testing.

Feel free to open issues if you have comments, suggestions or contributions.

  • The tunnel link is secured via --token flag using a shared secret
  • The default configuration uses websockets without SSL ws://, but to enable encryption you could enable SSL wss://
  • A timeout for requests can be configured via args on the server
  • The upstream URL has to be configured on both server and client until a discovery or service advertisement mechanism is added The client can advertise upstream URLs, which it can serve
  • The tunnel transport is wrapped by default which strips CORS headers from responses, but you can disable it with the --disable-transport-wrapping flag on the server

What are people saying about inlets?

You can share about inlets using @inletsdev, #inletsdev, and https://inlets.dev.

inlets has trended on the front page of Hacker News twice.

Tutorials:

Twitter:

Note: add a PR to send your story or use-case, I'd love to hear from you.

See ADOPTERS.md for what companies are doing with inlets today.

Get started

You can install the CLI with a curl utility script, brew or by downloading the binary from the releases page. Once installed you'll get the inlets command.

Install the CLI

Utility script with curl:

# Install to local directory
curl -sLS https://get.inlets.dev | sh

# Install to /usr/local/bin/
curl -sLS https://get.inlets.dev | sudo sh

Via brew:

brew install inlets

Note: the brew distribution is maintained by the brew team, so it may lag a little behind the GitHub release.

Binaries are made available on the releases page for Linux (x86_64, armhf & arm64), Windows (experimental), and for Darwin (MacOS). You will also find SHA checksums available if you want to verify your download.

Quickstart tutorial

You can run inlets between any two computers with connectivity, these could be containers, VMs, bare metal or even "loop-back" on your own laptop.

See how to provision an "exit-node" with a public IPv4 address using a VPS.

  • On the exit-node (or server)

Start the tunnel server on a machine with a publicly-accessible IPv4 IP address such as a VPS.

Example with a token for client authentication:

export token=$(head -c 16 /dev/urandom | shasum | cut -d" " -f1)
inlets server --port=8090 --token="$token"

Note: You can pass the --token argument followed by a token value to both the server and client to prevent unauthorized connections to the tunnel.

inlets server --port=8090

You can also run unprotected, but this is not recommended.

Note down your public IPv4 IP address.

  • Head over to your machine where you are running a sample service, or something you want to expose.

You can use my hash-browns service for instance which generates hashes.

Install hash-browns or run your own HTTP server

export GO111MODULE=off
export GOPATH=$HOME/go/

go get -u github.com/alexellis/hash-browns
cd $GOPATH/src/github.com/alexellis/hash-browns

port=3000 go run server.go

If you don't have Go installed, then you could run Python's built-in HTTP server:

mkdir -p /tmp/inlets-test/
cd /tmp/inlets-test/
touch hello-world
python -m SimpleHTTPServer 3000
  • On the same machine, start the inlets client

Start the tunnel client:

export REMOTE="127.0.0.1:8090"    # for testing inlets on your laptop, replace with the public IPv4
export TOKEN="CLIENT-TOKEN-HERE"  # the client token is found on your VPS or on start-up of "inlets server"
inlets client \
 --remote=$REMOTE \
 --upstream=http://127.0.0.1:3000 \
 --token $TOKEN
  • Replace the --remote with the address where your exit-node is running inlets server.
  • Replace the --token with the value from your server

We now have three processes:

  • example service running (hash-browns) or Python's webserver
  • an exit-node running the tunnel server (inlets server)
  • a client running the tunnel client (inlets client)

So send a request to the inlets server - use its domain name or IP address:

Assuming gateway.mydomain.tk points to 127.0.0.1 in /etc/hosts or your DNS server.

curl -d "hash this" http://127.0.0.1:8090/hash -H "Host: gateway.mydomain.tk"
# or
curl -d "hash this" http://127.0.0.1:8090/hash
# or
curl -d "hash this" http://gateway.mydomain.tk/hash

You will see the traffic pass between the exit node / server and your development machine. You'll see the hash message appear in the logs as below:

~/go/src/github.com/alexellis/hash-browns$ port=3000 go run server.go
2018/12/23 20:15:00 Listening on port: 3000
"hash this"

Now check the metrics endpoint which is built-into the hash-browns example service:

curl $REMOTE/metrics | grep hash

You can also use multiple domain names and tie them back to different internal services.

Here we start the Python server on two different ports, serving content from two different locations and then map it to two different Host headers, or domain names:

mkdir -p /tmp/store1
cd /tmp/store1/
touch hello-store-1
python -m SimpleHTTPServer 8001 &


mkdir -p /tmp/store2
cd /tmp/store2/
touch hello-store-2
python -m SimpleHTTPServer 8002 &
export REMOTE="127.0.0.1:8090"    # for testing inlets on your laptop, replace with the public IPv4
export TOKEN="CLIENT-TOKEN-HERE"  # the client token is found on your VPS or on start-up of "inlets server"
inlets client \
 --remote=$REMOTE \
 --token $TOKEN \
 --upstream="store1.example.com=http://127.0.0.1:8001,store2.example.com=http://127.0.0.1:8002"

You can now create two DNS entries or /etc/hosts file entries for store1.example.com and store2.example.com, then connet through your browser.

Going further

Docs & Featured tutorials

Tutorial: HTTPS for your local endpoints with inlets and Caddy

Docs: Inlets & Kubernetes recipes

Docs: Run Inlets on a VPS

Tutorial: Get a LoadBalancer for your private Kubernetes cluster with inlets-operator

Video demo

Using inlets I was able to set up a public endpoint (with a custom domain name) for my JavaScript & Webpack Create React App.

https://img.youtube.com/vi/jrAqqe8N3q4/hqdefault.jpg

Docker

Docker images are published as multi-arch for x86_64, arm64 and armhf

  • `inlets/inlets:2.6.1

Multiple services with on exit-node

You can expose an OpenFaaS or OpenFaaS Cloud deployment with inlets - just change --upstream=http://127.0.0.1:3000 to --upstream=http://127.0.0.1:8080 or --upstream=http://127.0.0.1:31112. You can even point at an IP address inside or outside your network for instance: --upstream=http://192.168.0.101:8080.

When using the scripts in hack to configure inlets with system, the process will restart if the tunnel crashes.

Bind a different port for the control-plane

You can bind two separate TCP ports for the user-facing port and the tunnel.

  • --port - the port for users to connect to and for serving data, i.e. the Data Plane
  • --control-port - the port for the websocket to connect to i.e. the Control Plane

Development

For development you will need Golang 1.10 or 1.11 on both the exit-node or server and the client.

You can get the code like this:

go get -u github.com/inlets/inlets
cd $GOPATH/src/github.com/inlets/inlets

Contributions are welcome. All commits must be signed-off with git commit -s to accept the Developer Certificate of Origin.

Packages

No packages published

Languages

  • Go 64.4%
  • Shell 23.9%
  • Makefile 7.6%
  • Dockerfile 4.1%