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This version of GitHub Enterprise was discontinued on 2022-10-12. No patch releases will be made, even for critical security issues. For better performance, improved security, and new features, upgrade to the latest version of GitHub Enterprise. For help with the upgrade, contact GitHub Enterprise support.

Securing your webhooks

Ensure your server is only receiving the expected GitHub requests for security reasons.

Once your server is configured to receive payloads, it'll listen for any payload sent to the endpoint you configured. For security reasons, you probably want to limit requests to those coming from GitHub. There are a few ways to go about this--for example, you could opt to allow requests from GitHub's IP address--but a far easier method is to set up a secret token and validate the information.

The webhook REST APIs enable you to manage repository, organization, and app webhooks. You can also use the REST API to change the configuration of the webhook. For example, you can modify the payload URL, content type, SSL verification, and secret. For more information, see:

Setting your secret token

You'll need to set up your secret token in two places: GitHub and your server.

To set your token on GitHub:

  1. Navigate to the repository where you're setting up your webhook.
  2. Fill out the Secret textbox. Use a random string with high entropy (e.g., by taking the output of ruby -rsecurerandom -e 'puts SecureRandom.hex(20)' at the terminal). Webhook secret token field
  3. Click Update Webhook.

Next, set up an environment variable on your server that stores this token. Typically, this is as simple as running:

$ export SECRET_TOKEN=YOUR-TOKEN

Never hardcode the token into your app!

Validating payloads from GitHub

When your secret token is set, GitHub Enterprise Server uses it to create a hash signature with each payload. This hash signature is included with the headers of each request as x-hub-signature-256.

Note: For backward-compatibility, we also include the x-hub-signature header that is generated using the SHA-1 hash function. If possible, we recommend that you use the x-hub-signature-256 header for improved security. The example below demonstrates using the x-hub-signature-256 header.

For example, if you have a basic server that listens for webhooks, it might be configured similar to this:

require 'sinatra'
require 'json'

post '/payload' do
  request.body.rewind
  push = JSON.parse(request.body.read)
  "I got some JSON: #{push.inspect}"
end

The intention is to calculate a hash using your SECRET_TOKEN, and ensure that the result matches the hash from GitHub Enterprise Server. GitHub Enterprise Server uses an HMAC hex digest to compute the hash, so you could reconfigure your server to look a little like this:

post '/payload' do
  request.body.rewind
  payload_body = request.body.read
  verify_signature(payload_body)
  push = JSON.parse(payload_body)
  "I got some JSON: #{push.inspect}"
end

def verify_signature(payload_body)
  signature = 'sha256=' + OpenSSL::HMAC.hexdigest(OpenSSL::Digest.new('sha256'), ENV['SECRET_TOKEN'], payload_body)
  return halt 500, "Signatures didn't match!" unless Rack::Utils.secure_compare(signature, request.env['HTTP_X_HUB_SIGNATURE_256'])
end

Note: Webhook payloads can contain unicode characters. If your language and server implementation specifies a character encoding, ensure that you handle the payload as UTF-8.

Your language and server implementations may differ from this example code. However, there are a number of very important things to point out:

  • No matter which implementation you use, the hash signature starts with sha256=, using the key of your secret token and your payload body.

  • Using a plain == operator is not advised. A method like secure_compare performs a "constant time" string comparison, which helps mitigate certain timing attacks against regular equality operators.