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MessageBus

A reliable, robust messaging bus for Ruby processes and web clients.

MessageBus implements a Server to Server channel based protocol and Server to Web Client protocol (using polling, long-polling or long-polling + streaming)

Since long-polling is implemented using Rack Hijack and Thin::Async, all common Ruby web servers (Thin, Puma, Unicorn, Passenger) can run MessageBus and handle a large number of concurrent connections that wait on messages.

MessageBus is implemented as Rack middleware and can be used by any Rails / Sinatra or pure Rack application.

Read the generated docs: https://www.rubydoc.info/gems/message_bus

Ruby version support

MessageBus only support officially supported versions of Ruby; as of 2018-06-20 this means we only support Ruby version 2.3 and up.

Can you handle concurrent requests?

Yes, MessageBus uses Rack Hijack and this interface allows us to take control of the underlying socket. MessageBus can handle thousands of concurrent long polls on all popular Ruby webservers. MessageBus runs as middleware in your Rack (or by extension Rails) application and does not require a dedicated server. Background work is minimized to ensure it does not interfere with existing non-MessageBus traffic.

Is this used in production at scale?

Yes, MessageBus was extracted out of Discourse and is used in thousands of production Discourse sites at scale.

Installation

Add this line to your application's Gemfile:

gem 'message_bus'

And then execute:

$ bundle

Or install it yourself as:

$ gem install message_bus

Usage

Server to Server messaging

message_id = MessageBus.publish "/channel", "message"

# in another process / spot

MessageBus.subscribe "/channel" do |msg|
  # block called in a background thread when message is received
end

# subscribe to channel and receive the entire backlog
MessageBus.subscribe "/channel", 0 do |msg|
  # block called in a background thread when message is received
end

# subscribe to channel and receive the backlog starting at message 6
MessageBus.subscribe "/channel", 5 do |msg|
  # block called in a background thread when message is received
end
# get the ID of the last message on a channel
id = MessageBus.last_id("/channel")

# returns all messages after some id
MessageBus.backlog "/channel", id

Targetted messages

Messages can be targetted to particular clients by supplying the client_ids option when publishing a message.

MessageBus.publish "/channel", "hello", client_ids: ["XXX", "YYY"] # (using MessageBus.clientId)

By configuring the user_id_lookup and group_ids_lookup options with a Proc or Lambda which will be called with a Rack specification environment, messages can be targetted to particular clients users or groups by supplying either the user_ids or group_ids options when publishing a message.

MessageBus.configure(user_id_lookup: proc do |env|
  # this lookup occurs on JS-client poolings, so that server can retrieve backlog
  # for the client considering/matching/filtering user_ids set on published messages
  # if user_id is not set on publish time, any user_id returned here will receive the message
  # return the user id here
end)

# Target user_ids when publishing a message
MessageBus.publish "/channel", "hello", user_ids: [1, 2, 3]

MessageBus.configure(group_ids_lookup: proc do |env|
  # return the group ids the user belongs to
  # can be nil or []
end)

# Target group_ids when publishing a message
MessageBus.publish "/channel", "hello", group_ids: [1, 2, 3]

# example of MessageBus to set user_ids from an initializer in Rails and Devise:
# config/inializers/message_bus.rb
MessageBus.user_id_lookup do |env|
  req = Rack::Request.new(env)

  if req.session && req.session["warden.user.user.key"] && req.session["warden.user.user.key"][0][0]
    user = User.find(req.session["warden.user.user.key"][0][0])
    user.id
  end
end

If both user_ids and group_ids options are supplied when publishing a message, the message will be targetted at clients with lookup return values that matches on either the user_ids or the group_ids options.

MessageBus.publish "/channel", "hello", user_ids: [1, 2, 3], group_ids: [1, 2, 3]

If the client_ids option is supplied with either the user_ids or group_ids options when publising a message, the client_ids option will be applied unconditionally and messages will be filtered further using user_id or group_id clauses.

MessageBus.publish "/channel", "hello", client_ids: ["XXX", "YYY"], user_ids: [1, 2, 3], group_ids: [1, 2, 3]

Passing nil or [] to either client_ids, user_ids or group_ids is equivalent to allowing all values on each option.

Filtering Client Messages

Custom client message filters can be registered via MessageBus#register_client_message_filter. This can be useful for filtering away messages from the client based on the message's payload.

For example, ensuring that only messages seen by the server in the last 20 seconds are published to the client:

MessageBus.register_client_message_filter('/test') do |message|
  (Time.now.to_i - message.data[:published_at]) <= 20
end

MessageBus.publish('/test/5', { data: "somedata", published_at: Time.now.to_i })

Error handling

MessageBus.configure(on_middleware_error: proc do |env, e|
   # If you wish to add special handling based on error
   # return a rack result array: [status, headers, body]
   # If you just want to pass it on return nil
end)

Disabling message_bus

In certain cases, it is undesirable for message_bus to start up on application start, for example in a Rails application during the db:create rake task when using the Postgres backend (which will error trying to connect to the non-existent database to subscribe). You can invoke MessageBus.off before the middleware chain is loaded in order to prevent subscriptions and publications from happening; in a Rails app you might do this in an initializer based on some environment variable or some other conditional means.

Debugging

When setting up MessageBus, it's useful to manually inspect channels before integrating a client application.

You can curl MessageBus; this is helpful when trying to debug what may be going wrong. This example uses https://chat.samsaffron.com:

curl -H "Content-Type: application/x-www-form-urlencoded" -X POST --data "/message=0" https://chat.samsaffron.com/message-bus/client-id/poll\?dlp\=t

You should see a reply with the messages of that channel you requested (in this case /message) starting at the message ID you requested (0). The URL parameter dlp=t disables long-polling: we do not want this request to stay open.

Diagnostics

MessageBus comes with a diagnostics interface, which you can access at /message-bus/_diagnostics. This interface allows you visibility into the runtime behaviour of message_bus.

In order to use the diagnostics UI in your application, it is necessary to:

  • Enable it
  • Define a user ID for requests
  • Define a check for admin role

as an example, you can do something like this:

MessageBus.enable_diagnostics # Must be called after `MessageBus.after_fork` if using a forking webserver

MessageBus.user_id_lookup do |_env|
  1
end

MessageBus.is_admin_lookup do |_env|
  true
end

Of course, in your real-world application, you would define these values according to your authentication/authorization logic.

Transport

MessageBus ships with 3 transport mechanisms.

  1. Long Polling with chunked encoding (streaming)
  2. Long Polling
  3. Polling

Long Polling with chunked encoding allows a single connection to stream multiple messages to a client, and this requires HTTP/1.1.

Chunked encoding provides all the benefits of EventSource with greater browser support (as it works on IE10 and up as well)

To setup NGINX to proxy to your app correctly be sure to enable HTTP1.1 and disable buffering:

location /message-bus/ {
  ...
  proxy_http_version 1.1;
  proxy_buffering off;
  ...
}

NOTE: do not set proxy_buffering off globally, it may have unintended consequences.

In order to disable chunked encoding for a specific client in Javascript:

MessageBus.enableChunkedEncoding = false;

or as a server-side policy in Ruby for all clients:

MessageBus.configure(chunked_encoding_enabled: false)

Long Polling requires no special setup; as soon as new data arrives on the channel the server delivers the data and closes the connection.

Polling also requires no special setup; MessageBus will fallback to polling after a tab becomes inactive and remains inactive for a period.

Multisite support

MessageBus can be used in an environment that hosts multiple sites by multiplexing channels. To use this mode:

# define a site_id lookup method, which is executed
# when `MessageBus.publish` is called
MessageBus.configure(site_id_lookup: proc do
  some_method_that_returns_site_id_string
end)

# you may post messages just to this site
MessageBus.publish "/channel", "some message"

# you can also choose to pass the `:site_id`.
# This takes precendence over whatever `site_id_lookup`
# returns
MessageBus.publish "/channel", "some message", site_id: "site-id"

# you may publish messages to ALL sites using the /global/ prefix
MessageBus.publish "/global/channel", "will go to all sites"

Client support

JavaScript Client

MessageBus ships a simple ~300 line JavaScript library which provides an API to interact with the server.

JavaScript clients can listen on any channel and receive messages via polling or long polling. You may simply include the source file (located in assets/ within the message_bus source code):

<script src="message-bus.js" type="text/javascript"></script>

or when used in a Rails application, import it through the asset pipeline:

//= require message-bus

In your application Javascript, you can then subscribe to particular channels and define callback functions to be executed when messages are received:

MessageBus.start(); // call once at startup

// how often do you want the callback to fire in ms
MessageBus.callbackInterval = 500;

// you will get all new messages sent to channel
MessageBus.subscribe("/channel", function(data){
  // data shipped from server
});

// you will get all new messages sent to channel (-1 is implicit)
MessageBus.subscribe("/channel", function(data){
  // data shipped from server
}, -1);

// all messages AFTER message id 7 AND all new messages
MessageBus.subscribe("/channel", function(data){
  // data shipped from server
}, 7);

// last 2 messages in channel AND all new messages
MessageBus.subscribe("/channel", function(data){
  // data shipped from server
}, -3);

// you will get the entire backlog
MessageBus.subscribe("/channel", function(data){
  // data shipped from server
}, 0);

JavaScript Client settings

All client settings are settable via MessageBus.OPTION

Setting Default Info
enableLongPolling true Allow long-polling (provided it is enabled by the server)
callbackInterval 15000 Safeguard to ensure background polling does not exceed this interval (in milliseconds)
backgroundCallbackInterval 60000 Interval to poll when long polling is disabled (either explicitly or due to browser being in background)
minPollInterval 100 When polling requests succeed, this is the minimum amount of time to wait before making the next request.
maxPollInterval 180000 If request to the server start failing, MessageBus will backoff, this is the upper limit of the backoff.
alwaysLongPoll false For debugging you may want to disable the "is browser in background" check and always long-poll
shouldLongPollCallback undefined A callback returning true or false that determines if we should long-poll or not, if unset ignore and simply depend on window visibility.
baseUrl / If message bus is mounted at a sub-path or different domain, you may configure it to perform requests there. See MessageBus.base_route= on how to configure the MessageBus server to listen on a sub-path.
ajax $.ajax falling back to XMLHttpRequest MessageBus will first attempt to use jQuery and then fallback to a plain XMLHttpRequest version that's contained in the message-bus-ajax.js file. message-bus-ajax.js must be loaded after message-bus.js for it to be used. You may override this option with a function that implements an ajax request by some other means
headers {} Extra headers to be include with requests. Properties and values of object must be valid values for HTTP Headers, i.e. no spaces or control characters.
minHiddenPollInterval 1500 Time to wait between poll requests performed by background or hidden tabs and windows, shared state via localStorage
enableChunkedEncoding true Allows streaming of message bus data over the HTTP connection without closing the connection after each message.

Javascript Client API

MessageBus.start() : Starts up the MessageBus poller

MessageBus.subscribe(channel,func,lastId) : Subscribes to a channel. You may optionally specify the id of the last message you received in the channel. The callback receives three arguments on message delivery: func(payload, globalId, messageId). You may save globalId or messageId of received messages and use then at a later time when client needs to subscribe, receiving the backlog since that id.

MessageBus.unsubscribe(channel,func) : Removes a subscription from a particular channel that was defined with a particular callback function (optional).

MessageBus.pause() : Pauses all MessageBus activity

MessageBus.resume() : Resumes MessageBus activity

MessageBus.stop() : Stops all MessageBus activity

MessageBus.status() : Returns status (started, paused, stopped)

MessageBus.diagnostics() : Returns a log that may be used for diagnostics on the status of message bus.

Ruby

The gem ships with a Ruby implementation of the client library available with an API very similar to that of the JavaScript client. It was inspired by https://github.com/lowjoel/message_bus-client.

# Creates a client with the default configuration
client = MessageBus::HTTPClient.new('http://some.test.com')

# Listen for the latest messages
client.subscribe("/channel") { |data| puts data }

# Listen for all messages after id 7
client.subscribe("/channel", last_message_id: 7) { |data| puts data }

# Listen for last message and all new messages
client.subscribe("/channel", last_message_id: -2) { |data| puts data }

# Unsubscribe from a channel
client.unsubscribe("/channel")

# Unsubscribe a particular callback from a channel
callback = -> { |data| puts data }
client.subscribe("/channel", &callback)
client.unsubscribe("/channel", &callback)

Ruby Client Settings

Setting Default Info
enable_long_polling true Allow long-polling (provided it is enabled by the server)
background_callback_interval 60s Interval to poll when long polling is disabled
min_poll_interval 0.1s When polling requests succeed, this is the minimum amount of time to wait before making the next request.
max_poll_interval 180s If request to the server start failing, MessageBus will backoff, this is the upper limit of the backoff.
enable_chunked_encoding true Allows streaming of message bus data over the HTTP connection without closing the connection after each message.
headers {} Extra headers to be include with requests. Properties and values of object must be valid values for HTTP Headers, i.e. no spaces or control characters.

Configuration

message_bus can be configured to use one of several available storage backends, and each has its own configuration options.

Redis

message_bus supports using Redis as a storage backend, and you can configure message_bus to use redis in config/initializers/message_bus.rb, like so:

MessageBus.configure(backend: :redis, url: "redis://:[email protected]:6380/15")

The redis client message_bus uses is redis-rb, so you can visit it's repo to see what other options you can pass besides a url.

Data Retention

Out of the box Redis keeps track of 2000 messages in the global backlog and 1000 messages in a per-channel backlog. Per-channel backlogs get cleared automatically after 7 days of inactivity.

This is configurable via accessors on the ReliablePubSub instance.

# only store 100 messages per channel
MessageBus.reliable_pub_sub.max_backlog_size = 100

# only store 100 global messages
MessageBus.reliable_pub_sub.max_global_backlog_size = 100

# flush per-channel backlog after 100 seconds of inactivity
MessageBus.reliable_pub_sub.max_backlog_age = 100

PostgreSQL

message_bus also supports PostgreSQL as a backend, and can be configured like so:

MessageBus.configure(backend: :postgres, backend_options: {user: 'message_bus', dbname: 'message_bus'})

The PostgreSQL client message_bus uses is ruby-pg, so you can visit it's repo to see what options you can include in :backend_options.

A :clear_every option is also supported, which limits backlog trimming frequency to the specified number of publications. If you set clear_every: 100, the backlog will only be cleared every 100 publications. This can improve performance in cases where exact backlog length limiting is not required.

Memory

message_bus also supports an in-memory backend. This can be used for testing or simple single-process environments that do not require persistence or horizontal scalability.

MessageBus.configure(backend: :memory)

The :clear_every option supported by the PostgreSQL backend is also supported by the in-memory backend.

Transport codecs

By default MessageBus serializes messages to the backend using JSON. Under most situation this performs extremely well.

In some exceptional cases you may consider a different transport codec. To configure a custom codec use:

MessageBus.configure(transport_codec: codec)

A codec class must implement MessageBus::Codec::Base. Specifically an encode and decode method.

See the bench directory for examples where the default JSON codec can perform poorly. A specific examples may be attempting to distribute a message to a restricted list of thousands of users. In cases like this you may consider using a packed string encoder.

Keep in mind, much of MessageBus internals and supporting tools expect data to be converted to JSON and back, if you use a naive (and fast) Marshal based codec you may need to limit the features you use. Specifically the Postgresql backend expects the codec never to return a string with \u0000, additionally some classes like DistributedCache expect keys to be converted to Strings.

Another example may be very large and complicated messages where Oj in compatability mode outperforms JSON. To opt for the Oj codec use:

MessageBus.configure(transport_codec: MessageBus::Codec::Oj.new)

Forking/threading app servers

If you're using a forking or threading app server and you're not getting immediate delivery of published messages, you might need to configure your web server to re-connect to the message_bus backend

Passenger

# Rails: config/application.rb or config.ru
if defined?(PhusionPassenger)
  PhusionPassenger.on_event(:starting_worker_process) do |forked|
    if forked
      # We're in smart spawning mode.
      MessageBus.after_fork
    else
      # We're in conservative spawning mode. We don't need to do anything.
    end
  end
end

MessageBus uses long polling which needs to be configured in Passenger

For passenger version < 5.0.21, add the following to application.rb:

PhusionPassenger.advertised_concurrency_level = 0

For passenger version > 5.0.21, add the following to nginx.conf:

location /message-bus {
  passenger_app_group_name foo_websocket;
  passenger_force_max_concurrent_requests_per_process 0;
}

For more information see the Passenger documentation on long-polling.

Puma

# path/to/your/config/puma.rb
require 'message_bus' # omit this line for Rails 5
on_worker_boot do
  MessageBus.after_fork
end

Unicorn

# path/to/your/config/unicorn.rb
require 'message_bus'
after_fork do |server, worker|
  MessageBus.after_fork
end

Middleware stack in Rails

MessageBus middleware has to show up after the session middleware, but depending on how the Rails app is configured that might be either ActionDispatch::Session::CookieStore or ActionDispatch::Session::ActiveRecordStore. To handle both cases, the middleware is inserted before ActionDispatch::Flash.

For APIs or apps that have ActionDispatch::Flash deleted from the stack the middleware is pushed to the bottom.

Should you wish to manipulate the default behavior please refer to Rails MiddlewareStackProxy documentation and alter the order of the middlewares in stack in app/config/initializers/message_bus.rb

# config/initializers/message_bus.rb
Rails.application.config do |config|
  # do anything you wish with config.middleware here
end

Specifically, if you use a Rack middleware-based authentication solution (such as Warden) in a Rails application and wish to use it for authenticating message_bus requests, you must ensure that the MessageBus middleware comes after it in the stack. Unfortunately, this can be difficult, but the following solution is known to work:

# config/initializers/message_bus.rb
Rails.application.config do |config|
  # See https://github.com/rails/rails/issues/26303#issuecomment-442894832
  MyAppMessageBusMiddleware = Class.new(MessageBus::Rack::Middleware)
  config.middleware.delete(MessageBus::Rack::Middleware)
  config.middleware.insert_after(Warden::Manager, MyAppMessageBusMiddleware)
end

A Distributed Cache

MessageBus ships with an optional DistributedCache API which provides a simple and efficient way of synchronizing a cache between processes, based on the core of message_bus:

require 'message_bus/distributed_cache'

# process 1

cache = MessageBus::DistributedCache.new("animals")

# process 2

cache = MessageBus::DistributedCache.new("animals")

# process 1

cache["frogs"] = 5

# process 2

puts cache["frogs"]
# => 5

cache["frogs"] = nil

# process 1

puts cache["frogs"]
# => nil

You can automatically expire the cache on application code changes by scoping the cache to a specific version of the application:

cache = MessageBus::DistributedCache.new("cache name", app_version: "12.1.7.ABDEB")
cache["a"] = 77

cache = MessageBus::DistributedCache.new("cache name", app_version: "12.1.7.ABDEF")

puts cache["a"]
# => nil

Error Handling

The internet is a chaotic environment and clients can drop off for a variety of reasons. If this happens while message_bus is trying to write a message to the client you may see something like this in your logs:

Errno::EPIPE: Broken pipe
  from message_bus/client.rb:159:in `write'
  from message_bus/client.rb:159:in `write_headers'
  from message_bus/client.rb:178:in `write_chunk'
  from message_bus/client.rb:49:in `ensure_first_chunk_sent'
  from message_bus/rack/middleware.rb:150:in `block in call'
  from message_bus/client.rb:21:in `block in synchronize'
  from message_bus/client.rb:21:in `synchronize'
  from message_bus/client.rb:21:in `synchronize'
  from message_bus/rack/middleware.rb:147:in `call'
  ...

The user doesn't see anything, but depending on your traffic you may acquire quite a few of these in your logs or exception tracking tool.

You can rescue from errors that occur in MessageBus's middleware stack by adding a config option:

MessageBus.configure(on_middleware_error: proc do |env, e|
  # env contains the Rack environment at the time of error
  # e contains the exception that was raised
  if Errno::EPIPE === e
    [422, {}, [""]]
  else
    raise e
  end
end)

Adding extra response headers

In e.g. config/initializers/message_bus.rb:

MessageBus.extra_response_headers_lookup do |env|
  [
      ["Access-Control-Allow-Origin", "http://example.com:3000"],
  ]
end

How it works

MessageBus provides durable messaging following the publish-subscribe (pubsub) pattern to subscribers who track their own subscriptions. Durability is by virtue of the persistence of messages in backlogs stored in the selected backend implementation (Redis, Postgres, etc) which can be queried up until a configurable expiry. Subscribers must keep track of the ID of the last message they processed, and request only more-recent messages in subsequent connections.

The MessageBus implementation consists of several key parts:

  • Backend implementations - these provide a consistent API over a variety of options for persisting published messages. The API they present is around the publication to and reading of messages from those backlogs in a manner consistent with message_bus' philosophy. Each of these inherits from MessageBus::Backends::Base and implements the interface it documents.
  • MessageBus::Rack::Middleware - which accepts requests from subscribers, validates and authenticates them, delivers existing messages from the backlog and informs a MessageBus::ConnectionManager of a connection which is remaining open.
  • MessageBus::ConnectionManager - manages a set of subscribers with active connections to the server, such that messages which are published during the connection may be dispatched.
  • MessageBus::Client - represents a connected subscriber and delivers published messages over its connected socket.
  • MessageBus::Message - represents a published message and its encoding for persistence.

The public API is all defined on the MessageBus module itself.

Subscriber protocol

The message_bus protocol for subscribing clients is based on HTTP, optionally with long-polling and chunked encoding, as specified by the HTTP/1.1 spec in RFC7230 and RFC7231.

The protocol consists of a single HTTP end-point at /message-bus/[client_id]/poll, which responds to POST and OPTIONS. In the course of a POST request, the client must indicate the channels from which messages are desired, along with the last message ID the client received for each channel, and an incrementing integer sequence number for each request (used to detect out of order requests and close those with the same client ID and lower sequence numbers).

Clients' specification of requested channels can be submitted in either JSON format (with a Content-Type of application/json) or as HTML form data (using application/x-www-form-urlencoded). An example request might look like:

POST /message-bus/3314c3f12b1e45b4b1fdf1a6e42ba826/poll HTTP/1.1
Host: foo.com
Content-Type: application/json
Content-Length: 37

{"/foo/bar":3,"/doo/dah":0,"__seq":7}

If there are messages more recent than the client-specified IDs in any of the requested channels, those messages will be immediately delivered to the client. If the server is configured for long-polling, the client has not requested to disable it (by specifying the dlp=t query parameter), and no new messages are available, the connection will remain open for the configured long-polling interval (25 seconds by default); if a message becomes available in that time, it will be delivered, else the connection will close. If chunked encoding is enabled, message delivery will not automatically end the connection, and messages will be continuously delivered during the life of the connection, separated by "\r\n|\r\n".

The format for delivered messages is a JSON array of message objects like so:

[
  {
    "global_id": 12,
    "message_id": 1,
    "channel": "/some/channel/name",
    "data": [the message as published]
  }
]

The global_id field here indicates the ID of the message in the global backlog, while the message_id is the ID of the message in the channel-specific backlog. The ID used for subscriptions is always the channel-specific one.

In certain conditions, a status message will be delivered and look like this:

{
  "global_id": -1,
  "message_id": -1,
  "channel": "/__status",
  "data": {
    "/some/channel":5,
    "/other/channel":9
  }
}

This message indicates the last ID in the backlog for each channel that the client subscribed to. It is sent in the following circumstances:

  • When the client subscribes to a channel starting from -1. When long-polling, this message will be delivered immediately.
  • When the client subscribes to a channel starting from a message ID that is beyond the last message on that channel.
  • When delivery of messages to a client is skipped because the message is filtered to other users/groups.

The values provided in this status message can be used by the client to skip requesting messages it will never receive and move forward in polling.

Publishing to MessageBus from outside of MessageBus

It may be necessary or desired for integration with existing systems to publish messages from outside the Ruby app where MessageBus is running. @tgodfrey has an example of how to do that, using the Redis backend, from Elixir here: https://gist.github.com/tgodfrey/1a67753d51cb202ca8eb04b933cec924.

Contributing

If you are looking to contribute to this project here are some ideas

  • MAKE THIS README BETTER!
  • Build backends for other providers (zeromq, rabbitmq, disque) - currently we support pg and redis.
  • Improve and properly document admin dashboard (add opt-in stats, better diagnostics into queues)
  • Improve general documentation (Add examples, refine existing examples)
  • Make MessageBus a nice website
  • Add optional transports for websocket and shared web workers

When submitting a PR, please be sure to include notes on it in the Unreleased section of the changelog, but do not bump the version number.

Running tests

To run tests you need both Postgres and Redis installed. By default on Redis the tests connect to localhost:6379 and on Postgres connect the database localhost:5432/message_bus_test with the system username; if you wish to override this, you can set alternative values:

PGUSER=some_user PGDATABASE=some_db bundle exec rake

We include a Docker Compose configuration to run test suite in isolation, or if you do not have Redis or Postgres installed natively. To execute it, do docker-compose run tests.

Generating the documentation

Run rake yard (or docker-compose run docs rake yard) in order to generate the implementation's API docs in HTML format, and open doc/index.html to view them.

While working on documentation, it is useful to automatically re-build it as you make changes. You can do yard server --reload (or docker-compose up docs) and open http://localhost:8808 to browse live-built docs as you edit them.

Benchmarks

Some simple benchmarks are implemented in spec/performance and can be executed using rake performance (or docker-compose run tests rake performance). You should run these before and after your changes to avoid introducing performance regressions.

Diagnostics Interface

It is possible to manually test the diagnostics interface by executing docker-compose up example and then open http://localhost:9292.

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