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Engine.IO: the realtime engine

Build Status NPM version

Engine is the implementation of transport-based cross-browser/cross-device bi-directional communication layer for Socket.IO.

Hello World

Server

(A) Listening on a port

var engine = require('engine.io')
  , server = engine.listen(80)

server.on('connection', function (socket) {
  socket.send('utf 8 string');
});

(B) Intercepting requests for a http.Server

var engine = require('engine.io')
  , http = require('http').createServer().listen(3000)
  , server = engine.attach(http)

server.on('connection', function (socket) {
  socket.on('message', function () { });
  socket.on('close', function () { });
});

(C) Passing in requests

var engine = require('engine.io')
  , server = new engine.Server()

server.on('connection', function (socket) {
  socket.send('hi');
});

// …
httpServer.on('upgrade', function (req, socket, head) {
  server.handleUpgrade(req, socket, head);
});
httpServer.on('request', function (req, res) {
  server.handleRequest(req, res);
});

Client

<script src="/path/to/engine.io.js"></script>
<script>
  var socket = new eio.Socket('ws://localhost/');
  socket.on('open', function () {
    socket.on('message', function (data) { });
    socket.on('close', function () { });
  });
</script>

For more information on the client refer to the engine-client repository.

What features does it have?

  • Isomorphic with WebSocket.IO. You can switch between a WebSocket server and a multi-transport server by changing the require.
  • Maximum reliability. Connections are established even in the presence of:
    • proxies and load balancers.
    • personal firewall and antivirus software.
    • for more information refer to Goals and Architecture sections
  • Minimal client size aided by:
    • lazy loading of flash transports.
    • lack of redundant transports.
  • Scalable
    • load balancer friendly
  • Future proof
  • 100% Node.JS core style
    • No API sugar (left for higher level projects)
    • Written in readable vanilla JavaScript

API

Server



Top-level

These are exposed by require('engine.io'):

Events
  • flush
    • Called when a socket buffer is being flushed.
    • Arguments
      • Socket: socket being flushed
      • Array: write buffer
  • drain
    • Called when a socket buffer is drained
    • Arguments
      • Socket: socket being flushed
Properties
  • protocol (Number): protocol revision number
  • Server: Server class constructor
  • Socket: Socket class constructor
  • Transport (Function): transport constructor
  • transports (Object): map of available transports
Methods
  • listen
    • Creates an http.Server which listens on the given port and attaches WS to it. It returns 501 Not Implemented for regular http requests.
    • Parameters
      • Number: port to listen on.
      • Function: callback for listen.
    • Returns Server
  • attach
    • Captures upgrade requests for a http.Server. In other words, makes a regular http.Server WebSocket-compatible.
    • Parameters
      • http.Server: server to attach to.
      • Object: optional, options object
    • Options
      • path (String): name of the path to capture (/engine.io).
      • policyFile (Boolean): whether to handle policy file requests (true)
      • destroyUpgrade (Boolean): destroy unhandled upgrade requests (true)
      • destroyUpgradeTimeout (Number): milliseconds after which unhandled requests are ended (1000)
      • See Server options below for additional options you can pass
    • Returns Server


Server

The main server/manager. Inherits from EventEmitter.

Events
  • connection
    • Fired when a new connection is established.
    • Arguments
      • Socket: a Socket object
Properties

Important: if you plan to use Engine.IO in a scalable way, please keep in mind the properties below will only reflect the clients connected to a single process.

  • clients (Object): hash of connected clients by id.
  • clientsCount (Number): number of connected clients.
Methods
  • constructor
    • Initializes the server
    • Parameters
      • Object: optional, options object
    • Options
      • pingTimeout (Number): how many ms without a pong packet to consider the connection closed (60000)
      • pingInterval (Number): how many ms before sending a new ping packet (25000)
      • transports (<Array> String): transports to allow connections to (['polling', 'websocket', 'flashsocket'])
      • allowUpgrades (Boolean): whether to allow transport upgrades (true)
      • cookie (String|Boolean): name of the HTTP cookie that contains the client sid to send as part of handshake response headers. Set to false to not send one. (io)
  • close
    • Closes all clients
    • Returns Server for chaining
  • handleRequest
    • Called internally when a Engine request is intercepted.
    • Parameters
      • http.ServerRequest: a node request object
      • http.ServerResponse: a node response object
    • Returns Server for chaining
  • handleUpgrade
    • Called internally when a Engine ws upgrade is intercepted.
    • Parameters (same as upgrade event)
      • http.ServerRequest: a node request object
      • net.Stream: TCP socket for the request
      • Buffer: legacy tail bytes
    • Returns Server for chaining
  • handleSocket
    • Called with raw TCP sockets from http requests to intercept flash policy file requests
    • Parameters
      • net.Stream: TCP socket on which requests are listened
    • Returns Server for chaining


Socket

A representation of a client. Inherits from EventEmitter.

Events
  • close
    • Fired when the client is disconnected.
    • Arguments
      • String: reason for closing
      • Object: description object (optional)
  • message
    • Fired when the client sends a message.
    • Arguments
      • String: Unicode string
  • error
    • Fired when an error occurs.
    • Arguments
      • Error: error object
  • flush
    • Called when the write buffer is being flushed.
    • Arguments
      • Array: write buffer
  • drain
    • Called when the write buffer is drained
  • packet
    • Called when a socket received a packet (message, ping)
    • Arguments
      • type: packet type
      • data: packet data (if type is message)
  • packetCreate
    • Called before a socket sends a packet (message, pong)
    • Arguments
      • type: packet type
      • data: packet data (if type is message)
Properties
  • server (Server): engine parent reference
  • request (http.ServerRequest): request that originated the Socket
  • upgraded (Boolean): whether the transport has been upgraded
  • readyState (String): opening|open|closing|closed
  • transport (Transport): transport reference
Methods
  • send:
    • Sends a message, performing message = toString(arguments[0]).
    • Parameters
      • String: a string or any object implementing toString(), with outgoing data
      • Function: optional, a callback executed when the message gets flushed out by the transport
    • Returns Socket for chaining
  • close
    • Disconnects the client
    • Returns Socket for chaining

Client



Exposed in the eio global namespace (in the browser), or by require('engine.io-client') (in Node.JS).

For the client API refer to the engine-client repository.

Debug / logging

Engine.IO is powered by debug. In order to see all the debug output, run your app with the environment variable DEBUG including the desired scope.

To see the output from all of Engine.IO's debugging scopes you can use:

DEBUG=engine* node myapp

Transports

  • polling: XHR / JSONP polling transport.
  • websocket: WebSocket transport.
  • flashsocket: WebSocket transport backed by flash.

Plugins

Support

The support channels for engine.io are the same as socket.io:

Development

To contribute patches, run tests or benchmarks, make sure to clone the repository:

git clone git://github.com/LearnBoost/engine.io.git

Then:

cd engine.io
npm install

Tests

Unit/Integration

$ make test

Acceptance

# make test-acceptance

And point browser/s to http://localhost:3000.

Server

Benchmarks

Server

$ make bench

Client

$ make bench-server

And point browser/s to http://localhost:3000.

Goals

The main goal of Engine is ensuring the most reliable realtime communication. Unlike the previous Socket.IO core, it always establishes a long-polling connection first, then tries to upgrade to better transports that are "tested" on the side.

During the lifetime of the Socket.IO projects, we've found countless drawbacks to relying on HTML5 WebSocket or Flash Socket as the first connection mechanisms.

Both are clearly the right way of establishing a bidirectional communication, with HTML5 WebSocket being the way of the future. However, to answer most business needs, alternative traditional HTTP 1.1 mechanisms are just as good as delivering the same solution.

WebSocket/FlashSocket based connections have two fundamental benefits:

  1. Better server performance
  • A: Load balancers
    Load balancing a long polling connection poses a serious architectural nightmare since requests can come from any number of open sockets by the user agent, but they all need to be routed to the process and computer that owns the Engine connection. This negatively impacts RAM and CPU usage.
  • B: Network traffic
    WebSocket is designed around the premise that each message frame has to be surrounded by the least amount of data. In HTTP 1.1 transports, each message frame is surrounded by HTTP headers and chunked encoding frames. If you try to send the message "Hello world" with xhr-polling, the message ultimately becomes larger than if you were to send it with WebSocket.
  • C: Lightweight parser
    As an effect of B, the server has to do a lot more work to parse the network data and figure out the message when traditional HTTP requests are used (as in long polling). This means that another advantage of WebSocket is less server CPU usage.
  1. Better user experience

    Due to the reasons stated in point 1, the most important effect of being able to establish a WebSocket connection is raw data transfer speed, which translates in some cases in better user experience.

    Applications with heavy realtime interaction (such as games) will benefit greatly, whereas applications like realtime chat (Gmail/Facebook), newsfeeds (Facebook) or timelines (Twitter) will have negligible user experience improvements.

Having said this, attempting to establish a WebSocket connection directly so far has proven problematic:

  1. Proxies
    Many corporate proxies block WebSocket traffic.

  2. Personal firewall and antivirus software
    As a result of our research, we've found that at least 3 personal security applications block WebSocket traffic.

  3. Cloud application platforms
    Platforms like Heroku or No.de have had trouble keeping up with the fast-paced nature of the evolution of the WebSocket protocol. Applications therefore end up inevitably using long polling, but the seamless installation experience of Socket.IO we strive for ("require() it and it just works") disappears.

Some of these problems have solutions. In the case of proxies and personal programs, however, the solutions many times involve upgrading software. Experience has shown that relying on client software upgrades to deliver a business solution is fruitless: the very existence of this project has to do with a fragmented panorama of user agent distribution, with clients connecting with latest versions of the most modern user agents (Chrome, Firefox and Safari), but others with versions as low as IE 5.5.

From the user perspective, an unsuccessful WebSocket connection can translate in up to at least 10 seconds of waiting for the realtime application to begin exchanging data. This perceptively hurts user experience.

To summarize, Engine focuses on reliability and user experience first, marginal potential UX improvements and increased server performance second. Engine is the result of all the lessons learned with WebSocket in the wild.

Architecture

The main premise of Engine, and the core of its existence, is the ability to swap transports on the fly. A connection starts as xhr-polling, but it can switch to WebSocket.

The central problem this poses is: how do we switch transports without losing messages?

Engine only switches from polling to another transport in between polling cycles. Since the server closes the connection after a certain timeout when there's no activity, and the polling transport implementation buffers messages in between connections, this ensures no message loss and optimal performance.

Another benefit of this design is that we workaround almost all the limitations of Flash Socket, such as slow connection times, increased file size (we can safely lazy load it without hurting user experience), etc.

FAQ

Can I use engine without Socket.IO ?

Absolutely. Although the recommended framework for building realtime applications is Socket.IO, since it provides fundamental features for real-world applications such as multiplexing, reconnection support, etc.

Engine is to Socket.IO what Connect is to Express. An essential piece for building realtime frameworks, but something you probably won't be using for building actual applications.

Does the server serve the client?

No. The main reason is that Engine is meant to be bundled with frameworks. Socket.IO includes Engine, therefore serving two clients is not necessary. If you use Socket.IO, including

<script src="/socket.io/socket.io.js">

has you covered.

Can I implement Engine in other languages?

Absolutely. The SPEC file contains the most up to date description of the implementation specification at all times. If you're targeting the latest stable release of Engine, make sure to look at the file in the appropriate git branch/tag.

The Java/NIO implementation will be officially supported, and is being worked on by the author.

License

(The MIT License)

Copyright (c) 2011 Guillermo Rauch <[email protected]>

Permission is hereby granted, free of charge, to any person obtaining a copy of this software and associated documentation files (the 'Software'), to deal in the Software without restriction, including without limitation the rights to use, copy, modify, merge, publish, distribute, sublicense, and/or sell copies of the Software, and to permit persons to whom the Software is furnished to do so, subject to the following conditions:

The above copyright notice and this permission notice shall be included in all copies or substantial portions of the Software.

THE SOFTWARE IS PROVIDED 'AS IS', WITHOUT WARRANTY OF ANY KIND, EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.