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How to build a basic Socket.IO client

In this guide, we will implement a basic Socket.IO client in JavaScript, in order to get a better understanding of the Socket.IO protocol.

We will implement the following features:

  • creating a WebSocket connection
  • managing reconnections
  • sending events
  • receiving events
  • disconnecting manually

The official client obviously contains a lot more features:

But that should be sufficient to give you a good overview of how the library works under the hood.

Our goal is to achieve something like this:

import { io } from "./basic-client.js";

const socket = io();

// connection
socket.on("connect", () => {
// ...
});

// receiving an event
socket.on("foo", (value) => {
// ...
});

// sending an event
socket.emit("bar", "abc");

Ready? Let's do this!

Event emitter

The Socket.IO API is heavily inspired from the Node.js EventEmitter class.

import { EventEmitter } from "node:events";

const myEmitter = new EventEmitter();

myEmitter.on("foo", () => {
console.log("foo!");
});

myEmitter.emit("foo");

The library provides a similar API, but between a server and a client:

  • server
io.on("connection", (socket) => {
// send a "foo" event to the client
socket.emit("foo");

// receive a "bar" event from the client
socket.on("bar", () => {
// ...
});
});
  • client
import { io } from "socket.io-client";

const socket = io();

// receive a "foo" event from the server
socket.on("foo", () => {
// ...
});

// send a "bar" event to the server
socket.emit("bar");

The underlying connection between the server and the client (WebSocket or HTTP long-polling) is abstracted away and managed by the library.

Let's create a minimalistic EventEmitter class:

class EventEmitter {
#listeners = new Map();

on(event, listener) {
let listeners = this.#listeners.get(event);
if (!listeners) {
this.#listeners.set(event, listeners = []);
}
listeners.push(listener);
}

emit(event, ...args) {
const listeners = this.#listeners.get(event);
if (listeners) {
for (const listener of listeners) {
listener.apply(null, args);
}
}
}
}

Our Socket class will then extend this class, in order to expose both the on() and the emit() methods:

class Socket extends EventEmitter {
constructor(uri, opts) {
super();
}
}

In our constructor, the uri argument is either:

  • provided by the user:
const socket = io("https://example.com");
const socket = io();

Let's create an entrypoint:

export function io(uri, opts) {
if (typeof uri !== "string") {
opts = uri;
uri = location.origin;
}
return new Socket(uri, opts);
}

OK, so that's a good start!

WebSocket connection

Now, let's create the WebSocket connection to the server:

class Socket extends EventEmitter {
+ #uri;
+ #opts;
+ #ws;

constructor(uri, opts) {
super();
+ this.#uri = uri;
+ this.#opts = Object.assign({
+ path: "/socket.io/"
+ }, opts);
+ this.#open();
}

+ #open() {
+ this.#ws = new WebSocket(this.#createUrl());
+ }
+
+ #createUrl() {
+ const uri = this.#uri.replace(/^http/, "ws");
+ const queryParams = "?EIO=4&transport=websocket";
+ return `${uri}${this.#opts.path}${queryParams}`;
+ }
}

Reference: https://developer.mozilla.org/en-US/docs/Web/API/WebSocket

Some explanations about the createUrl() method:

  • a WebSocket URL starts with ws:// or wss://, so we handle this in the replace() call
  • a Socket.IO URL always contains a specific request path, which defaults to /socket.io/
  • there are two mandatory query parameters:
    • EIO=4: the version of the Engine.IO protocol
    • transport=websocket: the transport used

So the final URL will look like: wss://example.com/socket.io/?EIO=4&transport=websocket

The Engine.IO protocol

The Socket.IO codebase is split into two distinct layers:

  • the low-level plumbing: what we call Engine.IO, the engine inside Socket.IO
  • the high-level API: Socket.IO itself

See also:

When using WebSocket, the format of the messages sent over the wire is simply: <packet type><payload>

Here are the different packet types in the 4th version (hence the EIO=4 above) of the protocol:

NameRepresentationDescription
OPEN0Used during the handshake.
CLOSE1Used to indicate that a transport can be closed.
PING2Used in the heartbeat mechanism.
PONG3Used in the heartbeat mechanism.
MESSAGE4Used to send a payload to the other side.
UPGRADE5Used during the upgrade process (not used here).
NOOP6Used during the upgrade process (not used here).

Example:

4hello

with:

4 => MESSAGE packet type
hello => message payload (UTF-8 encoded)

Let's handle the WebSocket messages:

+const EIOPacketType = {
+ OPEN: "0",
+ CLOSE: "1",
+ PING: "2",
+ PONG: "3",
+ MESSAGE: "4",
+};

+function noop() {}

class Socket extends EventEmitter {
[...]

#open() {
this.#ws = new WebSocket(this.#createUrl());
+ this.#ws.onmessage = ({ data }) => this.#onMessage(data);
+ this.#ws.onclose = () => this.#onClose("transport close");
}

+ #onMessage(data) {
+ if (typeof data !== "string") {
+ // TODO handle binary payloads
+ return;
+ }
+
+ switch (data[0]) {
+ case EIOPacketType.CLOSE:
+ this.#onClose("transport close");
+ break;
+
+ default:
+ this.#onClose("parse error");
+ break;
+ }
+ }
+
+ #onClose(reason) {
+ if (this.#ws) {
+ this.#ws.onclose = noop;
+ this.#ws.close();
+ }
+ }
+}

Heartbeat

A heartbeat mechanism is implemented to ensure that the connection between the server and the client is healthy.

The server sends two values during the initial handshake: pingInterval and pingTimeout

It will then send a PING packet every pingInterval ms, and expect a PONG packet back from the client. Let's do this:

class Socket extends EventEmitter {
+ #pingTimeoutTimer;
+ #pingTimeoutDelay;

[...]

#onMessage(data) {
if (typeof data !== "string") {
// TODO handle binary payloads
return;
}

switch (data[0]) {
+ case EIOPacketType.OPEN:
+ this.#onOpen(data);
+ break;
+
case EIOPacketType.CLOSE:
this.#onClose("transport close");
break;

+ case EIOPacketType.PING:
+ this.#resetPingTimeout();
+ this.#send(EIOPacketType.PONG);
+ break;

default:
this.#onClose("parse error");
break;
}
}

+ #onOpen(data) {
+ let handshake;
+ try {
+ handshake = JSON.parse(data.substring(1));
+ } catch (e) {
+ return this.#onClose("parse error");
+ }
+ this.#pingTimeoutDelay = handshake.pingInterval + handshake.pingTimeout;
+ this.#resetPingTimeout();
+ }
+
+ #resetPingTimeout() {
+ clearTimeout(this.#pingTimeoutTimer);
+ this.#pingTimeoutTimer = setTimeout(() => {
+ this.#onClose("ping timeout");
+ }, this.#pingTimeoutDelay);
+ }
+
+ #send(data) {
+ if (this.#ws.readyState === WebSocket.OPEN) {
+ this.#ws.send(data);
+ }
+ }

#onClose(reason) {
if (this.#ws) {
this.#ws.onclose = noop;
this.#ws.close();
}

+ clearTimeout(this.#pingTimeoutTimer);
}
}

Reconnection

While we're at it, we will also handle reconnections. WebSockets are awesome, but they can (and they will, in real-life conditions) get disconnected, so we must take care of that:

class Socket extends EventEmitter {
[...]

constructor(uri, opts) {
super();
this.#uri = uri;
this.#opts = Object.assign(
{
path: "/socket.io/",
+ reconnectionDelay: 2000,
},
opts
);
this.#open();
}

#onClose(reason) {
if (this.#ws) {
this.#ws.onclose = noop;
this.#ws.close();
}

clearTimeout(this.#pingTimeoutTimer);

+ setTimeout(() => this.#open(), this.#opts.reconnectionDelay);
}
}
info

The official Socket.IO client uses a fancy exponential delay with some randomness in order to prevent spikes of load when a lot of clients reconnect at the same time, but we'll keep it simple here and use a constant value.

OK, so let's sum up, we now have a client that can:

  • open a WebSocket connection to the server
  • honor the heartbeat mechanism by responding to PING packets
  • automatically reconnect upon failure

That's it for the Engine.IO protocol! Let's dig into the Socket.IO protocol now.

The Socket.IO protocol

The Socket.IO protocol is built on top of the Engine.IO protocol described earlier, which means that every Socket.IO packet will be prefixed by "4" (the Engine.IO MESSAGE packet type) when sent over the wire.

Reference: the Socket.IO protocol

Without binary elements, the format is the following:

<packet type>[JSON-stringified payload]

Here is the list of available packet types:

TypeIDUsage
CONNECT0Used during the connection to a namespace.
DISCONNECT1Used when disconnecting from a namespace.
EVENT2Used to send data to the other side.
ACK3Used to acknowledge an event (not used here).
CONNECT_ERROR4Used during the connection to a namespace (not used here).
BINARY_EVENT5Used to send binary data to the other side (not used here).
BINARY_ACK6Used to acknowledge an event (the response includes binary data) (not used here).

Example:

2["hello","world"]

with:

2 => EVENT packet type
["hello","world"] => JSON.stringified() payload

Connecting

The client must send a CONNECT packet at the beginning of the Socket.IO session:

+const SIOPacketType = {
+ CONNECT: 0,
+ DISCONNECT: 1,
+ EVENT: 2,
+};

class Socket extends EventEmitter {
[...]

#onOpen(data) {
let handshake;
try {
handshake = JSON.parse(data.substring(1));
} catch (e) {
return this.#onClose("parse error");
}
this.#pingTimeoutDelay = handshake.pingInterval + handshake.pingTimeout;
this.#resetPingTimeout();
+ this.#doConnect();
}

+ #doConnect() {
+ this.#sendPacket({ type: SIOPacketType.CONNECT });
+ }
+
+ #sendPacket(packet) {
+ this.#send(EIOPacketType.MESSAGE + encode(packet));
+ }
}

+function encode(packet) {
+ let output = "" + packet.type;
+
+ return output;
+}

If the connection is allowed, then the server will send a CONNECT packet back:

class Socket extends EventEmitter {
+ id;

[...]

#onMessage(data) {
switch (data[0]) {
[...]

+ case EIOPacketType.MESSAGE:
+ let packet;
+ try {
+ packet = decode(data);
+ } catch (e) {
+ return this.#onClose("parse error");
+ }
+ this.#onPacket(packet);
+ break;
}
}

+ #onPacket(packet) {
+ switch (packet.type) {
+ case SIOPacketType.CONNECT:
+ this.#onConnect(packet);
+ break;
+ }
+ }

+ #onConnect(packet) {
+ this.id = packet.data.sid;
+
+ super.emit("connect");
+ }
}

+function decode(data) {
+ let i = 1; // skip "4" prefix
+
+ const packet = {
+ type: parseInt(data.charAt(i++), 10),
+ };
+
+ if (!isPacketValid(packet)) {
+ throw new Error("invalid format");
+ }
+
+ return packet;
+}
+
+function isPacketValid(packet) {
+ switch (packet.type) {
+ case SIOPacketType.CONNECT:
+ return typeof packet.data === "object";
+ default:
+ return false;
+ }
+}
note

We are using super.emit(...) so that we will be able to override the emit() method later to send an event.

Sending an event

Let's send some data to the server. We need to track the state of the underlying connection and buffer the packets until the connection is ready:

class Socket extends EventEmitter {
+ connected = false;

+ #sendBuffer = [];

[...]

+ emit(...args) {
+ const packet = {
+ type: SIOPacketType.EVENT,
+ data: args,
+ };
+
+ if (this.connected) {
+ this.#sendPacket(packet);
+ } else {
+ this.#sendBuffer.push(packet);
+ }
+ }

#onConnect(packet) {
this.id = packet.data.sid;
+ this.connected = true;

+ this.#sendBuffer.forEach((packet) => this.#sendPacket(packet));
+ this.#sendBuffer.slice(0);

super.emit("connect");
}
}

function encode(packet) {
let output = "" + packet.type;

+ if (packet.data) {
+ output += JSON.stringify(packet.data);
+ }

return output;
}

Receiving an event

Conversely, let's handle the EVENT packets sent by the server:

class Socket extends EventEmitter {
[...]

#onPacket(packet) {
switch (packet.type) {
case SIOPacketType.CONNECT:
this.#onConnect(packet);
break;

+ case SIOPacketType.EVENT:
+ super.emit.apply(this, packet.data);
+ break;
}
}
}

function decode(data) {
let i = 1; // skip "4" prefix

const packet = {
type: parseInt(data.charAt(i++), 10),
};

+ if (data.charAt(i)) {
+ packet.data = JSON.parse(data.substring(i));
+ }

if (!isPacketValid(packet)) {
throw new Error("invalid format");
}

return packet;
}

function isPacketValid(packet) {
switch (packet.type) {
case SIOPacketType.CONNECT:
return typeof packet.data === "object";
+ case SIOPacketType.EVENT: {
+ const args = packet.data;
+ return (
+ Array.isArray(args) && args.length > 0 && typeof args[0] === "string"
+ );
+ }
default:
return false;
}
}

Disconnecting manually

And finally, let's handle the few cases where the socket shouldn't try to reconnect:

  • when the client calls socket.disconnect()
  • when the server calls socket.disconnect()
class Socket extends EventEmitter {
+ #reconnectTimer;
+ #shouldReconnect = true;

[...]

#onPacket(packet) {
switch (packet.type) {
case SIOPacketType.CONNECT:
this.#onConnect(packet);
break;

+ case SIOPacketType.DISCONNECT:
+ this.#shouldReconnect = false;
+ this.#onClose("io server disconnect");
+ break;

case SIOPacketType.EVENT:
super.emit.apply(this, packet.data);
break;
}
}

#onClose(reason) {
if (this.#ws) {
this.#ws.onclose = noop;
this.#ws.close();
}

clearTimeout(this.#pingTimeoutTimer);
+ clearTimeout(this.#reconnectTimer);
+
+ if (this.#shouldReconnect) {
+ this.#reconnectTimer = setTimeout(
+ () => this.#open(),
+ this.#opts.reconnectionDelay
+ );
+ }
- setTimeout(() => this.#open(), this.#opts.reconnectionDelay);
}

+ disconnect() {
+ this.#shouldReconnect = false;
+ this.#onClose("io client disconnect");
+ }
}

function isPacketValid(packet) {
switch (packet.type) {
case SIOPacketType.CONNECT:
return typeof packet.data === "object";
+ case SIOPacketType.DISCONNECT:
+ return packet.data === undefined;
case SIOPacketType.EVENT: {
const args = packet.data;
return (
Array.isArray(args) && args.length > 0 && typeof args[0] === "string"
);
}
default:
return false;
}
}

Ending notes

That's it for our basic Socket.IO client! So let's recap.

We have implemented the following features:

  • creating a WebSocket connection
  • managing reconnections
  • sending events
  • receiving events
  • disconnecting manually

Hopefully, you now have a better understanding of how the library works under the hood.

The complete source code can be found there.

Thanks for reading!