Google Online Security Blog

Protecting more with Site Isolation

July 20, 2021

Posted by Charlie Reis and Alex Moshchuk, Chrome Security Team Chrome's Site Isolation is an essential security defense that makes it harder for malicious web sites to steal data from other web sites. On Windows, Mac, Linux, and Chrome OS, Site Isolation protects all web sites from each other, and also ensures they do not share processes with extensions, which are more highly privileged than web sites. As of Chrome 92, we will start extending this capability so that extensions can no longer share processes with each other. This provides an extra line of defense against malicious extensions, without removing any existing extension capabilities. Meanwhile, Site Isolation on Android currently focuses on protecting only high-value sites, to keep performance overheads low. Today, we are announcing two Site Isolation improvements that will protect more sites for our Android users. Starting in Chrome 92, Site Isolation will apply to sites where users log in via third-party providers, as well as sites that carry Cross-Origin-Opener-Policy headers. Our ongoing goal with Site Isolation for Android is to offer additional layers of security without adversely affecting the user experience for resource-constrained devices. Site Isolation for all sites continues to be too costly for most Android devices, so our strategy is to improve heuristics for prioritizing sites that benefit most from added protection. So far, Chrome has been isolating sites where users log in by entering a password. However, many sites allow users to authenticate on a third-party site (for example, sites that offer "Sign in with Google"), possibly without the user ever typing in a password. This is most commonly accomplished with the industry-standard OAuth protocol. Starting in Chrome 92, Site Isolation will recognize common OAuth interactions and protect sites relying on OAuth-based login, so that user data is safe however a user chooses to authenticate. Additionally, Chrome will now trigger Site Isolation based on the new Cross-Origin-Opener-Policy (COOP) response header. Supported since Chrome 83, this header allows operators of security-conscious websites to request a new browsing context group for certain HTML documents. This allows the document to better isolate itself from untrustworthy origins, by preventing attackers from referencing or manipulating the site's top-level window. It’s also one of the headers required to use powerful APIs such as SharedArrayBuffers. Starting in Chrome 92, Site Isolation will treat non-default values of the COOP header on any document as a signal that the document's underlying site may have sensitive data and will start isolating such sites. Thus, site operators who wish to ensure their sites are protected by Site Isolation on Android can do so by serving COOP headers on their sites. As before, Chrome stores newly isolated sites locally on the device and clears the list whenever users clear their browsing history or other site data. Additionally, Chrome places certain restrictions on sites isolated by COOP to keep the list focused on recently-used sites, prevent it from growing overly large, and protect it from misuse (e.g., by requiring user interaction on COOP sites before adding them to the list). We continue to require a minimum RAM threshold (currently 2GB) for these new Site Isolation modes. With these considerations in place, our data suggests that the new Site Isolation improvements do not noticeably impact Chrome's overall memory usage or performance, while protecting many additional sites with sensitive user data. Given these improvements in Site Isolation on Android, we have also decided to disable V8 runtime mitigations for Spectre on Android. These mitigations are less effective than Site Isolation and impose a performance cost. Disabling them brings Android on par with desktop platforms, where they have been turned off since Chrome 70. We advise that sites wanting to protect data from Spectre should consider serving COOP headers, which will in turn trigger Site Isolation. Users who desire the most complete protection for their Android devices may manually opt in to full Site Isolation via chrome://flags/#enable-site-per-process, which will isolate all websites but carry higher memory cost.

Advancing an inclusive, diverse security industry

July 20, 2021

Posted by Sarah Morales, Community Outreach Manager, Security Women in Cybersecurity (WiCyS)SANS InstituteSecurity Training Scholarship Program

112 people received training-based scholarship

15 Full Scholarship Recipients received the full course training, which includes:

CyberStart Game and SANS BootUp CTF
SANS SEC275 Foundations & Exam
SANS 401 Security Essentials Bootcamp and GSEC
Elective - SANS SEC504/GCIH, SEC488/GCLD, SEC560/GPEN, or SEC548/GWAPT

24 certifications earned to date with 100% pass rate, with average score on GSEC 90%

Since 2013, only 2 people have scored 99% on GIAC Certified Incident Handler (GCIH) one is a WiCyS Scholarship Recipient

1/3 of students were employed in direct information security roles before the program ended

100% of Full Scholarship Recipients intend to have long term careers in information security (15+ years)

WiCyS application page

Verifiable design in modern systems

July 15, 2021

Posted by Ryan Hurst, Production Security Team
verifiable data structuresMerkle TreesCertificate Transparencyintroduce transparency and accountabilitybreaking the webplatformGo Checksum DatabaseannouncedSigstoreenable hardware-enforced supply chain integrity for device firmwaretaxonomy and modeling framework transparency.dev

Measuring Security Risks in Open Source Software: Scorecards Launches V2

July 1, 2021

Posted by Kim Lewandowski, Azeem Shaikh, Laurent Simon, Google Open Source Security Team
Scorecards projectour launch last fall.Open Source Security FoundationScorecards v2
Identifying RisksKnow, Prevent, Fix frameworkMalicious contributors

Contributors with malicious intent or compromised accounts can introduce potential backdoors into code. Code reviews help mitigate against such attacks. With the new Branch-Protection check, developers can verify that the project enforces mandatory code review from another developer before code is committed. Currently, this check can only be run by a repository admin due to GitHub API limitations. For a third-party repository, use the less informative Code-Review check instead.

Vulnerable code

Despite best efforts by developers and peer reviews, vulnerable code can enter source control and remain undetected. That’s why it's important to enable continuous fuzzing and static code analysis to catch bugs early in the development lifecycle. We have added checks to detect if a project uses Fuzzing and SAST tools as part of their CI/CD system.

Build system compromise

A common CI/CD solution used by GitHub projects is GitHub Actions. A danger with these action workflows is that they may handle untrusted user input. Meaning, an attacker can craft a malicious pull request to gain access to the privileged GitHub token, and with it the ability to push malicious code to the repo without review. To mitigate this risk, Scorecard's Token-Permissions prevention check now verifies that the GitHub workflows follow the principle of least privilege by making GitHub tokens read-only by default.

Bad dependencies

Any software is as secure as its weakest dependency. This may sound obvious, but the first step to knowing our dependencies is simply to declare them... and have our dependencies declare them too. Once we have this provenance information, we can assess the risks of our software and mitigate those risks. Unfortunately, there are several widely-used anti-patterns that break this provenance principle. The first of these anti-patterns is checked-in binaries -- as there's no way to easily verify or check the contents of the binary in the project. Scorecards provides Binary-Artifacts check for testing this.

Another anti-pattern is the use of curl | bash in scripts which dynamically pulls dependencies. Cryptographic hashes let us pin our dependencies to a known value: if this value ever changes, the build system will detect it and refuse to build. Pinning dependencies is useful everywhere we have dependencies: not just during compilation, but also in Dockerfiles, CI/CD workflows, etc. Scorecards checks for these anti-patterns with the Frozen-Deps check. This check is helpful for mitigating against malicious dependency attacks such as the recent CodeCov attack.

Even with hash-pinning, hashes need to be updated once in a while when dependencies patch vulnerabilities. Tools like dependabot or renovatebot give us the opportunity to review and update the hashes. The Scorecards Automated-Dependency-Update check verifies that developers rely on such tools to update their dependencies.

It is important to know vulnerabilities in a project before uptaking it as a dependency. Scorecards can provide this information via the new Vulnerabilities check, without the need to subscribe to a vulnerability alert system.

Scaling the impact

To date, the Scorecards project has scaled up to evaluate security criteria for over 50,000 open source projects. In order to scale this project, we undertook a massive redesign of our architecture and used a PubSub model which achieved horizontal scalability and higher throughput. This fully automated tool periodically evaluates critical open source projects and exposes the Scorecards check information through a public BigQuery dataset which is refreshed weekly.

This data can be retrieved using the bq command line tool. The following example shows how to export data for the Kubernetes project. Substitute the url for the repo to export data from a different project:

$ bq query --nouse_legacy_sql 'SELECT Repo, Date, Checks FROM openssf.scorecardcron.scorecard_latest WHERE Repo="github.com/kubernetes/kubernetes"'

To export the latest data on all analyzed projects, see instructions here.

How does the internet measure up?

Scorecards data for available projects is now included in the recently announced Google Open Source Insights project and also showcased in OpenSSF Security Metrics project. The data on these sites shows that there are still important security gaps to fill, even in widely used packages like Kubernetes.

We also analyzed Scorecards data through Google Data Studio -- one of our data analysis and visualization tools.The diagram below shows a breakdown of the checks that were run and the pass/fail outcome for the 50,000 repositories:

As we can see, a lot needs to be done to improve the security of these critical projects. A large number of these projects are not continuously fuzzed, do not define a security policy for reporting vulnerabilities, and do not pin dependencies, to name just a few common problems. We all need to come together as an industry to drive awareness of these widespread security risks, and to make improvements that will benefit everyone.

Scorecards in Action

Several large projects have adopted Scorecards and are keeping us updated on their experiences with it. Below are some examples of Scorecards in action:

Envoy
Early on we talked about how the Envoy maintainers adopted Scorecards for their project and integrated it within their policy on introducing new dependencies. Since then, pull requests introducing new dependencies to Envoy must get approval from a dependency maintainer who uses Scorecards to evaluate the dependency against a set of criteria.

In addition, Envoy also got right to work in improving its own security health metrics according to its own Scorecards evaluation, and is now pinning C++ dependencies and requiring pip hashes for python dependencies. Github actions are also pinned in the continuous integration flow.

Previously, Envoy had created a tool that outputs Scorecards data on its dependencies as a CSV that can be used to generate a table of results:

Now with more project data, Envoy is able to automatically generate up-to-date Scorecard information about its dependencies and publish it in documentation, like the following:

Scorecards
We improved our own score for the Scorecards! For example, we are now pinning our own dependencies by hash (e.g. docker dependencies, workflow dependencies) to prevent CodeCov style attacks. We’ve also included a Security Policy based on this recommended template.

Get involved

We look forward to continuing to grow the Scorecards community. The project now has contributions from 23 developers. Thank you to Azeem, Naveen, Laurent, Asra and Chris for their work building these new features and scaling Scorecards.

If you would like to join the fun, check out these good first timer issues.

If you would like us to help you run Scorecards on specific projects, please submit a GitHub pull request to add those projects here.

Last but not least, we have a lot of ideas and many more checks we’d like to add, but we want to hear from you. Tell us which checks you would like to see in the next version of Scorecards.

What’s next?

There are a couple of big enhancements we’re especially excited about:

Scorecards Badges - GitHub badges to show off compliance
Integration with CI/CD and GitHub Code Scanning Results
Integration with Allstar project - GitHub App for enforcing security policies

Thanks again to the entire Scorecards community and the OpenSSF for making this project successful. If you’re adopting and improving the score of the projects you maintain, tell us about it. Until next time, keep on improving those scores!

Announcing a unified vulnerability schema for open source

June 24, 2021

Posted by Oliver Chang, Google Open Source Security team and Russ Cox, Go team several effortsOpen Source Vulnerabilities (OSV) databaseOSS-FuzzGoRustPythonDWFUS Executive Order on Improving the Nation’s Cybersecurity
A simple, unified schema for describing vulnerabilities precisely

As with open source development, vulnerability databases in open source follow a distributed model, with many ecosystems and organizations creating their own database. Since each uses their own format to describe vulnerabilities, a client tracking vulnerabilities across multiple databases must handle each completely separately. Sharing of vulnerabilities between databases is also difficult.

The Google Open Source Security team, Go team, and the broader open-source community have been developing a simple vulnerability interchange schema for describing vulnerabilities that’s designed from the beginning for open-source ecosystems. After starting work on the schema a few months ago, we requested public feedback and received hundreds of comments. We have incorporated the input from readers to arrive at the current schema:

{

"id": string,

"modified": string,

"published": string,

"withdrawn": string,

"aliases": [ string ],

"related": [ string ],

"package": {

"ecosystem": string,

"name": string,

"purl": string,

"summary": string,

"details": string,

"affects": [ {

"ranges": [ {

"type": string,

"repo": string,

"introduced": string,

"fixed": string

} ],

"versions": [ string ]

} ],

"references": [ {

"type": string,

"url": string

} ],

"ecosystem_specific": { see spec },

"database_specific": { see spec },

}

This new vulnerability schema aims to address some key problems with managing vulnerabilities in open source. We found that there was no existing standard format which:

Enforces version specification that precisely matches naming and versioning schemes used in actual open source package ecosystems. For instance, matching a vulnerability such as a CVE to a package name and set of versions in a package manager is difficult to do in an automated way using existing mechanisms such as CPEs.
Can be used to describe vulnerabilities in any open source ecosystem, while not requiring ecosystem-dependent logic to process them.
Is easy to use by both automated systems and humans.

With this schema we hope to define a format that all vulnerability databases can export. A unified format means that vulnerability databases, open source users, and security researchers can easily share tooling and consume vulnerabilities across all of open source. This means a more complete view of vulnerabilities in open source for everyone, as well as faster detection and remediation times resulting from easier automation.

The current state

The vulnerability schema spec has gone through several iterations, and we are inviting further feedback as it gets closer to finalized. A number of public vulnerability databases today are already exporting this format, with more in the pipeline:

The OSV service has also aggregated all of these vulnerability databases, which are viewable at our web UI. They can also be queried with a single command via the same existing APIs:

curl -X POST -d \

'{"commit": "a46c08c533cfdf10260e74e2c03fa84a13b6c456"}' \

"https://api.osv.dev/v1/query"

curl -X POST -d \

'{"version": "2.4.1", "package": {"name": "jinja2", "ecosystem": "PyPI"}}' \

"https://api.osv.dev/v1/query"

Automating vulnerability database maintenance

Producing quality vulnerability data is also difficult. In addition to OSV’s existing automation, we built more automation tools for vulnerability database maintenance, and used these tools to bootstrap the community Python advisory database. This automation takes existing feeds, accurately matches them to packages, and generates entries containing precise, validated version ranges with minimal human intervention. We plan to extend this tooling to other ecosystems for which there is no existing vulnerability database, or little support for ongoing database maintenance.

Get involved

Thank you to all the open source developers who have provided feedback and adopted this format. We’re continuing to work with open source communities to develop this further and earn more widespread adoption in all ecosystems. If you are interested in adopting this format, we’d appreciate any feedback on our public spec.

Get ready for the 2021 Google CTF

June 18, 2021

Posted by Kristoffer Janke, Information Security Engineer

Are you ready for no sleep, no chill and a lot of hacking? Our annual Google CTF is back!

The competition kicks off on Saturday July 17 00:00:01 AM UTC and runs through Sunday July 18 23:59:59 UTC. Teams can register at http://goo.gle/ctf.

Just like last year, the top 16 teams will qualify for our Hackceler8 speed run and the chance to take home a total of $30,301.70 in prize money.

As we reminisce on last years event, we’d be remiss if we didn’t recognize our 2020 winning teams:

Plaid Parliament of Pwning
I Use Bing
pasten
The Flat Network Society

We are eager to see if they can defend their leet status. For those interested, we have published all 2020 Hackceler8 videos for your viewing pleasure here.

Whether you’re a seasoned CTF player or just curious about cyber security and ethical hacking, we want you to join us. Sign up to learn skills, meet new friends in the security community and even watch the pros in action. For the latest announcements, see g.co/ctf, subscribe to our mailing list or follow us on @GoogleVRP. See you there!

P.S. Curious about last year’s Google CTF challenges? We open-sourced them here.

Security Blog

Protecting more with Site Isolation

Advancing an inclusive, diverse security industry

Verifiable design in modern systems

Measuring Security Risks in Open Source Software: Scorecards Launches V2

Announcing a unified vulnerability schema for open source

Get ready for the 2021 Google CTF

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