How severe is GHSA-f7cq-gvh6-qr25?

GHSA-f7cq-gvh6-qr25 has a CVSS score of 9.8/10, rated CRITICAL. Immediate patching is strongly recommended.

Which packages are affected by GHSA-f7cq-gvh6-qr25?

GHSA-f7cq-gvh6-qr25 affects the following packages: github.com/ctfer-io/monitoring (Go). Ecosystems affected: Go.

How do I fix GHSA-f7cq-gvh6-qr25?

Update github.com/ctfer-io/monitoring to 0.2.2 or later, then make sure no transitive (indirect) dependency still pins the vulnerable range — O3 confirms GHSA-f7cq-gvh6-qr25 is resolved across your whole dependency graph.

How do I detect GHSA-f7cq-gvh6-qr25 in my Go dependencies?

Scan your dependency tree (package-lock.json, pnpm-lock.yaml, requirements.txt, go.sum, etc.) for github.com/ctfer-io/monitoring. 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.

How do I mitigate GHSA-f7cq-gvh6-qr25 if there is no patch (or I can't update yet)?

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 does O3 Security protect against GHSA-f7cq-gvh6-qr25?

O3 pinpoints whether GHSA-f7cq-gvh6-qr25 is reachable in your code and exactly where to fix it, then blocks exploitation in production at runtime until the patched version is deployed.

Is GHSA-f7cq-gvh6-qr25 actively exploited in the wild?

No public exploit code has been indexed for GHSA-f7cq-gvh6-qr25 yet. This does not mean the vulnerability cannot be exploited — absence of public exploits does not imply safety. Apply the recommended fix and use O3 Security to monitor your exposure.

What is the EPSS score for GHSA-f7cq-gvh6-qr25?

GHSA-f7cq-gvh6-qr25 has an EPSS (Exploit Prediction Scoring System) score of 0.7%, placing it in the 47th percentile of all CVEs. EPSS is maintained by FIRST.org and estimates the probability that a vulnerability will be exploited in the wild within the next 30 days. This score indicates relatively lower exploitation probability, though the CVSS severity should still guide your patching priority.

What type of vulnerability is GHSA-f7cq-gvh6-qr25?

GHSA-f7cq-gvh6-qr25 is classified as Path Traversal (CWE-22). This weakness type describe the underlying flaw category, which helps determine the potential impact and the right class of mitigation. This is a high-impact weakness class that often enables remote code execution or data exposure.

When was GHSA-f7cq-gvh6-qr25 published, and has it been updated?

GHSA-f7cq-gvh6-qr25 was published on March 16, 2026 and was last updated on May 5, 2026. Advisory data evolves as severity scores, affected ranges, and exploit intelligence are revised — always check the latest version of the advisory before acting.

🐹 Go

GHSA-f7cq-gvh6-qr25

CRITICAL

Monitoring is vulnerable to Archive Slip due to missing checks in sanitization

Also known asCVE-2026-32771GO-2026-4712

Published

Mar 16, 2026

Updated

May 5, 2026

Affected

1 pkg

Patched

1 / 1

Exploits

None indexed

EPSS Exploitation Probability

via FIRST.org ↗

0.7%probability of exploitation in next 30 days

Lower Risk47th percentile+0.61%

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

1 pkg affected

🐹github.com/ctfer-io/monitoring

Real-time download stats are indexed for npm and PyPI packages. This vulnerability affects Go packages — download data is not available via public APIs for these ecosystems.

Description

The sanitizeArchivePath function in pkg/extract/extract.go (lines 248–254) is vulnerable to a path traversal bypass due to a missing trailing path separator in the strings.HasPrefix check. A crafted tar archive can write files outside the intended destination directory when using the extractor CLI tool or the extract.DumpOTelCollector library function.

Vulnerable Code

File: pkg/extract/extract.go, lines 248–254

func sanitizeArchivePath(d, t string) (v string, err error) {
    v = filepath.Join(d, t)
    if strings.HasPrefix(v, filepath.Clean(d)) {   // ← missing trailing separator
        return v, nil
    }
    return "", fmt.Errorf("filepath is tainted: %s", t)
}

The function is called at line 219 inside untar, which is invoked by copyFromPod (line 205) during the Cold Extract data dump workflow.

Root Cause

strings.HasPrefix(v, filepath.Clean(d)) does not append a trailing / to the directory prefix, causing a directory name prefix collision. If the destination is /home/user/extract-output and a tar entry is named ../extract-outputevil/pwned, the joined path /home/user/extract-outputevil/pwned passes the prefix check — it starts with /home/user/extract-output — even though it is entirely outside the intended directory.

Steps to Reproduce

Deploy the monitoring stack with ColdExtract: true. The OTEL Collector begins writing signal data (otel_traces, otel_metrics, otel_logs) to the shared PVC.
Place the PoC tar on the PVC. Any pod with write access to the ReadWriteMany PVC (or the compromised OTEL Collector itself) copies a poc-path-traversal.tar into the /data/collector mount path. The archive contains three real-looking OTLP telemetry files alongside two crafted entries with path-traversal names.

Run the extractor against the namespace:

extractor \
  --namespace monitoring \
  --pvc-name <signals-pvc-name> \
  --directory /home/user/extract-output

Observe the bypass. untar processes the tar stream. For the malicious entries:

// entry name: ../extract-outputevil/poc-proof.txt
filepath.Join("/home/user/extract-output", "../extract-outputevil/poc-proof.txt")
  => "/home/user/extract-outputevil/poc-proof.txt"

strings.HasPrefix("/home/user/extract-outputevil/poc-proof.txt",
                  "/home/user/extract-output")
  => true   // BUG: prefix collision; file lands OUTSIDE target dir

Both malicious entries are written outside /home/user/extract-output/. The three legitimate OTLP files land correctly inside it.

Impact

Successful exploitation gives an attacker arbitrary file write on the machine running the extractor. Real-world primitives include:

Overwriting ~/.bashrc / ~/.zshrc / ~/.profile for RCE on next shell login
Appending to ~/.ssh/authorized_keys for persistent SSH backdoor
Dropping a malicious entry into ~/.kube/config to hijack cluster access
Writing crontab entries for persistent scheduled execution

The attack surface is widened by the default ReadWriteMany PVC access mode, which means any pod in the cluster with the PVC mounted can inject the payload — not just the OTEL Collector itself.

Affected Packages

1 total 1 fixed

Ecosystem	Package	Vulnerable range	Fix
🐹Go	`github.com/ctfer-io/monitoring`	all versions	0.2.2

Detection & mitigation playbook

Open-source dependency

Detect
Scan your dependency tree (package-lock.json, pnpm-lock.yaml, requirements.txt, go.sum, etc.) for github.com/ctfer-io/monitoring. 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.
Fix
Update github.com/ctfer-io/monitoring to 0.2.2 or later, then make sure no transitive (indirect) dependency still pins the vulnerable range — O3 confirms GHSA-f7cq-gvh6-qr25 is resolved across your whole dependency graph.
Workarounds
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-f7cq-gvh6-qr25 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-f7cq-gvh6-qr25. Runtime protection reduces exposure until a permanent patch is applied and verified — it complements patching, it doesn't replace it.

Frequently Asked Questions

The `sanitizeArchivePath` function in `pkg/extract/extract.go` (lines 248–254) is vulnerable to a path traversal bypass due to a missing trailing path separator in the `strings.HasPrefix` check. A crafted tar archive can write files outside the intended destination directory when using the `extractor` CLI tool or the `extract.DumpOTelCollector` library function. ## Vulnerable Code File: `pkg/extract/extract.go`, lines 248–254 ```go func sanitizeArchivePath(d, t string) (v string, err error) { v = filepath.Join(d, t) if strings.HasPrefix(v, filepath.Clean(d)) { // ← missing trailin

O3 Security · Impact-Aware SCA

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