A year ago, "AI security" mostly meant "don't let the chatbot say something dumb." Today, AI assistants
act: they read your files, query your databases, hit APIs, and browse the web. They do it through a
fast-spreading open standard called the Model Context Protocol (MCP) — think of it as USB for AI
agents, one standard plug between an assistant and the tools it uses.
That plug is powerful, and it's a brand-new place for things to go wrong. A malicious or compromised
tool can hide instructions in its own description, quietly swap its behavior after you've approved it,
or trick the agent into shipping your credentials to an attacker. The 2025–2026 research literature now
documents dozens of these attacks.
So the obvious question: when you put a security tool in front of your MCP servers, how much of that danger does it actually stop? Nobody had a good number. I set out to get one — and then something more
mcp-bastion
This is the story of that loop, and what it teaches about where AI-agent security actually stands.
I built mcp-defense-bench, an open, vendor-neutral The rubric behind it is a threat–control crosswalk: 24 MCP attack vectors, each mapped to an
architectural layer, a STRIDE class, and the governance frameworks organizations actually use — the
NIST AI Risk Management Framework, the NSA's MCP Security guidance, and the OWASP Top 10s for LLM and
Agentic applications. (If you want the "map of the whole landscape" version of this story, that's a
a separate write-up; here I'm focused on the improvement loop.)
Each attack scores one of three levels: none (missed), detect (warns you), or enforce (blocks it). Weighted coverage counts an enforce as 1.0, a detect as 0.5.
Here's the part that surprised me. A benchmark is usually a scoreboard you check at the end. This one
became a to-do list.
The proxy started at 9% — it scanned tool descriptions for poisoning and nothing else. Then the
benchmark pointed at the next gap, I closed it, and re-ran. Every step below was re-verified at zero false positives:
| Step | What the benchmark exposed → what I added | Coverage |
|---|---|---|
| baseline | description scanning only | 9% |
| 1 | result-borne injection → scan tool results, not just definitions | |
| 18% | ||
| 2 | parameter smuggling → validate arguments against the tool's schema | 23% |
| 3 | DNS-rebinding on local servers → an origin check that blocks | |
| 30% | ||
| 4 | cross-tool exfiltration → sensitive-argument + least-privilege scanning | 34% |
| 5 | a brand-new split-payload attack → cross-tool correlation | 38% |
| 6 | four vectors no tool covered → command-injection, config-drift, server-identity, cross-server taint | |
| 48% | ||
| 7 | depth, not breadth → evasion normalization + inline secret redaction + block-by-default | 63% |
Two moments in that table are worth slowing down on, because they're where "measure a defense" turned
into "discover something."
Halfway through, two attacks were published (June 2026) that my frozen rubric didn't have yet:
mid-session tool injection (a tool that mutates its behavior after you've approved it) and
ShareLock (a stealthy attack that splits a malicious payload across several tools, so no single
tool description looks suspicious).
I verified both against their source papers, encoded each as a matched attack/benign pair, and re-ran
every tool. The result was stark: ShareLock was covered by nothing. Every scanner looked at one tool
at a time and saw nothing wrong.
But a proxy sees the whole tool set at once. So I added cross-tool correlation — it scans the
combined descriptions and flags the coordinated "share/checksum"-style staging metadata the attack uses.
mcp-bastion
became the first and (on the benchmark) only measured tool to catch it. A benchmark that
only tested a fixed set of attacks would have missed this entirely. The value was in re-measuring as the threat surface moved.
Later, I added cross-server data-flow tracking. Picture an agent reading a secret from your vault
server and then, two calls later, posting it to a webhook on a different server. No single tool did
anything wrong; the danger is in the flow across a trust boundary. A per-server scanner is blind to
it. A proxy that fronts all your servers isn't — it can watch a credential-shaped token read from server
A reappear in an argument headed to server B, and stop it. That's not a rule you can bolt onto one
tool; it's a capability you only get from the vantage point.
A tool that detects an attack and prints a warning is a linter. A tool that blocks it is a firewall.
The last leg of the journey (48% → 63%) was mostly about turning warnings into blocks — safely.
Through all of it, the false-positive count stayed at zero across 35 test cases. That's the whole
point of the matched benign controls: you can push toward "block by default" because you've proven the
checks don't fire on innocent traffic.
Here's the result I care about most, and it's not the 63%. It's the 5 of 24 vectors that no measured tool covers — and that no content-scanning proxy ever will:
A proxy is necessary but not sufficient. The data makes the case for defense-in-depth across distinct mechanism classes better than any argument could: 19 of 24 vectors are caught by
The loop is no longer manual. mcp-bastion
's continuous-integration pipeline runs the full benchmark
on every change and fails the build if coverage drops below a floor or any false positive appears.
The measurement isn't a one-time paper result; it's a standing regression test on the defense. When the
next MCP attack drops, the process for handling it is already wired: add the vector, re-measure, close
the gap, and the gate makes sure it stays closed.
Everything is open:
mcp-defense-bench
mcp-bastion
npx -y mcp-bastion
) and in the official MCP registry.One disclosure, up front: I build one of the tools the benchmark measures. That's exactly why the
whole thing is open, vendor-neutral, driven through each tool's real code, and scored alongside
competitors and a do-nothing baseline — so you don't have to take my word for any of it. Re-run it
yourself.
The number that matters isn't 63%. It's that an honest measurement, applied relentlessly, turned a
9%-coverage scanner into the broadest MCP defense measured — and drew a bright line around the 37% that
needs a fundamentally different kind of tool. That line is the useful part.
If you work on MCP, agent security, or AI governance, I'd genuinely value critique of the rubric and the methodology — open an issue, or reach me at agowthaman90@gmail.com.