Skip to main content
Glama
Shonas301

headless-unity-mcp

by Shonas301

headless-unity-mcp

drive a unity project's build/test/screenshot loop from an MCP client — in batchmode, with no interactive editor open, ever.

six tools: unity_compile, unity_test, unity_scene, unity_build, unity_shot, unity_targets, plus unity_status. each returns a compact structured verdict, not a wall of unity log:

{"ok": true, "verdict": "OK EditMode total=234 passed=234 failed=0",
 "totals": [{"platform": "EditMode", "total": 234, "passed": 234, "failed": 0,
             "results_xml": "/path/Logs/editmode-results.xml"}]}

macOS only, for now. see limitations.


the problem

if you point an agent at a unity project, three things go wrong.

unity's exit codes lie. the editor exits 0 with error CS0103 sitting in the log. it exits nonzero when everything compiled. it writes no test results XML at all and still exits 0. an agent that trusts $? will tell you the build is green when it isn't, and that's the single worst failure an agent can have — not being wrong, but being confidently wrong.

batchmode output is a context bomb. a single -batchmode compile emits tens of thousands of lines even with -logFile set. a player screenshot is a PNG that costs thousands of tokens to look at. dump either into an agent's context and you've spent the budget you needed for the actual work. the usual workaround — wrap every call in a throwaway subagent that summarizes — is real overhead you shouldn't have to pay.

the existing unity MCP servers need a live editor. near all of them (coplaydev, codergamester, ivanmurzak, anklebreaker, unity's own first-party package) are editor-embedded bridges: a C# package that opens a socket inside a running, interactive unity editor. that's the architecture, not a gap in the docs. it means you cannot run headless, you cannot run in CI, and you inherit the domain-reload problem — recompile your scripts and the bridge's C# state is torn down underneath it, so the agent goes deaf mid-task (coplaydev #814 — "agents sleep after script changes").

Related MCP server: Union Unity MCP Server

what this does instead

spawn-and-exit. every verb launches Unity -batchmode -nographics, waits for it to exit, and parses the evidence it left on disk. there's no long-lived editor to go stale, so the domain-reload bug class doesn't exist here — the process is gone before the next call starts.

the verdict is derived from evidence, never from the exit code:

what

the actual verdict

compile

a error CS[0-9]+ grep of the unity log. exit code is ignored.

test

the NUnit results XML. missing XML is a FAIL, and any result="Failed" is a FAIL.

build

the .app exists on disk (and a .app is a directory — tested with -d, not -f).

shot

a PNG over 10KB captured from the player's real window, by CGWindowID.

fatal abort

Aborting batchmode due to fatal error never reaches -logFile — it goes to the process's stdout. we read that too, and surface it as an abort: line instead of a truncated log and a mystery exit code.

why this over the alternatives

editor-embedded bridges

headless-unity-mcp

needs an interactive editor open

yes

no

survives a script recompile mid-task

no (domain reload tears down the bridge)

n/a — nothing is long-lived

usable in CI / over ssh / on a headless box

no

yes

"run tests" means

the live test-runner API

-runTests + the results XML as evidence

trusts unity's exit code

typically yes

never

screenshots

the editor window (or unsupported on macOS)

the built player's window

concurrent calls

undefined

machine-wide lock, one cycle at a time

project-specific setup

a C# package in your project

one toml file

the honest counterpoint: an embedded bridge can do things a batchmode process fundamentally can't — inspect a live scene graph, read the editor console in real time, poke a GameObject while the game is running, offer 40+ fine-grained tools. if that's what you need, use one of those. this server does five verbs and does them verifiably.

requirements

  • macOS. the screenshot path is Quartz + screencapture, and the build targets a mac standalone player. the compile/test/build verbs are portable in principle; nothing else has been ported yet.

  • unity — any version, installed via the hub (or point [unity] path anywhere).

  • python 3.11+ (needs tomllib).

  • for unity_shot: pyobjc-framework-Quartz, plus the Screen Recording grant for whichever app hosts your shell. macOS gates all window capture behind it; without the grant every capture fails with could not create image from window. the driver preflights this and refuses with the fix rather than writing you a black PNG.

install

git clone https://github.com/Shonas301/headless-unity-mcp
cd headless-unity-mcp
python3 -m venv .venv
.venv/bin/pip install -e ".[shot]"      # drop [shot] if you don't need screenshots

configure

drop a unity-mcp.toml in the root of your unity project (next to Assets/ and ProjectSettings/). this is the only project-specific file — the server and the driver stay generic.

default_target = "mac"

[unity]
version = "6000.5.0f1"        # validated against ProjectSettings/ProjectVersion.txt
# path = "/Applications/Unity/Hub/Editor/6000.5.0f1/Unity.app/Contents/MacOS/Unity"

[shot]
delay_s = 9                   # wait out the unity splash; the splash window is NOT the game window
width = 800
height = 600

[targets.mac]
build_method = "MyGame.Editor.BuildScript.BuildMacDev"   # a public static method, via -executeMethod
app_path = "Build/Mac/MyGame.app"

# optional — only if your project authors scenes from code
scene_method = "MyGame.Editor.SceneBuilder.Generate"
scene_path = "Assets/Scenes/Main.unity"

build_method is an ordinary editor static method, the same one you'd call from CI:

public static class BuildScript {
    public static void BuildMacDev() { BuildPipeline.BuildPlayer(/* ... */); }
}

that [unity] version check is load-bearing. it's what stops a call aimed at the wrong project from cheerfully reporting all-green — a real failure mode, and one that is very hard to notice, because every individual line of the output looks fine.

see unity-mcp.example.toml for the annotated version.

register with an MCP client

.mcp.json (claude code, and most clients take the same shape):

{
  "mcpServers": {
    "unity": {
      "command": "/abs/path/to/headless-unity-mcp/.venv/bin/python",
      "args": ["-m", "unity_mcp.server"],
      "timeout": 1800000
    }
  }
}

the long timeout matters: a build or a PlayMode run takes minutes, and a queued call blocks until the machine lock frees. progress notifications do not extend an MCP client's tool timeout, so the timeout has to actually cover the wait.

every tool takes an optional workspace (absolute path to the unity project). omit it and the server uses its own cwd, which is what you want when the client launches one server per project.

the tools

tool

what it does

unity_compile

import + compile all assemblies. verdict is a log grep, never $?.

unity_test

platform: edit | play | all. returns parsed per-platform totals. missing XML = FAIL.

unity_scene

regenerate a target's scene via its scene_method.

unity_build

build a target's standalone player via its build_method.

unity_shot

launch the built player, screenshot its window, return the PNG path.

unity_targets

list the targets this project defines. never takes the lock.

unity_status

who holds the machine lock right now. never takes the lock.

one build at a time, machine-wide

there is one unity binary and one license on your machine, and two editors cannot open the same project at all — the second one dies with Multiple Unity instances cannot open the same project. so the server serializes.

it has to be a real OS lock, not an in-process one: each MCP client spawns its own stdio server process, so an asyncio.Lock would serialize nothing across them. this uses fcntl.flock on a file under ~/.cache/headless-unity-mcp/, machine-wide. a second caller blocks until the first finishes (bounded by queue_wait_timeout_s, default 900s), then runs. if it gives up, the refusal names who held the lock and since when.

unity_status reads the holder without taking the lock, so you can always ask.

about unity_shot

it returns the PNG's path, not the image. that's deliberate, but it means the one context bomb this server can't defuse is still live: deciding whether a screenshot shows a real gameplay frame or the unity splash requires looking at pixels, and that's thousands of tokens whoever does it.

so: read the PNG in a throwaway subagent, not in your main context. ask it for one sentence. the other five verbs return one-line verdicts and need no such thing.

standalone / CI

the driver is a plain shell script and works with no MCP client at all:

UNITY_MCP_PROJECT=/path/to/project ./src/unity_mcp/driver.sh compile
UNITY_MCP_PROJECT=/path/to/project ./src/unity_mcp/driver.sh test edit
UNITY_MCP_PROJECT=/path/to/project ./src/unity_mcp/driver.sh build mac

it prints the same verdict lines the tools parse, and exits nonzero on failure. the MCP server shells out to exactly this file — a verdict you see through a tool is a verdict this script printed. there is no second implementation to drift.

verifying it

the unit suite is hermetic (a stub driver fakes unity's failure modes; no unity needed):

.venv/bin/python -m pytest -q
.venv/bin/python -m ruff check .
.venv/bin/python -m mypy

the gates are the real harness — they assert the properties that actually matter, and they write machine-readable evidence to gates/evidence/:

.venv/bin/python gates/run_gates.py                    # G0–G4, hermetic
UNITY_MCP_GATE_WORKSPACE=/path/to/project \
UNITY_MCP_GATE_EDIT_FLOOR=230 \
  .venv/bin/python gates/run_gates.py                  # + G5/G6 against real unity

gate

asserts

G0

ruff + mypy + unit suite clean

G1

two concurrent calls to one server don't overlap

G2

two concurrent calls to separate server processes don't overlap (the test an asyncio.Lock fails)

G3

two workspaces, two processes, neutral cwd — each reports its own numbers (arithmetic tripwire: A must say 7, B must say 13)

G4

guard parity: exit-code-lies, fatal abort, missing XML, bad project and bad target both refused before the lock, and a timeout kills the whole process group (no orphaned 2GB editor)

G5

real unity: compile + EditMode against a real project, with a totals floor

G6

real screenshot: a >10KB PNG off the built player

SKIPPED always carries a reason and is never counted as a pass.

limitations

  • macOS only. the shot path is Quartz-specific and the build targets a mac player.

  • no live-editor introspection. no scene graph, no live console, no poking a running game. that's the trade for not needing an editor.

  • you cannot inject input into the player. a screenshot shows you a frame; it can't press a key. drive gameplay from PlayMode tests instead — give your controller an input seam (a Func<Vector2> the test can set) and assert on real physics.

  • one project at a time per machine, by construction. that's the lock, and it's a feature.

license

MIT.

A
license - permissive license
-
quality - not tested
C
maintenance

Maintenance

Maintainers
Response time
Release cycle
Releases (12mo)
Commit activity

Resources

Unclaimed servers have limited discoverability.

Looking for Admin?

If you are the server author, to access and configure the admin panel.

Latest Blog Posts

MCP directory API

We provide all the information about MCP servers via our MCP API.

curl -X GET 'https://glama.ai/api/mcp/v1/servers/Shonas301/headless-unity-mcp'

If you have feedback or need assistance with the MCP directory API, please join our Discord server