| name | managed-model-endpoints |
| description | Register a model service in the managed family — a local model server container the daemon starts/stops on demand, or a remote upstream model API (https). Read the runbook, allocate a port (local only), compose idempotent start/stop scripts (local only), register once. Load when the user wants a model service available for inference, or when list_compute shows managed endpoints. |
| license | Apache-2.0 |
Managed model endpoints
A managed model endpoint is a model service the daemon owns: you
register it once, then every compute_provider cell against it just
works — the daemon swaps the resident model off the device (one model at a
time, via the resident's own approved stop), runs your approved start
script, waits for the readiness route, then runs your cell, streaming its
lifecycle progress into the cell as it goes. You never run the container
runtime yourself, never poll readiness in cells, and never see the
credential value. Two verbs: register() (asks the user once) and ordinary
inference cells.
Container specifics — image, registry login, internal port, cache mount
target, readiness route — come from the model's own runbook skill; this
skill is the translation contract.
Calling a registered endpoint — inference cells
Calling a registered endpoint — use the using-model-endpoint skill
(this skill is the REGISTRATION contract; that one documents the call
side in full).
The ONLY dispatch form is the compute_provider tool with the endpoint's
registered name (list_compute shows them):
compute_provider(provider="boltz2-service", code="""
import requests
r = requests.post(BASE_URL + "/v1/infer", json=payload)
""")
The daemon brings the model up on demand (a first cold start downloads
image + weights — minutes; let it run) and preloads BASE_URL into the
cell — both as a Python variable (use it directly, as above) and as
os.environ["BASE_URL"] (plus INFER_API_KEY for remote endpoints). Endpoints are
not kernel environments: environment="boltz2-service" on a plain
python cell fails — plain cells get no BASE_URL.
Enablement — once per machine
The user connects the family under Customize → Compute → Model
endpoints (the setup flow saves the family credential first —
connect-without-key is not a state) and picks ONE mode: Local
(container registrations) or URL/remote (https against the configured
host). Until connected, free_port()/register() raise a precise error —
relay it; in the wrong mode they refuse with a teaching error naming the
setting (existing endpoints of the unarmed leg keep dispatching — only NEW
registrations refuse). Disconnecting is a full teardown: every active
local service is stopped via its approved stop script and every
registration (local AND hosted) is removed; caches stay on disk; a failing
stop keeps that one row, FAILED. The "Local machine GPU" toggle never
gates registration — it governs cell GPU access only; the approval card is
the per-registration gate.
Credential contract (platform rule): every registration passes
credential="NVIDIA_API_KEY" — the daemon rejects any other name. Locally
the value feeds the start script's registry login and never enters your
kernel env; for remote endpoints it authenticates the upstream and is
delivered only into the inference cell's env (as INFER_API_KEY), never
the repl kernel.
Register (repl kernel)
port = host.model_endpoints.free_port()
host.model_endpoints.register(
name="boltz2-service",
url=f"http://127.0.0.1:{port}",
credential="NVIDIA_API_KEY",
skill="<model-runbook-skill>",
start=START_SCRIPT,
stop="docker stop boltz2-service",
live="/v1/health/ready",
)
Name endpoints <model>-service (e.g. diffdock-service) — unambiguous in
provider lists; never just the bare model name. Name the CONTAINER after
the endpoint too (the template above does): the UI then follows the
service's own logs live while it starts.
register() always cards the user (scripts verbatim, port, service dir,
credential name). One exception: a byte-identical re-registration is
silent — same bytes are approved forever; any byte change re-cards. The
registration stays inspectable under Customize → Compute. Re-registering to
fix scripts: reuse the existing url — never call free_port() again
(the port is the endpoint's stable mutex).
Remote endpoints — upstream APIs (no lifecycle)
Pass url="https://<upstream>" and omit start/stop/live — no
port, no scripts, no readiness. Requires URL/remote mode (the setup
radio; in Local mode https registrations refuse). The url's HOST must
equal the configured upstream host exactly — you pick the path leaf,
never the authority. After approval,
cells are plain HTTP clients of BASE_URL authenticating with
$INFER_API_KEY. list_compute labels every row
location: "local" | "remote".
Composing the start script
The daemon hands scripts three things in their process environment
(never argv, never sudo): HOST_PORT (the registered port), SERVICE_DIR
(this endpoint's persistent directory — put the model cache here), and the
credential value under its own name. Nothing else is inherited — ambient
tokens are not visible; the ONLY secret a script sees is its registered
credential.
The start script must be idempotent (cold create / warm start / crash
re-entry), with the port-mismatch guard — the runtime freezes port
mappings at container creation, so a container created under an OLD port
must be recreated or readiness can never pass:
mkdir -p "$SERVICE_DIR/cache"
export DOCKER_CONFIG="$SERVICE_DIR/.docker"
create_service() {
docker run -d --name boltz2-service \
--restart unless-stopped \
-p 127.0.0.1:${HOST_PORT}:8000 --gpus all \
-e NVIDIA_API_KEY \
-v "$SERVICE_DIR/cache:<cache target from the runbook>" \
<image from the runbook>
}
if docker inspect boltz2-service >/dev/null 2>&1 && \
[ "$(docker inspect -f '{{(index (index .HostConfig.PortBindings "8000/tcp") 0).HostPort}}' boltz2-service)" != "$HOST_PORT" ]; then
docker rm -f boltz2-service
fi
if docker inspect boltz2-service >/dev/null 2>&1; then
docker start boltz2-service
else
echo "$NVIDIA_API_KEY" | docker login <registry> --username '<user>' --password-stdin
docker pull <image from the runbook>
CUID="$(docker inspect --format '{{.Config.User}}' <image from the runbook> 2>/dev/null | cut -d: -f1)"
case "$CUID" in ''|root) CUID=0;; *[!0-9]*) CUID=1000;; esac
if [ "$CUID" != "0" ]; then
docker run --rm -v "$SERVICE_DIR/cache:/c" alpine sh -c "chown -R $CUID:$CUID /c && chmod 700 /c"
else
chmod 700 "$SERVICE_DIR/cache" 2>/dev/null || true
fi
create_service
fi
if [ -z "$(docker port boltz2-service 2>/dev/null)" ]; then
docker rm -f boltz2-service
create_service
fi
Translation rules:
- Keep scripts ASCII — non-ASCII (em dashes, arrows, curly quotes)
triggers the approval card's spoofing warning; use
-- and -> in
comments.
export DOCKER_CONFIG="$SERVICE_DIR/.docker" before any docker login — login persists the credential in config.json, and scoping it
to the service dir means Remove honestly reclaims it (never ~/.docker,
which outlives stop/Remove/Disable).
-p 127.0.0.1:${HOST_PORT}:<internal> — loopback-only publish; the
internal port comes from the runbook.
- If the image reads a different env name, bridge env→env at the top:
export OTHER_NAME="$NVIDIA_API_KEY" (never argv, never a file).
-e NAME bare (argv is world-readable); the key rides the login
stdin pipe only.
-d, no --rm — managed containers are stopped, never removed:
stop parks them with weights loaded; --rm throws the cache away.
- Cache under
$SERVICE_DIR, owned by the container's uid: the
runbook states it when it matters; otherwise derive it post-pull with
docker inspect --format '{{.Config.User}}' <image> (empty or root
⇒ runs as root, no chown needed; a NAMED user can't be resolved
without running the image — default 1000). Getting it wrong is the
cache-empty symptom: the container can't write the mount, weights leak
into the writable layer and die on recreate (or the image crash-loops
on Permission denied). Never 777 — world-writable cache on a
multi-user host. The mount TARGET comes from the runbook.
- Cells need no auth header against local endpoints — the credential is
a pull key that never enters your kernel.
Failures
A failed start/stop flips the endpoint FAILED (transcript on the
endpoint panel — never echoed into cell errors; ask the user to read it
there) and your cell errors with the daemon's one-line cause. FAILED is
sticky: further cells fail fast until the user presses Stop or you
re-register (byte-identical re-register also clears it). If a stop is stuck
(exit 0 but the port never frees), removal is refused while the port is
bound — recover out-of-band; the daemon absorbs the freed port on its next
probe. A first-ever cold start downloads image + weights — minutes, once;
the cell streams the phase lines live and the endpoint detail view streams
the full script output, so let it run.