| name | kermt-setup |
| description | Bootstrap the KERMT agent environment — verify host docker + nvidia-container-toolkit, build the kermt:latest image from the repo's Dockerfile if it doesn't yet exist, and run a GPU smoke test inside the container. Every other kermt-* skill depends on this; invoke it first. |
| license | Apache-2.0 |
| compatibility | Requires docker, nvidia-container-toolkit, and a CUDA-capable NVIDIA GPU. Designed for Claude Code, Codex, and Nemotron. |
| metadata | {"owner":"evax@nvidia.com","classification":"atomic-skill","risk_tier":"skill"} |
kermt-setup
Bootstrap the KERMT agent environment. Run this once on a fresh machine (or
after the Dockerfile or environment.yml changes) before invoking any other
kermt-* skill.
Hardware requirements
- GPU: at least one CUDA-capable NVIDIA GPU visible to the host. The image
is based on
nvidia/cuda:12.6.3-cudnn-devel-ubuntu22.04, so the host driver
must support CUDA 12.6. Verify with host nvidia-smi before invoking.
- Host docker: docker engine + nvidia-container-toolkit. Without the
toolkit,
docker run --gpus all will fail at step 2 of the workflow below.
- Disk: ≈ 50 GB free for the built kermt image (
docker image inspect --format '{{.Size}}' reports ≈ 44 GB; the docker images Size column
can show ~100 GB because it counts shareable buildx attestation layers
that are deduplicated across images). Plan for ~50 GB of unique on-disk
storage; add a comfortable buffer if you're also keeping build cache.
- Memory: the build itself peaks at ~4 GB RAM during conda env solve.
- This skill does not run training/inference workloads itself; per-workflow
hardware requirements (VRAM, GPU count) are declared in the respective
kermt-<workflow> skills.
When to invoke
- User explicitly asks (
/kermt-setup, "set up kermt", "build the kermt image",
etc.).
- Or another
kermt-* skill detected that the image does not exist and routed
here. (Most other skills call kermt_ensure_image themselves, so this is
usually only needed for the first-time setup, debugging, or a forced rebuild.)
Inputs
The skill takes no required arguments. Optional overrides (via env vars before
invoking, or by setting them in the user's shell):
KERMT_IMAGE — image tag to build/verify (default: kermt:latest).
KERMT_REPO — host path of the kermt repo checkout (default: auto-derived
from the script's location).
If the user has not specified a repo path and the current working directory is
not inside a kermt repo clone, ask for the repo path before proceeding.
Workflow
All work goes through agent/scripts/kermt_container.sh. The script's
subcommand dispatch can be invoked directly without sourcing — that is the
preferred form for skill use.
Let HELPER=$KERMT_REPO/agent/scripts/kermt_container.sh.
-
Verify docker is installed and the daemon is reachable.
$HELPER check_docker
Exit 0 → continue. Non-zero → surface the error to the user (typically
"docker not on PATH" or "daemon not reachable"); do not attempt step 2.
-
Verify GPU passthrough works.
$HELPER check_gpu
This runs docker run --rm --gpus all nvidia/cuda:12.6.3-base-ubuntu22.04 nvidia-smi and checks the exit status. Non-zero → tell the user to install
nvidia-container-toolkit on the host and confirm a CUDA-capable NVIDIA GPU
is visible to the host (nvidia-smi on the host should also work). Stop
here; without GPU passthrough the kermt image will build but no workflow
will run.
-
Build or verify the kermt image.
$HELPER ensure_image
If the image already exists, this returns immediately. Otherwise it builds
from $KERMT_REPO/Dockerfile. Warn the user before invoking that the
first build takes ~10–20 minutes on a typical workstation and streams build
logs to the console. Do not run this in the background — the user wants to
see progress and any build failures must surface immediately.
-
GPU smoke test inside the container. Quote the whole python command
as a single string — the helper passes args through bash -c "$*", so
unquoted multi-word commands get re-parsed and any embedded quotes are
collapsed.
$HELPER run -- 'python -c "import torch; print(\"cuda_available:\", torch.cuda.is_available()); print(\"device_count:\", torch.cuda.device_count())"'
Expected output: cuda_available: True and a positive device_count. If
cuda_available is False despite step 2 passing, something is wrong with
the container's CUDA wiring — report the full output to the user and stop;
do not declare the environment ready.
-
Summary to user. Report:
- Image tag and ID (
docker image inspect $KERMT_IMAGE --format '{{.Id}}').
- Image size (
docker image inspect $KERMT_IMAGE --format '{{.Size}}').
- GPU count detected inside the container.
- "Ready" — the user can now invoke other
kermt-* skills.
Hard rules
- Do not pull or push docker images. The kermt image is built locally only.
- Do not auto-delete or prune older
kermt:* tags without the user's
explicit confirmation — the user may be running a finetune or pretrain in
another container that depends on a specific tag.
- Do not modify the host's docker daemon configuration, daemon.json, or
user-group membership.
- Do not modify the
Dockerfile or environment.yml as part of this
skill. If the build fails because of a Dockerfile issue, surface the error
and stop; let the user decide whether to edit.
- Do not rebuild the image when it already exists (i.e. do not pass a
--no-cache or --pull flag to ensure_image) unless the user explicitly
asks for a forced rebuild.
Forced rebuild
If the user explicitly asks to rebuild (e.g. after changing the Dockerfile or
environment.yml), the cleanest path is to remove the old image first, then
rerun ensure_image:
docker image rm $KERMT_IMAGE
$HELPER ensure_image
Confirm with the user before running docker image rm.