| name | kermt-pretrain-scratch |
| description | Pretrain a fresh KERMT model from scratch on a user-provided corpus. Builds a new vocabulary from the corpus, instantiates the model architecture from defaults, and launches pretrain_ddp.py inside the kermt container (detached for long runs). Unlike kermt-continue-pretrain, no starting checkpoint is loaded — the model is randomly initialized. |
| license | Apache-2.0 OR CC-BY-4.0 |
| compatibility | Requires docker, nvidia-container-toolkit, and a CUDA-capable NVIDIA GPU. Designed for Claude Code, Codex, and Nemotron. |
| metadata | {"classification":"workflow-skill","risk_tier":"skill"} |
kermt-pretrain-scratch
Pretrain a brand-new KERMT model from scratch on a user-provided corpus. Useful
when you want to retrain a model on a custom chemistry domain rather than
extending one of the released checkpoints. Significantly more expensive than
kermt-continue-pretrain — no warm start, so the loss curves need to descend
from scratch over many epochs.
Hardware requirements
Same as kermt-continue-pretrain:
-
GPUs: 1–N CUDA-capable. The runner auto-detects via
torch.cuda.device_count(); --gpus 0,2 overrides. Single-GPU fallback:
--batch_size 32 --save_interval 500. Multi-GPU keeps defaults
(--batch_size 256 etc.). Note: --gpus N uses torch.cuda indexing,
which can differ from nvidia-smi's display order on multi-GPU hosts
(PCI bus vs. CUDA enumeration). To target a specific physical GPU, set
CUDA_VISIBLE_DEVICES before invoking, or run
python -c "import torch; print([torch.cuda.get_device_name(i) for i in range(torch.cuda.device_count())])"
to confirm which device you're picking.
-
VRAM: the default --batch-size 256 is sized for A100-class hardware
(80 GB VRAM). On smaller GPUs, downscale to avoid OOM:
| GPU class | VRAM | Suggested --batch-size |
|---|
| L4, T4, V100 16 GB | 16–24 GB | 32–64 |
| A100 40 GB, L40, A40 | 40–48 GB | 128 |
| A100 80 GB, H100, H200 | 80 GB | 256 (default) |
These are rough starting points — pass --batch-size N to override.
-
Disk: tens of GB for shards + vocab + checkpoints, scaled by epochs.
-
Wall time: this is the big difference. Pretraining from scratch on an
11M-mol corpus at 100 epochs typically takes days even on a multi-GPU box.
The skill prints an estimate before launching; confirm with the user.
When to invoke
- User wants to train a new model on a custom corpus (e.g. domain-specific
chemistry that the released ckpts don't cover).
- User wants to reproduce a pretrain config end-to-end without depending on a
released ckpt.
For continuing an existing released ckpt, use kermt-continue-pretrain. For
adding a cMIM decoder to an encoder-only grover_base ckpt, use
kermt-add-cmim-pretrain.
Inputs
Required:
--csv <path> — the pretrain corpus CSV with a smiles column. Single file
by convention; multi-file corpora deferred. Use --val-csv for a separate
validation set.
--pretrain-target-mode {vocab|cmim|hybrid} — which pretrain objective to
use. No default — must be set explicitly so the user makes an informed
choice:
vocab — original GROVER-style atom + bond vocab prediction (encoder-only
output, lightweight).
cmim — contrastive + SMILES reconstruction objective. Requires building
a SMILES vocab from the corpus.
hybrid — both vocab and contrastive objectives jointly (the
state-of-the-art config from the KERMT manuscript).
Optional:
--val-csv <path> — separate validation CSV. Without it, prepare_data
auto-splits the input by --val-frac 0.1 (random shuffle with --seed).
- Training-hyperparameter overrides:
--epochs N / --batch-size N /
--init-lr F / --max-lr F / --final-lr F / --warmup-epochs F /
--weight-decay F / --dropout F / --save-interval N / --seed N.
Anything not given is filled from agent/config/defaults_pretrain.json.
--vocab-loss-weight F (hybrid only) / --latent-dim N /
--contrastive-temperature F (cmim and hybrid only).
--gpus 0,2 — restrict to a GPU subset.
Workflow
Let $KERMT_REPO be the path to your kermt repo checkout.
-
Pre-flight: ensure container + system probe (same as
kermt-continue-pretrain step 1). Refuse to proceed if check_system
reports gaps.
-
Compute run directory.
RUN_DIR=$KERMT_REPO/runs/pretrain-scratch_$(date -u +%Y-%m-%dT%H-%M-%SZ)
-
Validate the corpus (no ckpt to validate, so this is the only input
check):
$KERMT_REPO/agent/scripts/kermt_container.sh run --data <user-csv> -- \
"python agent/scripts/check_data.py --mode pretrain --csv /data/<basename>"
Abort on ok: false.
-
Prepare the data — no vocab pass-through (we want fresh vocab from
corpus):
$KERMT_REPO/agent/scripts/kermt_container.sh run --data <user-csv> --run-dir $RUN_DIR -- \
"python agent/scripts/prepare_data.py --mode pretrain \\
--csv /data/<basename> --out /runs/data \\
[--val-csv /data/<val-basename>] [--val-frac 0.1] [--seed 0]"
Outputs land at $RUN_DIR/data/prepare_data.json with
vocab_source: "built_fresh".
-
Estimate runtime + warn loudly. This is critical for pretrain-from-scratch:
- "Pretraining from scratch is days-scale even on multi-GPU; the released
KERMT checkpoints were each trained on millions of molecules for hundreds
of GPU-hours. If you mainly want to leverage existing knowledge for a
downstream task, consider
kermt-continue-pretrain from a released ckpt
instead, which converges in hours instead of days."
- Show the corpus size × epochs × GPU count → estimated wall time.
- Ask for explicit confirmation unless
--yes was given.
-
Launch the runner detached.
$KERMT_REPO/agent/scripts/kermt_container.sh run_detached \\
--name kermt-pretrain-scratch-<ts> \\
--run-dir $RUN_DIR -- \\
"python agent/scripts/run_pretrain_local.py \\
--from-scratch --pretrain-target-mode <vocab|cmim|hybrid> \\
--prepare-manifest /runs/data/prepare_data.json \\
--out /runs \\
[--epochs N --batch-size N ...]"
Note: NO --ckpt flag (the runner refuses if both --from-scratch and
--ckpt are given). The runner uses the arch group from
agent/config/defaults_pretrain.json to size the model.
-
Report to the user. Always include all of the following — do not
omit the TensorBoard line under output-length pressure:
- Container name + id
$RUN_DIR/run.json (the manifest with workflow: pretrain-scratch,
from_scratch: true, vocab_check: null, arch from defaults, full
cmd_replay)
- Log file:
$RUN_DIR/logs/pretrain_ddp.log
- TensorBoard:
$RUN_DIR/logs/tb (open with tensorboard --logdir $RUN_DIR/logs/tb)
- Suggest
kermt-monitor <RUN_DIR> for progress.
Hard rules
- Never accept a
--ckpt flag. From-scratch is exclusive with input
ckpt — the runner enforces this; the skill should too.
- Never silently default
--pretrain-target-mode. This is a significant
architectural choice (vocab = lightweight, hybrid = SOTA). Prompt the user
if not given on the CLI.
- Strong warning before launching. From-scratch pretrain is the most
expensive workflow. The user needs to know what they're committing to.
Common errors
--pretrain-target-mode is required when --from-scratch is set → user
forgot the mode flag. Prompt.
--from-scratch is incompatible with --ckpt → user provided both; ask which
one they meant.
defaults_pretrain.json has no arch group → repo state issue (should never
happen on a fresh clone); points the user at running kermt-setup again.
What's in the manifest after a from-scratch run
Same reproducibility fields as continue-pretrain (repo.commit, kermt_image,
cmd_replay, args_applied), plus:
workflow: "pretrain-scratch"
from_scratch: true
inputs.ckpt: null
ckpt_symlink: null
vocab_check: null (not verified — vocab built from corpus is
authoritative for from-scratch)
arch: the values pulled from agent/config/defaults_pretrain.json's
arch group (with any future CLI overrides applied).
Replayability
Same as continue-pretrain: cmd_replay is a copy-pasteable command. If
ok_to_replay: false, the kermt repo working tree was dirty at launch
time — check repo.commit and git checkout it first.