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SLURM HPC job management on Artemis — write submission scripts, submit jobs, monitor status, retrieve results
Codex または Claude でインストール この Prompt をコピーして Codex、Claude、または他のアシスタントに貼り付けると、Skill ページを確認してインストールできます。
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SLURM HPC job management on Artemis — write submission scripts, submit jobs, monitor status, retrieve results
Codex または Claude でインストール この Prompt をコピーして Codex、Claude、または他のアシスタントに貼り付けると、Skill ページを確認してインストールできます。
SOC 職業分類に基づく
Onboard and manage Paperclip AI for research-paper knowledge and agent orchestration
Generate a structured scientific post and publish it to Infinite. Runs a focused single-agent investigation (PubMed search → LLM analysis → hypothesis/method/findings/conclusion) and posts the result. Faster than scienceclaw-investigate — best for targeted, single-topic posts.
Infinite platform integration for AI agent collaboration
Read a CSV or XLSX file and return columns, shape, dtypes, and first N rows as JSON.
Execute arbitrary Python code and return stdout. NumPy, pandas, scipy, matplotlib, and other scientific libraries are available.
Generate a structured scientific PDF report from a JSON description. Accepts a JSON file specifying title, authors, abstract, sections (headings, text, tables, figures), and inline data panels (heatmap, bar, scatter, line). Produces a publication-style A4 PDF using reportlab with no LaTeX dependency. All figures are either loaded from PNG paths or generated on-the-fly from inline data.
| name | hpc |
| description | SLURM HPC job management on Artemis — write submission scripts, submit jobs, monitor status, retrieve results |
| metadata | null |
Manage SLURM batch jobs on the Artemis HPC cluster. This skill teaches the agent how to write SLURM submission scripts, submit them, monitor status, and retrieve results using standard SLURM CLI tools.
There are no wrapper scripts — use SLURM commands directly via bash.
33 nodes total: 25 CPU, 3 large-memory, 3 H100 GPU, 2 A100 GPU.
| Partition | Wall Time | Nodes | CPUs | RAM | GPUs | Notes |
|---|---|---|---|---|---|---|
venkvis-cpu | 48h | 25 | 96c (EPYC 9654) | 368 GB | — | Default for DFT |
venkvis-largemem | 48h | 3 | 96c (EPYC 9654) | 768 GB | — | Large-memory jobs |
venkvis-a100 | 8h | 2 | 32c (EPYC 7513) | 512 GB | 4× A100 80GB | GPU compute |
venkvis-h100 | 8h | 3 | 96c (EPYC 9654) | 368 GB | 4× H100 80GB | GPU compute (fastest) |
debug | 30m | 4 max | varies | varies | varies | Quick tests |
| Tier | Path | Capacity | Notes |
|---|---|---|---|
| Turbo | /nfs/turbo/coe-venkvis/ | 10 TB (500 GB fair share) | Persistent, backed up |
| Scratch | /scratch/venkvis_root/venkvis/ | 10 TB (500 GB fair share) | 60-day auto-purge |
| Home | /home/<user> | 80 GB | User home |
| Node Local | /tmp | 1.9 TB NVMe | Ephemeral, fast I/O |
Create a bash script with #SBATCH directives. Example for a GPU job:
#!/bin/bash
#SBATCH --job-name=my-job
#SBATCH --partition=venkvis-h100
#SBATCH --nodes=1
#SBATCH --ntasks-per-node=1
#SBATCH --cpus-per-task=4
#SBATCH --mem=32G
#SBATCH --time=02:00:00
#SBATCH --gres=gpu:1
#SBATCH --output=slurm-%j.out
#SBATCH --error=slurm-%j.err
# Activate Python environment
source /path/to/venv/bin/activate
# Export any needed API keys
export HF_TOKEN="..."
export MP_API_KEY="..."
# Run your computation
python3 my_script.py --arg1 value1 --format json > results.json
echo "Done: $(date)"
For CPU jobs, remove --gres=gpu:1 and use --partition=venkvis-cpu.
Key #SBATCH directives:
--partition=<name> — which queue (see table above)--gres=gpu:<N> — request N GPUs (GPU partitions only)--time=HH:MM:SS — wall time limit--mem=<N>G — memory per node--cpus-per-task=<N> — CPU cores--output=<path> / --error=<path> — stdout/stderr files (%j = job ID)--array=0-9 — submit a job array (10 tasks)# Submit a script
sbatch submit.sh
# Submit with partition override
sbatch --partition=venkvis-h100 submit.sh
# Submit with dependency (run after job 12345 completes)
sbatch --dependency=afterok:12345 next_step.sh
Output: Submitted batch job 12345
# Check your running/pending jobs
squeue -u $USER
# Check a specific job
squeue -j 12345
# Check a specific partition
squeue -p venkvis-h100
# Detailed job info (including completed jobs)
sacct -j 12345 --format=JobID,State,Elapsed,ExitCode,NodeList,MaxRSS
# Check estimated start time for pending job
squeue -j 12345 --start
Key job states: PENDING, RUNNING, COMPLETED, FAILED, CANCELLED, TIMEOUT, OUT_OF_MEMORY.
After a job completes, results are wherever your script wrote them:
# Check if job finished
sacct -j 12345 --format=JobID,State,Elapsed,ExitCode --noheader
# Read stdout/stderr
cat slurm-12345.out
cat slurm-12345.err
# Read structured results (if your script wrote JSON)
cat results.json | python3 -m json.tool
# Cancel a specific job
scancel 12345
# Cancel all your jobs
scancel -u $USER
# Cancel all pending jobs
scancel -u $USER --state=PENDING
For quick debugging or running scienceclaw-post with GPU access:
# Interactive shell with H100 GPU (up to 8 hours)
srun -N 1 -n 1 -p venkvis-h100 --gres=gpu:h100:1 --mem=32G -t 04:00:00 --pty bash
# Interactive shell with A100 GPU
srun -N 1 -n 1 -p venkvis-a100 --gres=gpu:a100:1 --mem=32G -t 04:00:00 --pty bash
# Quick debug session (30 min max, fastest scheduling)
srun --partition=debug --nodes=1 --gres=gpu:h100:1 --mem=2G --time=30 --pty bash
Once on the GPU node, activate the venv and run commands normally:
source /nfs/turbo/coe-venkvis/changwex/projects/scienceclaw/.venv/bin/activate
scienceclaw-post --agent MatSim --topic "..." --skills uma --dry-run
echo $SLURM_JOB_ID (should be empty on login node)/scratch/, not /nfs/turbo/ or /home/