// Deploy and run ML experiments on local, remote, Vast.ai, or Modal serverless GPU. Use when user says "run experiment", "deploy to server", "跑实验", or needs to launch training jobs.
Generate/edit images with OpenAI gpt-image-2 by default, falling back to Gemini (gemini-3.1-flash-image-preview) when OPENAI_API_KEY is unset. Supports text-to-image + image-to-image; 1K/2K/4K; use --input-image for editing, --provider to force a provider, --model to override the model.
Mandatory pre-flight compute resource check before running experiments. Detects whether local/remote GPU or compute resources are actually available. If resources are unavailable, STOPS the experiment pipeline immediately and reports to the user — preventing the model from hallucinating fake experiment results. Use when: about to run experiments, deploy training, or any GPU-intensive task.
Workflow 1.5: Bridge between idea discovery and auto review. Reads EXPERIMENT_PLAN.md, implements experiment code, deploys to GPU, collects initial results. Use when user says "实现实验", "implement experiments", "bridge", "从计划到跑实验", "deploy the plan", or has an experiment plan ready to execute.
Dr. Claw workspace skill for project lookup, session inspection, TaskMaster progress, OpenClaw structured schema, and event-driven reporting
Use when a quest needs one or more follow-up runs such as ablations, robustness checks, error analysis, or failure analysis after a main experiment.
Use when a quest needs to attach, import, reproduce, repair, verify, compare, or publish a baseline and its metrics.
| name | aris-run-experiment |
| description | Deploy and run ML experiments on local, remote, Vast.ai, or Modal serverless GPU. Use when user says "run experiment", "deploy to server", "跑实验", or needs to launch training jobs. |
| argument-hint | ["experiment-description"] |
| allowed-tools | Bash(*), Read, Grep, Glob, Edit, Write, Agent, Skill(serverless-modal) |
| license | MIT |
| metadata | {"author":"wanshuiyin/ARIS","version":"1.0.0"} |
Deploy and run ML experiment: $ARGUMENTS
Before doing ANYTHING else, run /aris-compute-guard to verify that compute resources are actually available.
If /aris-compute-guard is not available as a sub-skill, perform the check inline:
nvidia-smi --query-gpu=index,memory.used,memory.total --format=csv,noheader. A GPU is free if memory.used < 500 MiB.python3 -c "import torch; print(torch.backends.mps.is_available())".ssh <server> nvidia-smi --query-gpu=index,memory.used,memory.total --format=csv,noheader.modal token verify — Modal is serverless and always available if configured.If compute resources are NOT available:
If compute resources ARE available: Print a brief confirmation and proceed to Step 1.
Read the project's CLAUDE.md to determine the experiment environment:
gpu: local): Look for local CUDA/MPS setup infogpu: remote): Look for SSH alias, conda env, code directorygpu: vast): Check for vast-instances.json at project root — if a running instance exists, use it. Also check CLAUDE.md for a ## Vast.ai section.gpu: modal): Serverless GPU via Modal. No SSH, no Docker, auto scale-to-zero. Delegate to /aris-serverless-modal.Modal detection: If CLAUDE.md has gpu: modal or a ## Modal section, the entire deployment is handled by /aris-serverless-modal. Jump to Step 4: Deploy (Modal) — Steps 2-3 are not needed (Modal handles code sync and GPU allocation automatically).
Vast.ai detection priority:
CLAUDE.md has gpu: vast or a ## Vast.ai section:
vast-instances.json exists and has a running instance → use that instance/aris-vast-gpu provision which analyzes the task, presents cost-optimized GPU options, and rents the user's choiceCLAUDE.md, ask the user.Check GPU availability on the target machine:
Remote (SSH):
ssh <server> nvidia-smi --query-gpu=index,memory.used,memory.total --format=csv,noheader
Remote (Vast.ai):
ssh -p <PORT> root@<HOST> nvidia-smi --query-gpu=index,memory.used,memory.total --format=csv,noheader
(Read ssh_host and ssh_port from vast-instances.json, or run vastai ssh-url <INSTANCE_ID> which returns ssh://root@HOST:PORT)
Local:
nvidia-smi --query-gpu=index,memory.used,memory.total --format=csv,noheader
# or for Mac MPS:
python -c "import torch; print('MPS available:', torch.backends.mps.is_available())"
Free GPU = memory.used < 500 MiB.
Check the project's CLAUDE.md for a code_sync setting. If not specified, default to rsync.
Only sync necessary files — NOT data, checkpoints, or large files:
rsync -avz --include='*.py' --exclude='*' <local_src>/ <server>:<remote_dst>/
code_sync: git is set in CLAUDE.md)Push local changes to remote repo, then pull on the server:
# 1. Push from local
git add -A && git commit -m "sync: experiment deployment" && git push
# 2. Pull on server
ssh <server> "cd <remote_dst> && git pull"
Benefits: version-tracked, multi-server sync with one push, no rsync include/exclude rules needed.
Sync code to the vast.ai instance (always rsync, code dir is /workspace/project/):
rsync -avz -e "ssh -p <PORT>" \
--include='*.py' --include='*.yaml' --include='*.yml' --include='*.json' \
--include='*.txt' --include='*.sh' --include='*/' \
--exclude='*.pt' --exclude='*.pth' --exclude='*.ckpt' \
--exclude='__pycache__' --exclude='.git' --exclude='data/' \
--exclude='wandb/' --exclude='outputs/' \
./ root@<HOST>:/workspace/project/
If requirements.txt exists, install dependencies:
scp -P <PORT> requirements.txt root@<HOST>:/workspace/
ssh -p <PORT> root@<HOST> "pip install -q -r /workspace/requirements.txt"
wandb: true in CLAUDE.md)Skip this step entirely if wandb is not set or is false in CLAUDE.md.
Before deploying, ensure the experiment scripts have W&B logging:
Check if wandb is already in the script — look for import wandb or wandb.init. If present, skip to Step 4.
If not present, add W&B logging to the training script:
import wandb
wandb.init(project=WANDB_PROJECT, name=EXP_NAME, config={...hyperparams...})
# Inside training loop:
wandb.log({"train/loss": loss, "train/lr": lr, "step": step})
# After eval:
wandb.log({"eval/loss": eval_loss, "eval/ppl": ppl, "eval/accuracy": acc})
# At end:
wandb.finish()
Metrics to log (add whichever apply to the experiment):
train/loss — training loss per steptrain/lr — learning rateeval/loss, eval/ppl, eval/accuracy — eval metrics per epochgpu/memory_used — GPU memory (via torch.cuda.max_memory_allocated())speed/samples_per_sec — throughputVerify wandb login on the target machine:
ssh <server> "wandb status" # should show logged in
# If not logged in:
ssh <server> "wandb login <WANDB_API_KEY>"
The W&B project name and API key come from
CLAUDE.md(see example below). The experiment name is auto-generated from the script name + timestamp.
For each experiment, create a dedicated screen session with GPU binding:
ssh <server> "screen -dmS <exp_name> bash -c '\
eval \"\$(<conda_path>/conda shell.bash hook)\" && \
conda activate <env> && \
CUDA_VISIBLE_DEVICES=<gpu_id> python <script> <args> 2>&1 | tee <log_file>'"
No conda needed — the Docker image has the environment. Use /workspace/project/ as working dir:
ssh -p <PORT> root@<HOST> "screen -dmS <exp_name> bash -c '\
cd /workspace/project && \
CUDA_VISIBLE_DEVICES=<gpu_id> python <script> <args> 2>&1 | tee /workspace/<log_file>'"
After launching, update the experiment field in vast-instances.json for this instance.
When gpu: modal is detected, delegate to /aris-serverless-modal:
modal_launcher.py that wraps the training script using modal.Mount.from_local_dir for code and modal.Volume for resultsmodal run modal_launcher.py (runs locally, GPU executes remotely)Key Modal settings from CLAUDE.md:
modal_gpu: GPU override (default: auto-select based on VRAM analysis)modal_timeout: Max seconds (default: 21600 = 6 hours)modal_volume: Named volume for persistent resultsNo SSH, no code sync, no screen sessions needed. Modal handles everything.
# Linux with CUDA
CUDA_VISIBLE_DEVICES=<gpu_id> python <script> <args> 2>&1 | tee <log_file>
# Mac with MPS (PyTorch uses MPS automatically)
python <script> <args> 2>&1 | tee <log_file>
For local long-running jobs, use run_in_background: true to keep the conversation responsive.
Remote (SSH):
ssh <server> "screen -ls"
Remote (Vast.ai):
ssh -p <PORT> root@<HOST> "screen -ls"
Modal:
modal app list # Check app is running
modal app logs <app> # Stream logs
Local: Check process is running and GPU is allocated.
After deployment is verified, check ~/.claude/feishu.json:
experiment_done notification: which experiments launched, which GPUs, estimated time"off": skip entirely (no-op)gpu: vast and auto_destroy: true)Skip this step if not using vast.ai or auto_destroy is false.
After the experiment completes (detected via /aris-monitor-experiment or screen session ending):
Download results from the instance:
rsync -avz -e "ssh -p <PORT>" root@<HOST>:/workspace/project/results/ ./results/
Download logs:
scp -P <PORT> root@<HOST>:/workspace/*.log ./logs/
Destroy the instance to stop billing:
vastai destroy instance <INSTANCE_ID>
Update vast-instances.json — mark status as destroyed.
Report cost:
Vast.ai instance <ID> auto-destroyed.
- Duration: ~X.X hours
- Estimated cost: ~$X.XX
- Results saved to: ./results/
This ensures users are never billed for idle instances. When
auto_destroy: true(the default), the full lifecycle is automatic: rent → setup → run → collect → destroy.
tee to save logs for later inspectionrun_in_background: true to keep conversation responsivegpu: vast, always report the running cost. If auto_destroy: true, destroy the instance as soon as all experiments on it completeUsers should add their server info to their project's CLAUDE.md:
## Remote Server
- gpu: remote # use pre-configured SSH server
- SSH: `ssh my-gpu-server`
- GPU: 4x A100 (80GB each)
- Conda: `eval "$(/opt/conda/bin/conda shell.bash hook)" && conda activate research`
- Code dir: `/home/user/experiments/`
- code_sync: rsync # default. Or set to "git" for git push/pull workflow
- wandb: false # set to "true" to auto-add W&B logging to experiment scripts
- wandb_project: my-project # W&B project name (required if wandb: true)
- wandb_entity: my-team # W&B team/user (optional, uses default if omitted)
## Vast.ai
- gpu: vast # rent on-demand GPU from vast.ai
- auto_destroy: true # auto-destroy after experiment completes (default: true)
- max_budget: 5.00 # optional: max total $ to spend per experiment
## Modal
- gpu: modal # serverless GPU via Modal (no SSH, auto scale-to-zero)
- modal_gpu: A100-80GB # optional: override GPU selection (default: auto-select)
- modal_timeout: 21600 # optional: max seconds (default: 6 hours)
- modal_volume: my-results # optional: named volume for results persistence
## Local Environment
- gpu: local # use local GPU
- Mac MPS / Linux CUDA
- Conda env: `ml` (Python 3.10 + PyTorch)
Vast.ai setup: Run
pip install vastai && vastai set api-key YOUR_KEY. Upload your SSH public key at https://cloud.vast.ai/manage-keys/. Setgpu: vastin yourCLAUDE.md—/aris-run-experimentwill automatically rent an instance, run the experiment, and destroy it when done.
Modal setup: Run
pip install modal && modal setup. Bind a payment method at https://modal.com/settings (NEVER through CLI) to unlock the full $30/month free tier (without card: $5/month only). Set a workspace spending limit to prevent accidental charges. Setgpu: modalin yourCLAUDE.md— ideal for users without a local GPU who need to debug code or run small-scale tests.
W&B setup: Run
wandb loginon your server once (or setWANDB_API_KEYenv var). The skill reads project/entity from CLAUDE.md and addswandb.init()+wandb.log()to your training scripts automatically. Dashboard:https://wandb.ai/<entity>/<project>.