nanochat-llm-training
Train your own GPT-2 level LLM for under $100 using nanochat, Karpathy's minimal hackable harness covering tokenization, pretraining, finetuning, evaluation, inference, and chat UI.
How do I install this agent skill?
npx skills add https://github.com/aradotso/trending-skills --skill nanochat-llm-trainingIs this agent skill safe to install?
- Gen Agent Trust Hubfail
The skill provides a workflow for training and running LLMs based on the nanochat repository. It includes standard commands for dependency management and model training. A potential security risk is identified regarding indirect prompt injection, as the skill includes a code execution tool and processes external data, though this is a common characteristic of development environments.
- Socketpass
No alerts
- Snykfail
Risk: CRITICAL · 2 issues
- ZeroLeakspass
1 finding · Score: 82/100
What does this agent skill do?
nanochat LLM Training
Skill by ara.so — Daily 2026 Skills collection.
nanochat is Karpathy's minimal, hackable harness for training LLMs end-to-end on a single GPU node. It covers tokenization, pretraining, SFT finetuning, RL, evaluation (DCLM CORE score), inference with KV cache, and a ChatGPT-like web UI. A single complexity dial (--depth) auto-configures all other hyperparameters (width, heads, LR, training horizon, weight decay) for compute-optimal training. You can reproduce GPT-2 capability (~$43,000 in 2019) for ~$48 on an 8×H100 node (~2 hours).
Installation
nanochat uses uv for dependency management:
git clone https://github.com/karpathy/nanochat.git
cd nanochat
# Install uv if needed
curl -LsSf https://astral.sh/uv/install.sh | sh
# Create venv and install deps
uv sync
source .venv/bin/activate
Key Commands
Full GPT-2 Speedrun (8×H100 node, ~2–3 hours, ~$48)
# Run the reference pipeline: data download, pretraining, SFT, eval, chat
bash runs/speedrun.sh
Pretraining (distributed)
OMP_NUM_THREADS=1 torchrun --standalone --nproc_per_node=8 -m scripts.base_train -- \
--depth=26 \
--run="d26_run" \
--model-tag="d26"
Pretraining (single GPU)
python -m scripts.base_train -- \
--depth=26 \
--run="d26_single"
Quick Research Iteration (~5 min, GPT-1 scale)
OMP_NUM_THREADS=1 torchrun --standalone --nproc_per_node=8 -m scripts.base_train -- \
--depth=12 \
--run="d12_exp" \
--model-tag="d12" \
--core-metric-every=999999 \
--sample-every=-1 \
--save-every=-1
CPU / Apple Silicon (tiny model, ~minutes)
bash runs/runcpu.sh
Serve Chat UI
# After training completes
source .venv/bin/activate
python -m scripts.chat_web
# Visit http://<your-server-ip>:8000/
CLI Chat
python -m scripts.chat_cli -p "hello"
Scaling Laws / Miniseries
bash runs/scaling_laws.sh # sweep depths for scaling law data
bash runs/miniseries.sh # train full compute-optimal miniseries
The Depth Dial
The single most important parameter. Everything else is derived automatically:
--depth | Approximate model scale | Notes |
|---|---|---|
| 6–8 | Tiny (toy) | CPU/MPS feasible |
| 12 | GPT-1 size | ~5 min on 8×H100, great for research iteration |
| 16 | Medium | ~15 min on 8×H100 |
| 24–26 | GPT-2 size | ~2 hrs on 8×H100, ~$48 |
# Smaller/faster experiments
python -m scripts.base_train -- --depth=12 --run="quick_test"
# Full GPT-2 grade
torchrun --standalone --nproc_per_node=8 -m scripts.base_train -- --depth=26 --run="gpt2_repro"
Precision / dtype Configuration
nanochat uses explicit dtype management via COMPUTE_DTYPE in nanochat/common.py. No torch.amp.autocast.
| Hardware | Default | Override |
|---|---|---|
| CUDA SM 80+ (A100, H100) | bfloat16 | NANOCHAT_DTYPE=float32 |
| CUDA SM < 80 (V100, T4) | float32 | NANOCHAT_DTYPE=float16 |
| CPU / MPS | float32 | — |
# Force fp32 for inference
NANOCHAT_DTYPE=float32 python -m scripts.chat_cli -p "hello"
# Force bf16 for training
NANOCHAT_DTYPE=bfloat16 torchrun --nproc_per_node=8 -m scripts.base_train
# float16 training (enables GradScaler automatically)
NANOCHAT_DTYPE=float16 torchrun --nproc_per_node=8 -m scripts.base_train
How it works: Weights stored in fp32 (optimizer precision), custom Linear casts to COMPUTE_DTYPE in forward pass, embeddings stored directly in COMPUTE_DTYPE to save memory.
Key Python Modules
nanochat/
├── gpt.py # GPT nn.Module Transformer
├── engine.py # Inference with KV Cache
├── dataloader.py # Tokenizing Distributed Data Loader
├── dataset.py # Download/read utils for pretraining data
├── optim.py # AdamW + Muon optimizer (1GPU and distributed)
├── core_eval.py # DCLM CORE score evaluation
├── loss_eval.py # Bits-per-byte evaluation
├── checkpoint_manager.py # Save/Load checkpoints
├── common.py # Utilities, COMPUTE_DTYPE
├── execution.py # Python code execution tool for LLM
└── engine.py # Efficient KV-cache inference
scripts/
├── base_train.py # Pretraining entry point
├── chat_web.py # Web chat UI server
└── chat_cli.py # CLI chat interface
runs/
├── speedrun.sh # Reference full pipeline (GPT-2 speedrun)
├── scaling_laws.sh # Scaling law sweeps
├── miniseries.sh # Full compute-optimal miniseries
└── runcpu.sh # CPU/MPS example
Real Code Examples
Load and Run Inference on a Trained Model
import torch
from nanochat.gpt import GPT
from nanochat.engine import InferenceEngine
from nanochat.checkpoint_manager import CheckpointManager
# Load checkpoint
ckpt_manager = CheckpointManager("checkpoints/d26")
model, config = ckpt_manager.load()
model.eval()
# Run inference with KV cache
engine = InferenceEngine(model)
output = engine.generate(
prompt="Once upon a time",
max_new_tokens=200,
temperature=0.8,
top_p=0.95,
)
print(output)
Custom Training Script with Depth Dial
import subprocess
def train_model(depth: int, run_name: str, nproc: int = 8):
"""Launch a compute-optimal training run for given depth."""
cmd = [
"torchrun",
"--standalone",
f"--nproc_per_node={nproc}",
"-m", "scripts.base_train",
"--",
f"--depth={depth}",
f"--run={run_name}",
f"--model-tag={run_name}",
]
subprocess.run(cmd, env={"OMP_NUM_THREADS": "1", **__import__("os").environ})
# Quick research iteration
train_model(depth=12, run_name="my_experiment_d12")
# Full GPT-2 grade
train_model(depth=26, run_name="my_gpt2_repro")
Adjust Device Batch Size for Lower VRAM
# Default device_batch_size=32 needs ~80GB VRAM per GPU
# Reduce for smaller GPUs (gradient accumulation handles the rest)
torchrun --standalone --nproc_per_node=4 -m scripts.base_train -- \
--depth=12 \
--device_batch_size=16 \
--run="low_vram_run"
# Even smaller
python -m scripts.base_train -- \
--depth=8 \
--device_batch_size=4 \
--run="single_gpu_small"
Monitoring Key Metrics in wandb
# nanochat logs to wandb automatically. Key metrics to watch:
# - val_bpb: validation loss in bits-per-byte (vocab-size-invariant)
# as a function of step, total_training_time, total_training_flops
# - core_metric: DCLM CORE score (target > 0.2565 to beat GPT-2)
# - train/mfu: Model FLOPS utilization
# - train/tok_per_sec: Training throughput
# Set wandb project via env var before training
import os
os.environ["WANDB_PROJECT"] = "my-nanochat-runs"
Synthetic Data for SFT Personality
# dev/gen_synthetic_data.py — generate identity/personality data
# Then mix into SFT stage per the guide:
# https://github.com/karpathy/nanochat/discussions/139
# Example: generate data and point SFT to it
python dev/gen_synthetic_data.py --output data/identity_sft.jsonl
# Then reference in your SFT script configuration
Common Patterns
Research Iteration Loop
# 1. Make a code change in nanochat/
# 2. Run quick d12 to validate
OMP_NUM_THREADS=1 torchrun --standalone --nproc_per_node=8 -m scripts.base_train -- \
--depth=12 --run="test_my_change" \
--core-metric-every=999999 --sample-every=-1 --save-every=-1
# 3. Check wandb: val_bpb vs step/time/flops
# 4. If promising, test at d16 or d26
FP8 Training (H100 only, for speedrun)
# FP8 is used in the speedrun for additional speedup
# See runs/speedrun.sh for the exact invocation
bash runs/speedrun.sh
Evaluate CORE Score Only
python -m nanochat.core_eval --checkpoint checkpoints/d26/latest
Serve on Lambda / Remote Machine
# On remote machine after training:
source .venv/bin/activate
python -m scripts.chat_web
# Access via: http://<PUBLIC_IP>:8000/
# Use `screen` or `tmux` to keep alive
screen -S nanochat
python -m scripts.chat_web
# Ctrl+A, D to detach
Troubleshooting
OOM / Out of VRAM
# Reduce --device_batch_size (default 32)
# Code uses gradient accumulation to maintain effective batch size
--device_batch_size=16 # Try 16, 8, 4, 2, 1
Single GPU is 8× Slower
This is expected. Omit torchrun and use python -m scripts.base_train directly. Gradient accumulation kicks in automatically to maintain equivalent total batch size.
Running on Non-CUDA Hardware
# MPS (Apple Silicon) or CPU — use runcpu.sh as template
bash runs/runcpu.sh
# Results will be weak; this is for development/debugging only
float16 Gradient Underflow
# nanochat auto-enables GradScaler when NANOCHAT_DTYPE=float16
NANOCHAT_DTYPE=float16 torchrun --nproc_per_node=8 -m scripts.base_train -- --depth=12
# Note: RL scripts do NOT support float16 (SFT and base_train do)
V100 / T4 (SM < 80) — No bf16
# Default falls back to float32; optionally use float16
NANOCHAT_DTYPE=float16 torchrun --nproc_per_node=8 -m scripts.base_train -- --depth=12
Chat UI Not Accessible
# Ensure the port (default 8000) is open in your cloud provider's firewall/security group
# Use the public IP, not localhost:
# http://<PUBLIC_IP>:8000/
Resources
- DeepWiki Q&A: https://deepwiki.com/karpathy/nanochat
- Discussions: https://github.com/karpathy/nanochat/discussions
- Discord:
#nanochatchannel on Karpathy's Discord - Leaderboard docs:
dev/LEADERBOARD.md - Beating GPT-2 guide: https://github.com/karpathy/nanochat/discussions/481
- Miniseries v1: https://github.com/karpathy/nanochat/discussions/420
- Adding abilities guide: https://github.com/karpathy/nanochat/discussions/164
How can the creator link this skill?
Add the canonical catalog link to the repository README so users can inspect current installs and available audits. The publishing guide covers the complete discovery path.
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