6.5 KiB
Llama Factory
Install and fine-tune models with LLama Factory
Table of Contents
Overview
Basic idea
LLaMA Factory is an open-source framework that simplifies the process of training and fine tuning large language models. It offers a unified interface for a variety of cutting edge methods such as SFT, RLHF, and QLoRA techniques. It also supports a wide range of LLM architectures such as LLaMA, Mistral and Qwen. This playbook demonstrates how to fine-tune large language models using LLaMA Factory CLI on your NVIDIA Spark device.
What you'll accomplish
You'll set up LLaMA Factory on NVIDIA Spark with Blackwell architecture to fine-tune large language models using LoRA, QLoRA, and full fine-tuning methods. This enables efficient model adaptation for specialized domains while leveraging hardware-specific optimizations.
What to know before starting
- Basic Python knowledge for editing config files and troubleshooting
- Command line usage for running shell commands and managing environments
- Familiarity with PyTorch and Hugging Face Transformers ecosystem
- GPU environment setup including CUDA/cuDNN installation and VRAM management
- Fine-tuning concepts: understanding tradeoffs between LoRA, QLoRA, and full fine-tuning
- Dataset preparation: formatting text data into JSON structure for instruction tuning
- Resource management: adjusting batch size and memory settings for GPU constraints
Prerequisites
-
NVIDIA Spark device with Blackwell architecture
-
CUDA 12.9 or newer version installed:
nvcc --version -
Docker installed and configured for GPU access:
docker run --gpus all nvidia/cuda:12.9-devel nvidia-smi -
Git installed:
git --version -
Python environment with pip:
python --version && pip --version -
Sufficient storage space (>50GB for models and checkpoints):
df -h -
Internet connection for downloading models from Hugging Face Hub
Ancillary files
-
Official LLaMA Factory repository: https://github.com/hiyouga/LLaMA-Factory
-
NVIDIA PyTorch container: https://catalog.ngc.nvidia.com/orgs/nvidia/containers/pytorch
-
Example training configuration:
examples/train_lora/llama3_lora_sft.yaml(from repository) -
Documentation: https://llamafactory.readthedocs.io/en/latest/getting_started/data_preparation.html
Time & risk
Duration: 30-60 minutes for initial setup, 1-7 hours for training depending on model size and dataset.
Risks: Model downloads require significant bandwidth and storage. Training may consume substantial GPU memory and require parameter tuning for hardware constraints.
Rollback: Remove Docker containers and cloned repositories. Training checkpoints are saved locally and can be deleted to reclaim storage space.
Instructions
Step 1. Verify system prerequisites
Check that your NVIDIA Spark system has the required components installed and accessible.
nvcc --version
docker --version
nvidia-smi
python --version
git --version
Step 2. Launch PyTorch container with GPU support
Start the NVIDIA PyTorch container with GPU access and mount your workspace directory.
Note: This NVIDIA PyTorch container supports CUDA 13
docker run --gpus all --ipc=host --ulimit memlock=-1 -it --ulimit stack=67108864 --rm -v "$PWD":/workspace nvcr.io/nvidia/pytorch:25.09-py3 bash
Step 3. Clone LLaMA Factory repository
Download the LLaMA Factory source code from the official repository.
git clone --depth 1 https://github.com/hiyouga/LLaMA-Factory.git
cd LLaMA-Factory
Step 4. Install LLaMA Factory with dependencies
Install the package in editable mode with metrics support for training evaluation.
pip install -e ".[metrics]"
Step 5. Verify Pytorch CUDA support.
PyTorch is pre-installed with CUDA support. To verify installation:
python -c "import torch; print(f'PyTorch: {torch.__version__}, CUDA: {torch.cuda.is_available()}')"
Step 6. Prepare training configuration
Examine the provided LoRA fine-tuning configuration for Llama-3.
cat examples/train_lora/llama3_lora_sft.yaml
Step 7. Launch fine-tuning training
Note: Login to your hugging face hub to download the model if the model is gated. Execute the training process using the pre-configured LoRA setup.
huggingface-cli login # if the model is gated
llamafactory-cli train examples/train_lora/llama3_lora_sft.yaml
Example output:
***** train metrics *****
epoch = 3.0
total_flos = 22851591GF
train_loss = 0.9113
train_runtime = 0:22:21.99
train_samples_per_second = 2.437
train_steps_per_second = 0.306
Figure saved at: saves/llama3-8b/lora/sft/training_loss.png
Step 8. Validate training completion
Verify that training completed successfully and checkpoints were saved.
ls -la saves/llama3-8b/lora/sft/
Expected output should show:
- Final checkpoint directory (
checkpoint-21or similar) - Model configuration files (
config.json,adapter_config.json) - Training metrics showing decreasing loss values
- Training loss plot saved as PNG file
Step 9. Test inference with fine-tuned model
Test your fine-tuned model with custom prompts:
llamafactory-cli chat examples/inference/llama3_lora_sft.yaml
## Type: "Hello, how can you help me today?"
## Expect: Response showing fine-tuned behavior
Step 10. For production deployment, export your model
llamafactory-cli export examples/merge_lora/llama3_lora_sft.yaml
Step 11. Troubleshooting
| Symptom | Cause | Fix |
|---|---|---|
| CUDA out of memory during training | Batch size too large for GPU VRAM | Reduce per_device_train_batch_size or increase gradient_accumulation_steps |
| Model download fails or is slow | Network connectivity or Hugging Face Hub issues | Check internet connection, try using HF_HUB_OFFLINE=1 for cached models |
| Training loss not decreasing | Learning rate too high/low or insufficient data | Adjust learning_rate parameter or check dataset quality |
Step 12. Cleanup and rollback
Warning: This will delete all training progress and checkpoints.
To remove all generated files and free up storage space:
cd /workspace
rm -rf LLaMA-Factory/
docker system prune -f
To rollback Docker container changes:
exit # Exit container
docker container prune -f