torchtitan is under extensive development. To use the latest features of torchtitan, we recommend using the most recent PyTorch nightly.
torchtitan for AMD GPUs.torchtitan v0.2.0.torchtitan! See the tutorial here.torchtitan.torchtitan is a PyTorch native platform designed for rapid experimentation and large-scale training of generative AI models. As a minimal clean-room implementation of PyTorch native scaling techniques, torchtitan provides a flexible foundation for developers to build upon. With torchtitan extension points, one can easily create custom extensions tailored to specific needs.
Our mission is to accelerate innovation in the field of generative AI by empowering researchers and developers to explore new modeling architectures and infrastructure techniques.
The Guiding Principles when building torchtitan
* Designed to be easy to understand, use and extend for different training purposes.
* Minimal changes to the model code when applying multi-dimensional parallelism.
* Bias towards a clean, minimal codebase while providing basic reusable / swappable components.
torchtitan has been showcasing PyTorch's latest distributed training features, via support for pretraining Llama 3.1 LLMs of various sizes.
We look forward to your contributions!
experiments folder. New ideas should start there. To contribute, follow the experiments guidelines.guidelines.torchtune for fine-tuningtorch.compile support--training.global_batch_size argument in configurationWe report performance on up to 512 GPUs, and verify loss converging correctness of various techniques.
You may want to see how the model is defined or how parallelism techniques are applied. For a guided tour, see these files first:
* torchtitan/train.py - the main training loop and high-level setup code
* torchtitan/models/llama3/model/model.py - the Llama 3.1 model definition
* torchtitan/models/llama3/infra/parallelize.py - helpers for applying Data Parallel, Tensor Parallel, activation checkpointing, and torch.compile to the model
* torchtitan/models/llama3/infra/pipeline.py - helpers for applying Pipeline Parallel to the model
* torchtitan/components/checkpoint.py - utils for saving/loading distributed checkpoints
* torchtitan/components/quantization/float8.py - utils for applying Float8 techniques
One can directly run the source code, or install torchtitan from a nightly build, or a stable release.
This method requires the nightly build of PyTorch, or the latest PyTorch built from source.
git clone https://github.com/pytorch/torchtitan
cd torchtitan
pip install -r requirements.txt
This method requires the nightly build of PyTorch. You can replace cu126 with another version of cuda (e.g. cu128) or an AMD GPU (e.g. rocm6.3).
pip3 install --pre torch --index-url https://download.pytorch.org/whl/nightly/cu126 --force-reinstall
pip install --pre torchtitan --index-url https://download.pytorch.org/whl/nightly/cu126
One can install the latest stable release of torchtitan via pip or conda.
pip install torchtitan
conda install conda-forge::torchtitan
Note that each stable release pins the nightly versions of torch and torchao. Please see release.md for more details.
torchtitan currently supports training Llama 3.1 (8B, 70B, 405B) out of the box. To get started training these models, we need to download the tokenizer. Follow the instructions on the official meta-llama repository to ensure you have access to the Llama model weights.
Once you have confirmed access, you can run the following command to download the Llama 3.1 tokenizer to your local machine.
# Get your HF token from https://huggingface.co/settings/tokens
# Llama 3.1 tokenizer
python scripts/download_hf_assets.py --repo_id meta-llama/Llama-3.1-8B --assets tokenizer --hf_token=...
Llama 3 8B model locally on 8 GPUs
CONFIG_FILE="./torchtitan/models/llama3/train_configs/llama3_8b.toml" ./run_train.sh
For training on ParallelCluster/Slurm type configurations, you can use the multinode_trainer.slurm file to submit your sbatch job.
To get started adjust the number of nodes and GPUs
#SBATCH --ntasks=2
#SBATCH --nodes=2
Then start a run where nnodes is your total node count, matching the sbatch node count above.
srun torchrun --nnodes 2
If your gpu count per node is not 8, adjust --nproc_per_node in the torchrun command and #SBATCH --gpus-per-task in the SBATCH command section.
We provide a detailed look into the parallelisms and optimizations available in torchtitan, along with summary advice on when to use various techniques.
TorchTitan: One-stop PyTorch native solution for production ready LLM pre-training
@inproceedings{
liang2025torchtitan,
title={TorchTitan: One-stop PyTorch native solution for production ready {LLM} pretraining},
author={Wanchao Liang and Tianyu Liu and Less Wright and Will Constable and Andrew Gu and Chien-Chin Huang and Iris Zhang and Wei Feng and Howard Huang and Junjie Wang and Sanket Purandare and Gokul Nadathur and Stratos Idreos},
booktitle={The Thirteenth International Conference on Learning Representations},
year={2025},
url={https://openreview.net/forum?id=SFN6Wm7YBI}
}
Source code is made available under a BSD 3 license, however you may have other legal obligations that govern your use of other content linked in this repository, such as the license or terms of service for third-party data and models.
$ claude mcp add torchtitan \
-- python -m otcore.mcp_server <graph>