Steven Palma 9ce6633518 fix(groot): address review findings for the N1.7 port
N1.5 removal is now explicit and actionable:
- Legacy N1.5 checkpoint configs (tokenizer_assets_repo) parse and fail
  with a single clear error pointing to lerobot==0.5.1 instead of a
  cryptic draccus DecodingError
- Removed N1.5 processor registry names (groot_pack_inputs_v3,
  groot_eagle_encode_v3, groot_eagle_collate_v3) are stubbed to raise the
  same guidance; groot_action_unpack_unnormalize_v1 changed semantics, so
  the step is re-registered as _v2 and _v1 is stubbed
- N1.5 detection also recognizes checkpoint config.json content
  (model_type/architectures/eagle backbone), not just path names; every
  rejection surface includes the migration guidance
- groot.mdx documents the breaking change and migration path

Runtime fixes:
- use_bf16=False no longer crashes (compute_dtype only set when used)
- GrootN17ActionDecodeStep handles the 2-D (B, D) actions delivered by
  sync select_action (relative eef/non-eef decode was broken in
  lerobot-eval/record flows)
- Postprocessor falls back to dataset stats when a raw checkpoint lacks
  the configured embodiment tag instead of silently emitting normalized
  [-1, 1] actions
- Hub-hosted finetuned N1.7 checkpoints load: the processor config is
  resolved via hf_hub_download for non-local paths, with a tolerant
  retry when inspection fails
- Raw-checkpoint processor branch honors caller overrides (device,
  rename_map) instead of dropping them
- Relative-action raw-state cache is per-instance instead of
  process-global (cross-instance contamination)
- Camera/modality-key mismatches warn, including the zero-match
  fallback; checkpoint revision is no longer forwarded into backbone
  loading; deprecated Qwen2VLImageProcessorFast replaced with
  Qwen2VLImageProcessor

Config/UX:
- GrootConfig defaults are the N1.7 values; explicitly passed legacy
  N1.5-era values (chunk_size=50, max_state_dim=64, ...) are remapped
  with a warning instead of silently
- Explicit action_decode_transform='none' wins over the libero_sim
  default (new 'auto' sentinel) and survives save/load round-trips

Tests/CI:
- pytest.importorskip guards so fast_tests tiers pass without
  transformers (was 10 failures, now 0)
- Regression tests for every fix; from_pretrained rejection tests now
  actually exercise from_pretrained
- Parity test reads the artifact seed, fails on shape mismatch instead
  of silently truncating, and a new case runs LeRobot's real Qwen3-VL
  preprocessing on raw observations dumped by the producer
- docs: dead huggingface-cli download replaced with hf download

Co-Authored-By: Claude Fable 5 <noreply@anthropic.com>
2026-06-12 16:51:14 +02:00
2026-04-06 12:23:37 +02:00
2026-02-28 14:41:28 +01:00
2026-06-04 22:14:07 +00:00
2026-01-16 14:38:42 +01:00
2026-06-04 19:22:51 +02:00

LeRobot, Hugging Face Robotics Library

Tests Tests Python versions License Status Version Contributor Covenant Discord

LeRobot aims to provide models, datasets, and tools for real-world robotics in PyTorch. The goal is to lower the barrier to entry so that everyone can contribute to and benefit from shared datasets and pretrained models.

🤗 A hardware-agnostic, Python-native interface that standardizes control across diverse platforms, from low-cost arms (SO-100) to humanoids.

🤗 A standardized, scalable LeRobotDataset format (Parquet + MP4 or images) hosted on the Hugging Face Hub, enabling efficient storage, streaming and visualization of massive robotic datasets.

🤗 State-of-the-art policies that have been shown to transfer to the real-world ready for training and deployment.

🤗 Comprehensive support for the open-source ecosystem to democratize physical AI.

Quick Start

LeRobot can be installed directly from PyPI.

pip install lerobot
lerobot-info

Important

For detailed installation guide, please see the Installation Documentation.

Robots & Control

Reachy 2 Demo

LeRobot provides a unified Robot class interface that decouples control logic from hardware specifics. It supports a wide range of robots and teleoperation devices.

from lerobot.robots.myrobot import MyRobot

# Connect to a robot
robot = MyRobot(config=...)
robot.connect()

# Read observation and send action
obs = robot.get_observation()
action = model.select_action(obs)
robot.send_action(action)

Supported Hardware: SO100, LeKiwi, Koch, HopeJR, OMX, EarthRover, Reachy2, Gamepads, Keyboards, Phones, OpenARM, Unitree G1.

While these devices are natively integrated into the LeRobot codebase, the library is designed to be extensible. You can easily implement the Robot interface to utilize LeRobot's data collection, training, and visualization tools for your own custom robot.

For detailed hardware setup guides, see the Hardware Documentation.

LeRobot Dataset

To solve the data fragmentation problem in robotics, we utilize the LeRobotDataset format.

  • Structure: Synchronized MP4 videos (or images) for vision and Parquet files for state/action data.
  • HF Hub Integration: Explore thousands of robotics datasets on the Hugging Face Hub.
  • Tools: Seamlessly delete episodes, split by indices/fractions, add/remove features, and merge multiple datasets.
from lerobot.datasets.lerobot_dataset import LeRobotDataset

# Load a dataset from the Hub
dataset = LeRobotDataset("lerobot/aloha_mobile_cabinet")

# Access data (automatically handles video decoding)
episode_index=0
print(f"{dataset[episode_index]['action'].shape=}\n")

Learn more about it in the LeRobotDataset Documentation

SoTA Models

LeRobot implements state-of-the-art policies in pure PyTorch, covering Imitation Learning, Reinforcement Learning, and Vision-Language-Action (VLA) models, with more coming soon. It also provides you with the tools to instrument and inspect your training process.

Gr00t Architecture

Training a policy is as simple as running a script configuration:

lerobot-train \
  --policy=act \
  --dataset.repo_id=lerobot/aloha_mobile_cabinet
Category Models
Imitation Learning ACT, Diffusion, VQ-BeT, Multitask DiT Policy
Reinforcement Learning HIL-SERL, TDMPC & QC-FQL (coming soon)
VLAs Models Pi0Fast, Pi0.5, GR00T N1.7, SmolVLA, XVLA

Similarly to the hardware, you can easily implement your own policy & leverage LeRobot's data collection, training, and visualization tools, and share your model to the HF Hub

For detailed policy setup guides, see the Policy Documentation. For GPU/RAM requirements and expected training time per policy, see the Compute Hardware Guide.

Inference & Evaluation

Evaluate your policies in simulation or on real hardware using the unified evaluation script. LeRobot supports standard benchmarks like LIBERO, MetaWorld and more to come.

# Evaluate a policy on the LIBERO benchmark
lerobot-eval \
  --policy.path=lerobot/pi0_libero_finetuned \
  --env.type=libero \
  --env.task=libero_object \
  --eval.n_episodes=10

Learn how to implement your own simulation environment or benchmark and distribute it from the HF Hub by following the EnvHub Documentation

Resources

Citation

If you use LeRobot in your project, please cite the GitHub repository to acknowledge the ongoing development and contributors:

@misc{cadene2024lerobot,
    author = {Cadene, Remi and Alibert, Simon and Soare, Alexander and Gallouedec, Quentin and Zouitine, Adil and Palma, Steven and Kooijmans, Pepijn and Aractingi, Michel and Shukor, Mustafa and Aubakirova, Dana and Russi, Martino and Capuano, Francesco and Pascal, Caroline and Choghari, Jade and Moss, Jess and Wolf, Thomas},
    title = {LeRobot: State-of-the-art Machine Learning for Real-World Robotics in Pytorch},
    howpublished = "\url{https://github.com/huggingface/lerobot}",
    year = {2024}
}

If you are referencing our research or the academic paper, please also cite our ICLR publication:

ICLR 2026 Paper
@inproceedings{cadenelerobot,
  title={LeRobot: An Open-Source Library for End-to-End Robot Learning},
  author={Cadene, Remi and Alibert, Simon and Capuano, Francesco and Aractingi, Michel and Zouitine, Adil and Kooijmans, Pepijn and Choghari, Jade and Russi, Martino and Pascal, Caroline and Palma, Steven and Shukor, Mustafa and Moss, Jess and Soare, Alexander and Aubakirova, Dana and Lhoest, Quentin and Gallou\'edec, Quentin and Wolf, Thomas},
  booktitle={The Fourteenth International Conference on Learning Representations},
  year={2026},
  url={https://arxiv.org/abs/2602.22818}
}

Contribute

We welcome contributions from everyone in the community! To get started, please read our CONTRIBUTING.md guide. Whether you're adding a new feature, improving documentation, or fixing a bug, your help and feedback are invaluable. We're incredibly excited about the future of open-source robotics and can't wait to work with you on what's next—thank you for your support!

SO101 Video

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