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admin/lerobot:main admin/lerobot:feat/vla-jepa admin/lerobot:user/khalil-meftah/2026-02-16-rl-stack-refactor admin/lerobot:feat/clean-can-bus admin/lerobot:auto/update-uv-lock admin/lerobot:feat/episodes-filtering admin/lerobot:pr/3545 admin/lerobot:feat/language-annotation-pipeline admin/lerobot:feat/language-columns admin/lerobot:fix/vlabench-ci-faster admin/lerobot:feat/codec-parameters admin/lerobot:chore/colored-cli admin/lerobot:feat/smolvla-on-steerable admin/lerobot:feat/audio_dataset admin/lerobot:feat/leader_activate_teleop admin/lerobot:feat/leader-arm-intervention-pr2596 admin/lerobot:feat/rl-leader-arm-intervention admin/lerobot:test/rl-processor admin/lerobot:codex/fix-rollout-relative-actions admin/lerobot:codex/rollout-relative-action-fixes admin/lerobot:codex/model-profiling admin/lerobot:feat/lerobot-rollout-fix admin/lerobot:codex/robotwin-curobo-fix admin/lerobot:feat/decouple_record_script admin/lerobot:feat/libero-benchmark admin/lerobot:docs/feetech-wrist admin/lerobot:feat/benchmark-ci-clean admin/lerobot:dependabot/uv/uv-de6dee5cc7 admin/lerobot:feat/minimal_default_install admin/lerobot:fix/loading-errors admin/lerobot:test/my_little_pr admin/lerobot:security-fix/-github-workflows-claude-yml-1775744456 admin/lerobot:feat/health-dashboard admin/lerobot:fix/claude-code-action-precommit admin/lerobot:add-claude-github-actions-1775661722130 admin/lerobot:fix/images-transforms admin/lerobot:feat/eval-parallel admin/lerobot:fix/ci_token admin/lerobot:fix/re-enable-sac-normalization admin/lerobot:feat/eval-thread-safe-policy admin/lerobot:feat/umi admin/lerobot:feat/relative_umi admin/lerobot:feat/add-auto-subtask-annotation admin/lerobot:feat/unitree_g1_sonic admin/lerobot:feat/robomme-integration admin/lerobot:feat/dataset-visualization-tools admin/lerobot:feat/RL-token admin/lerobot:chore/dataset_error_handling admin/lerobot:lerobot_ui admin/lerobot:feat/multi-dataset admin/lerobot:feat/libero-plus-integration admin/lerobot:fix/dataset-conversion admin/lerobot:feat/robocasa-benchmark admin/lerobot:chore/fix-datasets admin/lerobot:dependabot/pip/pip-915b9422ef admin/lerobot:pr/2545 admin/lerobot:security-fix/-github-workflows-full_tests-yml-1772811260 admin/lerobot:feat/add-pi05 admin/lerobot:feat/trim-episode-start-main admin/lerobot:feat/trim-episode-start-skip-short admin/lerobot:security-fix/-github-workflows-full_tests-yml-1772788552 admin/lerobot:test/nightly-2 admin/lerobot:test/nightly-fix admin/lerobot:security-fix/-github-workflows-nightly-yml-1772713391 admin/lerobot:fix/pandas-parquet-dataset-v30 admin/lerobot:security-fix/-github-workflows-full_tests-yml-1772699180 admin/lerobot:feat/robot-teleop-pipeline admin/lerobot:feat/dynamixel-protocol-1 admin/lerobot:user/khalil-meftah/root-v1-native admin/lerobot:user/khalil-meftah/root-v2-native admin/lerobot:pr-2996 admin/lerobot:feat/slurm-mirror-dataset-script admin/lerobot:fix-missing-teleop-imports admin/lerobot:feat/improve_serial_exo admin/lerobot:user/khalil-meftah/pr/2822 admin/lerobot:fix/ci-tv5 admin/lerobot:feat/trim_episodes admin/lerobot:envs/support-more-args admin/lerobot:openarms_wallx_rebased_3 admin/lerobot:feat/mirror admin/lerobot:exp/wave-token admin/lerobot:pr-2888 admin/lerobot:tmp/fold_training admin/lerobot:feat/dart admin/lerobot:feat/training_time_rtc admin/lerobot:exp/videovla_additions admin/lerobot:refactor/lerobot_train_rabc admin/lerobot:exp/video-encoder admin/lerobot:feat/anyskin-sensors admin/lerobot:fix/force_cpu_nit admin/lerobot:openarms_wallx_rebased_2 admin/lerobot:feat/inter admin/lerobot:feat/try_interpolation admin/lerobot:feat/openarm_relative_ee admin/lerobot:feat/pifast admin/lerobot:feat/pi0fast admin/lerobot:pr-1411 admin/lerobot:peft-precommit-fixes admin/lerobot:feat/add-hirobot admin/lerobot:openarms_wallx_rebased admin/lerobot:openarms_tmp_rebase admin/lerobot:refactor/replay-buffer-gymnasium-terminology admin/lerobot:feat/add_record admin/lerobot:feat/test_hi admin/lerobot:feat/optimizer_fusion admin/lerobot:feat/bilateral_teleop admin/lerobot:jade/slurm-job admin/lerobot:feat/compare_state_action admin/lerobot:feat/unitree_g1_threading_fix admin/lerobot:feat/behavior-1k admin/lerobot:feat/convert_egodex admin/lerobot:feat/unitree_g1 admin/lerobot:fix/add-xvla-ci-main admin/lerobot:feat/sarm_uniform-sampling admin/lerobot:fix/unitree_g1_robot_linter admin/lerobot:feat/add_openarm admin/lerobot:feat/fracapuano-behavior-1k admin/lerobot:convert-hdf5 admin/lerobot:feat/rtc-docs admin/lerobot:feat/dummy admin/lerobot:fix/libero-reset admin/lerobot:feat/fracapuano-distributed-dataset-merging admin/lerobot:feat/add_dsrl admin/lerobot:fix/conversion_script_images admin/lerobot:fix/dataset_training_performance admin/lerobot:feat/multi-process-cameras admin/lerobot:feat/custom_teleop admin/lerobot:tmp/add_openarm admin/lerobot:tmp/wip_dsrl admin/lerobot:docs/add-env-api admin/lerobot:feat/accelerate-melt-gpus admin/lerobot:feat/add_macos_ci admin/lerobot:fix/keyboard_ee_teleop admin/lerobot:revert/raise_empty_feature_processor_normalize admin/lerobot:patch/fracapuano-improve-reward-classifier admin/lerobot:feat/add-memory-benchmark-pipeline admin/lerobot:feat/add_pi_pipeline_accell admin/lerobot:feat/add-memory-benchmark admin/lerobot:feat/add-multidataset-training admin/lerobot:feat/profile-streaming admin/lerobot:feat/add-sim-libero-pipeline admin/lerobot:smolvla-dev admin/lerobot:feat/validate_pi_libero admin/lerobot:fix/aloha admin/lerobot:user/CarolinePascal/2025_09_12_update_video_benchmark admin/lerobot:fracapuano/12_09_25-update-dataset-docs admin/lerobot:fix/pi0 admin/lerobot:chore/improve_tests_processor admin/lerobot:feat/add_processor_to_eval admin/lerobot:feat/convert_rlds admin/lerobot:user/michel-aractingi/2025-9-4-fix-reachy2-tests admin/lerobot:ci/convert_pipeline_1869 admin/lerobot:ci/convert_pipeline_1862 admin/lerobot:user/michel-aractingi/2025-9-4-downgrade-grpc-version admin/lerobot:accelerate-multi-gpu-support admin/lerobot:ci/convert_pipeline_1841 admin/lerobot:mypy_support admin/lerobot:feature/general_r_learning admin/lerobot:mrussi/glove_visualizer admin/lerobot:user/michel-aractingi/2025-8-13-dataset_tools admin/lerobot:user/michel-aractingi/2025-8-12-so101_leader_follower admin/lerobot:feat/accelerate-support admin/lerobot:backup/user/michel-aractingi/2025-08-01-gym-pipeline admin/lerobot:user/azouitine/fix-dtype-normalization admin/lerobot:user/fracapuano/2025_07_28_fix_test_datasets admin/lerobot:feat/add-biteleop-so101 admin/lerobot:user/michel-aractingi/defualt_viz_v2.1 admin/lerobot:pr-1484 admin/lerobot:user/fracapuano/2025_07_10_inf_endpoints admin/lerobot:danaaubakirova/25_06_2025 admin/lerobot:user/michel-aractingi/dataset_v3_backup admin/lerobot:merge_main_hopejr admin/lerobot:user/fracapuano/2025_06_19_droid_v3 admin/lerobot:user/fracapuano/2025_06_14_chunk_difference_regularize admin/lerobot:user/michel/datasetv3_remi_backup admin/lerobot:user/azouitine/2025-06-05-hil-normalization-check admin/lerobot:user/michel-aractingi/2025-06-02-docs-for-hil-serl admin/lerobot:origin/fix/record_policy_action_dict admin/lerobot:last-port-hil-backup admin/lerobot:test/robot_refactor_experiments admin/lerobot:user/aliberts/2025_04_19_refactor_cameras admin/lerobot:user/pepijn/2025_05_05_lekiwi_dual_teleop admin/lerobot:user/michel-aractingi/tmp-hil-serl-rebase admin/lerobot:user/michel-aractingi/tmp-port-hil-serl-new admin/lerobot:user/mrussi/2025_01_09_hope_junior admin/lerobot:2025_04_11_vla_eval admin/lerobot:user/mrussi/2025_04_12_hopejr admin/lerobot:user/azouitine/2025-4-8-softmax-grasp-critic admin/lerobot:user/michel_aractingi/2024-04-04-grasp-critic admin/lerobot:feat/add_rerun admin/lerobot:user/michel_adil/dump_hil_serl admin/lerobot:user/pepijn/2025_03_18_fix_rotation_so100_docs admin/lerobot:user/pepijn/2025_03_11_weighted_sampling admin/lerobot:torchcodec-cpu admin/lerobot:user/pepijn/2025_03_11_focal_loss admin/lerobot:feat/autopolicy admin/lerobot:user/mshukor/2025_02_25_accelerate admin/lerobot:user/michel-aractingi/2024-02-21-hilserl-threading-to-mp admin/lerobot:user/michel-aractingi/2024-02-18-hilserl-cache-embedding admin/lerobot:user/michel-aractingi/2025-01-21-server-client-arch admin/lerobot:user/michel-aractingi/2025-01-18-port-rlds-example
admin/lerobot:v0.5.1 admin/lerobot:v0.5.0 admin/lerobot:v0.4.4 admin/lerobot:v0.4.3 admin/lerobot:v0.4.2 admin/lerobot:v0.4.1 admin/lerobot:v0.4.0 admin/lerobot:v0.3.3 admin/lerobot:v0.3.2
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compare: admin/lerobot:feat/unitree_g1_threading_fix
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admin/lerobot:feat/vla-jepa admin/lerobot:main admin/lerobot:user/khalil-meftah/2026-02-16-rl-stack-refactor admin/lerobot:feat/clean-can-bus admin/lerobot:auto/update-uv-lock admin/lerobot:feat/episodes-filtering admin/lerobot:pr/3545 admin/lerobot:feat/language-annotation-pipeline admin/lerobot:feat/language-columns admin/lerobot:fix/vlabench-ci-faster admin/lerobot:feat/codec-parameters admin/lerobot:chore/colored-cli admin/lerobot:feat/smolvla-on-steerable admin/lerobot:feat/audio_dataset admin/lerobot:feat/leader_activate_teleop admin/lerobot:feat/leader-arm-intervention-pr2596 admin/lerobot:feat/rl-leader-arm-intervention admin/lerobot:test/rl-processor admin/lerobot:codex/fix-rollout-relative-actions admin/lerobot:codex/rollout-relative-action-fixes admin/lerobot:codex/model-profiling admin/lerobot:feat/lerobot-rollout-fix admin/lerobot:codex/robotwin-curobo-fix admin/lerobot:feat/decouple_record_script admin/lerobot:feat/libero-benchmark admin/lerobot:docs/feetech-wrist admin/lerobot:feat/benchmark-ci-clean admin/lerobot:dependabot/uv/uv-de6dee5cc7 admin/lerobot:feat/minimal_default_install admin/lerobot:fix/loading-errors admin/lerobot:test/my_little_pr admin/lerobot:security-fix/-github-workflows-claude-yml-1775744456 admin/lerobot:feat/health-dashboard admin/lerobot:fix/claude-code-action-precommit admin/lerobot:add-claude-github-actions-1775661722130 admin/lerobot:fix/images-transforms admin/lerobot:feat/eval-parallel admin/lerobot:fix/ci_token admin/lerobot:fix/re-enable-sac-normalization admin/lerobot:feat/eval-thread-safe-policy admin/lerobot:feat/umi admin/lerobot:feat/relative_umi admin/lerobot:feat/add-auto-subtask-annotation admin/lerobot:feat/unitree_g1_sonic admin/lerobot:feat/robomme-integration admin/lerobot:feat/dataset-visualization-tools admin/lerobot:feat/RL-token admin/lerobot:chore/dataset_error_handling admin/lerobot:lerobot_ui admin/lerobot:feat/multi-dataset admin/lerobot:feat/libero-plus-integration admin/lerobot:fix/dataset-conversion admin/lerobot:feat/robocasa-benchmark admin/lerobot:chore/fix-datasets admin/lerobot:dependabot/pip/pip-915b9422ef admin/lerobot:pr/2545 admin/lerobot:security-fix/-github-workflows-full_tests-yml-1772811260 admin/lerobot:feat/add-pi05 admin/lerobot:feat/trim-episode-start-main admin/lerobot:feat/trim-episode-start-skip-short admin/lerobot:security-fix/-github-workflows-full_tests-yml-1772788552 admin/lerobot:test/nightly-2 admin/lerobot:test/nightly-fix admin/lerobot:security-fix/-github-workflows-nightly-yml-1772713391 admin/lerobot:fix/pandas-parquet-dataset-v30 admin/lerobot:security-fix/-github-workflows-full_tests-yml-1772699180 admin/lerobot:feat/robot-teleop-pipeline admin/lerobot:feat/dynamixel-protocol-1 admin/lerobot:user/khalil-meftah/root-v1-native admin/lerobot:user/khalil-meftah/root-v2-native admin/lerobot:pr-2996 admin/lerobot:feat/slurm-mirror-dataset-script admin/lerobot:fix-missing-teleop-imports admin/lerobot:feat/improve_serial_exo admin/lerobot:user/khalil-meftah/pr/2822 admin/lerobot:fix/ci-tv5 admin/lerobot:feat/trim_episodes admin/lerobot:envs/support-more-args admin/lerobot:openarms_wallx_rebased_3 admin/lerobot:feat/mirror admin/lerobot:exp/wave-token admin/lerobot:pr-2888 admin/lerobot:tmp/fold_training admin/lerobot:feat/dart admin/lerobot:feat/training_time_rtc admin/lerobot:exp/videovla_additions admin/lerobot:refactor/lerobot_train_rabc admin/lerobot:exp/video-encoder admin/lerobot:feat/anyskin-sensors admin/lerobot:fix/force_cpu_nit admin/lerobot:openarms_wallx_rebased_2 admin/lerobot:feat/inter admin/lerobot:feat/try_interpolation admin/lerobot:feat/openarm_relative_ee admin/lerobot:feat/pifast admin/lerobot:feat/pi0fast admin/lerobot:pr-1411 admin/lerobot:peft-precommit-fixes admin/lerobot:feat/add-hirobot admin/lerobot:openarms_wallx_rebased admin/lerobot:openarms_tmp_rebase admin/lerobot:refactor/replay-buffer-gymnasium-terminology admin/lerobot:feat/add_record admin/lerobot:feat/test_hi admin/lerobot:feat/optimizer_fusion admin/lerobot:feat/bilateral_teleop admin/lerobot:jade/slurm-job admin/lerobot:feat/compare_state_action admin/lerobot:feat/unitree_g1_threading_fix admin/lerobot:feat/behavior-1k admin/lerobot:feat/convert_egodex admin/lerobot:feat/unitree_g1 admin/lerobot:fix/add-xvla-ci-main admin/lerobot:feat/sarm_uniform-sampling admin/lerobot:fix/unitree_g1_robot_linter admin/lerobot:feat/add_openarm admin/lerobot:feat/fracapuano-behavior-1k admin/lerobot:convert-hdf5 admin/lerobot:feat/rtc-docs admin/lerobot:feat/dummy admin/lerobot:fix/libero-reset admin/lerobot:feat/fracapuano-distributed-dataset-merging admin/lerobot:feat/add_dsrl admin/lerobot:fix/conversion_script_images admin/lerobot:fix/dataset_training_performance admin/lerobot:feat/multi-process-cameras admin/lerobot:feat/custom_teleop admin/lerobot:tmp/add_openarm admin/lerobot:tmp/wip_dsrl admin/lerobot:docs/add-env-api admin/lerobot:feat/accelerate-melt-gpus admin/lerobot:feat/add_macos_ci admin/lerobot:fix/keyboard_ee_teleop admin/lerobot:revert/raise_empty_feature_processor_normalize admin/lerobot:patch/fracapuano-improve-reward-classifier admin/lerobot:feat/add-memory-benchmark-pipeline admin/lerobot:feat/add_pi_pipeline_accell admin/lerobot:feat/add-memory-benchmark admin/lerobot:feat/add-multidataset-training admin/lerobot:feat/profile-streaming admin/lerobot:feat/add-sim-libero-pipeline admin/lerobot:smolvla-dev admin/lerobot:feat/validate_pi_libero admin/lerobot:fix/aloha admin/lerobot:user/CarolinePascal/2025_09_12_update_video_benchmark admin/lerobot:fracapuano/12_09_25-update-dataset-docs admin/lerobot:fix/pi0 admin/lerobot:chore/improve_tests_processor admin/lerobot:feat/add_processor_to_eval admin/lerobot:feat/convert_rlds admin/lerobot:user/michel-aractingi/2025-9-4-fix-reachy2-tests admin/lerobot:ci/convert_pipeline_1869 admin/lerobot:ci/convert_pipeline_1862 admin/lerobot:user/michel-aractingi/2025-9-4-downgrade-grpc-version admin/lerobot:accelerate-multi-gpu-support admin/lerobot:ci/convert_pipeline_1841 admin/lerobot:mypy_support admin/lerobot:feature/general_r_learning admin/lerobot:mrussi/glove_visualizer admin/lerobot:user/michel-aractingi/2025-8-13-dataset_tools admin/lerobot:user/michel-aractingi/2025-8-12-so101_leader_follower admin/lerobot:feat/accelerate-support admin/lerobot:backup/user/michel-aractingi/2025-08-01-gym-pipeline admin/lerobot:user/azouitine/fix-dtype-normalization admin/lerobot:user/fracapuano/2025_07_28_fix_test_datasets admin/lerobot:feat/add-biteleop-so101 admin/lerobot:user/michel-aractingi/defualt_viz_v2.1 admin/lerobot:pr-1484 admin/lerobot:user/fracapuano/2025_07_10_inf_endpoints admin/lerobot:danaaubakirova/25_06_2025 admin/lerobot:user/michel-aractingi/dataset_v3_backup admin/lerobot:merge_main_hopejr admin/lerobot:user/fracapuano/2025_06_19_droid_v3 admin/lerobot:user/fracapuano/2025_06_14_chunk_difference_regularize admin/lerobot:user/michel/datasetv3_remi_backup admin/lerobot:user/azouitine/2025-06-05-hil-normalization-check admin/lerobot:user/michel-aractingi/2025-06-02-docs-for-hil-serl admin/lerobot:origin/fix/record_policy_action_dict admin/lerobot:last-port-hil-backup admin/lerobot:test/robot_refactor_experiments admin/lerobot:user/aliberts/2025_04_19_refactor_cameras admin/lerobot:user/pepijn/2025_05_05_lekiwi_dual_teleop admin/lerobot:user/michel-aractingi/tmp-hil-serl-rebase admin/lerobot:user/michel-aractingi/tmp-port-hil-serl-new admin/lerobot:user/mrussi/2025_01_09_hope_junior admin/lerobot:2025_04_11_vla_eval admin/lerobot:user/mrussi/2025_04_12_hopejr admin/lerobot:user/azouitine/2025-4-8-softmax-grasp-critic admin/lerobot:user/michel_aractingi/2024-04-04-grasp-critic admin/lerobot:feat/add_rerun admin/lerobot:user/michel_adil/dump_hil_serl admin/lerobot:user/pepijn/2025_03_18_fix_rotation_so100_docs admin/lerobot:user/pepijn/2025_03_11_weighted_sampling admin/lerobot:torchcodec-cpu admin/lerobot:user/pepijn/2025_03_11_focal_loss admin/lerobot:feat/autopolicy admin/lerobot:user/mshukor/2025_02_25_accelerate admin/lerobot:user/michel-aractingi/2024-02-21-hilserl-threading-to-mp admin/lerobot:user/michel-aractingi/2024-02-18-hilserl-cache-embedding admin/lerobot:user/michel-aractingi/2025-01-21-server-client-arch admin/lerobot:user/michel-aractingi/2025-01-18-port-rlds-example
admin/lerobot:v0.5.1 admin/lerobot:v0.5.0 admin/lerobot:v0.4.4 admin/lerobot:v0.4.3 admin/lerobot:v0.4.2 admin/lerobot:v0.4.1 admin/lerobot:v0.4.0 admin/lerobot:v0.3.3 admin/lerobot:v0.3.2

5 Commits
v0.5.0 .. feat/unitree_g1_threading_fix

Author SHA1 Message Date
Martino Russi 393f01d445 edit holosoma 2025-12-08 11:04:17 +01:00
Martino Russi 0ed97de369 add policy from local path 2025-12-04 15:46:21 +01:00
Martino Russi 033cfb3d0b add amazon/unitree locomotion policies 2025-12-03 17:02:18 +01:00
Martino Russi c56f52f334 join subscribe thread after disconnecting robot 2025-12-02 16:36:33 +01:00
Martino Russi 289b7d50da use main thread to run cmd_forward_loop, close threads upon shutdown_event 2025-12-02 16:33:28 +01:00
394 changed files with 6125 additions and 45788 deletions
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@@ -12,83 +12,57 @@
# See the License for the specific language governing permissions and
# limitations under the License.
name: "🚀 Issue / Bug / Request"
description: Report a bug, suggest an improvement, or ask a technical question.
name: "\U0001F41B Bug Report"
description: Submit a bug report to help us improve LeRobot
body:
- type: markdown
attributes:
value: |
### Thanks for contributing to LeRobot! 🙌
Please choose the most relevant sections below. If this is a general "how-to" question, consider our [Discord](https://discord.gg/s3KuuzsPFb) for faster community support.
- type: dropdown
id: issue-type
attributes:
label: Ticket Type
description: What kind of ticket are you opening?
options:
- "🐛 Bug Report (Something isn't working)"
- "💡 Feature Request / Improvement"
- "❓ Technical Question"
- "🧹 Maintenance / Documentation"
validations:
required: true
Thanks for taking the time to submit a bug report! 🐛
If this is not a bug related to the LeRobot library directly, but instead a general question about your code or the library specifically please use our [discord](https://discord.gg/s3KuuzsPFb).
- type: textarea
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For bugs or technical questions, please run `lerobot-info` and paste the output.
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- type: checkboxes
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- label: "My own task or dataset (give details below)"
- type: textarea
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id: reproduction
validations:
required: true
attributes:
label: Description
label: Reproduction
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Provide a clear summary of the issue or your proposal.
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If needed, provide a simple code sample that reproduces the problem you ran into. It can be a Colab link or just a code snippet.
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- type: checkboxes
id: extras
attributes:
label: Checklist
options:
- label: I have searched existing tickets to ensure this isn't a duplicate.
- label: I am using the latest version of the `main` branch.
- label: I have verified this is not an environment-specific problem.
- type: textarea
id: workaround
attributes:
label: Additional Info / Workarounds
description: Anything else we should know? If you have a workaround, please share it!
label: Expected behavior
description: "A clear and concise description of what you would expect to happen."
.github/PULL_REQUEST_TEMPLATE.md
+27 -41
View File
@@ -1,55 +1,41 @@
## Title
## What this does
Short, imperative summary (e.g., "fix(robots): handle None in sensor parser"). See [CONTRIBUTING.md](../CONTRIBUTING.md) for PR conventions.
Explain what this PR does. Feel free to tag your PR with the appropriate label(s).
## Type / Scope
Examples:
| Title | Label |
|----------------------|-----------------|
| Fixes #[issue] | (🐛 Bug) |
| Adds new dataset | (🗃️ Dataset) |
| Optimizes something | (⚡️ Performance) |
- **Type**: (Bug | Feature | Docs | Performance | Test | CI | Chore)
- **Scope**: (optional — name of module or package affected)
## How it was tested
## Summary / Motivation
Explain/show how you tested your changes.
- One-paragraph description of what changes and why.
- Why this change is needed and any trade-offs or design notes.
Examples:
## Related issues
- Added `test_something` in `tests/test_stuff.py`.
- Added `new_feature` and checked that training converges with policy X on dataset/environment Y.
- Optimized `some_function`, it now runs X times faster than previously.
- Fixes / Closes: # (if any)
- Related: # (if any)
## How to checkout & try? (for the reviewer)
## What changed
Provide a simple way for the reviewer to try out your changes.
- Short, concrete bullets of the modifications (files/behaviour).
- Short note if this introduces breaking changes and migration steps.
Examples:
## How was this tested (or how to run locally)
```bash
pytest -sx tests/test_stuff.py::test_something
```
- Tests added: list new tests or test files.
- Manual checks / dataset runs performed.
- Instructions for the reviewer
```bash
lerobot-train --some.option=true
```
Example:
## SECTION TO REMOVE BEFORE SUBMITTING YOUR PR
- Ran the relevant tests:
**Note**: Anyone in the community is free to review the PR once the tests have passed. Feel free to tag
members/contributors who may be interested in your PR. Try to avoid tagging more than 3 people.
```bash
pytest -q tests/ -k <keyword>
```
- Reproduce with a quick example or CLI (if applicable):
```bash
lerobot-train --some.option=true
```
## Checklist (required before merge)
- [ ] Linting/formatting run (`pre-commit run -a`)
- [ ] All tests pass locally (`pytest`)
- [ ] Documentation updated
- [ ] CI is green
## Reviewer notes
- Anything the reviewer should focus on (performance, edge-cases, specific files) or general notes.
- Anyone in the community is free to review the PR.
**Note**: Before submitting this PR, please read the [contributor guideline](https://github.com/huggingface/lerobot/blob/main/CONTRIBUTING.md#submitting-a-pull-request-pr).
.github/labeler.yml
-69
View File
@@ -1,69 +0,0 @@
# Copyright 2025 The HuggingFace Inc. team. All rights reserved.
#
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
#
# http://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.
CI:
- changed-files:
- any-glob-to-any-file:
- '.github/**'
- 'docker/**'
github_actions:
- changed-files:
- any-glob-to-any-file: '.github/**'
documentation:
- changed-files:
- any-glob-to-any-file:
- '**/*.md'
- '**/*.mdx'
- 'docs/**'
examples:
- changed-files:
- any-glob-to-any-file: 'examples/**'
tests:
- changed-files:
- any-glob-to-any-file: 'tests/**'
sensors:
- changed-files:
- any-glob-to-any-file: 'src/lerobot/cameras/**'
configuration:
- changed-files:
- any-glob-to-any-file: 'src/lerobot/configs/**'
dataset:
- changed-files:
- any-glob-to-any-file: 'src/lerobot/datasets/**'
evaluation:
- changed-files:
- any-glob-to-any-file: 'src/lerobot/envs/**'
robots:
- changed-files:
- any-glob-to-any-file:
- 'src/lerobot/teleoperators/**'
- 'src/lerobot/robots/**'
- 'src/lerobot/motors/**'
policies:
- changed-files:
- any-glob-to-any-file: 'src/lerobot/policies/**'
processor:
- changed-files:
- any-glob-to-any-file: 'src/lerobot/processor/**'
.github/workflows/documentation-upload-pr.yml
+1 -2
View File
@@ -31,8 +31,7 @@ jobs:
name: Upload Preview and Comment
if: >
github.event.workflow_run.event == 'pull_request' &&
github.event.workflow_run.conclusion == 'success' &&
github.repository == 'huggingface/lerobot'
github.event.workflow_run.conclusion == 'success'
uses: huggingface/doc-builder/.github/workflows/upload_pr_documentation.yml@main
with:
package_name: lerobot
.github/workflows/documentation.yml
+3 -19
View File
@@ -18,11 +18,6 @@ name: Documentation
on:
# Allows running this workflow manually from the Actions tab
workflow_dispatch:
inputs:
version:
description: 'Version tag (e.g. v0.1.2) - Leave empty for standard main build'
required: false
type: string
# Triggers the workflow on push events to main for the docs folder
push:
@@ -38,9 +33,6 @@ on:
paths:
- "docs/**"
release:
types: [published]
# Ensures that only the latest commit for a PR or branch is built, canceling older runs.
concurrency:
group: ${{ github.workflow }}-${{ github.head_ref || github.run_id }}
@@ -50,22 +42,14 @@ jobs:
# This job builds and deploys the official documentation.
build_main_docs:
name: Build Main Docs
if: >
(github.event_name == 'push' || github.event_name == 'workflow_dispatch' || github.event_name == 'release') &&
github.repository == 'huggingface/lerobot'
if: github.event_name == 'push' || github.event_name == 'workflow_dispatch'
permissions:
contents: read
uses: huggingface/doc-builder/.github/workflows/build_main_documentation.yml@main
with:
commit_sha: ${{ github.sha }}
package: lerobot
additional_args: >-
--not_python_module
${{
(github.event_name == 'release' && format('--version {0}', github.event.release.tag_name)) ||
(inputs.version != '' && format('--version {0}', inputs.version)) ||
''
}}
additional_args: --not_python_module
secrets:
token: ${{ secrets.HUGGINGFACE_PUSH }}
hf_token: ${{ secrets.HF_DOC_BUILD_PUSH }}
@@ -74,7 +58,7 @@ jobs:
# The result of this job triggers the 'Upload PR Documentation' workflow.
build_pr_docs:
name: Build PR Docs
if: github.event_name == 'pull_request' && github.repository == 'huggingface/lerobot'
if: github.event_name == 'pull_request'
permissions:
contents: read
pull-requests: write
.github/workflows/fast_tests.yml
+3 -9
View File
@@ -44,7 +44,8 @@ permissions:
# Sets up the environment variables
env:
UV_VERSION: "0.8.0"
PYTHON_VERSION: "3.12"
PYTHON_VERSION: "3.10"
DOCKER_IMAGE_NAME: huggingface/lerobot-gpu
# Ensures that only the latest commit for a PR or branch is built, canceling older runs.
concurrency:
@@ -61,9 +62,8 @@ jobs:
MUJOCO_GL: egl
HF_HOME: /mnt/cache/.cache/huggingface
HF_LEROBOT_HOME: /mnt/cache/.cache/huggingface/lerobot
HF_USER_TOKEN: ${{ secrets.LEROBOT_HF_USER }}
steps:
- uses: actions/checkout@v6
- uses: actions/checkout@v4
with:
persist-credentials: false
lfs: true
@@ -90,11 +90,5 @@ jobs:
- name: Install lerobot with test extras
run: uv sync --extra "test"
- name: Login to Hugging Face
if: env.HF_USER_TOKEN != ''
run: |
uv run hf auth login --token "$HF_USER_TOKEN" --add-to-git-credential
uv run hf auth whoami
- name: Run pytest
run: uv run pytest tests -vv --maxfail=10
.github/workflows/full_tests.yml
+12 -32
View File
@@ -37,7 +37,7 @@ permissions:
# Sets up the environment variables
env:
UV_VERSION: "0.8.0"
PYTHON_VERSION: "3.12"
PYTHON_VERSION: "3.10"
DOCKER_IMAGE_NAME: huggingface/lerobot-gpu
# Ensures that only the latest action is built, canceling older runs.
@@ -60,9 +60,8 @@ jobs:
MUJOCO_GL: egl
HF_HOME: /mnt/cache/.cache/huggingface
HF_LEROBOT_HOME: /mnt/cache/.cache/huggingface/lerobot
HF_USER_TOKEN: ${{ secrets.LEROBOT_HF_USER }}
steps:
- uses: actions/checkout@v6
- uses: actions/checkout@v4
with:
lfs: true
persist-credentials: false
@@ -86,13 +85,7 @@ jobs:
python-version: ${{ env.PYTHON_VERSION }}
- name: Install lerobot with all extras
run: uv sync --extra all # TODO(Steven): Make flash-attn optional
- name: Login to Hugging Face
if: env.HF_USER_TOKEN != ''
run: |
uv run hf auth login --token "$HF_USER_TOKEN" --add-to-git-credential
uv run hf auth whoami
run: uv sync --all-extras --no-extra groot # TODO(Steven): Make flash-attn optional
- name: Run pytest (all extras)
run: uv run pytest tests -vv --maxfail=10
@@ -108,11 +101,9 @@ jobs:
runs-on:
group: aws-general-8-plus
if: |
github.repository == 'huggingface/lerobot' && (
(github.event_name == 'pull_request_review' && github.event.review.state == 'approved' && github.event.pull_request.head.repo.fork == false) ||
github.event_name == 'push' ||
github.event_name == 'workflow_dispatch'
)
(github.event_name == 'pull_request_review' && github.event.review.state == 'approved' && github.event.pull_request.head.repo.fork == false) ||
github.event_name == 'push' ||
github.event_name == 'workflow_dispatch'
outputs:
image_tag: ${{ steps.set_tag.outputs.image_tag }}
env:
@@ -136,7 +127,7 @@ jobs:
sudo apt-get update
sudo apt-get install git-lfs
git lfs install
- uses: actions/checkout@v6
- uses: actions/checkout@v4
with:
lfs: true
persist-credentials: false
@@ -169,7 +160,6 @@ jobs:
HF_LEROBOT_HOME: /home/user_lerobot/.cache/huggingface/lerobot
TORCH_HOME: /home/user_lerobot/.cache/torch
TRITON_CACHE_DIR: /home/user_lerobot/.cache/triton
HF_USER_TOKEN: ${{ secrets.LEROBOT_HF_USER }}
container:
image: ${{ needs.build-and-push-docker.outputs.image_tag }} # zizmor: ignore[unpinned-images]
options: --gpus all --shm-size "16gb"
@@ -181,13 +171,6 @@ jobs:
shell: bash
working-directory: /lerobot
steps:
- name: Login to Hugging Face
if: env.HF_USER_TOKEN != ''
run: |
hf auth login --token "$HF_USER_TOKEN" --add-to-git-credential
hf auth whoami
- name: Fix ptxas permissions
run: chmod +x /lerobot/.venv/lib/python3.12/site-packages/triton/backends/nvidia/bin/ptxas
- name: Run pytest on GPU
run: pytest tests -vv --maxfail=10
- name: Run end-to-end tests
@@ -203,18 +186,15 @@ jobs:
steps:
- name: Get Docker Hub Token and Delete Image
# zizmor: ignore[template-injection]
env:
DOCKERHUB_LEROBOT_USERNAME: ${{ secrets.DOCKERHUB_LEROBOT_USERNAME }}
DOCKERHUB_LEROBOT_PASSWORD: ${{ secrets.DOCKERHUB_LEROBOT_PASSWORD }}
IMAGE_FULL: ${{ needs.build-and-push-docker.outputs.image_tag }}
run: |
IMAGE_NAME=$(echo "$IMAGE_FULL" | cut -d':' -f1)
IMAGE_TAG=$(echo "$IMAGE_FULL" | cut -d':' -f2-)
IMAGE_NAME=$(echo "${{ needs.build-and-push-docker.outputs.image_tag }}" | cut -d':' -f1)
IMAGE_TAG=$(echo "${{ needs.build-and-push-docker.outputs.image_tag }}" | cut -d':' -f2)
echo "Attempting to delete image: $IMAGE_NAME:$IMAGE_TAG"
TOKEN=$(curl -s -H "Content-Type: application/json" \
-X POST \
-d "{\"username\": \"$DOCKERHUB_LEROBOT_USERNAME\", \"password\": \"$DOCKERHUB_LEROBOT_PASSWORD\"}" \
-d '{"username": "${{ secrets.DOCKERHUB_LEROBOT_USERNAME }}", "password": "${{ secrets.DOCKERHUB_LEROBOT_PASSWORD }}"}' \
https://hub.docker.com/v2/users/login/ | jq -r .token)
if [ "$TOKEN" == "null" ] || [ -z "$TOKEN" ]; then
@@ -225,7 +205,7 @@ jobs:
HTTP_RESPONSE=$(curl -s -o /dev/null -w "%{http_code}" \
-H "Authorization: JWT ${TOKEN}" \
-X DELETE \
https://hub.docker.com/v2/repositories/${IMAGE_NAME}/tags/$IMAGE_TAG)
https://hub.docker.com/v2/repositories/${IMAGE_NAME}/tags/${IMAGE_TAG}/)
if [ "$HTTP_RESPONSE" -eq 204 ]; then
echo "Successfully deleted Docker image tag: $IMAGE_NAME:$IMAGE_TAG"
.github/workflows/issue_labeler.yml
-77
View File
@@ -1,77 +0,0 @@
# Copyright 2025 The HuggingFace Inc. team. All rights reserved.
#
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
#
# http://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.
# This workflow automatically labels issues based on their content.
name: Issue Labeler
on:
# Trigger on new issues and edits to existing issues
issues:
types: [opened, edited]
permissions:
contents: read
issues: write
jobs:
label-issue:
name: Auto Label Issue
runs-on: ubuntu-latest
if: github.repository == 'huggingface/lerobot'
steps:
- uses: actions/github-script@v8
with:
script: |
// Setup Input Text
const body = (context.payload.issue.body || '');
const title = (context.payload.issue.title || '');
const cleanBody = body.replace(/```[\s\S]*?```/g, '');
const text = `${title}\n${cleanBody}`.toLowerCase();
const labelsToAdd = new Set();
const matches = (re) => re.test(text);
// Keyword Heuristics
if (matches(/\b(bug|error|crash|exception)\b/i)) labelsToAdd.add('bug');
if (matches(/\b(new feature|enhancement|improvement|proposal|feature request)\b/i)) labelsToAdd.add('enhancement');
if (matches(/\b(question|how to|clarify|explain|how do i|help me|question about)\b/i)) labelsToAdd.add('question');
if (matches(/\b(documentation|docs?|readme|tutorial|wiki|typo|docstring)\b/i)) labelsToAdd.add('documentation');
if (matches(/\b(example|sample|demo|notebook)s?\b/i)) labelsToAdd.add('examples');
if (matches(/\b(datasets?|data loader|data augmentation|data preprocessing)\b/i)) labelsToAdd.add('dataset');
if (matches(/\b(mujoco|isaac|simulation|sim)\b/i)) labelsToAdd.add('simulation');
if (matches(/\b(train|training|optimizer|gradient|wandb|sac)\b/i)) labelsToAdd.add('training');
if (matches(/\b(rerun|plot|render|rendering|visualizer)/i)) labelsToAdd.add('visualization');
if (matches(/\b(cameras?|opencv|realsense|lidars?|sensors?|imus?|microphones?|rgbd|encoders?)\b/i)) labelsToAdd.add('sensors');
if (matches(/\b(urdf|actuators?|calibration|end-effector|kinematics)\b/i)) labelsToAdd.add('robots');
if (matches(/\b(teleop|teleoperator|controller|leader|follower|joystick|gamepad)\b/i)) labelsToAdd.add('teleoperators');
if (matches(/\b(policy|policies|model?)\b/i)) labelsToAdd.add('policies');
if (matches(/\b(processor|pipeline|preprocessor|postprocessor)s?\b/i)) labelsToAdd.add('processor');
if (matches(/\b(eval|evaluate|evaluation|metrics?|score|benchmarks?)\b/i)) labelsToAdd.add('evaluation');
if (matches(/\b(tests?|pytest|unittest|failing test)\b/i)) labelsToAdd.add('tests');
if (matches(/\b(ci|github actions?|github workflows?|gha|docker|pypi)\b/i)) labelsToAdd.add('CI');
if (matches(/\b(perf|latency|throughput|fps|speed|performance|slow|fast|slower|faster|memory usage)\b/i)) labelsToAdd.add('performance');
if (matches(/\b(dependency|dependencies|pip|install error|importerror|package not found|pyproject)\b/i)) labelsToAdd.add('dependencies');
if (matches(/\b(configuration|config|arguments?|input feature|dracuss)\b/i)) labelsToAdd.add('configuration');
// Apply Labels
const labels = Array.from(labelsToAdd).filter(Boolean);
if (labels.length > 0) {
console.log(`Adding labels: ${labels.join(', ')}`);
await github.rest.issues.addLabels({
owner: context.repo.owner,
repo: context.repo.repo,
issue_number: context.issue.number,
labels,
});
}
.github/workflows/nightly.yml
+6 -24
View File
@@ -28,7 +28,7 @@ on:
# Sets up the environment variables
env:
UV_VERSION: "0.8.0"
PYTHON_VERSION: "3.12"
PYTHON_VERSION: "3.10"
DOCKER_IMAGE_NAME_CPU: huggingface/lerobot-cpu:latest
DOCKER_IMAGE_NAME_GPU: huggingface/lerobot-gpu:latest
@@ -43,7 +43,6 @@ jobs:
name: Build CPU Docker for Nightly
runs-on:
group: aws-general-8-plus
if: github.repository == 'huggingface/lerobot'
outputs:
image_tag: ${{ env.DOCKER_IMAGE_NAME_CPU }}
steps:
@@ -52,7 +51,7 @@ jobs:
sudo apt-get update
sudo apt-get install git-lfs
git lfs install
- uses: actions/checkout@v6
- uses: actions/checkout@v4
with:
lfs: true
persist-credentials: false
@@ -78,7 +77,6 @@ jobs:
name: Build GPU Docker for Nightly
runs-on:
group: aws-general-8-plus
if: github.repository == 'huggingface/lerobot'
outputs:
image_tag: ${{ env.DOCKER_IMAGE_NAME_GPU }}
steps:
@@ -87,7 +85,7 @@ jobs:
sudo apt-get update
sudo apt-get install git-lfs
git lfs install
- uses: actions/checkout@v6
- uses: actions/checkout@v4
with:
lfs: true
persist-credentials: false
@@ -119,7 +117,6 @@ jobs:
HF_LEROBOT_HOME: /home/user_lerobot/.cache/huggingface/lerobot
TORCH_HOME: /home/user_lerobot/.cache/torch
TRITON_CACHE_DIR: /home/user_lerobot/.cache/triton
HF_USER_TOKEN: ${{ secrets.LEROBOT_HF_USER }}
container:
image: ${{ needs.build-docker-cpu-nightly.outputs.image_tag }} # zizmor: ignore[unpinned-images]
options: --shm-size "16gb"
@@ -131,11 +128,6 @@ jobs:
shell: bash
working-directory: /lerobot
steps:
- name: Login to Hugging Face
if: env.HF_USER_TOKEN != ''
run: |
hf auth login --token "$HF_USER_TOKEN" --add-to-git-credential
hf auth whoami
- name: Run pytest on CPU
run: pytest tests -vv --maxfail=10
- name: Run end-to-end tests
@@ -152,7 +144,6 @@ jobs:
HF_LEROBOT_HOME: /home/user_lerobot/.cache/huggingface/lerobot
TORCH_HOME: /home/user_lerobot/.cache/torch
TRITON_CACHE_DIR: /home/user_lerobot/.cache/triton
HF_USER_TOKEN: ${{ secrets.LEROBOT_HF_USER }}
container:
image: ${{ needs.build-docker-gpu-nightly.outputs.image_tag }} # zizmor: ignore[unpinned-images]
options: --gpus all --shm-size "16gb"
@@ -164,11 +155,6 @@ jobs:
shell: bash
working-directory: /lerobot
steps:
- name: Login to Hugging Face
if: env.HF_USER_TOKEN != ''
run: |
hf auth login --token "$HF_USER_TOKEN" --add-to-git-credential
hf auth whoami
- name: Run pytest on GPU
run: pytest tests -vv --maxfail=10
- name: Run end-to-end tests
@@ -186,7 +172,6 @@ jobs:
TORCH_HOME: /home/user_lerobot/.cache/torch
TRITON_CACHE_DIR: /home/user_lerobot/.cache/triton
CUDA_VISIBLE_DEVICES: "0,1,2,3"
HF_USER_TOKEN: ${{ secrets.LEROBOT_HF_USER }}
container:
image: ${{ needs.build-docker-gpu-nightly.outputs.image_tag }} # zizmor: ignore[unpinned-images]
options: --gpus all --shm-size "16gb"
@@ -198,15 +183,12 @@ jobs:
shell: bash
working-directory: /lerobot
steps:
- name: Login to Hugging Face
if: env.HF_USER_TOKEN != ''
run: |
hf auth login --token "$HF_USER_TOKEN" --add-to-git-credential
hf auth whoami
- name: Verify GPU availability
run: |
nvidia-smi
python -c "import torch; print(f'PyTorch CUDA available: {torch.cuda.is_available()}'); print(f'Number of GPUs: {torch.cuda.device_count()}')"
- name: Run multi-GPU training tests
run: pytest -vv tests/training/
# TODO(Steven): Investigate why motors tests are failing in multi-GPU setup
run: pytest tests -vv --maxfail=10 --ignore=tests/motors/
timeout-minutes: 10
.github/workflows/pr_labeler.yml
-39
View File
@@ -1,39 +0,0 @@
# Copyright 2025 The HuggingFace Inc. team. All rights reserved.
#
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
#
# http://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.
# This workflow labels pull requests based on the files that were changed.
name: Pull Request Labeler
on:
# Allows labeling pull requests when they are opened or updated
# zizmor: ignore[dangerous-triggers] Needed to label PRs from forks
pull_request_target:
branches:
- main
types: [opened, synchronize, reopened, ready_for_review]
permissions:
contents: read
pull-requests: write
jobs:
triage:
name: Label PR
runs-on: ubuntu-latest
if: github.repository == 'huggingface/lerobot' && !github.event.pull_request.draft
steps:
- uses: actions/labeler@v6
with:
repo-token: ${{ secrets.GITHUB_TOKEN }}
sync-labels: true # Removes labels if files are removed from the PR
.github/workflows/quality.yml
+3 -3
View File
@@ -43,14 +43,14 @@ jobs:
runs-on: ubuntu-latest
steps:
- name: Checkout code
uses: actions/checkout@v6
uses: actions/checkout@v4
with:
persist-credentials: false
- name: Set up Python
uses: actions/setup-python@v6
uses: actions/setup-python@v5
with:
python-version: '3.12'
python-version: '3.10'
- name: Run pre-commit hooks
uses: pre-commit/action@v3.0.1 # zizmor: ignore[unpinned-uses]
.github/workflows/release.yml
+14 -6
View File
@@ -22,14 +22,13 @@ on:
# Sets up the environment variables
env:
UV_VERSION: "0.8.0"
PYTHON_VERSION: "3.12"
PYTHON_VERSION: "3.10"
jobs:
# This job builds the Python package and publishes it to PyPI
build-and-publish:
name: Build and publish Python distributions
runs-on: ubuntu-latest
if: github.repository == 'huggingface/lerobot'
outputs:
version: ${{ steps.extract_info.outputs.tag_version }}
permissions:
@@ -38,14 +37,14 @@ jobs:
steps:
- name: Checkout code
uses: actions/checkout@v6
uses: actions/checkout@v4
with:
persist-credentials: false
- name: Set up Python
uses: actions/setup-python@v6
uses: actions/setup-python@v5
with:
python-version: '3.12'
python-version: '3.10'
- name: Extract Version
id: extract_info
@@ -83,6 +82,14 @@ jobs:
exit 1
fi
- name: Remove Tags with Git dependencies
# TODO(Steven): Temporary patch to remove pi from PyPi 0.4.0 release due to its reliance on git dependencies.
run: |
echo "::info:: Checking for Git dependencies to remove from pyproject.toml..."
grep -E '@ git\+https|lerobot\[pi\]' pyproject.toml | sed 's/^/::warning:: Removing line: /' || true
sed -E -i '/@ git\+https|lerobot\[pi\]/d' pyproject.toml
echo "::info:: Git dependencies removed. Proceeding with build."
- name: Install build dependencies
run: python -m pip install build
@@ -127,7 +134,7 @@ jobs:
env:
MUJOCO_GL: egl
steps:
- uses: actions/checkout@v6
- uses: actions/checkout@v4
with:
lfs: true
persist-credentials: false
@@ -169,3 +176,4 @@ jobs:
# TODO(Steven): Publish draft/pre-release and to test pypi weekly
# TODO(Steven): Separate build and publish job
# TODO(Steven): Tag documentation with the same version as the package
.github/workflows/security.yml
+1 -1
View File
@@ -43,7 +43,7 @@ jobs:
runs-on: ubuntu-latest
steps:
- name: Checkout code
uses: actions/checkout@v6 # zizmor: ignore[unpinned-uses]
uses: actions/checkout@v4 # zizmor: ignore[unpinned-uses]
with:
fetch-depth: 0
persist-credentials: false
.github/workflows/stale.yml
-1
View File
@@ -45,7 +45,6 @@ jobs:
stale:
name: Close Stale Issues and PRs
runs-on: ubuntu-latest
if: github.repository == 'huggingface/lerobot'
permissions:
actions: write
contents: write # only for delete-branch option
.github/workflows/unbound_deps_tests.yml
+11 -28
View File
@@ -20,8 +20,8 @@ on:
workflow_dispatch:
# Run on the 1st and 15th of every month at 09:00 UTC
# schedule:
# - cron: '0 2 1,15 * *'
schedule:
- cron: '0 2 1,15 * *'
permissions:
contents: read
@@ -29,7 +29,7 @@ permissions:
# Sets up the environment variables
env:
UV_VERSION: "0.8.0"
PYTHON_VERSION: "3.12"
PYTHON_VERSION: "3.10"
DOCKER_IMAGE_NAME: huggingface/lerobot-gpu:unbound
# Ensures that only the latest action is built, canceling older runs.
@@ -43,14 +43,12 @@ jobs:
full-tests:
name: Full Unbound Tests
runs-on: ubuntu-latest
if: github.repository == 'huggingface/lerobot'
env:
MUJOCO_GL: egl
HF_HOME: /mnt/cache/.cache/huggingface
HF_LEROBOT_HOME: /mnt/cache/.cache/huggingface/lerobot
HF_USER_TOKEN: ${{ secrets.LEROBOT_HF_USER }}
steps:
- uses: actions/checkout@v6
- uses: actions/checkout@v4
with:
lfs: true
persist-credentials: false
@@ -79,12 +77,8 @@ jobs:
echo "Dependencies unbound:" && cat pyproject.toml
- name: Install lerobot with all extras
run: uv sync --extra all # TODO(Steven): Make flash-attn optional
- name: Login to Hugging Face
if: env.HF_USER_TOKEN != ''
run: |
uv run hf auth login --token "$HF_USER_TOKEN" --add-to-git-credential
uv run hf auth whoami
run: uv sync --all-extras --no-extra groot # TODO(Steven): Make flash-attn optional
- name: Run pytest (all extras)
run: uv run pytest tests -vv
@@ -96,7 +90,6 @@ jobs:
name: Build and Push Docker
runs-on:
group: aws-general-8-plus
if: github.repository == 'huggingface/lerobot'
outputs:
image_tag: ${{ env.DOCKER_IMAGE_NAME }}
env:
@@ -107,7 +100,7 @@ jobs:
sudo apt-get update
sudo apt-get install git-lfs
git lfs install
- uses: actions/checkout@v6
- uses: actions/checkout@v4
with:
lfs: true
persist-credentials: false
@@ -142,7 +135,6 @@ jobs:
HF_LEROBOT_HOME: /home/user_lerobot/.cache/huggingface/lerobot
TORCH_HOME: /home/user_lerobot/.cache/torch
TRITON_CACHE_DIR: /home/user_lerobot/.cache/triton
HF_USER_TOKEN: ${{ secrets.LEROBOT_HF_USER }}
container:
image: ${{ needs.build-and-push-docker.outputs.image_tag }} # zizmor: ignore[unpinned-images]
options: --gpus all --shm-size "16gb"
@@ -154,11 +146,6 @@ jobs:
shell: bash
working-directory: /lerobot
steps:
- name: Login to Hugging Face
if: env.HF_USER_TOKEN != ''
run: |
hf auth login --token "$HF_USER_TOKEN" --add-to-git-credential
hf auth whoami
- name: Run pytest on GPU
run: pytest tests -vv
- name: Run end-to-end tests
@@ -174,19 +161,15 @@ jobs:
steps:
- name: Get Docker Hub Token and Delete Image
# zizmor: ignore[template-injection]
env:
DOCKERHUB_LEROBOT_USERNAME: ${{ secrets.DOCKERHUB_LEROBOT_USERNAME }}
DOCKERHUB_LEROBOT_PASSWORD: ${{ secrets.DOCKERHUB_LEROBOT_PASSWORD }}
IMAGE_FULL: ${{ needs.build-and-push-docker.outputs.image_tag }}
run: |
IMAGE_NAME=$(echo "$IMAGE_FULL" | cut -d':' -f1)
IMAGE_TAG=$(echo "$IMAGE_FULL" | cut -d':' -f2)
IMAGE_NAME=$(echo "${{ needs.build-and-push-docker.outputs.image_tag }}" | cut -d':' -f1)
IMAGE_TAG=$(echo "${{ needs.build-and-push-docker.outputs.image_tag }}" | cut -d':' -f2)
echo "Attempting to delete image: $IMAGE_NAME:$IMAGE_TAG"
TOKEN=$(curl -s -H "Content-Type: application/json" \
-X POST \
-d "{\"username\": \"$DOCKERHUB_LEROBOT_USERNAME\", \"password\": \"$DOCKERHUB_LEROBOT_PASSWORD\"}" \
-d '{"username": "${{ secrets.DOCKERHUB_LEROBOT_USERNAME }}", "password": "${{ secrets.DOCKERHUB_LEROBOT_PASSWORD }}"}' \
https://hub.docker.com/v2/users/login/ | jq -r .token)
if [ "$TOKEN" == "null" ] || [ -z "$TOKEN" ]; then
@@ -197,7 +180,7 @@ jobs:
HTTP_RESPONSE=$(curl -s -o /dev/null -w "%{http_code}" \
-H "Authorization: JWT ${TOKEN}" \
-X DELETE \
https://hub.docker.com/v2/repositories/${IMAGE_NAME}/tags/$IMAGE_TAG)
https://hub.docker.com/v2/repositories/${IMAGE_NAME}/tags/${IMAGE_TAG}/)
if [ "$HTTP_RESPONSE" -eq 204 ]; then
echo "Successfully deleted Docker image tag: $IMAGE_NAME:$IMAGE_TAG"
.pre-commit-config.yaml
+3 -3
View File
@@ -13,7 +13,7 @@
# limitations under the License.
default_language_version:
python: python3.12
python: python3.10
exclude: "tests/artifacts/.*\\.safetensors$"
@@ -55,7 +55,7 @@ repos:
rev: v3.21.0
hooks:
- id: pyupgrade
args: [--py312-plus]
args: [--py310-plus]
##### Markdown Quality #####
- repo: https://github.com/rbubley/mirrors-prettier
@@ -87,7 +87,7 @@ repos:
# TODO(Steven): Uncomment when ready to use
##### Static Analysis & Typing #####
- repo: https://github.com/pre-commit/mirrors-mypy
rev: v1.19.1
rev: v1.18.2
hooks:
- id: mypy
args: [--config-file=pyproject.toml]
AI_POLICY.md
-25
View File
@@ -1,25 +0,0 @@
# AI Usage Policy
The LeRobot project welcomes contributions from everyone, and we have a few guidelines regarding AI usage to ensure high code quality, clear communication, and a healthy open-source ecosystem:
- **Please disclose significant AI assistance.** If you used AI tools (e.g., Copilot, Claude, Cursor, ChatGPT) to generate a substantial portion of your code or text, let us know in your PR description. Transparency helps us review your changes more effectively.
- **Own your code (The Human-in-the-Loop).** You must fully understand all the changes you are proposing. If you cannot explain what your AI-assisted code does or how it interacts with LeRobot's broader architecture, please take the time to learn and test it before submitting.
- **Keep issues and discussions focused.** You are welcome to use AI to help draft issues or PR descriptions, but please review and edit them carefully before posting. AI can often be overly verbose; trimming the noise and getting straight to the point helps our maintainers address your needs faster.
Our core maintainers also use AI tools to aid their workflows, but they do so while bringing deep contextual knowledge of the LeRobot codebase to validate the output. We ask all contributors to apply that same level of rigor.
## Remember the Human Maintainers
Please remember that LeRobot is maintained by a dedicated team of humans.
Every discussion, issue, and pull request is read and reviewed by real people. While AI tools can generate thousands of lines of code in seconds, reviewing that code still takes human time and energy. Submitting unverified or low-effort AI output puts an unfair burden on our maintainers.
Today, the quality of the AI output still heavily depends on the developer driving the tool. We ask that you respect our maintainers' time by thoroughly vetting, testing, and refining your submissions.
## AI is Welcome Here
LeRobot operates at the cutting edge of AI and robotics, and many of our maintainers actively embrace AI coding assistants as valuable productivity tools. We are a pro-AI project!
Our reason for having an AI policy is not an anti-AI stance. Rather, it exists to ensure that AI is used to enhance human contributions, not replace them with unverified noise. It's about how the tools are used, not the tools themselves.
We value the unique human insight you bring to the LeRobot community. Let AI empower your workflow, but always let your own judgment take the wheel.
CODE_OF_CONDUCT.md
+2 -2
View File
@@ -52,7 +52,7 @@ decisions when appropriate.
This Code of Conduct applies within all community spaces, and also applies when
an individual is officially representing the community in public spaces.
Examples of representing our community include using an official e-mail address,
Examples of representing our community include using an official email address,
posting via an official social media account, or acting as an appointed
representative at an online or offline event.
@@ -60,7 +60,7 @@ representative at an online or offline event.
Instances of abusive, harassing, or otherwise unacceptable behavior may be
reported to the community leaders responsible for enforcement at
feedback@huggingface.co.
[feedback@huggingface.co](mailto:feedback@huggingface.co).
All complaints will be reviewed and investigated promptly and fairly.
All community leaders are obligated to respect the privacy and security of the
CONTRIBUTING.md
+303 -63
View File
@@ -1,83 +1,323 @@
# How to contribute to 🤗 LeRobot
# How to contribute to 🤗 LeRobot?
Everyone is welcome to contribute, and we value everybody's contribution. Code is not the only way to help the community. Answering questions, helping others, reaching out, and improving the documentation are immensely valuable.
Everyone is welcome to contribute, and we value everybody's contribution. Code
is thus not the only way to help the community. Answering questions, helping
others, reaching out and improving the documentations are immensely valuable to
the community.
Whichever way you choose to contribute, please be mindful to respect our [code of conduct](./CODE_OF_CONDUCT.md) and our [AI policy](./AI_POLICY.md).
It also helps us if you spread the word: reference the library from blog posts
on the awesome projects it made possible, shout out on Twitter when it has
helped you, or simply ⭐️ the repo to say "thank you".
## Ways to Contribute
Whichever way you choose to contribute, please be mindful to respect our
[code of conduct](https://github.com/huggingface/lerobot/blob/main/CODE_OF_CONDUCT.md).
You can contribute in many ways:
## You can contribute in so many ways!
- **Fixing issues:** Resolve bugs or improve existing code.
- **New features:** Develop new features.
- **Extend:** Implement new models/policies, robots, or simulation environments and upload datasets to the Hugging Face Hub.
- **Documentation:** Improve examples, guides, and docstrings.
- **Feedback:** Submit tickets related to bugs or desired new features.
Some of the ways you can contribute to 🤗 LeRobot:
If you are unsure where to start, join our [Discord Channel](https://discord.gg/q8Dzzpym3f).
- Fixing outstanding issues with the existing code.
- Implementing new models, datasets or simulation environments.
- Contributing to the examples or to the documentation.
- Submitting issues related to bugs or desired new features.
## Development Setup
Following the guides below, feel free to open issues and PRs and to coordinate your efforts with the community on our [Discord Channel](https://discord.gg/VjFz58wn3R). For specific inquiries, reach out to [Remi Cadene](mailto:remi.cadene@huggingface.co).
To contribute code, you need to set up a development environment.
If you are not sure how to contribute or want to know the next features we working on, look on this project page: [LeRobot TODO](https://github.com/orgs/huggingface/projects/46)
### 1. Fork and Clone
## Submitting a new issue or feature request
Fork the repository on GitHub, then clone your fork:
```bash
git clone https://github.com/<your-handle>/lerobot.git
cd lerobot
git remote add upstream https://github.com/huggingface/lerobot.git
```
### 2. Environment Installation
Please follow our [Installation Guide](./docs/source/installation.mdx) for the environment setup & installation from source.
## Running Tests & Quality Checks
### Code Style (Pre-commit)
Install `pre-commit` hooks to run checks automatically before you commit:
```bash
pre-commit install
```
To run checks manually on all files:
```bash
pre-commit run --all-files
```
### Running Tests
We use `pytest`. First, ensure you have test artifacts by installing **git-lfs**:
Do your best to follow these guidelines when submitting an issue or a feature
request. It will make it easier for us to come back to you quickly and with good
feedback.
### Did you find a bug?
The 🤗 LeRobot library is robust and reliable thanks to the users who notify us of
the problems they encounter. So thank you for reporting an issue.
First, we would really appreciate it if you could **make sure the bug was not
already reported** (use the search bar on Github under Issues).
Did not find it? :( So we can act quickly on it, please follow these steps:
- Include your **OS type and version**, the versions of **Python** and **PyTorch**.
- A short, self-contained, code snippet that allows us to reproduce the bug in
less than 30s.
- The full traceback if an exception is raised.
- Attach any other additional information, like screenshots, you think may help.
### Do you want a new feature?
A good feature request addresses the following points:
1. Motivation first:
- Is it related to a problem/frustration with the library? If so, please explain
why. Providing a code snippet that demonstrates the problem is best.
- Is it related to something you would need for a project? We'd love to hear
about it!
- Is it something you worked on and think could benefit the community?
Awesome! Tell us what problem it solved for you.
2. Write a _paragraph_ describing the feature.
3. Provide a **code snippet** that demonstrates its future use.
4. In case this is related to a paper, please attach a link.
5. Attach any additional information (drawings, screenshots, etc.) you think may help.
If your issue is well written we're already 80% of the way there by the time you
post it.
## Adding new policies, datasets or environments
Look at our implementations for [datasets](./src/lerobot/datasets/), [policies](./src/lerobot/policies/),
environments ([aloha](https://github.com/huggingface/gym-aloha),
[pusht](https://github.com/huggingface/gym-pusht))
and follow the same api design.
When implementing a new dataset loadable with LeRobotDataset follow these steps:
- Update `available_datasets_per_env` in `lerobot/__init__.py`
When implementing a new environment (e.g. `gym_aloha`), follow these steps:
- Update `available_tasks_per_env` and `available_datasets_per_env` in `lerobot/__init__.py`
When implementing a new policy class (e.g. `DiffusionPolicy`) follow these steps:
- Update `available_policies` and `available_policies_per_env`, in `lerobot/__init__.py`
- Set the required `name` class attribute.
- Update variables in `tests/test_available.py` by importing your new Policy class
## Submitting a pull request (PR)
Before writing code, we strongly advise you to search through the existing PRs or
issues to make sure that nobody is already working on the same thing. If you are
unsure, it is always a good idea to open an issue to get some feedback.
You will need basic `git` proficiency to be able to contribute to
🤗 LeRobot. `git` is not the easiest tool to use but it has the greatest
manual. Type `git --help` in a shell and enjoy. If you prefer books, [Pro
Git](https://git-scm.com/book/en/v2) is a very good reference.
Follow these steps to start contributing:
1. Fork the [repository](https://github.com/huggingface/lerobot) by
clicking on the 'Fork' button on the repository's page. This creates a copy of the code
under your GitHub user account.
2. Clone your fork to your local disk, and add the base repository as a remote. The following command
assumes you have your public SSH key uploaded to GitHub. See the following guide for more
[information](https://docs.github.com/en/repositories/creating-and-managing-repositories/cloning-a-repository).
```bash
git clone git@github.com:<your Github handle>/lerobot.git
cd lerobot
git remote add upstream https://github.com/huggingface/lerobot.git
```
3. Create a new branch to hold your development changes, and do this for every new PR you work on.
Start by synchronizing your `main` branch with the `upstream/main` branch (more details in the [GitHub Docs](https://docs.github.com/en/github/collaborating-with-issues-and-pull-requests/syncing-a-fork)):
```bash
git checkout main
git fetch upstream
git rebase upstream/main
```
Once your `main` branch is synchronized, create a new branch from it:
```bash
git checkout -b a-descriptive-name-for-my-changes
```
🚨 **Do not** work on the `main` branch.
4. for development, we advise to use a tool like `poetry` or `uv` instead of just `pip` to easily track our dependencies.
Follow the instructions to [install poetry](https://python-poetry.org/docs/#installation) (use a version >=2.1.0) or to [install uv](https://docs.astral.sh/uv/getting-started/installation/#installation-methods) if you don't have one of them already.
Set up a development environment with conda:
```bash
conda create -y -n lerobot-dev python=3.10 && conda activate lerobot-dev
```
If you're using `uv`, it can manage python versions so you can instead do:
```bash
uv venv --python 3.10 && source .venv/bin/activate
```
To develop on 🤗 LeRobot, you will at least need to install the `dev` and `test` extras dependencies along with the core library:
using `poetry`
```bash
poetry sync --extras "dev test"
```
using `uv`
```bash
uv sync --extra dev --extra test
```
You can also install the project with all its dependencies (including environments):
using `poetry`
```bash
poetry sync --all-extras
```
using `uv`
```bash
uv sync --all-extras
```
> **Note:** If you don't install simulation environments with `--all-extras`, the tests that require them will be skipped when running the pytest suite locally. However, they _will_ be tested in the CI. In general, we advise you to install everything and test locally before pushing.
Whichever command you chose to install the project (e.g. `poetry sync --all-extras`), you should run it again when pulling code with an updated version of `pyproject.toml` and `poetry.lock` in order to synchronize your virtual environment with the new dependencies.
The equivalent of `pip install some-package`, would just be:
using `poetry`
```bash
poetry add some-package
```
using `uv`
```bash
uv add some-package
```
When making changes to the poetry sections of the `pyproject.toml`, you should run the following command to lock dependencies.
using `poetry`
```bash
poetry lock
```
using `uv`
```bash
uv lock
```
5. Develop the features on your branch.
As you work on the features, you should make sure that the test suite
passes. You should run the tests impacted by your changes like this (see
below an explanation regarding the environment variable):
```bash
pytest tests/<TEST_TO_RUN>.py
```
6. Follow our style.
`lerobot` relies on `ruff` to format its source code
consistently. Set up [`pre-commit`](https://pre-commit.com/) to run these checks
automatically as Git commit hooks.
Install `pre-commit` hooks:
```bash
pre-commit install
```
You can run these hooks whenever you need on staged files with:
```bash
pre-commit
```
Once you're happy with your changes, add changed files using `git add` and
make a commit with `git commit` to record your changes locally:
```bash
git add modified_file.py
git commit
```
Note, if you already committed some changes that have a wrong formatting, you can use:
```bash
pre-commit run --all-files
```
Please write [good commit messages](https://chris.beams.io/posts/git-commit/).
It is a good idea to sync your copy of the code with the original
repository regularly. This way you can quickly account for changes:
```bash
git fetch upstream
git rebase upstream/main
```
Push the changes to your account using:
```bash
git push -u origin a-descriptive-name-for-my-changes
```
7. Once you are satisfied (**and the checklist below is happy too**), go to the
webpage of your fork on GitHub. Click on 'Pull request' to send your changes
to the project maintainers for review.
8. It's ok if maintainers ask you for changes. It happens to core contributors
too! So everyone can see the changes in the Pull request, work in your local
branch and push the changes to your fork. They will automatically appear in
the pull request.
### Checklist
1. The title of your pull request should be a summary of its contribution;
2. If your pull request addresses an issue, please mention the issue number in
the pull request description to make sure they are linked (and people
consulting the issue know you are working on it);
3. To indicate a work in progress please prefix the title with `[WIP]`, or preferably mark
the PR as a draft PR. These are useful to avoid duplicated work, and to differentiate
it from PRs ready to be merged;
4. Make sure existing tests pass;
### Tests
An extensive test suite is included to test the library behavior and several examples. Library tests can be found in the [tests folder](https://github.com/huggingface/lerobot/tree/main/tests).
Install [git lfs](https://git-lfs.com/) to retrieve test artifacts (if you don't have it already).
On Mac:
```bash
brew install git-lfs
git lfs install
```
On Ubuntu:
```bash
sudo apt-get install git-lfs
git lfs install
```
Pull artifacts if they're not in [tests/artifacts](tests/artifacts)
```bash
git lfs pull
```
Run the full suite (this may require extras installed):
We use `pytest` in order to run the tests. From the root of the
repository, here's how to run tests with `pytest` for the library:
```bash
pytest -sv ./tests
python -m pytest -sv ./tests
```
Or run a specific test file during development:
```bash
pytest -sv tests/test_specific_feature.py
```
## Submitting Issues & Pull Requests
Use the templates for required fields and examples.
- **Issues:** Follow the [ticket template](./.github/ISSUE_TEMPLATE/bug-report.yml).
- **Pull requests:** Rebase on `upstream/main`, use a descriptive branch (don't work on `main`), run `pre-commit` and tests locally, and follow the [PR template](./.github/PULL_REQUEST_TEMPLATE.md).
One member of the LeRobot team will then review your contribution.
Thank you for contributing to LeRobot!
You can specify a smaller set of tests in order to test only the feature
you're working on.
MANIFEST.in
-1
View File
@@ -1,3 +1,2 @@
include src/lerobot/templates/lerobot_modelcard_template.md
include src/lerobot/datasets/card_template.md
include src/lerobot/envs/metaworld_config.json
README.md
+290 -122
View File
@@ -1,5 +1,7 @@
<p align="center">
<img alt="LeRobot, Hugging Face Robotics Library" src="./media/readme/lerobot-logo-thumbnail.png" width="100%">
<img alt="LeRobot, Hugging Face Robotics Library" src="https://raw.githubusercontent.com/huggingface/lerobot/main/media/lerobot-logo-thumbnail.png" width="100%">
<br/>
<br/>
</p>
<div align="center">
@@ -10,132 +12,323 @@
[![Status](https://img.shields.io/pypi/status/lerobot)](https://pypi.org/project/lerobot/)
[![Version](https://img.shields.io/pypi/v/lerobot)](https://pypi.org/project/lerobot/)
[![Contributor Covenant](https://img.shields.io/badge/Contributor%20Covenant-v2.1-ff69b4.svg)](https://github.com/huggingface/lerobot/blob/main/CODE_OF_CONDUCT.md)
[![Discord](https://img.shields.io/badge/Discord-Join_Us-5865F2?style=flat&logo=discord&logoColor=white)](https://discord.gg/q8Dzzpym3f)
[![Discord](https://dcbadge.vercel.app/api/server/C5P34WJ68S?style=flat)](https://discord.gg/s3KuuzsPFb)
<!-- [![Coverage](https://codecov.io/gh/huggingface/lerobot/branch/main/graph/badge.svg?token=TODO)](https://codecov.io/gh/huggingface/lerobot) -->
</div>
**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.
<h2 align="center">
<p><a href="https://huggingface.co/docs/lerobot/hope_jr">
Build Your Own HopeJR Robot!</a></p>
</h2>
🤗 A hardware-agnostic, Python-native interface that standardizes control across diverse platforms, from low-cost arms (SO-100) to humanoids.
<div align="center">
<img
src="https://raw.githubusercontent.com/huggingface/lerobot/main/media/hope_jr/hopejr.png"
alt="HopeJR robot"
title="HopeJR robot"
width="60%"
/>
🤗 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.
<p><strong>Meet HopeJR A humanoid robot arm and hand for dexterous manipulation!</strong></p>
<p>Control it with exoskeletons and gloves for precise hand movements.</p>
<p>Perfect for advanced manipulation tasks! 🤖</p>
🤗 State-of-the-art policies that have been shown to transfer to the real-world ready for training and deployment.
<p><a href="https://huggingface.co/docs/lerobot/hope_jr">
See the full HopeJR tutorial here.</a></p>
</div>
🤗 Comprehensive support for the open-source ecosystem to democratize physical AI.
<br/>
## Quick Start
<h2 align="center">
<p><a href="https://huggingface.co/docs/lerobot/so101">
Build Your Own SO-101 Robot!</a></p>
</h2>
LeRobot can be installed directly from PyPI.
<div align="center">
<table>
<tr>
<td align="center"><img src="https://raw.githubusercontent.com/huggingface/lerobot/main/media/so101/so101.webp" alt="SO-101 follower arm" title="SO-101 follower arm" width="90%"/></td>
<td align="center"><img src="https://raw.githubusercontent.com/huggingface/lerobot/main/media/so101/so101-leader.webp" alt="SO-101 leader arm" title="SO-101 leader arm" width="90%"/></td>
</tr>
</table>
<p><strong>Meet the updated SO100, the SO-101 Just €114 per arm!</strong></p>
<p>Train it in minutes with a few simple moves on your laptop.</p>
<p>Then sit back and watch your creation act autonomously! 🤯</p>
<p><a href="https://huggingface.co/docs/lerobot/so101">
See the full SO-101 tutorial here.</a></p>
<p>Want to take it to the next level? Make your SO-101 mobile by building LeKiwi!</p>
<p>Check out the <a href="https://huggingface.co/docs/lerobot/lekiwi">LeKiwi tutorial</a> and bring your robot to life on wheels.</p>
<img src="https://raw.githubusercontent.com/huggingface/lerobot/main/media/lekiwi/kiwi.webp" alt="LeKiwi mobile robot" title="LeKiwi mobile robot" width="50%">
</div>
<br/>
<h3 align="center">
<p>LeRobot: State-of-the-art AI for real-world robotics</p>
</h3>
---
🤗 LeRobot aims to provide models, datasets, and tools for real-world robotics in PyTorch. The goal is to lower the barrier to entry to robotics so that everyone can contribute and benefit from sharing datasets and pretrained models.
🤗 LeRobot contains state-of-the-art approaches that have been shown to transfer to the real-world with a focus on imitation learning and reinforcement learning.
🤗 LeRobot already provides a set of pretrained models, datasets with human collected demonstrations, and simulation environments to get started without assembling a robot. In the coming weeks, the plan is to add more and more support for real-world robotics on the most affordable and capable robots out there.
🤗 LeRobot hosts pretrained models and datasets on this Hugging Face community page: [huggingface.co/lerobot](https://huggingface.co/lerobot)
#### Examples of pretrained models on simulation environments
<table>
<tr>
<td><img src="https://raw.githubusercontent.com/huggingface/lerobot/main/media/gym/aloha_act.gif" width="100%" alt="ACT policy on ALOHA env"/></td>
<td><img src="https://raw.githubusercontent.com/huggingface/lerobot/main/media/gym/simxarm_tdmpc.gif" width="100%" alt="TDMPC policy on SimXArm env"/></td>
<td><img src="https://raw.githubusercontent.com/huggingface/lerobot/main/media/gym/pusht_diffusion.gif" width="100%" alt="Diffusion policy on PushT env"/></td>
</tr>
<tr>
<td align="center">ACT policy on ALOHA env</td>
<td align="center">TDMPC policy on SimXArm env</td>
<td align="center">Diffusion policy on PushT env</td>
</tr>
</table>
## Installation
LeRobot works with Python 3.10+ and PyTorch 2.2+.
### Environment Setup
Create a virtual environment with Python 3.10 and activate it, e.g. with [`miniforge`](https://conda-forge.org/download/):
```bash
conda create -y -n lerobot python=3.10
conda activate lerobot
```
When using `conda`, install `ffmpeg` in your environment:
```bash
conda install ffmpeg -c conda-forge
```
> **NOTE:** This usually installs `ffmpeg 7.X` for your platform compiled with the `libsvtav1` encoder. If `libsvtav1` is not supported (check supported encoders with `ffmpeg -encoders`), you can:
>
> - _[On any platform]_ Explicitly install `ffmpeg 7.X` using:
>
> ```bash
> conda install ffmpeg=7.1.1 -c conda-forge
> ```
>
> - _[On Linux only]_ Install [ffmpeg build dependencies](https://trac.ffmpeg.org/wiki/CompilationGuide/Ubuntu#GettheDependencies) and [compile ffmpeg from source with libsvtav1](https://trac.ffmpeg.org/wiki/CompilationGuide/Ubuntu#libsvtav1), and make sure you use the corresponding ffmpeg binary to your install with `which ffmpeg`.
### Install LeRobot 🤗
#### From Source
First, clone the repository and navigate into the directory:
```bash
git clone https://github.com/huggingface/lerobot.git
cd lerobot
```
Then, install the library in editable mode. This is useful if you plan to contribute to the code.
```bash
pip install -e .
```
> **NOTE:** If you encounter build errors, you may need to install additional dependencies (`cmake`, `build-essential`, and `ffmpeg libs`). On Linux, run:
> `sudo apt-get install cmake build-essential python3-dev pkg-config libavformat-dev libavcodec-dev libavdevice-dev libavutil-dev libswscale-dev libswresample-dev libavfilter-dev`. For other systems, see: [Compiling PyAV](https://pyav.org/docs/develop/overview/installation.html#bring-your-own-ffmpeg)
For simulations, 🤗 LeRobot comes with gymnasium environments that can be installed as extras:
- [aloha](https://github.com/huggingface/gym-aloha)
- [xarm](https://github.com/huggingface/gym-xarm)
- [pusht](https://github.com/huggingface/gym-pusht)
For instance, to install 🤗 LeRobot with aloha and pusht, use:
```bash
pip install -e ".[aloha, pusht]"
```
### Installation from PyPI
**Core Library:**
Install the base package with:
```bash
pip install lerobot
lerobot-info
```
> [!IMPORTANT]
> For detailed installation guide, please see the [Installation Documentation](https://huggingface.co/docs/lerobot/installation).
_This installs only the default dependencies._
## Robots & Control
<div align="center">
<img src="./media/readme/robots_control_video.webp" width="640px" alt="Reachy 2 Demo">
</div>
LeRobot provides a unified `Robot` class interface that decouples control logic from hardware specifics. It supports a wide range of robots and teleoperation devices.
```python
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](https://huggingface.co/docs/lerobot/integrate_hardware).
## 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](https://huggingface.co/lerobot).
- **Tools:** Seamlessly delete episodes, split by indices/fractions, add/remove features, and merge multiple datasets.
```python
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](https://huggingface.co/docs/lerobot/lerobot-dataset-v3)
## 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.
<p align="center">
<img alt="Gr00t Architecture" src="./media/readme/VLA_architecture.jpg" width="640px">
</p>
Training a policy is as simple as running a script configuration:
**Extra Features:**
To install additional functionality, use one of the following:
```bash
lerobot-train \
--policy=act \
--dataset.repo_id=lerobot/aloha_mobile_cabinet
pip install 'lerobot[all]' # All available features
pip install 'lerobot[aloha,pusht]' # Specific features (Aloha & Pusht)
pip install 'lerobot[feetech]' # Feetech motor support
```
| Category | Models |
| -------------------------- | ------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------ |
| **Imitation Learning** | [ACT](./docs/source/policy_act_README.md), [Diffusion](./docs/source/policy_diffusion_README.md), [VQ-BeT](./docs/source/policy_vqbet_README.md) |
| **Reinforcement Learning** | [HIL-SERL](./docs/source/hilserl.mdx), [TDMPC](./docs/source/policy_tdmpc_README.md) & QC-FQL (coming soon) |
| **VLAs Models** | [Pi0Fast](./docs/source/pi0fast.mdx), [Pi0.5](./docs/source/pi05.mdx), [GR00T N1.5](./docs/source/policy_groot_README.md), [SmolVLA](./docs/source/policy_smolvla_README.md), [XVLA](./docs/source/xvla.mdx) |
_Replace `[...]` with your desired features._
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
**Available Tags:**
For a full list of optional dependencies, see:
https://pypi.org/project/lerobot/
For detailed policy setup guides, see the [Policy Documentation](https://huggingface.co/docs/lerobot/bring_your_own_policies).
> [!NOTE]
> For lerobot 0.4.0, if you want to install pi tags, you will have to do: `pip install "lerobot[pi]@git+https://github.com/huggingface/lerobot.git"`.
>
> This will be solved in the next patch release
## Inference & Evaluation
### Weights & Biases
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.
To use [Weights and Biases](https://docs.wandb.ai/quickstart) for experiment tracking, log in with
```bash
# 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
wandb login
```
Learn how to implement your own simulation environment or benchmark and distribute it from the HF Hub by following the [EnvHub Documentation](https://huggingface.co/docs/lerobot/envhub)
(note: you will also need to enable WandB in the configuration. See below.)
## Resources
### Visualize datasets
- **[Documentation](https://huggingface.co/docs/lerobot/index):** The complete guide to tutorials & API.
- **[Chinese Tutorials: LeRobot+SO-ARM101中文教程-同济子豪兄](https://zihao-ai.feishu.cn/wiki/space/7589642043471924447)** Detailed doc for assembling, teleoperate, dataset, train, deploy. Verified by Seed Studio and 5 global hackathon players.
- **[Discord](https://discord.gg/q8Dzzpym3f):** Join the `LeRobot` server to discuss with the community.
- **[X](https://x.com/LeRobotHF):** Follow us on X to stay up-to-date with the latest developments.
- **[Robot Learning Tutorial](https://huggingface.co/spaces/lerobot/robot-learning-tutorial):** A free, hands-on course to learn robot learning using LeRobot.
Check out [example 1](https://github.com/huggingface/lerobot/blob/main/examples/dataset/load_lerobot_dataset.py) that illustrates how to use our dataset class which automatically downloads data from the Hugging Face hub.
You can also locally visualize episodes from a dataset on the hub by executing our script from the command line:
```bash
lerobot-dataset-viz \
--repo-id lerobot/pusht \
--episode-index 0
```
or from a dataset in a local folder with the `root` option and the `--mode local` (in the following case the dataset will be searched for in `./my_local_data_dir/lerobot/pusht`)
```bash
lerobot-dataset-viz \
--repo-id lerobot/pusht \
--root ./my_local_data_dir \
--mode local \
--episode-index 0
```
It will open `rerun.io` and display the camera streams, robot states and actions, like this:
https://github-production-user-asset-6210df.s3.amazonaws.com/4681518/328035972-fd46b787-b532-47e2-bb6f-fd536a55a7ed.mov?X-Amz-Algorithm=AWS4-HMAC-SHA256&X-Amz-Credential=AKIAVCODYLSA53PQK4ZA%2F20240505%2Fus-east-1%2Fs3%2Faws4_request&X-Amz-Date=20240505T172924Z&X-Amz-Expires=300&X-Amz-Signature=d680b26c532eeaf80740f08af3320d22ad0b8a4e4da1bcc4f33142c15b509eda&X-Amz-SignedHeaders=host&actor_id=24889239&key_id=0&repo_id=748713144
Our script can also visualize datasets stored on a distant server. See `lerobot-dataset-viz --help` for more instructions.
### The `LeRobotDataset` format
A dataset in `LeRobotDataset` format is very simple to use. It can be loaded from a repository on the Hugging Face hub or a local folder simply with e.g. `dataset = LeRobotDataset("lerobot/aloha_static_coffee")` and can be indexed into like any Hugging Face and PyTorch dataset. For instance `dataset[0]` will retrieve a single temporal frame from the dataset containing observation(s) and an action as PyTorch tensors ready to be fed to a model.
A specificity of `LeRobotDataset` is that, rather than retrieving a single frame by its index, we can retrieve several frames based on their temporal relationship with the indexed frame, by setting `delta_timestamps` to a list of relative times with respect to the indexed frame. For example, with `delta_timestamps = {"observation.image": [-1, -0.5, -0.2, 0]}` one can retrieve, for a given index, 4 frames: 3 "previous" frames 1 second, 0.5 seconds, and 0.2 seconds before the indexed frame, and the indexed frame itself (corresponding to the 0 entry). See example [1_load_lerobot_dataset.py](https://github.com/huggingface/lerobot/blob/main/examples/dataset/load_lerobot_dataset.py) for more details on `delta_timestamps`.
Under the hood, the `LeRobotDataset` format makes use of several ways to serialize data which can be useful to understand if you plan to work more closely with this format. We tried to make a flexible yet simple dataset format that would cover most type of features and specificities present in reinforcement learning and robotics, in simulation and in real-world, with a focus on cameras and robot states but easily extended to other types of sensory inputs as long as they can be represented by a tensor.
Here are the important details and internal structure organization of a typical `LeRobotDataset` instantiated with `dataset = LeRobotDataset("lerobot/aloha_static_coffee")`. The exact features will change from dataset to dataset but not the main aspects:
```
dataset attributes:
├ hf_dataset: a Hugging Face dataset (backed by Arrow/parquet). Typical features example:
│ ├ observation.images.cam_high (VideoFrame):
│ │ VideoFrame = {'path': path to a mp4 video, 'timestamp' (float32): timestamp in the video}
│ ├ observation.state (list of float32): position of an arm joints (for instance)
│ ... (more observations)
│ ├ action (list of float32): goal position of an arm joints (for instance)
│ ├ episode_index (int64): index of the episode for this sample
│ ├ frame_index (int64): index of the frame for this sample in the episode ; starts at 0 for each episode
│ ├ timestamp (float32): timestamp in the episode
│ ├ next.done (bool): indicates the end of an episode ; True for the last frame in each episode
│ └ index (int64): general index in the whole dataset
├ meta: a LeRobotDatasetMetadata object containing:
│ ├ info: a dictionary of metadata on the dataset
│ │ ├ codebase_version (str): this is to keep track of the codebase version the dataset was created with
│ │ ├ fps (int): frame per second the dataset is recorded/synchronized to
│ │ ├ features (dict): all features contained in the dataset with their shapes and types
│ │ ├ total_episodes (int): total number of episodes in the dataset
│ │ ├ total_frames (int): total number of frames in the dataset
│ │ ├ robot_type (str): robot type used for recording
│ │ ├ data_path (str): formattable string for the parquet files
│ │ └ video_path (str): formattable string for the video files (if using videos)
│ ├ episodes: a DataFrame containing episode metadata with columns:
│ │ ├ episode_index (int): index of the episode
│ │ ├ tasks (list): list of tasks for this episode
│ │ ├ length (int): number of frames in this episode
│ │ ├ dataset_from_index (int): start index of this episode in the dataset
│ │ └ dataset_to_index (int): end index of this episode in the dataset
│ ├ stats: a dictionary of statistics (max, mean, min, std) for each feature in the dataset, for instance
│ │ ├ observation.images.front_cam: {'max': tensor with same number of dimensions (e.g. `(c, 1, 1)` for images, `(c,)` for states), etc.}
│ │ └ ...
│ └ tasks: a DataFrame containing task information with task names as index and task_index as values
├ root (Path): local directory where the dataset is stored
├ image_transforms (Callable): optional image transformations to apply to visual modalities
└ delta_timestamps (dict): optional delta timestamps for temporal queries
```
A `LeRobotDataset` is serialised using several widespread file formats for each of its parts, namely:
- hf_dataset stored using Hugging Face datasets library serialization to parquet
- videos are stored in mp4 format to save space
- metadata are stored in plain json/jsonl files
Dataset can be uploaded/downloaded from the HuggingFace hub seamlessly. To work on a local dataset, you can specify its location with the `root` argument if it's not in the default `~/.cache/huggingface/lerobot` location.
#### Reproduce state-of-the-art (SOTA)
We provide some pretrained policies on our [hub page](https://huggingface.co/lerobot) that can achieve state-of-the-art performances.
You can reproduce their training by loading the config from their run. Simply running:
```bash
lerobot-train --config_path=lerobot/diffusion_pusht
```
reproduces SOTA results for Diffusion Policy on the PushT task.
## Contribute
If you would like to contribute to 🤗 LeRobot, please check out our [contribution guide](https://github.com/huggingface/lerobot/blob/main/CONTRIBUTING.md).
### Add a pretrained policy
Once you have trained a policy you may upload it to the Hugging Face hub using a hub id that looks like `${hf_user}/${repo_name}` (e.g. [lerobot/diffusion_pusht](https://huggingface.co/lerobot/diffusion_pusht)).
You first need to find the checkpoint folder located inside your experiment directory (e.g. `outputs/train/2024-05-05/20-21-12_aloha_act_default/checkpoints/002500`). Within that there is a `pretrained_model` directory which should contain:
- `config.json`: A serialized version of the policy configuration (following the policy's dataclass config).
- `model.safetensors`: A set of `torch.nn.Module` parameters, saved in [Hugging Face Safetensors](https://huggingface.co/docs/safetensors/index) format.
- `train_config.json`: A consolidated configuration containing all parameters used for training. The policy configuration should match `config.json` exactly. This is useful for anyone who wants to evaluate your policy or for reproducibility.
To upload these to the hub, run the following:
```bash
huggingface-cli upload ${hf_user}/${repo_name} path/to/pretrained_model
```
See [lerobot_eval.py](https://github.com/huggingface/lerobot/blob/main/src/lerobot/scripts/lerobot_eval.py) for an example of how other people may use your policy.
### Acknowledgment
- The LeRobot team 🤗 for building SmolVLA [Paper](https://arxiv.org/abs/2506.01844), [Blog](https://huggingface.co/blog/smolvla).
- Thanks to Tony Zhao, Zipeng Fu and colleagues for open sourcing ACT policy, ALOHA environments and datasets. Ours are adapted from [ALOHA](https://tonyzhaozh.github.io/aloha) and [Mobile ALOHA](https://mobile-aloha.github.io).
- Thanks to Cheng Chi, Zhenjia Xu and colleagues for open sourcing Diffusion policy, Pusht environment and datasets, as well as UMI datasets. Ours are adapted from [Diffusion Policy](https://diffusion-policy.cs.columbia.edu) and [UMI Gripper](https://umi-gripper.github.io).
- Thanks to Nicklas Hansen, Yunhai Feng and colleagues for open sourcing TDMPC policy, Simxarm environments and datasets. Ours are adapted from [TDMPC](https://github.com/nicklashansen/tdmpc) and [FOWM](https://www.yunhaifeng.com/FOWM).
- Thanks to Antonio Loquercio and Ashish Kumar for their early support.
- Thanks to [Seungjae (Jay) Lee](https://sjlee.cc/), [Mahi Shafiullah](https://mahis.life/) and colleagues for open sourcing [VQ-BeT](https://sjlee.cc/vq-bet/) policy and helping us adapt the codebase to our repository. The policy is adapted from [VQ-BeT repo](https://github.com/jayLEE0301/vq_bet_official).
## Citation
If you use LeRobot in your project, please cite the GitHub repository to acknowledge the ongoing development and contributors:
If you want, you can cite this work with:
```bibtex
@misc{cadene2024lerobot,
@@ -146,31 +339,6 @@ If you use LeRobot in your project, please cite the GitHub repository to acknowl
}
```
If you are referencing our research or the academic paper, please also cite our ICLR publication:
## Star History
<details>
<summary><b>ICLR 2026 Paper</b></summary>
```bibtex
@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}
}
```
</details>
## Contribute
We welcome contributions from everyone in the community! To get started, please read our [CONTRIBUTING.md](./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!
<p align="center">
<img alt="SO101 Video" src="./media/readme/so100_video.webp" width="640px">
</p>
<div align="center">
<sub>Built by the <a href="https://huggingface.co/lerobot">LeRobot</a> team at <a href="https://huggingface.co">Hugging Face</a> with ❤️</sub>
</div>
[![Star History Chart](https://api.star-history.com/svg?repos=huggingface/lerobot&type=Timeline)](https://star-history.com/#huggingface/lerobot&Timeline)
SECURITY.md
-48
View File
@@ -1,48 +0,0 @@
# Security Policy
## Project Status & Philosophy
`lerobot` has so far been primarily a research and prototyping tool, which is why deployment security hasnt been a strong focus until now. As `lerobot` continues to be adopted and deployed in production, we are paying much closer attention to these kinds of issues.
Fortunately, being an open-source project, the community can also help by reporting and fixing vulnerabilities. We appreciate your efforts to responsibly disclose your findings and will make every effort to acknowledge your contributions.
## Reporting a Vulnerability
To report a security issue, please use the GitHub Security Advisory ["Report a Vulnerability"](https://github.com/huggingface/lerobot/security/advisories/new) tab.
The `lerobot` team will send a response indicating the next steps in handling your report. After the initial reply to your report, the security team will keep you informed of the progress towards a fix and full announcement, and may ask for additional information or guidance.
#### Hugging Face Security Team
Since this project is part of the Hugging Face ecosystem, feel free to submit vulnerability reports directly to: **[security@huggingface.co](mailto:security@huggingface.co)**. Someone from the HF security team will review the report and recommend next steps.
#### Open Source Disclosures
If reporting a vulnerability specific to the open-source codebase (and not the underlying Hub infrastructure), you may also use [Huntr](https://huntr.com), a vulnerability disclosure program for open source software.
## Supported Versions
Currently, we treat `lerobot` as a rolling release. We prioritize security updates for the latest available version (`main` branch).
| Version | Supported |
| -------- | --------- |
| Latest | ✅ |
| < Latest | ❌ |
## Secure Usage Guidelines
`lerobot` is tightly coupled to the Hugging Face Hub for sharing data and pretrained policies. When downloading artifacts uploaded by others, you expose yourself to risks. Please read below for recommendations to keep your runtime and robot environment safe.
### Remote Artefacts (Weights & Policies)
Models and policies uploaded to the Hugging Face Hub come in different formats. We heavily recommend uploading and downloading models in the [`safetensors`](https://github.com/huggingface/safetensors) format.
`safetensors` was developed specifically to prevent arbitrary code execution on your system, which is critical when running software on physical hardware/robots.
To avoid loading models from unsafe formats (e.g., `pickle`), you should ensure you are prioritizing `safetensors` files.
### Remote Code
Some models or environments on the Hub may require `trust_remote_code=True` to run custom architecture code.
Please **always** verify the content of the modeling files when using this argument. We recommend setting a specific `revision` (commit hash) when loading remote code to ensure you protect yourself from unverified updates to the repository.
benchmarks/video/README.md
+42 -42
View File
@@ -28,9 +28,9 @@ We don't expect the same optimal settings for a dataset of images from a simulat
For these reasons, we run this benchmark on four representative datasets:
- `lerobot/pusht_image`: (96 x 96 pixels) simulation with simple geometric shapes, fixed camera.
- `lerobot/aloha_mobile_shrimp_image`: (480 x 640 pixels) real-world indoor, moving camera.
- `lerobot/paris_street`: (720 x 1280 pixels) real-world outdoor, moving camera.
- `lerobot/kitchen`: (1080 x 1920 pixels) real-world indoor, fixed camera.
- `aliberts/aloha_mobile_shrimp_image`: (480 x 640 pixels) real-world indoor, moving camera.
- `aliberts/paris_street`: (720 x 1280 pixels) real-world outdoor, moving camera.
- `aliberts/kitchen`: (1080 x 1920 pixels) real-world indoor, fixed camera.
Note: The datasets used for this benchmark need to be image datasets, not video datasets.
@@ -179,7 +179,7 @@ python benchmark/video/run_video_benchmark.py \
--output-dir outputs/video_benchmark \
--repo-ids \
lerobot/pusht_image \
lerobot/aloha_mobile_shrimp_image \
aliberts/aloha_mobile_shrimp_image \
--vcodec libx264 libx265 \
--pix-fmt yuv444p yuv420p \
--g 2 20 None \
@@ -203,9 +203,9 @@ python benchmark/video/run_video_benchmark.py \
--output-dir outputs/video_benchmark \
--repo-ids \
lerobot/pusht_image \
lerobot/aloha_mobile_shrimp_image \
lerobot/paris_street \
lerobot/kitchen \
aliberts/aloha_mobile_shrimp_image \
aliberts/paris_street \
aliberts/kitchen \
--vcodec libx264 libx265 \
--pix-fmt yuv444p yuv420p \
--g 1 2 3 4 5 6 10 15 20 40 None \
@@ -221,9 +221,9 @@ python benchmark/video/run_video_benchmark.py \
--output-dir outputs/video_benchmark \
--repo-ids \
lerobot/pusht_image \
lerobot/aloha_mobile_shrimp_image \
lerobot/paris_street \
lerobot/kitchen \
aliberts/aloha_mobile_shrimp_image \
aliberts/paris_street \
aliberts/kitchen \
--vcodec libsvtav1 \
--pix-fmt yuv420p \
--g 1 2 3 4 5 6 10 15 20 40 None \
@@ -252,37 +252,37 @@ Since we're using av1 encoding, we're choosing the `pyav` decoder as `video_read
These tables show the results for `g=2` and `crf=30`, using `timestamps-modes=6_frames` and `backend=pyav`
| video_images_size_ratio | vcodec | pix_fmt | | | |
| --------------------------------- | ---------- | ------- | --------- | --------- | --------- |
| | libx264 | | libx265 | | libsvtav1 |
| repo_id | yuv420p | yuv444p | yuv420p | yuv444p | yuv420p |
| lerobot/pusht_image | **16.97%** | 17.58% | 18.57% | 18.86% | 22.06% |
| lerobot/aloha_mobile_shrimp_image | 2.14% | 2.11% | 1.38% | **1.37%** | 5.59% |
| lerobot/paris_street | 2.12% | 2.13% | **1.54%** | **1.54%** | 4.43% |
| lerobot/kitchen | 1.40% | 1.39% | **1.00%** | **1.00%** | 2.52% |
| video_images_size_ratio | vcodec | pix_fmt | | | |
| ---------------------------------- | ---------- | ------- | --------- | --------- | --------- |
| | libx264 | | libx265 | | libsvtav1 |
| repo_id | yuv420p | yuv444p | yuv420p | yuv444p | yuv420p |
| lerobot/pusht_image | **16.97%** | 17.58% | 18.57% | 18.86% | 22.06% |
| aliberts/aloha_mobile_shrimp_image | 2.14% | 2.11% | 1.38% | **1.37%** | 5.59% |
| aliberts/paris_street | 2.12% | 2.13% | **1.54%** | **1.54%** | 4.43% |
| aliberts/kitchen | 1.40% | 1.39% | **1.00%** | **1.00%** | 2.52% |
| video_images_load_time_ratio | vcodec | pix_fmt | | | |
| --------------------------------- | ------- | ------- | -------- | ------- | --------- |
| | libx264 | | libx265 | | libsvtav1 |
| repo_id | yuv420p | yuv444p | yuv420p | yuv444p | yuv420p |
| lerobot/pusht_image | 6.45 | 5.19 | **1.90** | 2.12 | 2.47 |
| lerobot/aloha_mobile_shrimp_image | 11.80 | 7.92 | 0.71 | 0.85 | **0.48** |
| lerobot/paris_street | 2.21 | 2.05 | 0.36 | 0.49 | **0.30** |
| lerobot/kitchen | 1.46 | 1.46 | 0.28 | 0.51 | **0.26** |
| video_images_load_time_ratio | vcodec | pix_fmt | | | |
| ---------------------------------- | ------- | ------- | -------- | ------- | --------- |
| | libx264 | | libx265 | | libsvtav1 |
| repo_id | yuv420p | yuv444p | yuv420p | yuv444p | yuv420p |
| lerobot/pusht_image | 6.45 | 5.19 | **1.90** | 2.12 | 2.47 |
| aliberts/aloha_mobile_shrimp_image | 11.80 | 7.92 | 0.71 | 0.85 | **0.48** |
| aliberts/paris_street | 2.21 | 2.05 | 0.36 | 0.49 | **0.30** |
| aliberts/kitchen | 1.46 | 1.46 | 0.28 | 0.51 | **0.26** |
| | | vcodec | pix_fmt | | | |
| --------------------------------- | -------- | -------- | ------------ | -------- | --------- | ------------ |
| | | libx264 | | libx265 | | libsvtav1 |
| repo_id | metric | yuv420p | yuv444p | yuv420p | yuv444p | yuv420p |
| lerobot/pusht_image | avg_mse | 2.90E-04 | **2.03E-04** | 3.13E-04 | 2.29E-04 | 2.19E-04 |
| | avg_psnr | 35.44 | 37.07 | 35.49 | **37.30** | 37.20 |
| | avg_ssim | 98.28% | **98.85%** | 98.31% | 98.84% | 98.72% |
| lerobot/aloha_mobile_shrimp_image | avg_mse | 2.76E-04 | 2.59E-04 | 3.17E-04 | 3.06E-04 | **1.30E-04** |
| | avg_psnr | 35.91 | 36.21 | 35.88 | 36.09 | **40.17** |
| | avg_ssim | 95.19% | 95.18% | 95.00% | 95.05% | **97.73%** |
| lerobot/paris_street | avg_mse | 6.89E-04 | 6.70E-04 | 4.03E-03 | 4.02E-03 | **3.09E-04** |
| | avg_psnr | 33.48 | 33.68 | 32.05 | 32.15 | **35.40** |
| | avg_ssim | 93.76% | 93.75% | 89.46% | 89.46% | **95.46%** |
| lerobot/kitchen | avg_mse | 2.50E-04 | 2.24E-04 | 4.28E-04 | 4.18E-04 | **1.53E-04** |
| | avg_psnr | 36.73 | 37.33 | 36.56 | 36.75 | **39.12** |
| | avg_ssim | 95.47% | 95.58% | 95.52% | 95.53% | **96.82%** |
| | | vcodec | pix_fmt | | | |
| ---------------------------------- | -------- | -------- | ------------ | -------- | --------- | ------------ |
| | | libx264 | | libx265 | | libsvtav1 |
| repo_id | metric | yuv420p | yuv444p | yuv420p | yuv444p | yuv420p |
| lerobot/pusht_image | avg_mse | 2.90E-04 | **2.03E-04** | 3.13E-04 | 2.29E-04 | 2.19E-04 |
| | avg_psnr | 35.44 | 37.07 | 35.49 | **37.30** | 37.20 |
| | avg_ssim | 98.28% | **98.85%** | 98.31% | 98.84% | 98.72% |
| aliberts/aloha_mobile_shrimp_image | avg_mse | 2.76E-04 | 2.59E-04 | 3.17E-04 | 3.06E-04 | **1.30E-04** |
| | avg_psnr | 35.91 | 36.21 | 35.88 | 36.09 | **40.17** |
| | avg_ssim | 95.19% | 95.18% | 95.00% | 95.05% | **97.73%** |
| aliberts/paris_street | avg_mse | 6.89E-04 | 6.70E-04 | 4.03E-03 | 4.02E-03 | **3.09E-04** |
| | avg_psnr | 33.48 | 33.68 | 32.05 | 32.15 | **35.40** |
| | avg_ssim | 93.76% | 93.75% | 89.46% | 89.46% | **95.46%** |
| aliberts/kitchen | avg_mse | 2.50E-04 | 2.24E-04 | 4.28E-04 | 4.18E-04 | **1.53E-04** |
| | avg_psnr | 36.73 | 37.33 | 36.56 | 36.75 | **39.12** |
| | avg_ssim | 95.47% | 95.58% | 95.52% | 95.53% | **96.82%** |
docker/Dockerfile.internal
+2 -4
View File
@@ -24,7 +24,7 @@ ARG OS_VERSION=22.04
FROM nvidia/cuda:${CUDA_VERSION}-base-ubuntu${OS_VERSION}
# Define Python version argument
ARG PYTHON_VERSION=3.12
ARG PYTHON_VERSION=3.10
# Configure environment variables
ENV DEBIAN_FRONTEND=noninteractive \
@@ -73,7 +73,7 @@ ENV HOME=/home/user_lerobot \
RUN uv venv --python python${PYTHON_VERSION}
# Install Python dependencies for caching
COPY --chown=user_lerobot:user_lerobot setup.py pyproject.toml README.md MANIFEST.in ./
COPY --chown=user_lerobot:user_lerobot pyproject.toml README.md MANIFEST.in ./
COPY --chown=user_lerobot:user_lerobot src/ src/
ARG UNBOUND_DEPS=false
@@ -85,8 +85,6 @@ RUN if [ "$UNBOUND_DEPS" = "true" ]; then \
RUN uv pip install --no-cache ".[all]"
RUN chmod +x /lerobot/.venv/lib/python${PYTHON_VERSION}/site-packages/triton/backends/nvidia/bin/ptxas
# Copy the rest of the application source code
# Make sure to have the git-LFS files for testing
COPY --chown=user_lerobot:user_lerobot . .
docker/Dockerfile.user
+2 -2
View File
@@ -19,7 +19,7 @@
# docker run -it --rm lerobot-user
# Configure the base image
ARG PYTHON_VERSION=3.12
ARG PYTHON_VERSION=3.10
FROM python:${PYTHON_VERSION}-slim
# Configure environment variables
@@ -59,7 +59,7 @@ ENV HOME=/home/user_lerobot \
RUN uv venv
# Install Python dependencies for caching
COPY --chown=user_lerobot:user_lerobot setup.py pyproject.toml README.md MANIFEST.in ./
COPY --chown=user_lerobot:user_lerobot pyproject.toml README.md MANIFEST.in ./
COPY --chown=user_lerobot:user_lerobot src/ src/
ARG UNBOUND_DEPS=false
docs/source/_toctree.yml
+2 -36
View File
@@ -7,8 +7,8 @@
- sections:
- local: il_robots
title: Imitation Learning for Robots
- local: bring_your_own_policies
title: Bring Your Own Policies
- local: cameras
title: Cameras
- local: integrate_hardware
title: Bring Your Own Hardware
- local: hilserl
@@ -17,8 +17,6 @@
title: Train RL in Simulation
- local: multi_gpu_training
title: Multi GPU training
- local: peft_training
title: Training with PEFT (e.g., LoRA)
title: "Tutorials"
- sections:
- local: lerobot-dataset-v3
@@ -27,10 +25,6 @@
title: Porting Large Datasets
- local: using_dataset_tools
title: Using the Dataset Tools
- local: dataset_subtask
title: Using Subtasks in the Dataset
- local: streaming_video_encoding
title: Streaming Video Encoding
title: "Datasets"
- sections:
- local: act
@@ -39,21 +33,11 @@
title: SmolVLA
- local: pi0
title: π₀ (Pi0)
- local: pi0fast
title: π₀-FAST (Pi0Fast)
- local: pi05
title: π₀.₅ (Pi05)
- local: groot
title: NVIDIA GR00T N1.5
- local: xvla
title: X-VLA
- local: walloss
title: WALL-OSS
title: "Policies"
- sections:
- local: sarm
title: SARM
title: "Reward Models"
- sections:
- local: async
title: Use Async Inference
@@ -65,8 +49,6 @@
title: Environments from the Hub
- local: envhub_leisaac
title: Control & Train Robots in Sim (LeIsaac)
- local: envhub_isaaclab_arena
title: NVIDIA IsaacLab Arena Environments
- local: libero
title: Using Libero
- local: metaworld
@@ -99,32 +81,16 @@
title: Reachy 2
- local: unitree_g1
title: Unitree G1
- local: earthrover_mini_plus
title: Earth Rover Mini
- local: omx
title: OMX
- local: openarm
title: OpenArm
title: "Robots"
- sections:
- local: phone_teleop
title: Phone
title: "Teleoperators"
- sections:
- local: cameras
title: Cameras
title: "Sensors"
- sections:
- local: torch_accelerators
title: PyTorch accelerators
title: "Supported Hardware"
- sections:
- local: notebooks
title: Notebooks
- local: feetech
title: Updating Feetech Firmware
- local: damiao
title: Damiao Motors and CAN Bus
title: "Resources"
- sections:
- local: contributing
docs/source/act.mdx
-3
View File
@@ -88,8 +88,5 @@ lerobot-record \
--dataset.repo_id=${HF_USER}/eval_act_your_dataset \
--dataset.num_episodes=10 \
--dataset.single_task="Your task description" \
--dataset.streaming_encoding=true \
--dataset.encoder_threads=2 \
# --dataset.vcodec=auto \
--policy.path=${HF_USER}/act_policy
```
docs/source/async.mdx
+4 -5
View File
@@ -48,7 +48,7 @@ python -m lerobot.async_inference.robot_client \
--task="dummy" \ # POLICY: The task to run the policy on (`Fold my t-shirt`). Not necessarily defined for all policies, such as `act`
--policy_type=your_policy_type \ # POLICY: the type of policy to run (smolvla, act, etc)
--pretrained_name_or_path=user/model \ # POLICY: the model name/path on server to the checkpoint to run (e.g., lerobot/smolvla_base)
--policy_device=mps \ # POLICY: the device to run the policy on, on the server (cuda, mps, xpu, cpu)
--policy_device=mps \ # POLICY: the device to run the policy on, on the server
--actions_per_chunk=50 \ # POLICY: the number of actions to output at once
--chunk_size_threshold=0.5 \ # CLIENT: the threshold for the chunk size before sending a new observation to the server
--aggregate_fn_name=weighted_average \ # CLIENT: the function to aggregate actions on overlapping portions
@@ -169,7 +169,7 @@ python -m lerobot.async_inference.robot_client \
<!-- prettier-ignore-start -->
```python
import threading
from lerobot.robots.so_follower import SO100FollowerConfig
from lerobot.robots.so100_follower import SO100FollowerConfig
from lerobot.cameras.opencv.configuration_opencv import OpenCVCameraConfig
from lerobot.async_inference.configs import RobotClientConfig
from lerobot.async_inference.robot_client import RobotClient
@@ -195,7 +195,6 @@ client_cfg = RobotClientConfig(
robot=robot_cfg,
server_address="localhost:8080",
policy_device="mps",
client_device="cpu",
policy_type="smolvla",
pretrained_name_or_path="<user>/smolvla_async",
chunk_size_threshold=0.5,
@@ -279,7 +278,7 @@ We found the default values of `actions_per_chunk` and `chunk_size_threshold` to
2. **Adjust your `fps` based on inference latency.** While the server generates a new action chunk, the client is not idle and is stepping through its current action queue. If the two processes happen at fundamentally different speeds, the client might end up with an empty queue. As such, you should reduce your fps if you consistently run out of actions in queue.
3. **Adjust `chunk_size_threshold`**.
- Values closer to `0.0` result in almost sequential behavior. Values closer to `1.0` → send observation every step (more bandwidth, relies on good world-model).
- We found values around 0.5-0.6 to work well. If you want to tweak this, spin up a `RobotClient` setting the `--debug_visualize_queue_size` to `True`. This will plot the action queue size evolution at runtime, and you can use it to find the value of `chunk_size_threshold` that works best for your setup.
- We found values around 0.5-0.6 to work well. If you want to tweak this, spin up a `RobotClient` setting the `--debug-visualize-queue-size` to `True`. This will plot the action queue size evolution at runtime, and you can use it to find the value of `chunk_size_threshold` that works best for your setup.
<p align="center">
<img
@@ -290,7 +289,7 @@ We found the default values of `actions_per_chunk` and `chunk_size_threshold` to
<p align="center">
<i>
The action queue size is plotted at runtime when the
`--debug_visualize_queue_size` flag is passed, for various levels of
`--debug-visualize-queue-size` flag is passed, for various levels of
`chunk_size_threshold` (`g` in the SmolVLA paper).
</i>
</p>
docs/source/bring_your_own_policies.mdx
-175
View File
@@ -1,175 +0,0 @@
# Bring Your Own Policies
This tutorial explains how to integrate your own custom policy implementations into the LeRobot ecosystem, allowing you to leverage all LeRobot tools for training, evaluation, and deployment while using your own algorithms.
## Step 1: Create a Policy Package
Your custom policy should be organized as an installable Python package following LeRobot's plugin conventions.
### Package Structure
Create a package with the prefix `lerobot_policy_` (IMPORTANT!) followed by your policy name:
```bash
lerobot_policy_my_custom_policy/
├── pyproject.toml
└── src/
└── lerobot_policy_my_custom_policy/
├── __init__.py
├── configuration_my_custom_policy.py
├── modeling_my_custom_policy.py
└── processor_my_custom_policy.py
```
### Package Configuration
Set up your `pyproject.toml`:
```toml
[project]
name = "lerobot_policy_my_custom_policy"
version = "0.1.0"
dependencies = [
# your policy-specific dependencies
]
requires-python = ">= 3.12"
[build-system]
build-backend = # your-build-backend
requires = # your-build-system
```
## Step 2: Define the Policy Configuration
Create a configuration class that inherits from `PreTrainedConfig` and registers your policy type:
```python
# configuration_my_custom_policy.py
from dataclasses import dataclass, field
from lerobot.configs.policies import PreTrainedConfig
from lerobot.configs.types import NormalizationMode
@PreTrainedConfig.register_subclass("my_custom_policy")
@dataclass
class MyCustomPolicyConfig(PreTrainedConfig):
"""Configuration class for MyCustomPolicy.
Args:
n_obs_steps: Number of observation steps to use as input
horizon: Action prediction horizon
n_action_steps: Number of action steps to execute
hidden_dim: Hidden dimension for the policy network
# Add your policy-specific parameters here
"""
# ...PreTrainedConfig fields...
pass
def __post_init__(self):
super().__post_init__()
# Add any validation logic here
def validate_features(self) -> None:
"""Validate input/output feature compatibility."""
# Implement validation logic for your policy's requirements
pass
```
## Step 3: Implement the Policy Class
Create your policy implementation by inheriting from LeRobot's base `PreTrainedPolicy` class:
```python
# modeling_my_custom_policy.py
import torch
import torch.nn as nn
from typing import Any
from lerobot.policies.pretrained import PreTrainedPolicy
from .configuration_my_custom_policy import MyCustomPolicyConfig
class MyCustomPolicy(PreTrainedPolicy):
config_class = MyCustomPolicyConfig
name = "my_custom_policy"
def __init__(self, config: MyCustomPolicyConfig, dataset_stats: dict[str, Any] = None):
super().__init__(config, dataset_stats)
...
```
## Step 4: Add Data Processors
Create processor functions:
```python
# processor_my_custom_policy.py
from typing import Any
import torch
def make_my_custom_policy_pre_post_processors(
config,
) -> tuple[
PolicyProcessorPipeline[dict[str, Any], dict[str, Any]],
PolicyProcessorPipeline[PolicyAction, PolicyAction],
]:
"""Create preprocessing and postprocessing functions for your policy."""
pass # Define your preprocessing and postprocessing logic here
```
## Step 5: Package Initialization
Expose your classes in the package's `__init__.py`:
```python
# __init__.py
"""Custom policy package for LeRobot."""
try:
import lerobot # noqa: F401
except ImportError:
raise ImportError(
"lerobot is not installed. Please install lerobot to use this policy package."
)
from .configuration_my_custom_policy import MyCustomPolicyConfig
from .modeling_my_custom_policy import MyCustomPolicy
from .processor_my_custom_policy import make_my_custom_policy_pre_post_processors
__all__ = [
"MyCustomPolicyConfig",
"MyCustomPolicy",
"make_my_custom_policy_pre_post_processors",
]
```
## Step 6: Installation and Usage
### Install Your Policy Package
```bash
cd lerobot_policy_my_custom_policy
pip install -e .
# Or install from PyPI if published
pip install lerobot_policy_my_custom_policy
```
### Use Your Policy
Once installed, your policy automatically integrates with LeRobot's training and evaluation tools:
```bash
lerobot-train \
--policy.type my_custom_policy \
--env.type pusht \
--steps 200000
```
## Examples and Community Contributions
Check out these example policy implementations:
- [DiTFlow Policy](https://github.com/danielsanjosepro/lerobot_policy_ditflow) - Diffusion Transformer policy with flow-matching objective. Try it out in this example: [DiTFlow Example](https://github.com/danielsanjosepro/test_lerobot_policy_ditflow)
Share your policy implementations with the community! 🤗
docs/source/cameras.mdx
+81 -95
View File
@@ -1,22 +1,12 @@
# Cameras
LeRobot offers multiple options for video capture:
LeRobot offers multiple options for video capture, including phone cameras, built-in laptop cameras, external webcams, and Intel RealSense cameras. To efficiently record frames from most cameras, you can use either the `OpenCVCamera` or `RealSenseCamera` class. For additional compatibility details on the `OpenCVCamera` class, refer to the [Video I/O with OpenCV Overview](https://docs.opencv.org/4.x/d0/da7/videoio_overview.html).
| Class | Supported Cameras |
| ----------------- | ----------------------------------- |
| `OpenCVCamera` | Phone, built-in laptop, USB webcams |
| `ZMQCamera` | Network-connected cameras |
| `RealSenseCamera` | Intel RealSense (with depth) |
| `Reachy2Camera` | Reachy 2 robot cameras |
### Finding your camera
> [!TIP]
> For `OpenCVCamera` compatibility details, see the [Video I/O with OpenCV Overview](https://docs.opencv.org/4.x/d0/da7/videoio_overview.html).
To instantiate a camera, you need a camera identifier. This identifier might change if you reboot your computer or re-plug your camera, a behavior mostly dependant on your operating system.
### Find your camera
Every camera requires a unique identifier to be instantiated, allowing you to distinguish between multiple connected devices.
`OpenCVCamera` and `RealSenseCamera` support auto-discovery. Run the command below to list available devices and their identifiers. Note that these identifiers may change after rebooting your computer or re-plugging the camera, depending on your operating system.
To find the camera indices of the cameras plugged into your system, run the following script:
```bash
lerobot-find-cameras opencv # or realsense for Intel Realsense cameras
@@ -24,7 +14,7 @@ lerobot-find-cameras opencv # or realsense for Intel Realsense cameras
The output will look something like this if you have two cameras connected:
```bash
```
--- Detected Cameras ---
Camera #0:
Name: OpenCV Camera @ 0
@@ -43,37 +33,13 @@ Camera #0:
> [!WARNING]
> When using Intel RealSense cameras in `macOS`, you could get this [error](https://github.com/IntelRealSense/librealsense/issues/12307): `Error finding RealSense cameras: failed to set power state`, this can be solved by running the same command with `sudo` permissions. Note that using RealSense cameras in `macOS` is unstable.
`ZMQCamera` and `Reachy2Camera` do not support auto-discovery. They must be configured manually by providing their network address and port or robot SDK settings.
## Use Cameras
## Use cameras
Below are two examples, demonstrating how to work with the API.
### Frame access modes
All camera classes implement three access modes for capturing frames:
| Method | Behavior | Blocks? | Best For |
| ------------------------- | ---------------------------------------------------------------------------------------------------------------------------------------------------------- | -------------- | ---------------------------------------- |
| `read()` | Waits for the camera hardware to return a frame. May block for a long time depending on the camera and SDK. | Yes | Simple scripts, sequential capture |
| `async_read(timeout_ms)` | Returns the latest unconsumed frame from background thread. Blocks only if buffer is empty, up to `timeout_ms`. Raises `TimeoutError` if no frame arrives. | With a timeout | Control loops synchronized to camera FPS |
| `read_latest(max_age_ms)` | Peeks at the most recent frame in buffer (may be stale). Raises `TimeoutError` if frame is older than `max_age_ms`. | No | UI visualization, logging, monitoring |
### Usage examples
The following examples show how to use the camera API to configure and capture frames from different camera types.
- **Blocking and non-blocking frame capture** using an OpenCV-based camera
- **Asynchronous frame capture** using an OpenCV-based camera
- **Color and depth capture** using an Intel RealSense camera
> [!WARNING]
> Failing to cleanly disconnect cameras can cause resource leaks. Use the context manager protocol to ensure automatic cleanup:
>
> ```python
> with OpenCVCamera(config) as camera:
> ...
> ```
>
> You can also call `connect()` and `disconnect()` manually, but always use a `finally` block for the latter.
<hfoptions id="shell_restart">
<hfoption id="Open CV Camera">
@@ -94,30 +60,16 @@ config = OpenCVCameraConfig(
)
# Instantiate and connect an `OpenCVCamera`, performing a warm-up read (default).
with OpenCVCamera(config) as camera:
# Read a frame synchronously — blocks until hardware delivers a new frame
frame = camera.read()
print(f"read() call returned frame with shape:", frame.shape)
# Read a frame asynchronously with a timeout — returns the latest unconsumed frame or waits up to timeout_ms for a new one
try:
for i in range(10):
frame = camera.async_read(timeout_ms=200)
print(f"async_read call returned frame {i} with shape:", frame.shape)
except TimeoutError as e:
print(f"No frame received within timeout: {e}")
# Instantly return a frame - returns the most recent frame captured by the camera
try:
initial_frame = camera.read_latest(max_age_ms=1000)
for i in range(10):
frame = camera.read_latest(max_age_ms=1000)
print(f"read_latest call returned frame {i} with shape:", frame.shape)
print(f"Was a new frame received by the camera? {not (initial_frame == frame).any()}")
except TimeoutError as e:
print(f"Frame too old: {e}")
camera = OpenCVCamera(config)
camera.connect()
# Read frames asynchronously in a loop via `async_read(timeout_ms)`
try:
for i in range(10):
frame = camera.async_read(timeout_ms=200)
print(f"Async frame {i} shape:", frame.shape)
finally:
camera.disconnect()
```
<!-- prettier-ignore-end -->
@@ -159,10 +111,10 @@ finally:
</hfoption>
</hfoptions>
## Use your phone's camera
## Use your phone
<hfoptions id="use phone">
<hfoption id="iPhone & macOS">
<hfoption id="Mac">
To use your iPhone as a camera on macOS, enable the Continuity Camera feature:
@@ -172,49 +124,83 @@ To use your iPhone as a camera on macOS, enable the Continuity Camera feature:
For more details, visit [Apple support](https://support.apple.com/en-gb/guide/mac-help/mchl77879b8a/mac).
Your iPhone should be detected automatically when running the camera setup script in the next section.
</hfoption>
<hfoption id="OBS virtual camera">
<hfoption id="Linux">
If you want to use your phone as a camera using OBS, follow these steps to set up a virtual camera.
If you want to use your phone as a camera on Linux, follow these steps to set up a virtual camera
1. _(Linux only) Install `v4l2loopback-dkms` and `v4l-utils`_. These packages create virtual camera devices and verify their settings. Install with:
1. _Install `v4l2loopback-dkms` and `v4l-utils`_. Those packages are required to create virtual camera devices (`v4l2loopback`) and verify their settings with the `v4l2-ctl` utility from `v4l-utils`. Install them using:
```bash
<!-- prettier-ignore-start -->
```python
sudo apt install v4l2loopback-dkms v4l-utils
```
<!-- prettier-ignore-end -->
2. _Install the [DroidCam app](https://droidcam.app) on your phone_. This app is available for both iOS and Android.
3. _Download and install [OBS Studio](https://obsproject.com)_.
4. _Download and install the [DroidCam OBS plugin](https://droidcam.app/obs)_.
5. _Start OBS Studio_.
2. _Install [DroidCam](https://droidcam.app) on your phone_. This app is available for both iOS and Android.
3. _Install [OBS Studio](https://obsproject.com)_. This software will help you manage the camera feed. Install it using [Flatpak](https://flatpak.org):
6. _Add your phone as a source_. Follow the instructions [here](https://droidcam.app/obs/usage). Be sure to set the resolution to `640x480` to avoid the watermarks.
7. _Adjust resolution settings_. In OBS Studio, go to `File > Settings > Video` or `OBS > Preferences... > Video`. Change the `Base(Canvas) Resolution` and the `Output(Scaled) Resolution` to `640x480` by manually typing it.
<!-- prettier-ignore-start -->
```python
flatpak install flathub com.obsproject.Studio
```
<!-- prettier-ignore-end -->
4. _Install the DroidCam OBS plugin_. This plugin integrates DroidCam with OBS Studio. Install it with:
<!-- prettier-ignore-start -->
```python
flatpak install flathub com.obsproject.Studio.Plugin.DroidCam
```
<!-- prettier-ignore-end -->
5. _Start OBS Studio_. Launch with:
<!-- prettier-ignore-start -->
```python
flatpak run com.obsproject.Studio
```
<!-- prettier-ignore-end -->
6. _Add your phone as a source_. Follow the instructions [here](https://droidcam.app/obs/usage). Be sure to set the resolution to `640x480`.
7. _Adjust resolution settings_. In OBS Studio, go to `File > Settings > Video`. Change the `Base(Canvas) Resolution` and the `Output(Scaled) Resolution` to `640x480` by manually typing it in.
8. _Start virtual camera_. In OBS Studio, follow the instructions [here](https://obsproject.com/kb/virtual-camera-guide).
9. _Verify the virtual camera setup and resolution_.
- **Linux**: Use `v4l2-ctl` to list devices and check resolution:
```bash
v4l2-ctl --list-devices # find VirtualCam and note its /dev/videoX path
v4l2-ctl -d /dev/videoX --get-fmt-video # replace with your VirtualCam path
```
You should see `VirtualCam` listed and resolution `640x480`.
- **macOS**: Open Photo Booth or FaceTime and select "OBS Virtual Camera" as the input.
- **Windows**: The native Camera app doesn't support virtual cameras. Use a video conferencing app (Zoom, Teams) or run `lerobot-find-cameras opencv` directly to verify.
9. _Verify the virtual camera setup_. Use `v4l2-ctl` to list the devices:
<details>
<summary><strong>Troubleshooting</strong></summary>
<!-- prettier-ignore-start -->
```python
v4l2-ctl --list-devices
```
<!-- prettier-ignore-end -->
> The virtual camera resolution is incorrect.
You should see an entry like:
Delete the virtual camera source and recreate it. The resolution cannot be changed after creation.
```
VirtualCam (platform:v4l2loopback-000):
/dev/video1
```
> Error reading frame in background thread for OpenCVCamera(X): OpenCVCamera(X) frame width=640 or height=480 do not match configured width=1920 or height=1080.
10. _Check the camera resolution_. Use `v4l2-ctl` to ensure that the virtual camera output resolution is `640x480`. Change `/dev/video1` to the port of your virtual camera from the output of `v4l2-ctl --list-devices`.
This error is caused by OBS Virtual Camera advertising a `1920x1080` resolution despite rescaling. The only fix for now is to comment out the width and height check in `_postprocess_image()`.
<!-- prettier-ignore-start -->
```python
v4l2-ctl -d /dev/video1 --get-fmt-video
```
<!-- prettier-ignore-end -->
</details>
You should see an entry like:
```
>>> Format Video Capture:
>>> Width/Height : 640/480
>>> Pixel Format : 'YUYV' (YUYV 4:2:2)
```
Troubleshooting: If the resolution is not correct you will have to delete the Virtual Camera port and try again as it cannot be changed.
If everything is set up correctly, you can proceed with the rest of the tutorial.
</hfoption>
</hfoptions>
If everything is set up correctly, your phone will appear as a standard OpenCV camera and can be used with `OpenCVCamera`.
docs/source/damiao.mdx
-165
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@@ -1,165 +0,0 @@
# Damiao Motors and CAN Bus
This guide covers setup and usage of Damiao motors with LeRobot via CAN bus communication.
Currently, only Linux is supported, as the OpenArms CAN adapter only has drivers for Linux.
## Linux CAN Setup
Before using Damiao motors, you need to set up the CAN interface on your Linux system.
### Install CAN Utilities
```bash
sudo apt-get install can-utils
```
### Configure CAN Interface (Manual)
For standard CAN FD (recommended for OpenArms):
```bash
sudo ip link set can0 down
sudo ip link set can0 type can bitrate 1000000 dbitrate 5000000 fd on
sudo ip link set can0 up
```
For standard CAN (without FD):
```bash
sudo ip link set can0 down
sudo ip link set can0 type can bitrate 1000000
sudo ip link set can0 up
```
### Configure CAN Interface (Using LeRobot)
LeRobot provides a utility script to setup and test CAN interfaces:
```bash
# Setup multiple interfaces (e.g., OpenArms Followers with 2 CAN buses)
lerobot-setup-can --mode=setup --interfaces=can0,can1
```
## Debugging CAN Communication
Use the built-in debug tools to test motor communication:
```bash
# Test motors on all interfaces
lerobot-setup-can --mode=test --interfaces=can0,can1
# Run speed/latency test
lerobot-setup-can --mode=speed --interfaces=can0
```
The test mode will scan for motors (IDs 0x01-0x08) and report which ones respond. Example output:
```
can0: UP (CAN FD)
Motor 0x01 (joint_1): ✓ FOUND
→ Response 0x11 [FD]: 00112233...
Motor 0x02 (joint_2): ✓ FOUND
Motor 0x03 (joint_3): ✗ No response
...
Summary: 2/8 motors found
```
## Usage
### Basic Setup
```python
from lerobot.motors import Motor
from lerobot.motors.damiao import DamiaoMotorsBus
# Define your motors with send/receive CAN IDs
motors = {
"joint_1": Motor(id=0x01, motor_type_str="dm8009", recv_id=0x11),
"joint_2": Motor(id=0x02, motor_type_str="dm4340", recv_id=0x12),
"joint_3": Motor(id=0x03, motor_type_str="dm4310", recv_id=0x13),
}
# Create the bus
bus = DamiaoMotorsBus(
port="can0", # Linux socketcan interface
motors=motors,
)
# Connect
bus.connect()
```
### Reading Motor States
```python
# Read single motor position (degrees)
position = bus.read("Present_Position", "joint_1")
# Read from multiple motors
positions = bus.sync_read("Present_Position") # All motors
positions = bus.sync_read("Present_Position", ["joint_1", "joint_2"])
# Read all states at once (position, velocity, torque)
states = bus.sync_read_all_states()
# Returns: {'joint_1': {'position': 45.2, 'velocity': 1.3, 'torque': 0.5}, ...}
```
### Writing Motor Commands
```python
# Enable torque
bus.enable_torque()
# Set goal position (degrees)
bus.write("Goal_Position", "joint_1", 45.0)
# Set positions for multiple motors
bus.sync_write("Goal_Position", {
"joint_1": 45.0,
"joint_2": -30.0,
"joint_3": 90.0,
})
# Disable torque
bus.disable_torque()
```
## Configuration Options
| Parameter | Default | Description |
| -------------- | --------- | ----------------------------------------------------------- |
| `port` | - | CAN interface (`can0`) or serial port (`/dev/cu.usbmodem*`) |
| `use_can_fd` | `True` | Enable CAN FD for higher data rates |
| `bitrate` | `1000000` | Nominal bitrate (1 Mbps) |
| `data_bitrate` | `5000000` | CAN FD data bitrate (5 Mbps) |
## Motor Configuration
Each motor requires:
- `id`: CAN ID for sending commands
- `motor_type`: One of the supported motor types (e.g., `"dm8009"`, `"dm4340"`)
- `recv_id`: CAN ID for receiving responses
OpenArms default IDs follow the pattern: send ID `0x0N`, receive ID `0x1N` where N is the joint number.
## Troubleshooting
### No Response from Motors
1. **Check power**
2. **Verify CAN wiring**: Check CAN-H, CAN-L, and GND connections
3. **Check motor IDs**: Use Damiao Debugging Tools to verify/configure IDs
4. **Test CAN interface**: Run `candump can0` to see if messages are being received
5. **Run diagnostics**: `lerobot-setup-can --mode=test --interfaces=can0`
### Motor Timeout Parameter
If motors were configured with timeout=0, they won't respond to commands. Use Damiao Debugging Tools to set a non-zero timeout value.
### Verify CAN FD Status
```bash
ip -d link show can0 | grep fd
```
docs/source/dataset_subtask.mdx
-278
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@@ -1,278 +0,0 @@
# Using Subtasks in LeRobot Datasets
Subtask support in robotics datasets has proven effective in improving robot reasoning and understanding. Subtasks are particularly useful for:
- **Hierarchical policies**: Building policies that include subtask predictions to visualize robot reasoning in real time
- **Reward modeling**: Helping reward models understand task progression (e.g., SARM-style stage-aware reward models)
- **Task decomposition**: Breaking down complex manipulation tasks into atomic, interpretable steps
LeRobotDataset now supports subtasks as part of its dataset structure, alongside tasks.
## What are Subtasks?
While a **task** describes the overall goal (e.g., "Pick up the apple and place it in the basket"), **subtasks** break down the execution into finer-grained steps:
1. "Approach the apple"
2. "Grasp the apple"
3. "Lift the apple"
4. "Move to basket"
5. "Release the apple"
Each frame in the dataset can be annotated with its corresponding subtask, enabling models to learn and predict these intermediate stages.
<img
src="https://huggingface.co/datasets/huggingface/documentation-images/resolve/main/lerobot/subtask-asset.png"
alt="An overview of subtask annotation showing how frames are labeled with intermediate subtask stages"
width="80%"
/>
<p>
<em>Figure: Overview of subtask annotation.</em>
</p>
**Reference:** _Subtask-learning based for robot self-assembly in flexible collaborative assembly in manufacturing_, Original Article, Published: 19 April 2022.
## Dataset Structure
Subtask information is stored in the dataset metadata:
```
my-dataset/
├── data/
│ └── ...
├── meta/
│ ├── info.json
│ ├── stats.json
│ ├── tasks.parquet
│ ├── subtasks.parquet # Subtask index → subtask string mapping
│ └── episodes/
│ └── ...
└── videos/
└── ...
```
### Subtasks Parquet File
The `meta/subtasks.parquet` file maps subtask indices to their natural language descriptions:
| subtask_index | subtask (index column) |
| ------------- | ---------------------- |
| 0 | "Approach the apple" |
| 1 | "Grasp the apple" |
| 2 | "Lift the apple" |
| ... | ... |
### Frame-Level Annotations
Each frame in the dataset can include a `subtask_index` field that references the subtasks parquet file:
```python
# Example frame data in the parquet file
{
"index": 42,
"timestamp": 1.4,
"episode_index": 0,
"task_index": 0,
"subtask_index": 2, # References "Lift the apple"
"observation.state": [...],
"action": [...],
}
```
## Annotating Datasets with Subtasks
We provide a HuggingFace Space for easily annotating any LeRobotDataset with subtasks:
**[https://huggingface.co/spaces/lerobot/annotate](https://huggingface.co/spaces/lerobot/annotate)**
After completing your annotation:
1. Click "Push to Hub" to upload your annotated dataset
2. You can also run the annotation space locally by following the instructions at [github.com/huggingface/lerobot-annotate](https://github.com/huggingface/lerobot-annotate)
## Loading Datasets with Subtasks
When you load a dataset with subtask annotations, the subtask information is automatically available:
```python
from lerobot.datasets.lerobot_dataset import LeRobotDataset
# Load a dataset with subtask annotations
dataset = LeRobotDataset("jadechoghari/collect-fruit-annotated")
# Access a sample
sample = dataset[100]
# The sample includes both task and subtask information
print(sample["task"]) # "Collect the fruit"
print(sample["subtask"]) # "Grasp the apple"
print(sample["task_index"]) # tensor(0)
print(sample["subtask_index"]) # tensor(2)
```
### Checking for Subtask Support
You can check if a dataset has subtask annotations:
```python
# Check if subtasks are available
has_subtasks = (
"subtask_index" in dataset.features
and dataset.meta.subtasks is not None
)
if has_subtasks:
print(f"Dataset has {len(dataset.meta.subtasks)} unique subtasks")
print("Subtasks:", list(dataset.meta.subtasks.index))
```
## Using Subtasks for Training
### With the Tokenizer Processor
The `TokenizerProcessor` automatically handles subtask tokenization for Vision-Language Action (VLA) models:
```python
from lerobot.processor.tokenizer_processor import TokenizerProcessor
from lerobot.processor.pipeline import ProcessorPipeline
# Create a tokenizer processor
tokenizer_processor = TokenizerProcessor(
tokenizer_name_or_path="google/paligemma-3b-pt-224",
padding="max_length",
max_length=64,
)
# The processor will automatically tokenize subtasks if present in the batch
# and add them to the observation under:
# - "observation.subtask.tokens"
# - "observation.subtask.attention_mask"
```
When subtasks are available in the batch, the tokenizer processor adds:
- `observation.subtask.tokens`: Tokenized subtask text
- `observation.subtask.attention_mask`: Attention mask for the subtask tokens
### DataLoader with Subtasks
```python
import torch
from lerobot.datasets.lerobot_dataset import LeRobotDataset
dataset = LeRobotDataset("jadechoghari/collect-fruit-annotated")
dataloader = torch.utils.data.DataLoader(
dataset,
batch_size=16,
shuffle=True,
)
for batch in dataloader:
# Access subtask information in the batch
subtasks = batch["subtask"] # List of subtask strings
subtask_indices = batch["subtask_index"] # Tensor of subtask indices
# Use for training hierarchical policies or reward models
print(f"Batch subtasks: {set(subtasks)}")
```
## Example Datasets with Subtask Annotations
Try loading a dataset with subtask annotations:
```python
from lerobot.datasets.lerobot_dataset import LeRobotDataset
# Example dataset with subtask annotations
dataset = LeRobotDataset("jadechoghari/collect-fruit-annotated")
# Explore the subtasks
print("Available subtasks:")
for subtask_name in dataset.meta.subtasks.index:
print(f" - {subtask_name}")
# Get subtask distribution
subtask_counts = {}
for i in range(len(dataset)):
sample = dataset[i]
subtask = sample["subtask"]
subtask_counts[subtask] = subtask_counts.get(subtask, 0) + 1
print("\nSubtask distribution:")
for subtask, count in sorted(subtask_counts.items(), key=lambda x: -x[1]):
print(f" {subtask}: {count} frames")
```
## Use Cases
### 1. Hierarchical Policy Training
Train policies that predict both actions and current subtask:
```python
class HierarchicalPolicy(nn.Module):
def __init__(self, num_subtasks):
super().__init__()
self.action_head = nn.Linear(hidden_dim, action_dim)
self.subtask_head = nn.Linear(hidden_dim, num_subtasks)
def forward(self, observations):
features = self.encoder(observations)
actions = self.action_head(features)
subtask_logits = self.subtask_head(features)
return actions, subtask_logits
```
### 2. Stage-Aware Reward Modeling (SARM)
Build reward models that understand task progression:
```python
# SARM predicts:
# - Stage: Which subtask is being executed (discrete)
# - Progress: How far along the subtask (continuous 0-1)
class SARMRewardModel(nn.Module):
def forward(self, observations):
features = self.encoder(observations)
stage_logits = self.stage_classifier(features)
progress = self.progress_regressor(features)
return stage_logits, progress
```
### 3. Progress Visualization
Monitor robot execution by tracking subtask progression:
```python
def visualize_execution(model, observations):
for t, obs in enumerate(observations):
action, subtask_logits = model(obs)
predicted_subtask = subtask_names[subtask_logits.argmax()]
print(f"t={t}: Executing '{predicted_subtask}'")
```
## API Reference
### LeRobotDataset Properties
| Property | Type | Description |
| --------------------------- | ---------------------- | ------------------------------------------ |
| `meta.subtasks` | `pd.DataFrame \| None` | DataFrame mapping subtask names to indices |
| `features["subtask_index"]` | `dict` | Feature spec for subtask_index if present |
### Sample Keys
When subtasks are available, each sample includes:
| Key | Type | Description |
| --------------- | -------------- | ------------------------------------ |
| `subtask_index` | `torch.Tensor` | Integer index of the current subtask |
| `subtask` | `str` | Natural language subtask description |
## Related Resources
- [SARM Paper](https://arxiv.org/pdf/2509.25358) - Stage-Aware Reward Modeling for Long Horizon Robot Manipulation
- [LeRobot Annotate Space](https://huggingface.co/spaces/lerobot/annotate) - Interactive annotation tool
- [LeRobotDataset v3.0](./lerobot-dataset-v3) - Dataset format documentation
docs/source/earthrover_mini_plus.mdx
-234
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@@ -1,234 +0,0 @@
# EarthRover Mini Plus
<img
src="https://huggingface.co/datasets/huggingface/documentation-images/resolve/main/lerobot/Earth_Rover_Mini_5_240c9adc-4f9e-44b7-982f-5d1dc24af1d8.png.webp"
alt="EarthRover Mini Plus"
width="70%"
/>
The EarthRover Mini Plus is a fully open source mobile robot that connects through the cloud using the Frodobots SDK. This lets you control the robot and record datasets for training AI models.
## What You Need
### Hardware
- EarthRover Mini robot
- Computer with Python 3.12 or newer
- Internet connection
### Setting Up the Frodobots SDK
The robot needs the [Frodobots SDK](https://github.com/frodobots-org/earth-rovers-sdk) running on your computer. Here's how:
1. Download and install the SDK:
```bash
git clone https://github.com/frodobots-org/earth-rovers-sdk.git
cd earth-rovers-sdk
pip install -r requirements.txt
```
2. Save Credentials:
Write your .env variables with the SDK API key and bot name provided by the Frodobots team.
```bash
SDK_API_TOKEN=your_sdk_api_token_here
BOT_SLUG=your_bot_slug_here
CHROME_EXECUTABLE_PATH=/path/to/chrome_or_chromium
# Default value is MAP_ZOOM_LEVEL=18 https://wiki.openstreetmap.org/wiki/Zoom_levels
MAP_ZOOM_LEVEL=18
MISSION_SLUG=your_mission_slug_here
# Image quality between 0.1 and 1.0 (default: 0.8)
# Recommended: 0.8 for better performance
IMAGE_QUALITY=0.8
# Image format: jpeg, png or webp (default: png)
# Recommended: jpeg for better performance and lower bandwidth usage
IMAGE_FORMAT=jpeg
```
3. Start the SDK:
```bash
hypercorn main:app --reload
```
4. Open your web browser and go to `http://localhost:8000`, then click "Join"
The SDK gives you:
- Live video from front and rear cameras
> [!IMPORTANT]
> The SDK must be running before you can use the robot.
## Install LeRobot
Follow our [Installation Guide](./installation) to install LeRobot.
In addition to the base installation, install the EarthRover Mini dependencies:
```bash
pip install -e .
```
## How It Works
The robot uses the internet to communicate:
- **Movement commands**: Sent through the SDK
- **Camera video**: Received from the SDK
- **Robot info**: Battery, location, speed from the SDK
You don't need to plug anything in - it all works through the SDK.
## Calibration
No calibration needed! The robot is ready to use as soon as the SDK is running.
## Controlling the Robot
You control the robot using your keyboard - just like playing a video game with WASD keys.
### Keyboard Controls
| Key | Action |
| --- | -------------------------------- |
| W | Move forward |
| S | Move backward |
| A | Turn left (with forward motion) |
| D | Turn right (with forward motion) |
| Q | Rotate left in place |
| E | Rotate right in place |
| X | Stop all movement |
| +/= | Increase speed |
| - | Decrease speed |
| ESC | Disconnect |
### Speed Settings
You can adjust how fast the robot moves:
- **Forward/backward speed**: Default is full speed (1.0)
- **Turning speed**: Default is full speed (1.0)
- **Speed changes**: Use +/- keys to adjust by 0.1 each time
### Try It Out
Test driving the robot before recording data:
```python
from lerobot.robots.earthrover_mini_plus import EarthRoverMiniPlus, EarthRoverMiniPlusConfig
from lerobot.teleoperators.keyboard import KeyboardRoverTeleop, KeyboardRoverTeleopConfig
# Initialize robot
robot_config = EarthRoverMiniPlusConfig()
robot = EarthRoverMiniPlus(robot_config)
# Initialize teleoperator
teleop_config = KeyboardRoverTeleopConfig(
linear_speed=1.0,
angular_speed=1.0,
speed_increment=0.1
)
teleop = KeyboardRoverTeleop(teleop_config)
# Connect
robot.connect()
teleop.connect()
# Teleoperate (use keyboard controls)
try:
while True:
action = teleop.get_action()
robot.send_action(action)
except KeyboardInterrupt:
pass
finally:
robot.disconnect()
teleop.disconnect()
```
> [!TIP]
> If you're using a Mac, you might need to give Terminal permission to access your keyboard for teleoperation. Go to System Preferences > Security & Privacy > Input Monitoring and check the box for Terminal.
## Recording Data
Once you can drive the robot well, you can start recording data to train AI models. The system records:
- **What you do**: How you move the robot (forward, backward, turning)
- **What the robot sees**:
- Videos from both cameras
- Robot speed and direction
- Battery level and location
- GPS position and signal
- Other sensor data
- **When it happened**: Timestamps for everything
### Setting Up Hugging Face
We use Hugging Face to store your data online. First, log in with your token from [Hugging Face settings](https://huggingface.co/settings/tokens):
```bash
hf auth login --token ${HUGGINGFACE_TOKEN} --add-to-git-credential
```
Store your Hugging Face username:
```bash
HF_USER=$(hf auth whoami | awk -F': *' 'NR==1 {print $2}')
echo $HF_USER
```
### Start Recording
Use the standard recording command:
```bash
lerobot-record \
--robot.type=earthrover_mini_plus \
--teleop.type=keyboard_rover \
--dataset.repo_id=your_username/dataset_name \
--dataset.num_episodes=2 \
--dataset.fps=10 \
--dataset.single_task="Navigate around obstacles" \
--dataset.streaming_encoding=true \
--dataset.encoder_threads=2 \
# --dataset.vcodec=auto \
--display_data=true
```
Replace `your_username/dataset_name` with your Hugging Face username and a name for your dataset.
### What Gets Saved
Your dataset includes:
**Your Actions (2 things)**:
- How much you moved forward/backward
- How much you turned left/right
**Robot Observations (12 things)**:
- Front camera video
- Rear camera video
- Current speed
- Battery level
- Which way the robot is facing
- GPS location (latitude, longitude, signal strength)
- Network signal strength
- Vibration level
- Lamp status (on/off)
### Where Your Data Goes
On your computer: `~/.cache/huggingface/lerobot/{repo-id}`
After recording, your data automatically uploads to your Hugging Face page:
```bash
echo https://huggingface.co/datasets/${HF_USER}/earthrover-navigation
```
Your dataset will be tagged with `LeRobot` for community discovery.
docs/source/envhub.mdx
+19 -26
View File
@@ -2,32 +2,14 @@
The **EnvHub** feature allows you to load simulation environments directly from the Hugging Face Hub with a single line of code. This unlocks a powerful new model for collaboration: instead of environments being locked away inside monolithic libraries, anyone can publish custom environments and share them with the community.
## What is EnvHub?
## Overview
EnvHub lets you create custom robotics simulation environments with your own robot models and scenarios, and make them easily usable by anyone through the LeRobot framework.
With EnvHub, you can:
EnvHub packages are stored on the Hugging Face Hub, and can be seamlessly pulled and used in your AI robotics projects through LeRobot with a single line of code.
Thanks to EnvHub, you can:
1. **Create and publish environments** to the Hugging Face Hub as Git repositories, and distribute complex physics simulations without packaging hassles
2. **Load environments** dynamically, without installing them as packages
3. **Version and track** environment changes using Git semantics
4. **Discover** new simulation tasks shared by the community
This design means you can go from discovering an interesting environment on the Hub to running experiments in seconds, or create your own custom robot and environment without worrying about dependency conflicts or complex installation procedures.
When you create an EnvHub package, you can build anything you want inside it and use any simulation tool you like: this is your own space to play with. The only requirement is that the package contains an `env.py` file that defines the environment and allows LeRobot to load and use your EnvHub package.
This `env.py` file needs to expose a small API so LeRobot can load and run it. In particular, you must provide a `make_env(n_envs: int = 1, use_async_envs: bool = False)` or `make_env(n_envs: int = 1, use_async_envs: bool = False, cfg: EnvConfig)` function, which is the main entry point for LeRobot. It should return one of:
- A `gym.vector.VectorEnv` (most common)
- A single `gym.Env` (will be automatically wrapped)
- A dict mapping `{suite_name: {task_id: VectorEnv}}` (for multi-task benchmarks)
You can also pass an `EnvConfig` object to `make_env` to configure the environment (e.g. the number of environments, task, camera name, initial states, control mode, episode length, etc.).
Finally, your environment must implement the standard `gym.vector.VectorEnv` interface so it works with LeRobot, including methods like `reset` and `step`.
- Load environments from the Hub instantly
- Share your custom simulation tasks with the community
- Version control your environments using Git
- Distribute complex physics simulations without packaging hassles
## Quick Start
@@ -47,6 +29,17 @@ env = make_env("lerobot/cartpole-env", trust_remote_code=True)
hash for reproducibility and security.
</Tip>
## What is EnvHub?
EnvHub is a framework that allows researchers and developers to:
1. **Publish environments** to the Hugging Face Hub as Git repositories
2. **Load environments** dynamically without installing them as packages
3. **Version and track** environment changes using Git semantics
4. **Discover** new simulation tasks shared by the community
This design means you can go from discovering an interesting environment on the Hub to running experiments in seconds, without worrying about dependency conflicts or complex installation procedures.
## Repository Structure
To make your environment loadable from the Hub, your repository must contain at minimum:
@@ -155,10 +148,10 @@ Upload your repository to Hugging Face:
pip install huggingface_hub
# Login to Hugging Face
hf auth login
huggingface-cli login
# Create a new repository
hf repo create my-org/my-custom-env
huggingface-cli repo create my-custom-env --type space --org my-org
# Initialize git and push
git init
docs/source/envhub_isaaclab_arena.mdx
-510
View File
@@ -1,510 +0,0 @@
# NVIDIA IsaacLab Arena & LeRobot
LeRobot EnvHub now supports **GPU-accelerated simulation** with IsaacLab Arena for policy evaluation at scale.
Train and evaluate imitation learning policies with high-fidelity simulation — all integrated into the LeRobot ecosystem.
<img
src="https://huggingface.co/nvidia/isaaclab-arena-envs/resolve/main/assets/Gr1OpenMicrowaveEnvironment.png"
alt="IsaacLab Arena - GR1 Microwave Environment"
style={{ maxWidth: "100%", borderRadius: "8px", marginBottom: "1rem" }}
/>
[IsaacLab Arena](https://github.com/isaac-sim/IsaacLab-Arena) integrates with NVIDIA IsaacLab to provide:
- 🤖 **Humanoid embodiments**: GR1, G1, Galileo with various configurations
- 🎯 **Manipulation & loco-manipulation tasks**: Door opening, pick-and-place, button pressing, and more
- ⚡ **GPU-accelerated rollouts**: Parallel environment execution on NVIDIA GPUs
- 🖼️ **RTX Rendering**: Evaluate vision-based policies with realistic rendering, reflections and refractions
- 📦 **LeRobot-compatible datasets**: Ready for training with GR00T N1x, PI0, SmolVLA, ACT, and Diffusion policies
- 🔄 **EnvHub integration**: Load environments from HuggingFace EnvHub with one line
## Installation
### Prerequisites
Hardware requirements are shared with Isaac Sim, and are detailed in [Isaac Sim Requirements](https://docs.isaacsim.omniverse.nvidia.com/5.1.0/installation/requirements.html).
- NVIDIA GPU with CUDA support
- NVIDIA driver compatible with IsaacSim 5.1.0
- Linux (Ubuntu 22.04 / 24.04)
### Setup
```bash
# 1. Create conda environment
conda create -y -n lerobot-arena python=3.11
conda activate lerobot-arena
conda install -y -c conda-forge ffmpeg=7.1.1
# 2. Install Isaac Sim 5.1.0
pip install "isaacsim[all,extscache]==5.1.0" --extra-index-url https://pypi.nvidia.com
# Accept NVIDIA EULA (required)
export ACCEPT_EULA=Y
export PRIVACY_CONSENT=Y
# 3. Install IsaacLab 2.3.0
git clone https://github.com/isaac-sim/IsaacLab.git
cd IsaacLab
git checkout v2.3.0
./isaaclab.sh -i
cd ..
# 4. Install IsaacLab Arena
git clone https://github.com/isaac-sim/IsaacLab-Arena.git
cd IsaacLab-Arena
git checkout release/0.1.1
pip install -e .
cd ..
# 5. Install LeRobot
git clone https://github.com/huggingface/lerobot.git
cd lerobot
pip install -e .
cd ..
# 6. Install additional dependencies
pip install onnxruntime==1.23.2 lightwheel-sdk==1.0.1 vuer[all]==0.0.70 qpsolvers==4.8.1
pip install numpy==1.26.0 # Isaac Sim 5.1 depends on numpy==1.26.0, this will be fixed in next release
```
## Evaluating Policies
### Pre-trained Policies
The following trained policies are available:
| Policy | Architecture | Task | Link |
| :-------------------------- | :----------- | :------------ | :----------------------------------------------------------------------- |
| pi05-arena-gr1-microwave | PI0.5 | GR1 Microwave | [HuggingFace](https://huggingface.co/nvidia/pi05-arena-gr1-microwave) |
| smolvla-arena-gr1-microwave | SmolVLA | GR1 Microwave | [HuggingFace](https://huggingface.co/nvidia/smolvla-arena-gr1-microwave) |
### Evaluate SmolVLA
```bash
pip install -e ".[smolvla]"
pip install numpy==1.26.0 # revert numpy to version 1.26
```
```bash
lerobot-eval \
--policy.path=nvidia/smolvla-arena-gr1-microwave \
--env.type=isaaclab_arena \
--env.hub_path=nvidia/isaaclab-arena-envs \
--rename_map='{"observation.images.robot_pov_cam_rgb": "observation.images.robot_pov_cam"}' \
--policy.device=cuda \
--env.environment=gr1_microwave \
--env.embodiment=gr1_pink \
--env.object=mustard_bottle \
--env.headless=false \
--env.enable_cameras=true \
--env.video=true \
--env.video_length=10 \
--env.video_interval=15 \
--env.state_keys=robot_joint_pos \
--env.camera_keys=robot_pov_cam_rgb \
--trust_remote_code=True \
--eval.batch_size=1
```
### Evaluate PI0.5
```bash
pip install -e ".[pi]"
pip install numpy==1.26.0 # revert numpy to version 1.26
```
<Tip>PI0.5 requires disabling torch compile for evaluation:</Tip>
```bash
TORCH_COMPILE_DISABLE=1 TORCHINDUCTOR_DISABLE=1 lerobot-eval \
--policy.path=nvidia/pi05-arena-gr1-microwave \
--env.type=isaaclab_arena \
--env.hub_path=nvidia/isaaclab-arena-envs \
--rename_map='{"observation.images.robot_pov_cam_rgb": "observation.images.robot_pov_cam"}' \
--policy.device=cuda \
--env.environment=gr1_microwave \
--env.embodiment=gr1_pink \
--env.object=mustard_bottle \
--env.headless=false \
--env.enable_cameras=true \
--env.video=true \
--env.video_length=15 \
--env.video_interval=15 \
--env.state_keys=robot_joint_pos \
--env.camera_keys=robot_pov_cam_rgb \
--trust_remote_code=True \
--eval.batch_size=1
```
<Tip>
To change the number of parallel environments, use the ```--eval.batch_size```
flag.
</Tip>
### What to Expect
During evaluation, you will see a progress bar showing the running success rate:
```
Stepping through eval batches: 8%|██████▍ | 4/50 [00:45<08:06, 10.58s/it, running_success_rate=25.0%]
```
### Video Recording
To enable video recording during evaluation, add the following flags to your command:
```bash
--env.video=true \
--env.video_length=15 \
--env.video_interval=15
```
For more details on video recording, see the [IsaacLab Recording Documentation](https://isaac-sim.github.io/IsaacLab/main/source/how-to/record_video.html).
<Tip>
When running headless with `--env.headless=true`, you must also enable cameras explicitly for camera enabled environments:
```bash
--env.headless=true --env.enable_cameras=true
```
</Tip>
### Output Directory
Evaluation videos are saved to the output directory with the following structure:
```
outputs/eval/<date>/<timestamp>_<env>_<policy>/videos/<task>_<env_id>/eval_episode_<n>.mp4
```
For example:
```
outputs/eval/2026-01-02/14-38-01_isaaclab_arena_smolvla/videos/gr1_microwave_0/eval_episode_0.mp4
```
## Training Policies
To learn more about training policies with LeRobot, please refer to the training documentation:
- [SmolVLA](./smolvla)
- [Pi0.5](./pi05)
- [GR00T N1.5](./groot)
Sample IsaacLab Arena datasets are available on HuggingFace Hub for experimentation:
| Dataset | Description | Frames |
| :-------------------------------------------------------------------------------------------------------- | :------------------------- | :----- |
| [Arena-GR1-Manipulation-Task](https://huggingface.co/datasets/nvidia/Arena-GR1-Manipulation-Task-v3) | GR1 microwave manipulation | ~4K |
| [Arena-G1-Loco-Manipulation-Task](https://huggingface.co/datasets/nvidia/Arena-G1-Loco-Manipulation-Task) | G1 loco-manipulation | ~4K |
## Environment Configuration
### Full Configuration Options
```python
from lerobot.envs.configs import IsaaclabArenaEnv
config = IsaaclabArenaEnv(
# Environment selection
environment="gr1_microwave", # Task environment
embodiment="gr1_pink", # Robot embodiment
object="power_drill", # Object to manipulate
# Simulation settings
episode_length=300, # Max steps per episode
headless=True, # Run without GUI
device="cuda:0", # GPU device
seed=42, # Random seed
# Observation configuration
state_keys="robot_joint_pos", # State observation keys (comma-separated)
camera_keys="robot_pov_cam_rgb", # Camera observation keys (comma-separated)
state_dim=54, # Expected state dimension
action_dim=36, # Expected action dimension
camera_height=512, # Camera image height
camera_width=512, # Camera image width
enable_cameras=True, # Enable camera observations
# Video recording
video=False, # Enable video recording
video_length=100, # Frames per video
video_interval=200, # Steps between recordings
# Advanced
mimic=False, # Enable mimic mode
teleop_device=None, # Teleoperation device
disable_fabric=False, # Disable fabric optimization
enable_pinocchio=True, # Enable Pinocchio for IK
)
```
### Using Environment Hub directly for advanced usage
Create a file called `test_env_load_arena.py` or [download from the EnvHub](https://huggingface.co/nvidia/isaaclab-arena-envs/blob/main/tests/test_env_load_arena.py):
```python
import logging
from dataclasses import asdict
from pprint import pformat
import torch
import tqdm
from lerobot.configs import parser
from lerobot.configs.eval import EvalPipelineConfig
@parser.wrap()
def main(cfg: EvalPipelineConfig):
"""Run random action rollout for IsaacLab Arena environment."""
logging.info(pformat(asdict(cfg)))
from lerobot.envs.factory import make_env
env_dict = make_env(
cfg.env,
n_envs=cfg.env.num_envs,
trust_remote_code=True,
)
env = next(iter(env_dict.values()))[0]
env.reset()
for _ in tqdm.tqdm(range(cfg.env.episode_length)):
with torch.inference_mode():
actions = env.action_space.sample()
obs, rewards, terminated, truncated, info = env.step(actions)
if terminated.any() or truncated.any():
obs, info = env.reset()
env.close()
if __name__ == "__main__":
main()
```
Run with:
```bash
python test_env_load_arena.py \
--env.environment=g1_locomanip_pnp \
--env.embodiment=gr1_pink \
--env.object=cracker_box \
--env.num_envs=4 \
--env.enable_cameras=true \
--env.seed=1000 \
--env.video=true \
--env.video_length=10 \
--env.video_interval=15 \
--env.headless=false \
--env.hub_path=nvidia/isaaclab-arena-envs \
--env.type=isaaclab_arena
```
## Creating New Environments
First create a new IsaacLab Arena environment by following the [IsaacLab Arena Documentation](https://isaac-sim.github.io/IsaacLab-Arena/release/0.1.1/index.html).
Clone our EnvHub repo:
```bash
git clone https://huggingface.co/nvidia/isaaclab-arena-envs
```
Modify the `example_envs.yaml` file based on your new environment.
[Upload](./envhub#step-3-upload-to-the-hub) your modified repo to HuggingFace EnvHub.
<Tip>
Your IsaacLab Arena environment code must be locally available during
evaluation. Users can clone your environment repository separately, or you can
bundle the environment code and assets directly in your EnvHub repo.
</Tip>
Then, when evaluating, use your new environment:
```bash
lerobot-eval \
--env.hub_path=<your-env-hub-path>/isaaclab-arena-envs \
--env.environment=<your new environment> \
...other flags...
```
We look forward to your contributions!
## Troubleshooting
### CUDA out of memory
Reduce `batch_size` or use a GPU with more VRAM:
```bash
--eval.batch_size=1
```
### EULA not accepted
Set environment variables before running:
```bash
export ACCEPT_EULA=Y
export PRIVACY_CONSENT=Y
```
### Video recording not working
Enable cameras when running headless:
```bash
--env.video=true --env.enable_cameras=true --env.headless=true
```
### Policy output dimension mismatch
Ensure `action_dim` matches your policy:
```bash
--env.action_dim=36
```
### libGLU.so.1 Errors during Isaac Sim initialization
Ensure you have the following dependencies installed, this is likely to happen on headless machines.
```bash
sudo apt update && sudo apt install -y libglu1-mesa libxt6
```
## See Also
- [EnvHub Documentation](./envhub.mdx) - General EnvHub usage
- [IsaacLab Arena GitHub](https://github.com/isaac-sim/IsaacLab-Arena)
- [IsaacLab Documentation](https://isaac-sim.github.io/IsaacLab/)
## Lightwheel LW-BenchHub
[Lightwheel](https://www.lightwheel.ai) is bringing `Lightwheel-Libero-Tasks` and `Lightwheel-RoboCasa-Tasks` with 268 tasks to the LeRobot ecosystem.
LW-BenchHub collects and generates large-scale datasets via teleoperation that comply with the LeRobot specification, enabling out-of-the-box training and evaluation workflows.
With the unified interface provided by EnvHub, developers can quickly build end-to-end experimental pipelines.
### Install
Assuming you followed the [Installation](#installation) steps, you can install LW-BenchHub with:
```bash
conda install pinocchio -c conda-forge -y
pip install numpy==1.26.0 # revert numpy to version 1.26
sudo apt-get install git-lfs && git lfs install
git clone https://github.com/LightwheelAI/lw_benchhub
git lfs pull # Ensure LFS files (e.g., .usd assets) are downloaded
cd lw_benchhub
pip install -e .
```
For more detailed instructions, please refer to the [LW-BenchHub Documentation](https://docs.lightwheel.net/lw_benchhub/usage/Installation).
### Lightwheel Tasks Dataset
LW-BenchHub datasets are available on HuggingFace Hub:
| Dataset | Description | Tasks | Frames |
| :------------------------------------------------------------------------------------------------------------ | :---------------------- | :---- | :----- |
| [Lightwheel-Tasks-X7S](https://huggingface.co/datasets/LightwheelAI/Lightwheel-Tasks-X7S) | X7S LIBERO and RoboCasa | 117 | ~10.3M |
| [Lightwheel-Tasks-Double-Piper](https://huggingface.co/datasets/LightwheelAI/Lightwheel-Tasks-Double-Piper) | Double-Piper LIBERO | 130 | ~6.0M |
| [Lightwheel-Tasks-G1-Controller](https://huggingface.co/datasets/LightwheelAI/Lightwheel-Tasks-G1-Controller) | G1-Controller LIBERO | 62 | ~2.7M |
| [Lightwheel-Tasks-G1-WBC](https://huggingface.co/datasets/LightwheelAI/Lightwheel-Tasks-G1-WBC) | G1-WBC RoboCasa | 32 | ~1.5M |
For training policies, refer to the [Training Policies](#training-policies) section.
### Evaluating Policies
#### Pre-trained Policies
The following trained policies are available:
| Policy | Architecture | Task | Layout | Robot | Link |
| :----------------------- | :----------- | :----------------------------- | :--------- | :-------------- | :------------------------------------------------------------------------------------ |
| smolvla-double-piper-pnp | SmolVLA | L90K1PutTheBlackBowlOnThePlate | libero-1-1 | DoublePiper-Abs | [HuggingFace](https://huggingface.co/LightwheelAI/smolvla-double-piper-pnp/tree/main) |
#### Evaluate SmolVLA
```bash
lerobot-eval \
--policy.path=LightwheelAI/smolvla-double-piper-pnp \
--env.type=isaaclab_arena \
--rename_map='{"observation.images.left_hand_camera_rgb": "observation.images.left_hand", "observation.images.right_hand_camera_rgb": "observation.images.right_hand", "observation.images.first_person_camera_rgb": "observation.images.first_person"}' \
--env.hub_path=LightwheelAI/lw_benchhub_env \
--env.kwargs='{"config_path": "configs/envhub/example.yml"}' \
--trust_remote_code=true \
--env.state_keys=joint_pos \
--env.action_dim=12 \
--env.camera_keys=left_hand_camera_rgb,right_hand_camera_rgb,first_person_camera_rgb \
--policy.device=cuda \
--eval.batch_size=10 \
--eval.n_episodes=100
```
### Environment Configuration
Evaluation can be quickly launched by modifying the `robot`, `task`, and `layout` settings in the configuration file.
#### Full Configuration Options
```yml
# =========================
# Basic Settings
# =========================
disable_fabric: false
device: cuda:0
sensitivity: 1.0
step_hz: 50
enable_cameras: true
execute_mode: eval
episode_length_s: 20.0 # Episode length in seconds, increase if episodes timeout during eval
# =========================
# Robot Settings
# =========================
robot: DoublePiper-Abs # Robot type, DoublePiper-Abs, X7S-Abs, G1-Controller or G1-Controller-DecoupledWBC
robot_scale: 1.0
# =========================
# Task & Scene Settings
# =========================
task: L90K1PutTheBlackBowlOnThePlate # Task name
scene_backend: robocasa
task_backend: robocasa
debug_assets: null
layout: libero-1-1 # Layout and style ID
sources:
- objaverse
- lightwheel
- aigen_objs
object_projects: []
usd_simplify: false
seed: 42
# =========================
# Object Placement Retry Settings
# =========================
max_scene_retry: 4
max_object_placement_retry: 3
resample_objects_placement_on_reset: true
resample_robot_placement_on_reset: true
# =========================
# Replay Configuration Settings
# =========================
replay_cfgs:
add_camera_to_observation: true
render_resolution: [640, 480]
```
### See Also
- [LW-BenchHub GitHub](https://github.com/LightwheelAI/LW-BenchHub)
- [LW-BenchHub Documentation](https://docs.lightwheel.net/lw_benchhub/)
docs/source/envhub_leisaac.mdx
+3 -4
View File
@@ -137,8 +137,7 @@ from lerobot.teleoperators import ( # noqa: F401
Teleoperator,
TeleoperatorConfig,
make_teleoperator_from_config,
so_leader,
bi_so_leader,
so101_leader,
)
from lerobot.utils.robot_utils import precise_sleep
from lerobot.utils.utils import init_logging
@@ -197,7 +196,7 @@ def teleop_loop(teleop: Teleoperator, env: gym.Env, fps: int):
obs, info = env.reset()
dt_s = time.perf_counter() - loop_start
precise_sleep(max(1 / fps - dt_s, 0.0))
precise_sleep(1 / fps - dt_s)
loop_s = time.perf_counter() - loop_start
print(f"\ntime: {loop_s * 1e3:.2f}ms ({1 / loop_s:.0f} Hz)")
@@ -223,7 +222,7 @@ def teleoperate(cfg: TeleoperateConfig):
def main():
teleoperate(TeleoperateConfig(
teleop=so_leader.SO101LeaderConfig(
teleop=so101_leader.SO101LeaderConfig(
port="/dev/ttyACM0",
id='leader',
use_degrees=False,
docs/source/groot.mdx
+4 -13
View File
@@ -12,12 +12,6 @@ Developers and researchers can post-train GR00T N1.5 with their own real or synt
GR00T N1.5 (specifically the GR00T-N1.5-3B model) is built using pre-trained vision and language encoders. It utilizes a flow matching action transformer to model a chunk of actions, conditioned on vision, language, and proprioception.
<img
src="https://huggingface.co/datasets/huggingface/documentation-images/resolve/main/lerobot/lerobot-groot-paper1%20(1).png"
alt="An overview of GR00T"
width="80%"
/>
Its strong performance comes from being trained on an expansive and diverse humanoid dataset, which includes:
- Real captured data from robots.
@@ -109,7 +103,7 @@ Once you have trained your model using your parameters you can run inference in
```bash
lerobot-record \
--robot.type=bi_so_follower \
--robot.type=bi_so100_follower \
--robot.left_arm_port=/dev/ttyACM1 \
--robot.right_arm_port=/dev/ttyACM0 \
--robot.id=bimanual_follower \
@@ -120,12 +114,9 @@ lerobot-record \
--display_data=true \
--dataset.repo_id=<user>/eval_groot-bimanual \
--dataset.num_episodes=10 \
--dataset.single_task="Grab and handover the red cube to the other arm" \
--dataset.streaming_encoding=true \
--dataset.encoder_threads=2 \
# --dataset.vcodec=auto \
--policy.path=<user>/groot-bimanual \ # your trained model
--dataset.episode_time_s=30 \
--dataset.single_task="Grab and handover the red cube to the other arm"
--policy.path=<user>/groot-bimanual # your trained model
--dataset.episode_time_s=30
--dataset.reset_time_s=10
```
docs/source/hope_jr.mdx
+5 -11
View File
@@ -224,15 +224,12 @@ lerobot-record \
--teleop.port=/dev/tty.usbmodem1201 \
--teleop.id=right \
--teleop.side=right \
--dataset.repo_id=<USER>/hand_record_test_with_video_data \
--dataset.repo_id=nepyope/hand_record_test_with_video_data \
--dataset.single_task="Hand recording test with video data" \
--dataset.num_episodes=1 \
--dataset.episode_time_s=5 \
--dataset.push_to_hub=true \
--dataset.private=true \
--dataset.streaming_encoding=true \
--dataset.encoder_threads=2 \
# --dataset.vcodec=auto \
--display_data=true
```
@@ -244,7 +241,7 @@ lerobot-replay \
--robot.port=/dev/tty.usbmodem58760432281 \
--robot.id=right \
--robot.side=right \
--dataset.repo_id=<USER>/hand_record_test_with_camera \
--dataset.repo_id=nepyope/hand_record_test_with_camera \
--dataset.episode=0
```
@@ -252,13 +249,13 @@ lerobot-replay \
```bash
lerobot-train \
--dataset.repo_id=<USER>/hand_record_test_with_video_data \
--dataset.repo_id=nepyope/hand_record_test_with_video_data \
--policy.type=act \
--output_dir=outputs/train/hopejr_hand \
--job_name=hopejr \
--policy.device=mps \
--wandb.enable=true \
--policy.repo_id=<USER>/hand_test_policy
--policy.repo_id=nepyope/hand_test_policy
```
### Evaluate
@@ -273,11 +270,8 @@ lerobot-record \
--robot.side=right \
--robot.cameras='{"main": {"type": "opencv", "index_or_path": 0, "width": 640, "height": 480, "fps": 30}}' \
--display_data=false \
--dataset.repo_id=<USER>/eval_hopejr \
--dataset.repo_id=nepyope/eval_hopejr \
--dataset.single_task="Evaluate hopejr hand policy" \
--dataset.num_episodes=10 \
--dataset.streaming_encoding=true \
--dataset.encoder_threads=2 \
# --dataset.vcodec=auto \
--policy.path=outputs/train/hopejr_hand/checkpoints/last/pretrained_model
```
docs/source/il_robots.mdx
+23 -46
View File
@@ -58,8 +58,8 @@ lerobot-teleoperate \
<!-- prettier-ignore-start -->
```python
from lerobot.teleoperators.so_leader import SO101LeaderConfig, SO101Leader
from lerobot.robots.so_follower import SO101FollowerConfig, SO101Follower
from lerobot.teleoperators.so101_leader import SO101LeaderConfig, SO101Leader
from lerobot.robots.so101_follower import SO101FollowerConfig, SO101Follower
robot_config = SO101FollowerConfig(
port="/dev/tty.usbmodem58760431541",
@@ -159,13 +159,13 @@ We use the Hugging Face hub features for uploading your dataset. If you haven't
Add your token to the CLI by running this command:
```bash
hf auth login --token ${HUGGINGFACE_TOKEN} --add-to-git-credential
huggingface-cli login --token ${HUGGINGFACE_TOKEN} --add-to-git-credential
```
Then store your Hugging Face repository name in a variable:
```bash
HF_USER=$(hf auth whoami | awk -F': *' 'NR==1 {print $2}')
HF_USER=$(hf auth whoami | head -n 1)
echo $HF_USER
```
@@ -185,10 +185,7 @@ lerobot-record \
--display_data=true \
--dataset.repo_id=${HF_USER}/record-test \
--dataset.num_episodes=5 \
--dataset.single_task="Grab the black cube" \
--dataset.streaming_encoding=true \
# --dataset.vcodec=auto \
--dataset.encoder_threads=2
--dataset.single_task="Grab the black cube"
```
</hfoption>
<hfoption id="API example">
@@ -198,14 +195,13 @@ lerobot-record \
from lerobot.cameras.opencv.configuration_opencv import OpenCVCameraConfig
from lerobot.datasets.lerobot_dataset import LeRobotDataset
from lerobot.datasets.utils import hw_to_dataset_features
from lerobot.robots.so_follower import SO100Follower, SO100FollowerConfig
from lerobot.teleoperators.so_leader.config_so100_leader import SO100LeaderConfig
from lerobot.teleoperators.so_leader.so100_leader import SO100Leader
from lerobot.robots.so100_follower import SO100Follower, SO100FollowerConfig
from lerobot.teleoperators.so100_leader.config_so100_leader import SO100LeaderConfig
from lerobot.teleoperators.so100_leader.so100_leader import SO100Leader
from lerobot.utils.control_utils import init_keyboard_listener
from lerobot.utils.utils import log_say
from lerobot.utils.visualization_utils import init_rerun
from lerobot.scripts.lerobot_record import record_loop
from lerobot.processor import make_default_processors
from lerobot.record import record_loop
NUM_EPISODES = 5
FPS = 30
@@ -213,19 +209,12 @@ EPISODE_TIME_SEC = 60
RESET_TIME_SEC = 10
TASK_DESCRIPTION = "My task description"
# Create robot configuration
# Create the robot and teleoperator configurations
camera_config = {"front": OpenCVCameraConfig(index_or_path=0, width=640, height=480, fps=FPS)}
robot_config = SO100FollowerConfig(
id="my_awesome_follower_arm",
cameras={
"front": OpenCVCameraConfig(index_or_path=0, width=640, height=480, fps=FPS) # Optional: fourcc="MJPG" for troubleshooting OpenCV async error.
},
port="/dev/tty.usbmodem58760434471",
)
teleop_config = SO100LeaderConfig(
id="my_awesome_leader_arm",
port="/dev/tty.usbmodem585A0077581",
port="/dev/tty.usbmodem58760434471", id="my_awesome_follower_arm", cameras=camera_config
)
teleop_config = SO100LeaderConfig(port="/dev/tty.usbmodem585A0077581", id="my_awesome_leader_arm")
# Initialize the robot and teleoperator
robot = SO100Follower(robot_config)
@@ -254,9 +243,6 @@ init_rerun(session_name="recording")
robot.connect()
teleop.connect()
# Create the required processors
teleop_action_processor, robot_action_processor, robot_observation_processor = make_default_processors()
episode_idx = 0
while episode_idx < NUM_EPISODES and not events["stop_recording"]:
log_say(f"Recording episode {episode_idx + 1} of {NUM_EPISODES}")
@@ -265,9 +251,6 @@ while episode_idx < NUM_EPISODES and not events["stop_recording"]:
robot=robot,
events=events,
fps=FPS,
teleop_action_processor=teleop_action_processor,
robot_action_processor=robot_action_processor,
robot_observation_processor=robot_observation_processor,
teleop=teleop,
dataset=dataset,
control_time_s=EPISODE_TIME_SEC,
@@ -282,9 +265,6 @@ while episode_idx < NUM_EPISODES and not events["stop_recording"]:
robot=robot,
events=events,
fps=FPS,
teleop_action_processor=teleop_action_processor,
robot_action_processor=robot_action_processor,
robot_observation_processor=robot_observation_processor,
teleop=teleop,
control_time_s=RESET_TIME_SEC,
single_task=TASK_DESCRIPTION,
@@ -327,7 +307,7 @@ You can look for other LeRobot datasets on the hub by searching for `LeRobot` [t
You can also push your local dataset to the Hub manually, running:
```bash
hf upload ${HF_USER}/record-test ~/.cache/huggingface/lerobot/{repo-id} --repo-type dataset
huggingface-cli upload ${HF_USER}/record-test ~/.cache/huggingface/lerobot/{repo-id} --repo-type dataset
```
#### Record function
@@ -411,8 +391,8 @@ lerobot-replay \
import time
from lerobot.datasets.lerobot_dataset import LeRobotDataset
from lerobot.robots.so_follower.config_so100_follower import SO100FollowerConfig
from lerobot.robots.so_follower.so100_follower import SO100Follower
from lerobot.robots.so100_follower.config_so100_follower import SO100FollowerConfig
from lerobot.robots.so100_follower.so100_follower import SO100Follower
from lerobot.utils.robot_utils import precise_sleep
from lerobot.utils.utils import log_say
@@ -435,7 +415,7 @@ for idx in range(dataset.num_frames):
}
robot.send_action(action)
precise_sleep(max(1.0 / dataset.fps - (time.perf_counter() - t0), 0.0))
precise_sleep(1.0 / dataset.fps - (time.perf_counter() - t0))
robot.disconnect()
```
@@ -448,7 +428,7 @@ Your robot should replicate movements similar to those you recorded. For example
## Train a policy
To train a policy to control your robot, use the [`lerobot-train`](https://github.com/huggingface/lerobot/blob/main/src/lerobot/scripts/lerobot_train.py) script. A few arguments are required. Here is an example command:
To train a policy to control your robot, use the [`lerobot-train`](https://github.com/huggingface/lerobot/blob/main/src/lerobot/scripts/train.py) script. A few arguments are required. Here is an example command:
```bash
lerobot-train \
@@ -491,7 +471,7 @@ If your local computer doesn't have a powerful GPU you could utilize Google Cola
Once training is done, upload the latest checkpoint with:
```bash
hf upload ${HF_USER}/act_so101_test \
huggingface-cli upload ${HF_USER}/act_so101_test \
outputs/train/act_so101_test/checkpoints/last/pretrained_model
```
@@ -499,13 +479,13 @@ You can also upload intermediate checkpoints with:
```bash
CKPT=010000
hf upload ${HF_USER}/act_so101_test${CKPT} \
huggingface-cli upload ${HF_USER}/act_so101_test${CKPT} \
outputs/train/act_so101_test/checkpoints/${CKPT}/pretrained_model
```
## Run inference and evaluate your policy
You can use the `record` script from [`lerobot-record`](https://github.com/huggingface/lerobot/blob/main/src/lerobot/scripts/lerobot_record.py) with a policy checkpoint as input, to run inference and evaluate your policy. For instance, run this command or API example to run inference and record 10 evaluation episodes:
You can use the `record` script from [`lerobot/record.py`](https://github.com/huggingface/lerobot/blob/main/src/lerobot/record.py) with a policy checkpoint as input, to run inference and evaluate your policy. For instance, run this command or API example to run inference and record 10 evaluation episodes:
<hfoptions id="eval">
<hfoption id="Command">
@@ -518,9 +498,6 @@ lerobot-record \
--display_data=false \
--dataset.repo_id=${HF_USER}/eval_so100 \
--dataset.single_task="Put lego brick into the transparent box" \
--dataset.streaming_encoding=true \
--dataset.encoder_threads=2 \
# --dataset.vcodec=auto \
# <- Teleop optional if you want to teleoperate in between episodes \
# --teleop.type=so100_leader \
# --teleop.port=/dev/ttyACM0 \
@@ -537,8 +514,8 @@ from lerobot.datasets.lerobot_dataset import LeRobotDataset
from lerobot.datasets.utils import hw_to_dataset_features
from lerobot.policies.act.modeling_act import ACTPolicy
from lerobot.policies.factory import make_pre_post_processors
from lerobot.robots.so_follower.config_so100_follower import SO100FollowerConfig
from lerobot.robots.so_follower.so100_follower import SO100Follower
from lerobot.robots.so100_follower.config_so100_follower import SO100FollowerConfig
from lerobot.robots.so100_follower.so100_follower import SO100Follower
from lerobot.scripts.lerobot_record import record_loop
from lerobot.utils.control_utils import init_keyboard_listener
from lerobot.utils.utils import log_say
docs/source/installation.mdx
+15 -71
View File
@@ -1,57 +1,30 @@
# Installation
This guide uses `conda` (via miniforge) to manage environments (recommended). If you prefer another environment manager (e.g. `uv`, `venv`), ensure you have Python >=3.12 and `ffmpeg` installed with the `libsvtav1` encoder, then skip ahead to [Environment Setup](#step-2-environment-setup).
## Step 1 (`conda` only): Install [`miniforge`](https://conda-forge.org/download/)
## Install [`miniforge`](https://conda-forge.org/download/)
```bash
wget "https://github.com/conda-forge/miniforge/releases/latest/download/Miniforge3-$(uname)-$(uname -m).sh"
bash Miniforge3-$(uname)-$(uname -m).sh
```
## Step 2: Environment Setup
## Environment Setup
Create a virtual environment with Python 3.12:
Create a virtual environment with Python 3.10, using conda:
<!-- prettier-ignore-start -->
<hfoptions id="create_venv">
<hfoption id="conda">
```bash
conda create -y -n lerobot python=3.12
conda create -y -n lerobot python=3.10
```
</hfoption>
<hfoption id="uv">
Then activate your conda environment, you have to do this each time you open a shell to use lerobot:
```bash
uv python install 3.12
uv venv --python 3.12
```
</hfoption>
</hfoptions>
<!-- prettier-ignore-end -->
Then activate your virtual environment, you have to do this each time you open a shell to use lerobot:
<!-- prettier-ignore-start -->
<hfoptions id="activate_venv">
<hfoption id="conda">```bash
conda activate lerobot
```</hfoption>
<hfoption id="uv">
```bash
# Linux/macOSsource
source .venv/bin/activate
# Windows PowerShell
source .venv\Scripts\Activate.ps1
```
</hfoption>
</hfoptions>
<!-- prettier-ignore-end -->
When using `conda`, install `ffmpeg` in your environment:
```bash
conda install ffmpeg -c conda-forge
ffmpeg -version # ffmpeg 8.X is not yet supported !
```
> [!TIP]
@@ -65,17 +38,7 @@ ffmpeg -version # ffmpeg 8.X is not yet supported !
>
> - _[On Linux only]_ If you want to bring your own ffmpeg: Install [ffmpeg build dependencies](https://trac.ffmpeg.org/wiki/CompilationGuide/Ubuntu#GettheDependencies) and [compile ffmpeg from source with libsvtav1](https://trac.ffmpeg.org/wiki/CompilationGuide/Ubuntu#libsvtav1), and make sure you use the corresponding ffmpeg binary to your install with `which ffmpeg`.
> [!NOTE]
> When installing LeRobot inside WSL (Windows Subsystem for Linux), make sure to install `evdev` with the following command:
>
> ```bash
> conda install evdev -c conda-forge
> ```
> [!IMPORTANT]
> If you are using `uv` you will have to install `ffmpeg` system-wide (outside of the virtual environment). You rely on `uv` and `torchcodec` ability to dynamically link to the system `ffmpeg`.
## Step 3: Install LeRobot 🤗
## Install LeRobot 🤗
### From Source
@@ -88,45 +51,23 @@ cd lerobot
Then, install the library in editable mode. This is useful if you plan to contribute to the code.
<!-- prettier-ignore-start -->
<hfoptions id="install_lerobot_src">
<hfoption id="conda">
```bash
pip install -e .
```
</hfoption>
<hfoption id="uv">
```bash
uv pip install -e .
```
</hfoption>
</hfoptions>
<!-- prettier-ignore-end -->
### Installation from PyPI
**Core Library:**
Install the base package with:
<!-- prettier-ignore-start -->
<hfoptions id="install_lerobot_pypi">
<hfoption id="conda">
```bash
pip install lerobot
```
</hfoption>
<hfoption id="uv">
```bash
uv pip install lerobot
```
</hfoption>
</hfoptions>
<!-- prettier-ignore-end -->
_This installs only the default dependencies._
**Extra Features:**
To install additional functionality, use one of the following (If you are using `uv`, replace `pip install` with `uv pip install` in the commands below.):
To install additional functionality, use one of the following:
```bash
pip install 'lerobot[all]' # All available features
@@ -140,20 +81,23 @@ _Replace `[...]` with your desired features._
For a full list of optional dependencies, see:
https://pypi.org/project/lerobot/
> [!NOTE]
> For lerobot 0.4.0, if you want to install pi, you will have to do: `pip install "lerobot[pi]@git+https://github.com/huggingface/lerobot.git"`
### Troubleshooting
If you encounter build errors, you may need to install additional dependencies: `cmake`, `build-essential`, and `ffmpeg libs`.
To install these for Linux run:
To install these for linux run:
```bash
sudo apt-get install cmake build-essential python3-dev pkg-config libavformat-dev libavcodec-dev libavdevice-dev libavutil-dev libswscale-dev libswresample-dev libavfilter-dev
sudo apt-get install cmake build-essential python-dev pkg-config libavformat-dev libavcodec-dev libavdevice-dev libavutil-dev libswscale-dev libswresample-dev libavfilter-dev pkg-config
```
For other systems, see: [Compiling PyAV](https://pyav.org/docs/develop/overview/installation.html#bring-your-own-ffmpeg)
## Optional dependencies
LeRobot provides optional extras for specific functionalities. Multiple extras can be combined (e.g., `.[aloha,feetech]`). For all available extras, refer to `pyproject.toml`. If you are using `uv`, replace `pip install` with `uv pip install` in the commands below.
LeRobot provides optional extras for specific functionalities. Multiple extras can be combined (e.g., `.[aloha,feetech]`). For all available extras, refer to `pyproject.toml`.
### Simulations
docs/source/integrate_hardware.mdx
+1 -1
View File
@@ -18,7 +18,7 @@ If you're using Feetech or Dynamixel motors, LeRobot provides built-in bus inter
- [`DynamixelMotorsBus`](https://github.com/huggingface/lerobot/blob/main/src/lerobot/motors/dynamixel/dynamixel.py) for controlling Dynamixel servos
Please refer to the [`MotorsBus`](https://github.com/huggingface/lerobot/blob/main/src/lerobot/motors/motors_bus.py) abstract class to learn about its API.
For a good example of how it can be used, you can have a look at our own [SO101 follower implementation](https://github.com/huggingface/lerobot/blob/main/src/lerobot/robots/so_follower/so101_follower/so101_follower.py)
For a good example of how it can be used, you can have a look at our own [SO101 follower implementation](https://github.com/huggingface/lerobot/blob/main/src/lerobot/robots/so101_follower/so101_follower.py)
Use these if compatible. Otherwise, you'll need to find or write a Python interface (not covered in this tutorial):
docs/source/lekiwi.mdx
+3 -9
View File
@@ -1,11 +1,5 @@
# LeKiwi
<img
src="https://huggingface.co/datasets/huggingface/documentation-images/resolve/main/lerobot/1740517739083.jpeg"
alt="LeKiwi"
width="70%"
/>
In the steps below, we explain how to assemble the LeKiwi mobile robot.
## Source the parts
@@ -210,7 +204,7 @@ lerobot-calibrate \
<!-- prettier-ignore-start -->
```python
from lerobot.teleoperators.so_leader import SO100LeaderConfig, SO100Leader
from lerobot.teleoperators.so100_leader import SO100LeaderConfig, SO100Leader
config = SO100LeaderConfig(
port="/dev/tty.usbmodem58760431551",
@@ -279,13 +273,13 @@ We use the Hugging Face hub features for uploading your dataset. If you haven't
Add your token to the CLI by running this command:
```bash
hf auth login --token ${HUGGINGFACE_TOKEN} --add-to-git-credential
huggingface-cli login --token ${HUGGINGFACE_TOKEN} --add-to-git-credential
```
Then store your Hugging Face repository name in a variable:
```bash
HF_USER=$(hf auth whoami | awk -F': *' 'NR==1 {print $2}')
HF_USER=$(huggingface-cli whoami | head -n 1)
echo $HF_USER
```
docs/source/lerobot-dataset-v3.mdx
+1 -4
View File
@@ -41,10 +41,7 @@ lerobot-record \
--display_data=true \
--dataset.repo_id=${HF_USER}/record-test \
--dataset.num_episodes=5 \
--dataset.single_task="Grab the black cube" \
--dataset.streaming_encoding=true \
# --dataset.vcodec=auto \
--dataset.encoder_threads=2
--dataset.single_task="Grab the black cube"
```
See the [recording guide](./il_robots#record-a-dataset) for more details.
docs/source/libero.mdx
-6
View File
@@ -42,7 +42,6 @@ lerobot-eval \
```
- `--env.task` picks the suite (`libero_object`, `libero_spatial`, etc.).
- `--env.task_ids` picks task ids to run (`[0]`, `[1,2,3]`, etc.). Omit this flag (or set it to `null`) to run all tasks in the suite.
- `--eval.batch_size` controls how many environments run in parallel.
- `--eval.n_episodes` sets how many episodes to run in total.
@@ -63,11 +62,6 @@ lerobot-eval \
- Pass a comma-separated list to `--env.task` for multi-suite evaluation.
### Control Mode
LIBERO now supports two control modes: relative and absolute. This matters because different VLA checkpoints are trained with different mode of action to output hence control parameterizations.
You can switch them with: `env.control_mode = "relative"` and `env.control_mode = "absolute"`
### Policy inputs and outputs
When using LIBERO through LeRobot, policies interact with the environment via **observations** and **actions**:
docs/source/omx.mdx
-197
View File
@@ -1,197 +0,0 @@
## Order and Assemble the parts
First, assemble the OMX hardware following the official assembly guide.
OMX Assembly Guide: https://ai.robotis.com/omx/assembly_guide_omx.html
OMX robots are shipped preconfigured from the factory. Motor IDs, communication parameters, and joint offsets are already set, so no additional motor setup or calibration is required before using LeRobot.
## Install LeRobot 🤗
To install LeRobot, follow our [Installation Guide](./installation)
In addition to these instructions, you need to install the Dynamixel SDK:
```bash
pip install -e ".[dynamixel]"
```
## Connect the robot
To find the port for each bus servo adapter, run this script:
```bash
lerobot-find-port
```
This command runs and when prompted, disconnect the USB cable from either the leader or follower arm and press Enter. The output will show 'The port of this MotorsBus is [port]'. This identifies the port for the disconnected arm. Repeat for the other arm to identify both ports.
<hfoptions id="find_port">
<hfoption id="Mac">
Example output on macOS:
```
Finding all available ports for the MotorBus.
['/dev/tty.usbmodem575E0032081', '/dev/tty.usbmodem575E0031751']
Remove the USB cable from your MotorsBus and press Enter when done.
[...Disconnect corresponding leader or follower arm and press Enter...]
The port of this MotorsBus is /dev/tty.usbmodem575E0032081
Reconnect the USB cable.
```
Where the found port is: `/dev/tty.usbmodem575E0032081` corresponding to your leader or follower arm.
</hfoption>
<hfoption id="Linux">
On Linux, we strongly recommend using udev rules to assign persistent and human-readable device names to the OMX leader and follower arms. This avoids issues where device names such as ttyACM0 and ttyACM1 change when the robot is unplugged, replugged, or when the system is rebooted.
#### 1. Find your device serial numbers
You should have obtained the port numbers like ../../ttyACM? for the leader and follower using `lerobot-find-port`. You can match those results with the serial numbers using the `ls -l /dev/serial/by-id/` command.
To create udev rules, you need the unique serial number for each OMX device. The easiest way is to list devices under:
```bash
ls -l /dev/serial/by-id/
```
You will see output similar to:
```bash
usb-ROBOTIS_OpenRB-150_228BDD7B503059384C2E3120FF0A2B19-if00 -> ../../ttyACM0
usb-ROBOTIS_OpenRB-150_67E1ED68503059384C2E3120FF092234-if00 -> ../../ttyACM1
```
In each line, the serial number is the long string after `usb-ROBOTIS_OpenRB-150_` and before `-if00`.
Follower serial: `228BDD7B503059384C2E3120FF0A2B19`
Leader serial: `67E1ED68503059384C2E3120FF092234`
#### 2. Create the udev rule
Create a new udev rule file:
```bash
sudo nano /etc/udev/rules.d/99-omx.rules
```
Paste the following lines, replacing the serial numbers with the values you found above:
```bash
SUBSYSTEM=="tty", ATTRS{idVendor}=="0403", ATTRS{serial}=="228BDD7B503059384C2E3120FF0A2B19", SYMLINK+="omx_follower"
SUBSYSTEM=="tty", ATTRS{idVendor}=="0403", ATTRS{serial}=="67E1ED68503059384C2E3120FF092234", SYMLINK+="omx_leader"
```
Save the file and reload udev rules:
```bash
sudo udevadm control --reload-rules
sudo udevadm trigger
```
Now unplug and replug both devices once.
#### 3. Verify the symlinks
Check that the persistent device names exist:
```bash
ls -l /dev/omx_follower /dev/omx_leader
```
You should see them pointing to ttyACM\* devices:
```bash
/dev/omx_follower -> ttyACM*
/dev/omx_leader -> ttyACM*
```
These names remain stable across reboots and reconnections.
</hfoption>
</hfoptions>
## Teleoperate
After identifying the correct ports, you can directly teleoperate the follower arm using the leader arm.
<hfoptions id="teleoperate">
<hfoption id="Mac">
### Teleoperate without camera
```bash
lerobot-teleoperate \
--robot.type=omx_follower \
--robot.port=<your_follower_port> \
--robot.id=omx_follower_arm \
--teleop.type=omx_leader \
--teleop.port=<your_leader_port> \
--teleop.id=omx_leader_arm
```
During teleoperation, motions of the leader arm are mirrored in real time by the follower arm. OMX is already preconfigured, teleoperation can begin immediately without any calibration steps.
### Teleoperate with camera
You can also enable camera input during teleoperation by providing a camera configuration for the follower arm.
```bash
lerobot-teleoperate \
--robot.type=omx_follower \
--robot.port=<your_follower_port> \
--robot.id=omx_follower_arm \
--robot.cameras="{front: {type: opencv, index_or_path: '/dev/video0', width: 640, height: 480, fps: 30}}" \
--teleop.type=omx_leader \
--teleop.port=<your_leader_port> \
--teleop.id=omx_leader_arm \
--display_data=true
```
When the camera is enabled, the camera stream is displayed in real time and synchronized with the robot state. This setup is useful for visual monitoring and can be reused later for demonstration recording and imitation learning.
</hfoption>
<hfoption id="Linux">
### Teleoperate without camera
```bash
lerobot-teleoperate \
--robot.type=omx_follower \
--robot.port=/dev/omx_follower \
--robot.id=omx_follower_arm \
--teleop.type=omx_leader \
--teleop.port=/dev/omx_leader \
--teleop.id=omx_leader_arm
```
During teleoperation, motions of the leader arm are mirrored in real time by the follower arm. OMX is already preconfigured, teleoperation can begin immediately without any calibration steps.
### Teleoperate with camera
You can also enable camera input during teleoperation by providing a camera configuration for the follower arm.
```bash
lerobot-teleoperate \
--robot.type=omx_follower \
--robot.port=/dev/omx_follower \
--robot.id=omx_follower_arm \
--robot.cameras="{front: {type: opencv, index_or_path: '/dev/video0', width: 640, height: 480, fps: 30}}" \
--teleop.type=omx_leader \
--teleop.port=/dev/omx_leader \
--teleop.id=omx_leader_arm \
--display_data=true
```
When the camera is enabled, the camera stream is displayed in real time and synchronized with the robot state. This setup is useful for visual monitoring and can be reused later for demonstration recording and imitation learning.
</hfoption>
</hfoptions>
Congrats 🎉, your robot is all set to learn a task on its own.
> If you have any questions or need help, please reach out on [Discord](https://discord.com/invite/robotis).
docs/source/openarm.mdx
-276
View File
@@ -1,276 +0,0 @@
# OpenArm
[OpenArm](https://openarm.dev) is an open-source 7DOF humanoid arm designed for physical AI research and deployment.
To get your OpenArm, assembled or DIY, and join the global community, browse verified and certified manufacturers worldwide at [openarm.dev](https://openarm.dev).
## What's Unique?
- **Human-Scale Design**: OpenArm is designed with human-like proportions, scaled for a person around 160-165cm tall. This provides an optimal balance between practical reach and manageable inertia for safe, responsive operation.
- **Safety-First Architecture**: Built with QDD backdrivable motors and high compliance, OpenArm prioritizes safe human-robot interaction while maintaining practical payload capabilities (6.0kg peak / 4.1kg nominal) for real-world tasks.
- **Built for Durability**: Critical structural components use aluminum and stainless steel construction, ensuring robust performance for repetitive data collection and continuous research use.
- **Fully Accessible & Buildable**: Every component, from CNC parts and 3D-printed casings to electrical wiring is designed to be purchasable and buildable by individual researchers and labs, with complete fabrication data provided.
- **Practical & Affordable**: At $6,500 USD for a complete bimanual system, OpenArm delivers research-grade capabilities at a fraction of traditional humanoid robot costs.
## Platform Requirements
<Tip warning={true}>
**Linux Only**: OpenArm currently only works on Linux. The CAN bus USB adapter
does not have macOS drivers and has not been tested on Windows.
</Tip>
## Safety Guide
Before operating OpenArm, please read the [official safety guide](https://docs.openarm.dev/getting-started/safety-guide). Key points:
- **Secure installation**: Fasten the arm to a flat, stable surface with screws or clamps
- **Safe distance**: Keep body parts and objects outside the range of motion during operation
- **Protective equipment**: Always wear safety goggles; use additional PPE as needed
- **Payload limits**: Do not exceed specified payload limits (6.0kg peak / 4.1kg nominal per arm)
- **Emergency stop**: Know the location and operation of the emergency stop device
- **Regular inspection**: Check for loose screws, damaged mechanical limits, unusual noises, and wiring damage
## Hardware Setup
Follow the official [OpenArm hardware documentation](https://docs.openarm.dev) for:
- Bill of materials and sourcing
- 3D printing instructions
- Mechanical assembly
- Electrical wiring
The hardware repositories are available at [github.com/enactic/openarm](https://github.com/enactic/openarm).
## CAN Bus Setup
OpenArm uses CAN bus communication with Damiao motors. Once you have the CAN bus USB adapter plugged into your Linux PC, follow the [Damiao Motors and CAN Bus guide](./damiao) to configure the interface.
Quick setup:
```bash
# Setup CAN interfaces
lerobot-setup-can --mode=setup --interfaces=can0,can1
# Test motor communication
lerobot-setup-can --mode=test --interfaces=can0,can1
```
## Install LeRobot 🤗
Follow our [Installation Guide](./installation), then install the Damiao motor support:
```bash
pip install -e ".[damiao]"
```
## Usage
### Follower Arm (Robot)
<hfoptions id="follower">
<hfoption id="Command">
```bash
lerobot-calibrate \
--robot.type=openarm_follower \
--robot.port=can0 \
--robot.side=right \
--robot.id=my_openarm_follower
```
</hfoption>
<hfoption id="API example">
```python
from lerobot.robots.openarm_follower import OpenArmFollower, OpenArmFollowerConfig
config = OpenArmFollowerConfig(
port="can0",
side="right", # or "left" for left arm
id="my_openarm_follower",
)
follower = OpenArmFollower(config)
follower.connect()
# Read current state
obs = follower.get_observation()
print(obs)
# Send action (position in degrees)
action = {
"joint_1.pos": 0.0,
"joint_2.pos": 0.0,
"joint_3.pos": 0.0,
"joint_4.pos": 45.0,
"joint_5.pos": 0.0,
"joint_6.pos": 0.0,
"joint_7.pos": 0.0,
"gripper.pos": 0.0,
}
follower.send_action(action)
follower.disconnect()
```
</hfoption>
</hfoptions>
### Leader Arm (Teleoperator)
The leader arm is used for teleoperation - manually moving it to control the follower arm.
<hfoptions id="leader">
<hfoption id="Command">
```bash
lerobot-calibrate \
--teleop.type=openarm_leader \
--teleop.port=can1 \
--teleop.id=my_openarm_leader
```
</hfoption>
<hfoption id="API example">
```python
from lerobot.teleoperators.openarm_leader import OpenArmLeader, OpenArmLeaderConfig
config = OpenArmLeaderConfig(
port="can1",
id="my_openarm_leader",
manual_control=True, # Disable torque for manual movement
)
leader = OpenArmLeader(config)
leader.connect()
# Read current position (as action to send to follower)
action = leader.get_action()
print(action)
leader.disconnect()
```
</hfoption>
</hfoptions>
### Teleoperation
To teleoperate OpenArm with leader-follower control:
```bash
lerobot-teleoperate \
--robot.type=openarm_follower \
--robot.port=can0 \
--robot.side=right \
--robot.id=my_follower \
--teleop.type=openarm_leader \
--teleop.port=can1 \
--teleop.id=my_leader
```
### Bimanual Teleoperation
To teleoperate a bimanual OpenArm setup with two leader and two follower arms:
```bash
lerobot-teleoperate \
--robot.type=bi_openarm_follower \
--robot.left_arm_config.port=can0 \
--robot.left_arm_config.side=left \
--robot.right_arm_config.port=can1 \
--robot.right_arm_config.side=right \
--robot.id=my_bimanual_follower \
--teleop.type=bi_openarm_leader \
--teleop.left_arm_config.port=can2 \
--teleop.right_arm_config.port=can3 \
--teleop.id=my_bimanual_leader
```
### Recording Data
To record a dataset during teleoperation:
```bash
lerobot-record \
--robot.type=openarm_follower \
--robot.port=can0 \
--robot.side=right \
--robot.id=my_follower \
--teleop.type=openarm_leader \
--teleop.port=can1 \
--teleop.id=my_leader \
--repo-id=my_hf_username/my_openarm_dataset \
--fps=30 \
--num-episodes=10
```
## Configuration Options
### Follower Configuration
| Parameter | Default | Description |
| --------------------- | --------- | ---------------------------------------------------------- |
| `port` | - | CAN interface (e.g., `can0`) |
| `side` | `None` | Arm side: `"left"`, `"right"`, or `None` for custom limits |
| `use_can_fd` | `True` | Enable CAN FD for higher data rates |
| `can_bitrate` | `1000000` | Nominal bitrate (1 Mbps) |
| `can_data_bitrate` | `5000000` | CAN FD data bitrate (5 Mbps) |
| `max_relative_target` | `None` | Safety limit for relative target positions |
| `position_kp` | Per-joint | Position control proportional gains |
| `position_kd` | Per-joint | Position control derivative gains |
### Leader Configuration
| Parameter | Default | Description |
| ------------------ | --------- | ----------------------------------- |
| `port` | - | CAN interface (e.g., `can1`) |
| `manual_control` | `True` | Disable torque for manual movement |
| `use_can_fd` | `True` | Enable CAN FD for higher data rates |
| `can_bitrate` | `1000000` | Nominal bitrate (1 Mbps) |
| `can_data_bitrate` | `5000000` | CAN FD data bitrate (5 Mbps) |
## Motor Configuration
OpenArm uses Damiao motors with the following default configuration:
| Joint | Motor Type | Send ID | Recv ID |
| --------------------------- | ---------- | ------- | ------- |
| joint_1 (Shoulder pan) | DM8009 | 0x01 | 0x11 |
| joint_2 (Shoulder lift) | DM8009 | 0x02 | 0x12 |
| joint_3 (Shoulder rotation) | DM4340 | 0x03 | 0x13 |
| joint_4 (Elbow flex) | DM4340 | 0x04 | 0x14 |
| joint_5 (Wrist roll) | DM4310 | 0x05 | 0x15 |
| joint_6 (Wrist pitch) | DM4310 | 0x06 | 0x16 |
| joint_7 (Wrist rotation) | DM4310 | 0x07 | 0x17 |
| gripper | DM4310 | 0x08 | 0x18 |
## Troubleshooting
### No Response from Motors
1. Check power supply connections
2. Verify CAN wiring (CAN-H, CAN-L, GND)
3. Run diagnostics: `lerobot-setup-can --mode=test --interfaces=can0`
4. See the [Damiao troubleshooting guide](./damiao#troubleshooting) for more details
### CAN Interface Not Found
Ensure the CAN interface is configured:
```bash
ip link show can0
```
## Resources
- [OpenArm Website](https://openarm.dev)
- [OpenArm Documentation](https://docs.openarm.dev)
- [OpenArm GitHub](https://github.com/enactic/openarm)
- [Safety Guide](https://docs.openarm.dev/getting-started/safety-guide)
- [Damiao Motors and CAN Bus](./damiao)
docs/source/peft_training.mdx
-62
View File
@@ -1,62 +0,0 @@
# Parameter efficient fine-tuning with 🤗 PEFT
[🤗 PEFT](https://github.com/huggingface/peft) (Parameter-Efficient Fine-Tuning) is a library for efficiently adapting
large pretrained models such as pre-trained policies (e.g., SmolVLA, π₀, ...) to new tasks without training all
of the model's parameters while yielding comparable performance.
Install the `lerobot[peft]` optional package to enable PEFT support.
To read about all the possible methods of adaption, please refer to the [🤗 PEFT docs](https://huggingface.co/docs/peft/index).
## Training SmolVLA
In this section we'll show you how to train a pre-trained SmolVLA policy with PEFT on the libero dataset.
For brevity we're only training on the `libero_spatial` subset. We will use `lerobot/smolvla_base` as the model
to parameter efficiently fine-tune:
```
lerobot-train \
--policy.path=lerobot/smolvla_base \
--policy.repo_id=your_hub_name/my_libero_smolvla \
--dataset.repo_id=HuggingFaceVLA/libero \
--policy.output_features=null \
--policy.input_features=null \
--policy.optimizer_lr=1e-3 \
--policy.scheduler_decay_lr=1e-4 \
--env.type=libero \
--env.task=libero_spatial \
--steps=100000 \
--batch_size=32 \
--peft.method_type=LORA \
--peft.r=64
```
Note the `--peft.method_type` parameter that let's you select which PEFT method to use. Here we use
[LoRA](https://huggingface.co/docs/peft/main/en/package_reference/lora) (Low-Rank Adapter) which is probably the most
popular fine-tuning method to date. Low-rank adaption means that we only fine-tune a matrix with comparably low rank
instead of the full weight matrix. This rank can be specified using the `--peft.r` parameter. The higher the rank
the closer you get to full fine-tuning
There are more complex methods that have more parameters. These are not yet supported, feel free to raise an issue
if you want to see a specific PEFT method supported.
By default, PEFT will target the `q_proj` and `v_proj` layers of the LM expert in SmolVLA. It will also target the
state and action projection matrices as they are most likely task-dependent. If you need to target different layers
you can use `--peft.target_modules` to specify which layers to target. You can refer to the respective PEFT method's
documentation to see what inputs are supported, (e.g., [LoRA's target_modules documentation](https://huggingface.co/docs/peft/main/en/package_reference/lora#peft.LoraConfig.target_modules)).
Usually a list of suffixes or a regex are supported. For example, to target the MLPs of the `lm_expert` instead of
the `q` and `v` projections, use:
```
--peft.target_modules='(model\.vlm_with_expert\.lm_expert\..*\.(down|gate|up)_proj|.*\.(state_proj|action_in_proj|action_out_proj|action_time_mlp_in|action_time_mlp_out))'
```
In case you need to fully fine-tune a layer instead of just adapting it, you can supply a list of layer suffixes
to the `--peft.full_training_modules` parameter:
```
--peft.full_training_modules=["state_proj"]
```
The learning rate and the scheduled target learning rate can usually be scaled by a factor of 10 compared to the
learning rate used for full fine-tuning (e.g., 1e-4 normal, so 1e-3 using LoRA).
docs/source/phone_teleop.mdx
+13 -17
View File
@@ -44,7 +44,7 @@ Modify the examples to use `PhoneOS.IOS` or `PhoneOS.ANDROID` in `PhoneConfig`.
Teleoperation example:
```python
```36:43:examples/phone_so100_teleop.py
from lerobot.teleoperators.phone.config_phone import PhoneConfig, PhoneOS
teleop_config = PhoneConfig(phone_os=PhoneOS.IOS) # or PhoneOS.ANDROID
@@ -66,13 +66,12 @@ Run on of the examples scripts to teleoperate, record a dataset, replay a datase
All scripts assume you configured your robot (e.g., SO-100 follower) and set the correct serial port.
Additionally you need to **copy the URDF of the robot into the examples folder**. For the examples in this tutorial (using SO100/SO101), copy the `SO101` folder from the [SO-ARM100 repo](https://github.com/TheRobotStudio/SO-ARM100/blob/main/Simulation/SO101) into the `examples/phone_to_so100/` directory, so that the URDF file path becomes `examples/phone_to_so100/SO101/so101_new_calib.urdf`.
Additionally you need to **copy the urdf of the robot to the examples folder**. For the examples in this tutorial (Using SO100/SO101) it is highly recommended to use the urdf in the [SO-ARM100 repo](https://github.com/TheRobotStudio/SO-ARM100/blob/main/Simulation/SO101/so101_new_calib.urdf)
- Run this example to teleoperate:
```bash
cd examples/phone_to_so100
python teleoperate.py
python examples/phone_to_so100/teleoperate.py
```
After running the example:
@@ -85,29 +84,26 @@ Additionally you can customize mapping or safety limits by editing the processor
- Run this example to record a dataset, which saves absolute end effector observations and actions:
```bash
cd examples/phone_to_so100
python record.py
python examples/phone_to_so100/record.py
```
- Run this example to replay recorded episodes:
```bash
cd examples/phone_to_so100
python replay.py
python examples/phone_to_so100/replay.py
```
- Run this example to evaluate a pretrained policy:
```bash
cd examples/phone_to_so100
python evaluate.py
python examples/phone_to_so100/evaluate.py
```
### Important pipeline steps and options
- Kinematics are used in multiple steps. We use [Placo](https://github.com/Rhoban/placo) which is a wrapper around Pinocchio for handling our kinematics. We construct the kinematics object by passing the robot's URDF and target frame. We set `target_frame_name` to the gripper frame.
```python
```examples/phone_to_so100/teleoperate.py
kinematics_solver = RobotKinematics(
urdf_path="./SO101/so101_new_calib.urdf",
target_frame_name="gripper_frame_link",
@@ -118,7 +114,7 @@ Additionally you can customize mapping or safety limits by editing the processor
- The `MapPhoneActionToRobotAction` step converts the calibrated phone pose and inputs into target deltas and gripper commands, below is shown what the step outputs.
```python
```src/lerobot/teleoperators/phone/phone_processor.py
action["enabled"] = enabled
action["target_x"] = -pos[1] if enabled else 0.0
action["target_y"] = pos[0] if enabled else 0.0
@@ -131,7 +127,7 @@ Additionally you can customize mapping or safety limits by editing the processor
- The `EEReferenceAndDelta` step converts target deltas to an absolute desired EE pose, storing a reference on enable, the `end_effector_step_sizes` are the step sizes for the EE pose and can be modified to change the motion speed.
```python
```examples/phone_to_so100/teleoperate.py
EEReferenceAndDelta(
kinematics=kinematics_solver,
end_effector_step_sizes={"x": 0.5, "y": 0.5, "z": 0.5},
@@ -142,7 +138,7 @@ Additionally you can customize mapping or safety limits by editing the processor
- The `EEBoundsAndSafety` step clamps EE motion to a workspace and checks for large ee step jumps to ensure safety. The `end_effector_bounds` are the bounds for the EE pose and can be modified to change the workspace. The `max_ee_step_m` are the step limits for the EE pose and can be modified to change the safety limits.
```python
```examples/phone_to_so100/teleoperate.py
EEBoundsAndSafety(
end_effector_bounds={"min": [-1.0, -1.0, -1.0], "max": [1.0, 1.0, 1.0]},
max_ee_step_m=0.10,
@@ -151,7 +147,7 @@ Additionally you can customize mapping or safety limits by editing the processor
- The `GripperVelocityToJoint` step turns a velocitylike gripper input into absolute gripper position using the current measured state. The `speed_factor` is the factor by which the velocity is multiplied.
```python
```examples/phone_to_so100/teleoperate.py
GripperVelocityToJoint(speed_factor=20.0)
```
@@ -161,7 +157,7 @@ We use different IK initial guesses in the kinematic steps. As initial guess eit
- Closed loop (used in record/eval): sets `initial_guess_current_joints=True` so IK starts from the measured joints each frame.
```python
```examples/phone_to_so100/record.py
InverseKinematicsEEToJoints(
kinematics=kinematics_solver,
motor_names=list(robot.bus.motors.keys()),
@@ -171,7 +167,7 @@ We use different IK initial guesses in the kinematic steps. As initial guess eit
- Open loop (used in replay): sets `initial_guess_current_joints=False` so IK continues from the previous IK solution rather than the measured state. This preserves action stability when we replay without feedback.
```python
```examples/phone_to_so100/replay.py
InverseKinematicsEEToJoints(
kinematics=kinematics_solver,
motor_names=list(robot.bus.motors.keys()),
docs/source/pi0.mdx
+6 -18
View File
@@ -6,12 +6,6 @@
π₀ represents a breakthrough in robotics as the first general-purpose robot foundation model developed by [Physical Intelligence](https://www.physicalintelligence.company/blog/pi0). Unlike traditional robot programs that are narrow specialists programmed for repetitive motions, π₀ is designed to be a generalist policy that can understand visual inputs, interpret natural language instructions, and control a variety of different robots across diverse tasks.
<img
src="https://huggingface.co/datasets/huggingface/documentation-images/resolve/main/lerobot/lerobot-pi0%20(1).png"
alt="An overview of Pi0"
width="85%"
/>
### The Vision for Physical Intelligence
As described by Physical Intelligence, while AI has achieved remarkable success in digital domains, from chess-playing to drug discovery, human intelligence still dramatically outpaces AI in the physical world. To paraphrase Moravec's paradox, winning a game of chess represents an "easy" problem for AI, but folding a shirt or cleaning up a table requires solving some of the most difficult engineering problems ever conceived. π₀ represents a first step toward developing artificial physical intelligence that enables users to simply ask robots to perform any task they want, just like they can with large language models.
@@ -34,6 +28,11 @@ As described by Physical Intelligence, while AI has achieved remarkable success
pip install -e ".[pi]"
```
> [!NOTE]
> For lerobot 0.4.0, if you want to install pi tag, you will have to do: `pip install "lerobot[pi]@git+https://github.com/huggingface/lerobot.git"`.
>
> This will be solved in the next patch release
## Training Data and Capabilities
π₀ is trained on the largest robot interaction dataset to date, combining three key data sources:
@@ -55,7 +54,7 @@ policy.type=pi0
For training π₀, you can use the standard LeRobot training script with the appropriate configuration:
```bash
lerobot-train \
python src/lerobot/scripts/lerobot_train.py \
--dataset.repo_id=your_dataset \
--policy.type=pi0 \
--output_dir=./outputs/pi0_training \
@@ -65,8 +64,6 @@ lerobot-train \
--policy.compile_model=true \
--policy.gradient_checkpointing=true \
--policy.dtype=bfloat16 \
--policy.freeze_vision_encoder=false \
--policy.train_expert_only=false \
--steps=3000 \
--policy.device=cuda \
--batch_size=32
@@ -82,15 +79,6 @@ lerobot-train \
- [lerobot/pi0_base](https://huggingface.co/lerobot/pi0_base)
- [lerobot/pi0_libero](https://huggingface.co/lerobot/pi0_libero) (specifically trained on the Libero dataset)
### Training Parameters Explained
| Parameter | Default | Description |
| ----------------------- | ------- | ------------------------------------------- |
| `freeze_vision_encoder` | `false` | Do not freeze the vision encoder |
| `train_expert_only` | `false` | Do not freeze the VLM, train all parameters |
**💡 Tip**: Setting `train_expert_only=true` freezes the VLM and trains only the action expert and projections, allowing finetuning with reduced memory usage.
## License
This model follows the **Apache 2.0 License**, consistent with the original [OpenPI repository](https://github.com/Physical-Intelligence/openpi).
docs/source/pi05.mdx
+6 -12
View File
@@ -36,6 +36,11 @@ This diverse training mixture creates a "curriculum" that enables generalization
pip install -e ".[pi]"
```
> [!NOTE]
> For lerobot 0.4.0, if you want to install pi tag, you will have to do: `pip install "lerobot[pi]@git+https://github.com/huggingface/lerobot.git"`.
>
> This will be solved in the next patch release
## Usage
To use π₀.₅ in your LeRobot configuration, specify the policy type as:
@@ -51,7 +56,7 @@ policy.type=pi05
Here's a complete training command for finetuning the base π₀.₅ model on your own dataset:
```bash
lerobot-train \
python src/lerobot/scripts/lerobot_train.py\
--dataset.repo_id=your_dataset \
--policy.type=pi05 \
--output_dir=./outputs/pi05_training \
@@ -62,8 +67,6 @@ lerobot-train \
--policy.gradient_checkpointing=true \
--wandb.enable=true \
--policy.dtype=bfloat16 \
--policy.freeze_vision_encoder=false \
--policy.train_expert_only=false \
--steps=3000 \
--policy.device=cuda \
--batch_size=32
@@ -79,15 +82,6 @@ lerobot-train \
- [lerobot/pi05_base](https://huggingface.co/lerobot/pi05_base)
- [lerobot/pi05_libero](https://huggingface.co/lerobot/pi05_libero) (specifically trained on the Libero dataset)
### Training Parameters Explained
| Parameter | Default | Description |
| ----------------------- | ------- | ------------------------------------------- |
| `freeze_vision_encoder` | `false` | Do not freeze the vision encoder |
| `train_expert_only` | `false` | Do not freeze the VLM, train all parameters |
**💡 Tip**: Setting `train_expert_only=true` freezes the VLM and trains only the action expert and projections, allowing finetuning with reduced memory usage.
If your dataset is not converted with `quantiles`, you can convert it with the following command:
```bash
docs/source/pi0fast.mdx
-241
View File
@@ -1,241 +0,0 @@
# π₀-FAST (Pi0-FAST)
π₀-FAST is a **Vision-Language-Action model for general robot control** that uses autoregressive next-token prediction to model continuous robot actions.
## Model Overview
π₀-FAST combines the power of Vision-Language Models with a novel action tokenization approach called **FAST (Frequency-space Action Sequence Tokenization)**. This enables training autoregressive VLAs on highly dexterous tasks that are impossible with standard binning-based discretization, while training **up to 5x faster** than diffusion-based approaches like π₀.
<img
src="https://huggingface.co/datasets/huggingface/documentation-images/resolve/main/lerobot/lerobot-pifast.png"
alt="An overview of Pi0-FAST"
width="85%"
/>
### Why FAST?
Standard approaches for robot action tokenization use simple per-dimension, per-timestep binning schemes. While passable for simple behaviors, this rapidly breaks down for complex and dexterous skills that require precision and high-frequency control.
FAST solves this by compressing action sequences using signal processing techniques, resulting in a dense sequence of action tokens that can be predicted autoregressively—just like language tokens.
### How FAST Tokenization Works
The FAST tokenizer compresses action sequences through the following steps:
1. **Normalize**: Take a continuous action chunk of shape `(H, D)` where `H` is the horizon and `D` is the action dimension. Normalize using one of the supported normalization methods (Quantiles recommended to handle outliers).
2. **Discrete Cosine Transform (DCT)**: Apply DCT (via scipy) to each action dimension separately. DCT is a compression algorithm commonly used in image and audio codecs (JPEG, MP3).
3. **Quantization**: Round and remove insignificant coefficients for each action dimension, producing a sparse frequency matrix.
4. **Flatten**: Flatten the matrix into a 1D vector, with low-frequency components first.
5. **Byte Pair Encoding (BPE)**: Train a BPE tokenizer to compress the DCT coefficients into dense action tokens, typically achieving **10x compression** over prior tokenization approaches.
This approach can transform **any existing VLM** into a VLA by training it to predict these FAST tokens.
## Installation Requirements
1. Install LeRobot by following our [Installation Guide](./installation).
2. Install π₀-FAST dependencies by running:
```bash
pip install -e ".[pi]"
```
## Training a Custom FAST Tokenizer
You have two options for the FAST tokenizer:
1. **Use the pre-trained tokenizer**: The `lerobot/fast-action-tokenizer` tokenizer was trained on 1M+ real robot action sequences and works as a general-purpose tokenizer.
2. **Train your own tokenizer**: For maximum performance on your specific dataset, you can finetune the tokenizer on your own data.
### Training Your Own Tokenizer
```bash
lerobot-train-tokenizer \
--repo_id "user/my-lerobot-dataset" \
--action_horizon 10 \
--encoded_dims "0:6" \
--vocab_size 1024 \
--scale 10.0 \
--normalization_mode QUANTILES \
--output_dir "./my_fast_tokenizer" \
--push_to_hub \
--hub_repo_id "username/my-action-tokenizer"
```
### Key Tokenizer Parameters
| Parameter | Description | Default |
| ---------------------- | --------------------------------------------------------------------------------- | ------------ |
| `--repo_id` | LeRobot dataset repository ID | Required |
| `--action_horizon` | Number of future actions in each chunk | `10` |
| `--encoded_dims` | Comma-separated dimension ranges to encode (e.g., `"0:6,7:23"`) | `"0:6,7:23"` |
| `--vocab_size` | BPE vocabulary size | `1024` |
| `--scale` | DCT scaling factor for quantization | `10.0` |
| `--normalization_mode` | Normalization mode (`MEAN_STD`, `MIN_MAX`, `QUANTILES`, `QUANTILE10`, `IDENTITY`) | `QUANTILES` |
| `--sample_fraction` | Fraction of chunks to sample per episode | `0.1` |
## Usage
To use π₀-FAST in LeRobot, specify the policy type as:
```python
policy.type=pi0_fast
```
## Training
For training π₀-FAST, you can use the LeRobot training script:
```bash
lerobot-train \
--dataset.repo_id=your_dataset \
--policy.type=pi0_fast \
--output_dir=./outputs/pi0fast_training \
--job_name=pi0fast_training \
--policy.pretrained_path=lerobot/pi0_fast_base \
--policy.dtype=bfloat16 \
--policy.gradient_checkpointing=true \
--policy.chunk_size=10 \
--policy.n_action_steps=10 \
--policy.max_action_tokens=256 \
--steps=100000 \
--batch_size=4 \
--policy.device=cuda
```
### Key Training Parameters
| Parameter | Description | Default |
| -------------------------------------- | -------------------------------------------------- | ------------------------------- |
| `--policy.gradient_checkpointing=true` | Reduces memory usage significantly during training | `false` |
| `--policy.dtype=bfloat16` | Use mixed precision training for efficiency | `float32` |
| `--policy.chunk_size` | Number of action steps to predict (action horizon) | `50` |
| `--policy.n_action_steps` | Number of action steps to execute | `50` |
| `--policy.max_action_tokens` | Maximum number of FAST tokens per action chunk | `256` |
| `--policy.action_tokenizer_name` | FAST tokenizer to use | `lerobot/fast-action-tokenizer` |
| `--policy.compile_model=true` | Enable torch.compile for faster training | `false` |
## Inference
### KV-Caching for Fast Inference
π₀-FAST supports **KV-caching**, a widely used optimization in LLM inference. This caches the key-value pairs from the attention mechanism, avoiding redundant computation during autoregressive decoding.
```python
# KV-caching is enabled by default
policy.use_kv_cache=true
```
### Inference Example
```python
from lerobot.policies.pi0_fast import PI0FastPolicy, PI0FastConfig
# Load the policy
policy = PI0FastPolicy.from_pretrained("your-model-path")
# During inference
actions = policy.predict_action_chunk(batch)
```
## Model Architecture
π₀-FAST uses a PaliGemma-based architecture:
- **Vision Encoder**: SigLIP vision tower for image understanding
- **Language Model**: Gemma 2B for processing language instructions and predicting action tokens
The model takes images, text instructions, and robot state as input, and outputs discrete FAST tokens that are decoded back to continuous actions.
## Configuration Options
| Parameter | Description | Default |
| -------------------- | ----------------------------------------------- | ---------- |
| `paligemma_variant` | VLM backbone variant (`gemma_300m`, `gemma_2b`) | `gemma_2b` |
| `max_state_dim` | Maximum state vector dimension (padded) | `32` |
| `max_action_dim` | Maximum action vector dimension (padded) | `32` |
| `temperature` | Sampling temperature (0.0 for greedy) | `0.0` |
| `max_decoding_steps` | Maximum decoding steps | `256` |
| `use_kv_cache` | Enable KV caching for faster inference | `true` |
## Comparison with π₀
| Feature | π₀ | π₀-FAST |
| --------------------- | ------------------------- | ---------------------------- |
| Action Representation | Flow Matching (Diffusion) | Autoregressive Tokens (FAST) |
| Training Speed | 1x | **5x faster** |
| Dexterity | High | High |
| Inference Method | Iterative Denoising | Autoregressive Decoding |
| KV-Caching | N/A | Supported |
## Reproducing π₀Fast results
We reproduce the results of π₀Fast on the LIBERO benchmark using the LeRobot implementation. We take the LeRobot PiFast base model [lerobot/pi0fast-base](https://huggingface.co/lerobot/pi0fast-base) and finetune for an additional 40kk steps in bfloat16, with batch size of 256 on 8 H100 GPUs using the [HuggingFace LIBERO dataset](https://huggingface.co/datasets/HuggingFaceVLA/libero).
The finetuned model can be found here:
- **π₀Fast LIBERO**: [lerobot/pi0fast-libero](https://huggingface.co/lerobot/pi0fast-libero)
With the following training command:
```bash
lerobot-train \
--dataset.repo_id=lerobot/libero \
--output_dir=outputs/libero_pi0fast \
--job_name=libero_pi0fast \
--policy.path=lerobot/pi0fast_base \
--policy.dtype=bfloat16 \
--steps=100000 \
--save_freq=20000 \
--batch_size=4 \
--policy.device=cuda \
--policy.scheduler_warmup_steps=4000 \
--policy.scheduler_decay_steps=100000 \
--policy.scheduler_decay_lr=1e-5 \
--policy.gradient_checkpointing=true \
--policy.chunk_size=10 \
--policy.n_action_steps=10 \
--policy.max_action_tokens=256 \
--policy.empty_cameras=1 \
```
We then evaluate the finetuned model using the LeRobot LIBERO implementation, by running the following command:
```bash
tasks="libero_object,libero_spatial,libero_goal,libero_10"
lerobot-eval \
--policy.path=lerobot/pi0fast-libero \
--policy.max_action_tokens=256 \
--env.type=libero \
--policy.gradient_checkpointing=false \
--env.task=${tasks} \
--eval.batch_size=1 \
--eval.n_episodes=1 \
--rename_map='{"observation.images.image":"observation.images.base_0_rgb","observation.images.image2":"observation.images.left_wrist_0_rgb"}'
```
**Note:** We set `n_action_steps=10`, similar to the original OpenPI implementation.
### Results
We obtain the following results on the LIBERO benchmark:
| Model | LIBERO Spatial | LIBERO Object | LIBERO Goal | LIBERO 10 | Average |
| ----------- | -------------- | ------------- | ----------- | --------- | -------- |
| **π₀-fast** | 70.0 | 100.0 | 100.0 | 60.0 | **82.5** |
The full evaluation output folder, including videos, is available [here](https://drive.google.com/drive/folders/1HXpwPTRm4hx6g1sF2P7OOqGG0TwPU7LQ?usp=sharing)
## License
This model follows the **Apache 2.0 License**, consistent with the original [OpenPI repository](https://github.com/Physical-Intelligence/openpi).
## References
- [FAST: Efficient Robot Action Tokenization](https://www.physicalintelligence.company/research/fast) - Physical Intelligence Blog
- [OpenPI Repository](https://github.com/Physical-Intelligence/openpi) - Original implementation
- [FAST Tokenizer on Hugging Face](https://huggingface.co/physical-intelligence/fast) - Pre-trained tokenizer
docs/source/policy_walloss_README.md
-45
View File
@@ -1,45 +0,0 @@
# WALL-OSS
This repository contains the Hugging Face port of [**WALL-OSS**](https://x2robot.com/en/research/68bc2cde8497d7f238dde690), a Vision-Language-Action model for cross-embodiment robotic control based on Qwen2.5-VL with flow matching/FAST action prediction.
---
## Model Overview
| Feature | Description |
| ------------------ | ----------------------------------------------------- |
| Base Model | Qwen2.5-VL (Vision-Language Model) |
| Action Prediction | Flow Matching (diffusion) or FAST (discrete tokens) |
| Architecture | Mixture of Experts (MoE) with action-specific routing |
| Multi-Modal Inputs | Vision (images/videos), Language, Proprioception |
---
## Additional Resources
Paper: https://arxiv.org/pdf/2509.11766
Official Repository: https://github.com/X-Square-Robot/wall-x
Hugging Face: https://huggingface.co/x-square-robot
---
## Citation
If you use this work, please cite:
```bibtex
@article{zhai2025igniting,
title = {Igniting VLMs Toward the Embodied Space},
author = {Zhai, Andy and Liu, Brae and Fang, Bruno and Cai, Chalse and Ma, Ellie and Yin, Ethan and Wang, Hao and Zhou, Hugo and Wang, James and Shi, Lights and Liang, Lucy and Wang, Make and Wang, Qian and Gan, Roy and Yu, Ryan and Li, Shalfun and Liu, Starrick and Chen, Sylas and Chen, Vincent and Xu, Zach},
journal = {arXiv preprint arXiv:2509.11766},
year = {2025}
}
```
---
## License
This model follows the **Apache 2.0 License**, consistent with the original [WallX repository](https://github.com/X-Square-Robot/wall-x).
docs/source/processors_robots_teleop.mdx
+3 -3
View File
@@ -30,7 +30,7 @@ Each of these pipelines handle different conversions between different action an
Below is an example of the three pipelines that we use in the phone to SO-100 follower examples:
```python
```69:90:examples/phone_so100_record.py
phone_to_robot_ee_pose_processor = RobotProcessorPipeline[RobotAction, RobotAction]( # teleop -> dataset action
steps=[
MapPhoneActionToRobotAction(platform=teleop_config.phone_os),
@@ -84,7 +84,7 @@ Dataset features are determined by the keys saved in the dataset. Each step can
Below is and example of how we declare features with the `transform_features` method in the phone to SO-100 follower examples:
```python
```src/lerobot/robots/so100_follower/robot_kinematic_processor.py
def transform_features(
self, features: dict[PipelineFeatureType, dict[str, PolicyFeature]]
) -> dict[PipelineFeatureType, dict[str, PolicyFeature]]:
@@ -103,7 +103,7 @@ Here we declare what PolicyFeatures we modify in this step, so we know what feat
Below is an example of how we aggregate and merge features in the phone to SO-100 record example:
```python
```121:145:examples/phone_so100_record.py
features=combine_feature_dicts(
# Run the feature contract of the pipelines
# This tells you how the features would look like after the pipeline steps
docs/source/reachy2.mdx
+21 -42
View File
@@ -38,7 +38,6 @@ docker run --rm -it \
start_rviz:=true start_sdk_server:=true mujoco:=true
```
> [!NOTE]
> If MuJoCo runs slowly (low simulation frequency), append `-e LD_LIBRARY_PATH="/opt/host-libs:$LD_LIBRARY_PATH" \` to the previous command to improve performance:
>
> ```
@@ -142,7 +141,7 @@ If you choose this option but still want to use the VR teleoperation application
First add reachy2 and reachy2_teleoperator to the imports of the record script. Then you can use the following command:
```bash
lerobot-record \
python -m lerobot.record \
--robot.type=reachy2 \
--robot.ip_address=192.168.0.200 \
--robot.id=r2-0000 \
@@ -151,7 +150,6 @@ lerobot-record \
--teleop.type=reachy2_teleoperator \
--teleop.ip_address=192.168.0.200 \
--teleop.with_mobile_base=false \
--robot.with_torso_camera=true \
--dataset.repo_id=pollen_robotics/record_test \
--dataset.single_task="Reachy 2 recording test" \
--dataset.num_episodes=1 \
@@ -159,9 +157,6 @@ lerobot-record \
--dataset.fps=15 \
--dataset.push_to_hub=true \
--dataset.private=true \
--dataset.streaming_encoding=true \
--dataset.encoder_threads=2 \
# --dataset.vcodec=auto \
--display_data=true
```
@@ -170,7 +165,7 @@ lerobot-record \
**Extended setup overview (all options included):**
```bash
lerobot-record \
python -m lerobot.record \
--robot.type=reachy2 \
--robot.ip_address=192.168.0.200 \
--robot.use_external_commands=true \
@@ -182,8 +177,6 @@ lerobot-record \
--robot.with_left_teleop_camera=true \
--robot.with_right_teleop_camera=true \
--robot.with_torso_camera=false \
--robot.camera_width=640 \
--robot.camera_height=480 \
--robot.disable_torque_on_disconnect=false \
--robot.max_relative_target=5.0 \
--teleop.type=reachy2_teleoperator \
@@ -201,9 +194,6 @@ lerobot-record \
--dataset.fps=15 \
--dataset.push_to_hub=true \
--dataset.private=true \
--dataset.streaming_encoding=true \
--dataset.encoder_threads=2 \
# --dataset.vcodec=auto \
--display_data=true
```
@@ -222,10 +212,9 @@ Must be set to true if a compliant Reachy 2 is used to control another one.
From our initial tests, recording **all** joints when only some are moving can reduce model quality with certain policies.
To avoid this, you can exclude specific parts from recording and replay using:
```bash
````
--robot.with_<part>=false
```
```,
with `<part>` being one of : `mobile_base`, `l_arm`, `r_arm", `neck`, `antennas`.
It determine whether the corresponding part is recorded in the observations. True if not set.
@@ -233,60 +222,49 @@ By default, **all parts are recorded**.
The same per-part mechanism is available in `reachy2_teleoperator` as well.
```bash
--teleop.with\_<part>
```
````
--teleop.with\_<part>
```
with `<part>` being one of : `mobile_base`, `l_arm`, `r_arm", `neck`, `antennas`.
Determine whether the corresponding part is recorded in the actions. True if not set.
> **Important:** In a given session, the **enabled parts must match** on both the robot and the teleoperator.
> For example, if the robot runs with `--robot.with_mobile_base=false`, the teleoperator must disable the same part `--teleoperator.with_mobile_base=false`.
For example, if the robot runs with `--robot.with_mobile_base=false`, the teleoperator must disable the same part `--teleoperator.with_mobile_base=false`.
##### Use the relevant cameras
You can do the same for **cameras**. Enable or disable each camera with default parameters using:
You can do the same for **cameras**. By default, only the **teleoperation cameras** are recorded (both `left_teleop_camera` and `right_teleop_camera`). Enable or disable each camera with:
```bash
--robot.with_left_teleop_camera=<true|false> \
--robot.with_right_teleop_camera=<true|false> \
```
--robot.with_left_teleop_camera=<true|false>
--robot.with_right_teleop_camera=<true|false>
--robot.with_torso_camera=<true|false>
```
By default, no camera is recorded, all camera arguments are set to `false`.
If you want to, you can use custom `width` and `height` parameters for Reachy 2's cameras using the `--robot.camera_width` & `--robot.camera_height` argument:
````
```bash
--robot.camera_width=1920 \
--robot.camera_height=1080
```
This will change the resolution of all 3 default robot cameras (enabled by the above bool arguments).
If you want, you can add additional cameras other than the ones in the robot as usual with:
```bash
--robot.cameras="{ extra: {type: opencv, index_or_path: 42, width: 640, height: 480, fps: 30}}" \
```
## Step 2: Replay
Make sure the robot is configured with the same parts as the dataset:
```bash
lerobot-replay \
python -m lerobot.replay \
--robot.type=reachy2 \
--robot.ip_address=192.168.0.200 \
--robot.use_external_commands=false \
--robot.with_mobile_base=false \
--dataset.repo_id=pollen_robotics/record_test \
--dataset.episode=0
```
--display_data=true
````
## Step 3: Train
```bash
lerobot-train \
python -m lerobot.scripts.train \
--dataset.repo_id=pollen_robotics/record_test \
--policy.type=act \
--output_dir=outputs/train/reachy2_test \
@@ -299,9 +277,10 @@ lerobot-train \
## Step 4: Evaluate
```bash
lerobot-eval \
python -m lerobot.record \
--robot.type=reachy2 \
--robot.ip_address=192.168.0.200 \
--display_data=false \
--dataset.repo_id=pollen_robotics/eval_record_test \
--dataset.single_task="Evaluate reachy2 policy" \
--dataset.num_episodes=10 \
docs/source/sarm.mdx
-592
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@@ -1,592 +0,0 @@
# SARM: Stage-Aware Reward Modeling
SARM (Stage-Aware Reward Modeling) is a video-based reward modeling framework for long-horizon robot manipulation tasks. This guide covers how to train SARM reward models and optionally use them with Reward-Aligned Behavior Cloning (RA-BC).
**Paper**: [SARM: Stage-Aware Reward Modeling for Long Horizon Robot Manipulation](https://arxiv.org/abs/2509.25358)
<img
src="https://huggingface.co/datasets/huggingface/documentation-images/resolve/main/lerobot/lerobot-sarm.png"
alt="An overview of SARM"
width="80%"
/>
## Why Reward Models?
Standard behavior cloning treats all demonstration frames equally, but real-world robot datasets are messy. They contain hesitations, corrections, and variable-quality trajectories. Reward models solve this by learning a generalizable notion of **task progress** from demonstrations: given video frames and a task description, they predict how close the robot is to completing the task (0→1). This learned "progress signal" can be used in multiple ways, two promising applications are: (1) **weighted imitation learning** (RA-BC), where high-progress frames receive more weight during policy training, and (2) **reinforcement learning**, where the reward model provides dense rewards for online or offline policy improvement.
## Overview
SARM has following features:
1. **Stage-aware architecture**: Jointly predicts the high-level task stage and fine-grained progress within each stage
2. **Subtask annotations**: Uses natural language subtask annotations to derive consistent progress labels
3. **Temporal proportions**: Computes dataset-level priors (α̅\_k) for each subtask to normalize progress across variable-length demonstrations
SARM trains on a compact **stage+tau** target for each frame:
- **stage**: integer stage index `k ∈ {0, ..., K-1}`
- **τ (tau)**: within-stage progress `τ ∈ [0, 1]`
- **target encoding**: `y = k + τ` (this is what the dataset processor produces)
At inference time (and in downstream RA-BC), SARM converts the raw `k + τ` value into a **normalized progress** in `[0, 1]` using dataset-level **temporal proportions** `α̅_k` (stored in `meta/temporal_proportions_*.json`).
This matches **Formula (2)** from the paper:
```
progress_t = P_{k-1} + α̅_k × τ_t
```
Where:
- `τ_t = (t - s_k) / (e_k - s_k)` is within-subtask normalized time
- `P_{k-1}` is cumulative prior (sum of previous subtask proportions)
- `α̅_k` is the temporal proportion for subtask k
This ensures identical task states map to consistent progress values, even across demonstrations of different lengths.
## Inputs and Targets (What the new code expects)
SARM is trained through its processor (`src/lerobot/policies/sarm/processor_sarm.py`), which:
- **Encodes** images and task text with CLIP (ViT-B/32) into `video_features` and `text_features`
- **Pads/truncates** robot state into `state_features` (up to `max_state_dim`)
- **Builds targets** as `sparse_targets` (and `dense_targets` in `dense_only`/`dual`) using the stage+tau encoding `y = k + τ`
- **Masks rewind frames** using a per-sample `lengths` tensor (rewind is a training-time augmentation)
At minimum, each training sample needs:
- `task` (string): task description
- `policy.image_key` images and `policy.state_key` states from the dataset
---
## Annotation Modes
You can choose from **3 annotation modes** that determine how progress labels are computed:
| Mode | Annotations Required | Heads | Use Case |
| -------------- | -------------------- | ---------------------------- | ------------------------------------------------------------ |
| `single_stage` | None | Sparse only | Simple tasks, quick experiments, no VLM needed |
| `dense_only` | Dense (VLM) | Dual (sparse auto-generated) | Detailed subtask tracking without defining high-level stages |
| `dual` | Sparse + Dense (VLM) | Dual | Full SARM paper setup with both granularities |
### Mode Details
<hfoptions id="mode_explanation">
<hfoption id="single_stage">
**No annotations required.** The entire episode is treated as a single stage called `"task"`, and progress is linear from 0 to 1 over the episode duration.
- **Sparse head**: 1 stage ("task"), linear progress
- **Dense head**: Not used
- **Best for**: Simple tasks, quick experiments, or when VLM annotation is not available
## Set Up Your Environment
1. Install LeRobot by following our [Installation Guide](./installation).
2. Install SARM dependencies by running:
```bash
pip install -e ".[sarm]"
```
Workflow:
```
1. Train SARM → 2. Visualize predictions → 3. (Optional) Train policy with RA-BC
```
</hfoption>
<hfoption id="dense_only">
**Only dense (fine-grained) annotations from a VLM.** The sparse head automatically uses a single `"task"` stage covering the full episode, while the dense head learns detailed subtask progression.
- **Sparse head**: 1 stage ("task"), linear progress (auto-generated)
- **Dense head**: Multiple fine-grained stages from VLM annotations
- **Best for**: When you want detailed subtask tracking but don't need to define high-level stages
Workflow:
```
1. Annotate (dense) → 2. Verify → 3. Train SARM → 4. Visualize → 5. (Optional) Train policy with RA-BC
```
</hfoption>
<hfoption id="dual">
**Both sparse and dense annotations from VLM.** Full dual-head mode as described in the SARM paper, with both high-level (sparse) and fine-grained (dense) stage predictions.
- **Sparse head**: High-level stages from VLM annotations
- **Dense head**: Fine-grained stages from VLM annotations
- **Best for**: Complex multi-stage tasks where both granularities are useful
Workflow:
```
1. Annotate (sparse+dense) → 2. Verify → 3. Train SARM → 4. Visualize → 5. (Optional) Train policy with RA-BC
```
</hfoption>
</hfoptions>
---
## Step 1: Subtask Annotation
<hfoptions id="annotation_mode">
<hfoption id="single_stage">
**No annotation required!** Skip this step entirely. The model will use the episode's task description and compute linear progress automatically.
</hfoption>
<hfoption id="dense_only">
Generate **dense (fine-grained) annotations only** using a VLM. The sparse stage will be auto-generated.
```bash
python src/lerobot/data_processing/sarm_annotations/subtask_annotation.py \
--repo-id your-username/your-dataset \
--dense-only \
--dense-subtasks "Bring robot arms up from starting position,Grab near side and do 1st fold,Grab side and do 2nd fold,Grab side and do 3rd fold to finish folding" \
--video-key observation.images.base \
--num-workers 4 \
--push-to-hub
```
**What gets saved:**
- `meta/temporal_proportions_sparse.json` - Auto-generated sparse proportions (`{"task": 1.0}`)
- `meta/temporal_proportions_dense.json` - Dense temporal proportions
- Per-episode columns in `episodes/*.parquet`:
- `dense_subtask_names`, `dense_subtask_start_frames`, `dense_subtask_end_frames`
- (also time-based columns: `dense_subtask_start_times`, `dense_subtask_end_times`)
</hfoption>
<hfoption id="dual">
Generate **both sparse (high-level) and dense (fine-grained) annotations** using a VLM.
```bash
python src/lerobot/data_processing/sarm_annotations/subtask_annotation.py \
--repo-id your-username/your-dataset \
--sparse-subtasks "Bring arms up from starting position,Fold the towel (3 folds in total)" \
--dense-subtasks "Bring robot arms up from starting position,Grab near side and do 1st fold,Grab side and do 2nd fold,Grab side and do 3rd fold to finish folding" \
--video-key observation.images.base \
--num-workers 4 \
--push-to-hub
```
**What gets saved:**
- `meta/temporal_proportions_sparse.json` - Sparse temporal proportions
- `meta/temporal_proportions_dense.json` - Dense temporal proportions
- Per-episode columns in `episodes/*.parquet`:
- `sparse_subtask_names`, `sparse_subtask_start_frames`, `sparse_subtask_end_frames`
- `dense_subtask_names`, `dense_subtask_start_frames`, `dense_subtask_end_frames`
- (also time-based columns: `*_subtask_start_times`, `*_subtask_end_times`)
</hfoption>
</hfoptions>
### Annotation Arguments
| Argument | Description |
| ---------------------- | ------------------------------------------------------------------------------- |
| `--repo-id` | HuggingFace dataset repository ID |
| `--sparse-subtasks` | Comma-separated list of high-level subtask names |
| `--dense-subtasks` | Comma-separated list of fine-grained subtask names |
| `--dense-only` | Generate only dense annotations (auto-creates sparse "task" stage) |
| `--video-key` | Camera/video key to use (e.g., `observation.images.top`) |
| `--num-workers` | Number of parallel GPU workers (default: 1) |
| `--episodes` | Specific episode indices to annotate (default: all) |
| `--skip-existing` | Skip episodes that already have annotations |
| `--model` | VLM model (default: `Qwen/Qwen3-VL-30B-A3B-Instruct`) |
| `--num-visualizations` | Number of episodes to visualize after annotation (default: 5, set to 0 to skip) |
> **Note**: After annotation completes, 5 episodes are automatically visualized by default. Use `--num-visualizations 0` to skip this step.
---
## Step 2: Verify Annotations
<hfoptions id="verify_mode">
<hfoption id="single_stage">
**No verification needed!** Skip this step.
</hfoption>
<hfoption id="dense_only">
Visualize annotations using the `--visualize-only` flag:
```bash
python src/lerobot/data_processing/sarm_annotations/subtask_annotation.py \
--repo-id your-username/your-dataset \
--visualize-only \
--visualize-type dense \
--num-visualizations 5 \
--video-key observation.images.base \
--output-dir ./subtask_viz
```
</hfoption>
<hfoption id="dual">
Visualize annotations using the `--visualize-only` flag:
```bash
python src/lerobot/data_processing/sarm_annotations/subtask_annotation.py \
--repo-id your-username/your-dataset \
--visualize-only \
--visualize-type both \
--num-visualizations 5 \
--video-key observation.images.base \
--output-dir ./subtask_viz
```
</hfoption>
</hfoptions>
This generates visualizations showing video frames with subtask boundaries overlaid and timeline of subtasks.
### Visualization Arguments
| Argument | Description |
| ---------------------- | -------------------------------------------------------------- |
| `--visualize-only` | Only visualize existing annotations (no generation) |
| `--num-visualizations` | Number of episodes to visualize (default: 5) |
| `--visualize-type` | Type of annotations to visualize: `sparse`, `dense`, or `both` |
**Tip**: If annotations are inaccurate, adjust your subtask descriptions to be more specific and re-run.
---
## Step 3: Train SARM
<hfoptions id="train_mode">
<hfoption id="single_stage">
Train with **no annotations** - uses linear progress from 0 to 1:
```bash
lerobot-train \
--dataset.repo_id=your-username/your-dataset \
--policy.type=sarm \
--policy.annotation_mode=single_stage \
--policy.image_key=observation.images.base \
--output_dir=outputs/train/sarm_single \
--batch_size=32 \
--steps=5000 \
--wandb.enable=true \
--wandb.project=sarm \
--policy.repo_id=your-username/your-model-name
```
</hfoption>
<hfoption id="dense_only">
Train with **dense annotations only** (sparse auto-generated):
```bash
lerobot-train \
--dataset.repo_id=your-username/your-dataset \
--policy.type=sarm \
--policy.annotation_mode=dense_only \
--policy.image_key=observation.images.base \
--output_dir=outputs/train/sarm_dense \
--batch_size=32 \
--steps=5000 \
--wandb.enable=true \
--wandb.project=sarm \
--policy.repo_id=your-username/your-model-name
```
</hfoption>
<hfoption id="dual">
Train with **both sparse and dense annotations**:
```bash
lerobot-train \
--dataset.repo_id=your-username/your-dataset \
--policy.type=sarm \
--policy.annotation_mode=dual \
--policy.image_key=observation.images.base \
--output_dir=outputs/train/sarm_dual \
--batch_size=32 \
--steps=5000 \
--wandb.enable=true \
--wandb.project=sarm \
--policy.repo_id=your-username/your-model-name
```
</hfoption>
</hfoptions>
### Multi-GPU Training
Add `accelerate launch --multi_gpu --num_processes=4` to use multiple GPUs for training.
### Training Arguments
| Argument | Description | Default |
| -------------------------- | ----------------------------------------------------------------- | ------------------------ |
| `--policy.annotation_mode` | `single_stage`, `dense_only`, or `dual` | `single_stage` |
| `--policy.image_key` | Camera key for images | `observation.images.top` |
| `--policy.state_key` | Key for joint states | `observation.state` |
| `--policy.n_obs_steps` | Observation history steps (total obs frames = `n_obs_steps + 1`) | `8` |
| `--policy.frame_gap` | Gap (in frames) between sampled observations (at 30 fps: 30 ≈ 1s) | `30` |
---
## Step 4: Visualize Predictions
Use `compute_rabc_weights.py` with `--visualize-only` to visualize model predictions (and, if available, annotation-derived targets) without writing a parquet file.
<hfoptions id="viz_mode">
<hfoption id="single_stage">
```bash
python src/lerobot/policies/sarm/compute_rabc_weights.py \
--dataset-repo-id your-username/your-dataset \
--reward-model-path your-username/sarm-model \
--visualize-only \
--num-visualizations 5 \
--head-mode sparse \
--output-dir ./sarm_viz
```
</hfoption>
<hfoption id="dense_only">
```bash
python src/lerobot/policies/sarm/compute_rabc_weights.py \
--dataset-repo-id your-username/your-dataset \
--reward-model-path your-username/sarm-model \
--visualize-only \
--num-visualizations 5 \
--head-mode dense \
--output-dir ./sarm_viz
```
</hfoption>
<hfoption id="dual">
```bash
python src/lerobot/policies/sarm/compute_rabc_weights.py \
--dataset-repo-id your-username/your-dataset \
--reward-model-path your-username/sarm-model \
--visualize-only \
--num-visualizations 5 \
--head-mode both \
--output-dir ./sarm_viz
```
</hfoption>
</hfoptions>
The visualization shows:
- **Progress plot**: Predicted progress (and optional annotation-derived “GT” when available and `--stride 1`)
- **Stage probabilities**: Stacked area plot of predicted stage probabilities
- **Sample frames**: Key frames from the episode with progress/stage labels
### Visualization Arguments
| Argument | Description |
| ---------------------- | --------------------------------------------------------- |
| `--visualize-only` | Only visualize predictions (no RABC computation) |
| `--num-visualizations` | Number of episodes to visualize (default: 5) |
| `--head-mode` | SARM head to use: `sparse`, `dense`, or `both` |
| `--stride` | Compute every N frames, interpolate the rest (default: 1) |
---
## Step 5 (Optional): Train Policy with RA-BC
Reward-Aligned Behavior Cloning (RA-BC) uses the trained SARM model to weight training samples based on predicted progress improvement. This requires two steps:
1. **Precompute progress values** for all frames using the trained SARM model
2. **Train policy** with RA-BC weighting using the precomputed values
### How RA-BC Works
For each training sample, RA-BC computes the progress delta:
```
r_i = φ(o_{t+Δ}) - φ(o_t)
```
Where `φ` is the SARM progress prediction and `Δ` is the policy's `chunk_size`. Samples with positive progress (good demonstrations) get higher weights, while samples with negative or zero progress get down-weighted.
The weighting follows **Equations 8-9** from the paper:
- **Soft weight**: `w̃_i = clip((r_i 2σ)) / (4σ + ε), 0, 1)`
- **Final weight**: `w_i = 𝟙{r_i > κ} + 𝟙{0 ≤ r_i ≤ κ} × w̃_i`
### Step 5a: Compute SARM Progress Values
First, run the SARM model on all frames in your dataset to compute progress values:
```bash
python src/lerobot/policies/sarm/compute_rabc_weights.py \
--dataset-repo-id your-username/your-dataset \
--reward-model-path your-username/sarm-model \
--head-mode sparse \
--num-visualizations 5 \
--push-to-hub
```
This script:
- Processes all frames and computes progress values
- Saves progress values to a parquet file next to the dataset on disk (defaults to `<dataset_root>/sarm_progress.parquet`)
- Generates visualizations of the first N episodes (default: 5)
**Arguments:**
| Argument | Description | Default |
| ---------------------- | -------------------------------------------------------------- | ---------- |
| `--reward-model-path` | Path to trained SARM model | (required) |
| `--head-mode` | SARM head to use: `sparse`, `dense`, or `both` | `sparse` |
| `--device` | Device for inference | `cuda` |
| `--visualize-only` | Only visualize predictions (no RA-BC computation) | `false` |
| `--num-visualizations` | Number of episodes to visualize (default: 5, set to 0 to skip) | `5` |
**Output format** (`sarm_progress.parquet`):
| Column | Description |
| ----------------- | ---------------------------------------------- |
| `index` | Global frame index in dataset |
| `episode_index` | Episode number |
| `frame_index` | Local frame index within episode |
| `progress_sparse` | Sparse head progress value [0, 1] |
| `progress_dense` | Dense head progress value [0, 1] (if computed) |
### Step 5b: Train Policy with RA-BC
Once you have the progress file, train your policy with RA-BC weighting. The progress file is auto-detected from the dataset path (`sarm_progress.parquet`). Currently PI0, PI0.5 and SmolVLA are supported with RA-BC:
```bash
lerobot-train \
--dataset.repo_id=your-username/your-dataset \
--policy.type=pi0 \
--use_rabc=true \
--rabc_head_mode=sparse \
--rabc_kappa=0.01 \
--output_dir=outputs/train/policy_rabc \
--batch_size=32 \
--steps=40000
```
The training script automatically:
- Loads the precomputed progress values from the parquet file
- Uses the policy's `chunk_size` to compute progress deltas (Δ)
- Computes sample weights based on progress improvement
- Applies weighted loss during training
**RA-BC Arguments:**
| Argument | Description | Default |
| ---------------------- | ---------------------------------------------------------- | ---------------------------------- |
| `--use_rabc` | Enable RA-BC sample weighting | `false` |
| `--rabc_progress_path` | Path to progress parquet file (auto-detected from dataset) | `sarm_progress.parquet` in dataset |
| `--rabc_head_mode` | Which SARM head's progress to use: `sparse` or `dense` | `sparse` |
| `--rabc_kappa` | Threshold κ for high-quality samples | `0.01` |
### Tuning RA-BC Kappa
The `kappa` parameter is the threshold that determines which samples get full weight (w=1). Understanding how to tune it is critical for RA-BC to work effectively.
**How the weighting works:**
| Condition | Weight |
| ------------------- | ----------------------- |
| `delta > kappa` | 1.0 (hard threshold) |
| `0 ≤ delta ≤ kappa` | Soft weight from Eq. 8 |
| `delta < 0` | 0.0 (negative progress) |
**Diagnosing kappa issues:**
Monitor these WandB metrics during training:
| Metric | Healthy Range | Problem Indicator |
| ------------------ | ------------- | ------------------------- |
| `rabc_mean_weight` | 0.3 - 0.8 | ≈ 1.0 means kappa too low |
| `rabc_delta_mean` | > 0 | Should be positive |
| `rabc_delta_std` | > 0 | Variance in data quality |
**If `rabc_mean_weight ≈ 1.0`:** Your kappa is too low. Most samples have `delta > kappa` and bypass the soft-weighting entirely. RA-BC becomes equivalent to vanilla BC.
**Setting kappa based on your data:**
The default `kappa=0.01` was tuned for the paper's T-shirt folding task (~90s episodes at 30fps). For your dataset, check the logged `rabc_delta_mean` and `rabc_delta_std`:
```
# If delta_mean ≈ 0.03 and delta_std ≈ 0.02:
# Most deltas fall in range [0.01, 0.05]
# Option 1: Set kappa = delta_mean (medium selectivity)
--rabc_kappa=0.03
# Option 2: Set kappa = delta_mean + delta_std (high selectivity)
--rabc_kappa=0.05
# Option 3: Set kappa = delta_mean + 2*delta_std (very selective)
--rabc_kappa=0.07
```
**When RA-BC may not help:**
If your dataset is already high quality (consistent progress across all demonstrations), RA-BC won't provide much benefit since there's nothing to filter.
### Multi-GPU Training with RA-BC
```bash
accelerate launch \
--multi_gpu \
--num_processes=4 \
src/lerobot/scripts/lerobot_train.py \
--dataset.repo_id=your-username/your-dataset \
--policy.type=pi0 \
--use_rabc=true \
--rabc_kappa=0.01 \
--output_dir=outputs/train/policy_rabc \
--batch_size=32 \
--steps=40000
```
---
## Tips & Best Practices
### Choosing a Mode
- **Start with `single_stage`** for quick experiments - no annotation overhead
- Use **`dense_only`** when you want detailed progress tracking but tasks don't have clear high-level stages
- Use **`dual`** for complex tasks where both coarse and fine-grained progress is meaningful
### Annotation Quality
1. **Be specific with subtask names**: Instead of "fold", use "grab near side and fold toward center"
2. **Verify with visualization**: Always check a few episodes before training
3. **Consistent naming**: Use the same subtask names across all episodes
### RA-BC
1. **Train SARM first**: RA-BC quality depends entirely on SARM quality
2. **Monitor `rabc_mean_weight`**: If it's ≈ 1.0, increase kappa (see [Tuning RA-BC Kappa](#tuning-ra-bc-kappa))
---
## Citation
```bibtex
@article{chen2025sarm,
title={SARM: Stage-Aware Reward Modeling for Long Horizon Robot Manipulation},
author={Chen, Qianzhong and Yu, Justin and Schwager, Mac and Abbeel, Pieter and Shentu, Yide and Wu, Philipp},
journal={arXiv preprint arXiv:2509.25358},
year={2025}
}
```
docs/source/smolvla.mdx
-3
View File
@@ -106,9 +106,6 @@ lerobot-record \
--dataset.repo_id=${HF_USER}/eval_DATASET_NAME_test \ # <- This will be the dataset name on HF Hub
--dataset.episode_time_s=50 \
--dataset.num_episodes=10 \
--dataset.streaming_encoding=true \
--dataset.encoder_threads=2 \
# --dataset.vcodec=auto \
# <- Teleop optional if you want to teleoperate in between episodes \
# --teleop.type=so100_leader \
# --teleop.port=/dev/ttyACM0 \
docs/source/so100.mdx
+4 -4
View File
@@ -103,7 +103,7 @@ lerobot-setup-motors \
<!-- prettier-ignore-start -->
```python
from lerobot.robots.so_follower import SO100Follower, SO100FollowerConfig
from lerobot.robots.so100_follower import SO100Follower, SO100FollowerConfig
config = SO100FollowerConfig(
port="/dev/tty.usbmodem585A0076841",
@@ -177,7 +177,7 @@ lerobot-setup-motors \
<!-- prettier-ignore-start -->
```python
from lerobot.teleoperators.so_leader import SO100Leader, SO100LeaderConfig
from lerobot.teleoperators.so100_leader import SO100Leader, SO100LeaderConfig
config = SO100LeaderConfig(
port="/dev/tty.usbmodem585A0076841",
@@ -579,7 +579,7 @@ lerobot-calibrate \
<!-- prettier-ignore-start -->
```python
from lerobot.robots.so_follower import SO100FollowerConfig, SO100Follower
from lerobot.robots.so100_follower import SO100FollowerConfig, SO100Follower
config = SO100FollowerConfig(
port="/dev/tty.usbmodem585A0076891",
@@ -617,7 +617,7 @@ lerobot-calibrate \
<!-- prettier-ignore-start -->
```python
from lerobot.teleoperators.so_leader import SO100LeaderConfig, SO100Leader
from lerobot.teleoperators.so100_leader import SO100LeaderConfig, SO100Leader
config = SO100LeaderConfig(
port="/dev/tty.usbmodem58760431551",
docs/source/so101.mdx
+187 -200
View File
@@ -1,18 +1,5 @@
# SO-101
<div style="display: flex; align-items: center; gap: 10px;">
<img
src="https://huggingface.co/datasets/huggingface/documentation-images/resolve/main/lerobot/SO101_Follower.webp"
alt="SO-101"
width="60%"
/>
<img
src="https://huggingface.co/datasets/huggingface/documentation-images/resolve/main/lerobot/SO101_Leader.webp"
alt="SO-101"
width="60%"
/>
</div>
In the steps below, we explain how to assemble our flagship robot, the SO-101.
## Source the parts
@@ -43,191 +30,6 @@ The follower arm uses 6x STS3215 motors with 1/345 gearing. The leader, however,
| Wrist Roll | 5 | 1 / 147 |
| Gripper | 6 | 1 / 147 |
## Configure the motors
### 1. Find the USB ports associated with each arm
To find the port for each bus servo adapter, connect MotorBus to your computer via USB and power. Run the following script and disconnect the MotorBus when prompted:
```bash
lerobot-find-port
```
<hfoptions id="example">
<hfoption id="Mac">
Example output:
```
Finding all available ports for the MotorBus.
['/dev/tty.usbmodem575E0032081', '/dev/tty.usbmodem575E0031751']
Remove the USB cable from your MotorsBus and press Enter when done.
[...Disconnect corresponding leader or follower arm and press Enter...]
The port of this MotorsBus is /dev/tty.usbmodem575E0032081
Reconnect the USB cable.
```
Where the found port is: `/dev/tty.usbmodem575E0032081` corresponding to your leader or follower arm.
</hfoption>
<hfoption id="Linux">
On Linux, you might need to give access to the USB ports by running:
```bash
sudo chmod 666 /dev/ttyACM0
sudo chmod 666 /dev/ttyACM1
```
Example output:
```
Finding all available ports for the MotorBus.
['/dev/ttyACM0', '/dev/ttyACM1']
Remove the usb cable from your MotorsBus and press Enter when done.
[...Disconnect corresponding leader or follower arm and press Enter...]
The port of this MotorsBus is /dev/ttyACM1
Reconnect the USB cable.
```
Where the found port is: `/dev/ttyACM1` corresponding to your leader or follower arm.
</hfoption>
</hfoptions>
### 2. Set the motors ids and baudrates
Each motor is identified by a unique id on the bus. When brand new, motors usually come with a default id of `1`. For the communication to work properly between the motors and the controller, we first need to set a unique, different id to each motor. Additionally, the speed at which data is transmitted on the bus is determined by the baudrate. In order to talk to each other, the controller and all the motors need to be configured with the same baudrate.
To that end, we first need to connect to each motor individually with the controller in order to set these. Since we will write these parameters in the non-volatile section of the motors' internal memory (EEPROM), we'll only need to do this once.
If you are repurposing motors from another robot, you will probably also need to perform this step as the ids and baudrate likely won't match.
The video below shows the sequence of steps for setting the motor ids.
##### Setup motors video
<div class="video-container">
<video controls width="600">
<source
src="https://huggingface.co/datasets/huggingface/documentation-images/resolve/main/lerobot/setup_motors_so101_2.mp4"
type="video/mp4"
/>
</video>
</div>
#### Follower
Connect the usb cable from your computer and the power supply to the follower arm's controller board. Then, run the following command or run the API example with the port you got from the previous step. You'll also need to give your leader arm a name with the `id` parameter.
<hfoptions id="setup_motors">
<hfoption id="Command">
```bash
lerobot-setup-motors \
--robot.type=so101_follower \
--robot.port=/dev/tty.usbmodem585A0076841 # <- paste here the port found at previous step
```
</hfoption>
<hfoption id="API example">
<!-- prettier-ignore-start -->
```python
from lerobot.robots.so_follower import SO101Follower, SO101FollowerConfig
config = SO101FollowerConfig(
port="/dev/tty.usbmodem585A0076841",
id="my_awesome_follower_arm",
)
follower = SO101Follower(config)
follower.setup_motors()
```
<!-- prettier-ignore-end -->
</hfoption>
</hfoptions>
You should see the following instruction
```bash
Connect the controller board to the 'gripper' motor only and press enter.
```
As instructed, plug the gripper's motor. Make sure it's the only motor connected to the board, and that the motor itself is not yet daisy-chained to any other motor. As you press `[Enter]`, the script will automatically set the id and baudrate for that motor.
<details>
<summary>Troubleshooting</summary>
If you get an error at that point, check your cables and make sure they are plugged in properly:
<ul>
<li>Power supply</li>
<li>USB cable between your computer and the controller board</li>
<li>The 3-pin cable from the controller board to the motor</li>
</ul>
If you are using a Waveshare controller board, make sure that the two jumpers are set on the `B` channel (USB).
</details>
You should then see the following message:
```bash
'gripper' motor id set to 6
```
Followed by the next instruction:
```bash
Connect the controller board to the 'wrist_roll' motor only and press enter.
```
You can disconnect the 3-pin cable from the controller board, but you can leave it connected to the gripper motor on the other end, as it will already be in the right place. Now, plug in another 3-pin cable to the wrist roll motor and connect it to the controller board. As with the previous motor, make sure it is the only motor connected to the board and that the motor itself isn't connected to any other one.
Repeat the operation for each motor as instructed.
> [!TIP]
> Check your cabling at each step before pressing Enter. For instance, the power supply cable might disconnect as you manipulate the board.
When you are done, the script will simply finish, at which point the motors are ready to be used. You can now plug the 3-pin cable from each motor to the next one, and the cable from the first motor (the 'shoulder pan' with id=1) to the controller board, which can now be attached to the base of the arm.
#### Leader
Do the same steps for the leader arm.
<hfoptions id="setup_motors">
<hfoption id="Command">
```bash
lerobot-setup-motors \
--teleop.type=so101_leader \
--teleop.port=/dev/tty.usbmodem575E0031751 # <- paste here the port found at previous step
```
</hfoption>
<hfoption id="API example">
<!-- prettier-ignore-start -->
```python
from lerobot.teleoperators.so_leader import SO101Leader, SO101LeaderConfig
config = SO101LeaderConfig(
port="/dev/tty.usbmodem585A0076841",
id="my_awesome_leader_arm",
)
leader = SO101Leader(config)
leader.setup_motors()
```
<!-- prettier-ignore-end -->
</hfoption>
</hfoptions>
### Clean Parts
Remove all support material from the 3D-printed parts. The easiest way to do this is using a small screwdriver to get underneath the support material.
@@ -353,6 +155,191 @@ It is advisable to install one 3-pin cable in the motor after placing them befor
</hfoption>
</hfoptions>
## Configure the motors
### 1. Find the USB ports associated with each arm
To find the port for each bus servo adapter, connect MotorBus to your computer via USB and power. Run the following script and disconnect the MotorBus when prompted:
```bash
lerobot-find-port
```
<hfoptions id="example">
<hfoption id="Mac">
Example output:
```
Finding all available ports for the MotorBus.
['/dev/tty.usbmodem575E0032081', '/dev/tty.usbmodem575E0031751']
Remove the USB cable from your MotorsBus and press Enter when done.
[...Disconnect corresponding leader or follower arm and press Enter...]
The port of this MotorsBus is /dev/tty.usbmodem575E0032081
Reconnect the USB cable.
```
Where the found port is: `/dev/tty.usbmodem575E0032081` corresponding to your leader or follower arm.
</hfoption>
<hfoption id="Linux">
On Linux, you might need to give access to the USB ports by running:
```bash
sudo chmod 666 /dev/ttyACM0
sudo chmod 666 /dev/ttyACM1
```
Example output:
```
Finding all available ports for the MotorBus.
['/dev/ttyACM0', '/dev/ttyACM1']
Remove the usb cable from your MotorsBus and press Enter when done.
[...Disconnect corresponding leader or follower arm and press Enter...]
The port of this MotorsBus is /dev/ttyACM1
Reconnect the USB cable.
```
Where the found port is: `/dev/ttyACM1` corresponding to your leader or follower arm.
</hfoption>
</hfoptions>
### 2. Set the motors ids and baudrates
Each motor is identified by a unique id on the bus. When brand new, motors usually come with a default id of `1`. For the communication to work properly between the motors and the controller, we first need to set a unique, different id to each motor. Additionally, the speed at which data is transmitted on the bus is determined by the baudrate. In order to talk to each other, the controller and all the motors need to be configured with the same baudrate.
To that end, we first need to connect to each motor individually with the controller in order to set these. Since we will write these parameters in the non-volatile section of the motors' internal memory (EEPROM), we'll only need to do this once.
If you are repurposing motors from another robot, you will probably also need to perform this step as the ids and baudrate likely won't match.
The video below shows the sequence of steps for setting the motor ids.
##### Setup motors video
<div class="video-container">
<video controls width="600">
<source
src="https://huggingface.co/datasets/huggingface/documentation-images/resolve/main/lerobot/setup_motors_so101_2.mp4"
type="video/mp4"
/>
</video>
</div>
#### Follower
Connect the usb cable from your computer and the power supply to the follower arm's controller board. Then, run the following command or run the API example with the port you got from the previous step. You'll also need to give your leader arm a name with the `id` parameter.
<hfoptions id="setup_motors">
<hfoption id="Command">
```bash
lerobot-setup-motors \
--robot.type=so101_follower \
--robot.port=/dev/tty.usbmodem585A0076841 # <- paste here the port found at previous step
```
</hfoption>
<hfoption id="API example">
<!-- prettier-ignore-start -->
```python
from lerobot.robots.so101_follower import SO101Follower, SO101FollowerConfig
config = SO101FollowerConfig(
port="/dev/tty.usbmodem585A0076841",
id="my_awesome_follower_arm",
)
follower = SO101Follower(config)
follower.setup_motors()
```
<!-- prettier-ignore-end -->
</hfoption>
</hfoptions>
You should see the following instruction
```bash
Connect the controller board to the 'gripper' motor only and press enter.
```
As instructed, plug the gripper's motor. Make sure it's the only motor connected to the board, and that the motor itself is not yet daisy-chained to any other motor. As you press `[Enter]`, the script will automatically set the id and baudrate for that motor.
<details>
<summary>Troubleshooting</summary>
If you get an error at that point, check your cables and make sure they are plugged in properly:
<ul>
<li>Power supply</li>
<li>USB cable between your computer and the controller board</li>
<li>The 3-pin cable from the controller board to the motor</li>
</ul>
If you are using a Waveshare controller board, make sure that the two jumpers are set on the `B` channel (USB).
</details>
You should then see the following message:
```bash
'gripper' motor id set to 6
```
Followed by the next instruction:
```bash
Connect the controller board to the 'wrist_roll' motor only and press enter.
```
You can disconnect the 3-pin cable from the controller board, but you can leave it connected to the gripper motor on the other end, as it will already be in the right place. Now, plug in another 3-pin cable to the wrist roll motor and connect it to the controller board. As with the previous motor, make sure it is the only motor connected to the board and that the motor itself isn't connected to any other one.
Repeat the operation for each motor as instructed.
> [!TIP]
> Check your cabling at each step before pressing Enter. For instance, the power supply cable might disconnect as you manipulate the board.
When you are done, the script will simply finish, at which point the motors are ready to be used. You can now plug the 3-pin cable from each motor to the next one, and the cable from the first motor (the 'shoulder pan' with id=1) to the controller board, which can now be attached to the base of the arm.
#### Leader
Do the same steps for the leader arm.
<hfoptions id="setup_motors">
<hfoption id="Command">
```bash
lerobot-setup-motors \
--teleop.type=so101_leader \
--teleop.port=/dev/tty.usbmodem575E0031751 # <- paste here the port found at previous step
```
</hfoption>
<hfoption id="API example">
<!-- prettier-ignore-start -->
```python
from lerobot.teleoperators.so101_leader import SO101Leader, SO101LeaderConfig
config = SO101LeaderConfig(
port="/dev/tty.usbmodem585A0076841",
id="my_awesome_leader_arm",
)
leader = SO101Leader(config)
leader.setup_motors()
```
<!-- prettier-ignore-end -->
</hfoption>
</hfoptions>
## Calibrate
Next, you'll need to calibrate your robot to ensure that the leader and follower arms have the same position values when they are in the same physical position.
@@ -377,7 +364,7 @@ lerobot-calibrate \
<!-- prettier-ignore-start -->
```python
from lerobot.robots.so_follower import SO101FollowerConfig, SO101Follower
from lerobot.robots.so101_follower import SO101FollowerConfig, SO101Follower
config = SO101FollowerConfig(
port="/dev/tty.usbmodem585A0076891",
@@ -426,7 +413,7 @@ lerobot-calibrate \
<!-- prettier-ignore-start -->
```python
from lerobot.teleoperators.so_leader import SO101LeaderConfig, SO101Leader
from lerobot.teleoperators.so101_leader import SO101LeaderConfig, SO101Leader
config = SO101LeaderConfig(
port="/dev/tty.usbmodem58760431551",
docs/source/streaming_video_encoding.mdx
-155
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@@ -1,155 +0,0 @@
# Streaming Video Encoding Guide
## 1. Overview
Streaming video encoding eliminates the traditional PNG round-trip during video dataset recording. Instead of:
1. Capture frame -> write PNG to disk -> (at episode end) read PNG's -> encode to MP4 -> delete PNG's
Frames can be encoded in real-time during capture:
1. Capture frame -> queue to encoder thread -> encode to MP4 directly
This makes `save_episode()` near-instant (the video is already encoded by the time the episode ends) and removes the blocking wait that previously occurred between episodes, especially with multiple cameras in long episodes.
## 2. Tuning Parameters
| Parameter | CLI Flag | Type | Default | Description |
| ----------------------- | --------------------------------- | ------------- | ------------- | ----------------------------------------------------------------- |
| `streaming_encoding` | `--dataset.streaming_encoding` | `bool` | `True` | Enable real-time encoding during capture |
| `vcodec` | `--dataset.vcodec` | `str` | `"libsvtav1"` | Video codec. `"auto"` detects best HW encoder |
| `encoder_threads` | `--dataset.encoder_threads` | `int \| None` | `None` (auto) | Threads per encoder instance. `None` will leave the vcoded decide |
| `encoder_queue_maxsize` | `--dataset.encoder_queue_maxsize` | `int` | `60` | Max buffered frames per camera (~2s at 30fps). Consumes RAM |
## 3. Performance Considerations
Streaming encoding means the CPU is encoding video **during** the capture loop, not after. This creates a CPU budget that must be shared between:
- **Control loop** (reading cameras, control the robot, writing non-video data)
- **Encoder threads** (one pool per camera)
- **Rerun visualization** (if enabled)
- **OS and other processes**
### Resolution & Number of Cameras Impact
| Setup | Throughput (px/sec) | CPU Encoding Load | Notes |
| ------------------------- | ------------------- | ----------------- | ------------------------------ |
| 2camsx 640x480x3 @30fps | 55M | Low | Works on most systems |
| 2camsx 1280x720x3 @30fps | 165M | Moderate | Comfortable on modern systems |
| 2camsx 1920x1080x3 @30fps | 373M | High | Requires powerful high-end CPU |
### `encoder_threads` Tuning
This parameter controls how many threads each encoder instance uses internally:
- **Higher values** (e.g., 4-5): Faster encoding, but uses more CPU cores per camera. Good for high-end systems with many cores.
- **Lower values** (e.g., 1-2): Less CPU per camera, freeing cores for capture and visualization. Good for low-res images and capable CPUs.
- **`None` (default)**: Lets the codec decide. Information available in the codec logs.
### Backpressure and Frame Dropping
Each camera has a bounded queue (`encoder_queue_maxsize`, default 60 frames). When the encoder can't keep up:
1. The queue fills up (consuming RAM)
2. New frames are **dropped** (not blocked) — the capture loop continues uninterrupted
3. A warning is logged: `"Encoder queue full for {camera}, dropped N frame(s)"`
4. At episode end, total dropped frames per camera are reported
### Symptoms of Encoder Falling Behind
- **System feels laggy and freezes**: all CPUs are at 100%
- **Dropped frame warnings** in the log or lower frames/FPS than expected in the recorded dataset
- **Choppy robot movement**: If CPU is severely overloaded, even the capture loop may be affected
- **Accumulated rerun lag**: Visualization falls behind real-time
## 4. Hardware-Accelerated Encoding
### When to Use
Use HW encoding when:
- CPU is the bottleneck (dropped frames, choppy robot, rerun lag)
- You have compatible hardware (GPU or dedicated encoder)
- You're recording at high throughput (high resolution or with many cameras)
### Choosing a Codec
| Codec | CPU Usage | File Size | Quality | Notes |
| --------------------- | --------- | -------------- | ------- | ---------------------------------------------------------------- |
| `libsvtav1` (default) | High | Smallest | Best | Default. Best compression but most CPU-intensive |
| `h264` | Medium | ~30-50% larger | Good | Software H.264. Lower CPU |
| HW encoders | Very Low | Largest | Good | Offloads to dedicated hardware. Best for CPU-constrained systems |
### Available HW Encoders
| Encoder | Platform | Hardware | CLI Value |
| ------------------- | ------------- | ------------------------------------------------------------------------------------------------ | ------------------------------------ |
| `h264_videotoolbox` | macOS | Apple Silicon / Intel | `--dataset.vcodec=h264_videotoolbox` |
| `hevc_videotoolbox` | macOS | Apple Silicon / Intel | `--dataset.vcodec=hevc_videotoolbox` |
| `h264_nvenc` | Linux/Windows | NVIDIA GPU | `--dataset.vcodec=h264_nvenc` |
| `hevc_nvenc` | Linux/Windows | NVIDIA GPU | `--dataset.vcodec=hevc_nvenc` |
| `h264_vaapi` | Linux | Intel/AMD GPU | `--dataset.vcodec=h264_vaapi` |
| `h264_qsv` | Linux/Windows | Intel Quick Sync | `--dataset.vcodec=h264_qsv` |
| `auto` | Any | Probes the system for available HW encoders. Falls back to `libsvtav1` if no HW encoder is found | `--dataset.vcodec=auto` |
> [!NOTE]
> In order to use the HW accelerated encoders you might need to upgrade your GPU drivers.
> [!NOTE]
> `libsvtav1` is the default because it provides the best training performance; other vcodecs can reduce CPU usage and be faster, but they typically produce larger files and may affect training time.
## 5. Troubleshooting
| Symptom | Likely Cause | Fix |
| ------------------------------------------------------------------ | -------------------------------------------- | ------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------ |
| System freezes or choppy robot movement or Rerun visualization lag | CPU starved (100% load usage) | Close other apps, reduce encoding throughput, lower `encoder_threads`, use `h264`, use `display_data=False`. If the CPU continues to be at 100% then it might be insufficient for your setup, consider `--dataset.streaming_encoding=false` or HW encoding (`--dataset.vcodec=auto`) |
| "Encoder queue full" warnings or dropped frames in dataset | Encoder can't keep up (Queue overflow) | If CPU is not at 100%: Increase `encoder_threads`, increase `encoder_queue_maxsize` or use HW encoding (`--dataset.vcodec=auto`). |
| High RAM usage | Queue filling faster than encoding | `encoder_threads` too low or CPU insufficient. Reduce `encoder_queue_maxsize` or use HW encoding |
| Large video files | Using HW encoder or H.264 | Expected trade-off. Switch to `libsvtav1` if CPU allows |
| `save_episode()` still slow | `streaming_encoding` is `False` | Set `--dataset.streaming_encoding=true` |
| Encoder thread crash | Codec not available or invalid settings | Check `vcodec` is installed, try `--dataset.vcodec=auto` |
| Recorded dataset is missing frames | CPU/GPU starvation or occasional load spikes | If ~5% of frames are missing, your system is likely overloaded — follow the recommendations above. If fewer frames are missing (~2%), they are probably due to occasional transient load spikes (often at startup) and can be considered expected. |
## 6. Recommended Configurations
These estimates are conservative; we recommend testing them on your setup—start with a low load and increase it gradually.
### High-End Systems: modern 12+ cores (24+ threads)
A throughput between ~250-500M px/sec should be comfortable in CPU. For even better results try HW encoding if available.
```bash
# 3camsx 1280x720x3 @30fps: Defaults work well. Optionally increase encoder parallelism.
# 2camsx 1920x1080x3 @30fps: Defaults work well. Optionally increase encoder parallelism.
lerobot-record --dataset.encoder_threads=5 ...
# 3camsx 1920x1080x3 @30fps: Might require some tuning.
```
### Mid-Range Systems: modern 8+ cores (16+ threads) or Apple Silicon
A throughput between ~80-300M px/sec should be possible in CPU.
```bash
# 3camsx 640x480x3 @30fps: Defaults work well. Optionally decrease encoder parallelism.
# 2camsx 1280x720x3 @30fps: Defaults work well. Optionally decrease encoder parallelism.
lerobot-record --dataset.encoder_threads=2 ...
# 2camsx 1920x1080x3 @30fps: Might require some tuning.
```
### Low-Resource Systems: modern 4+ cores (8+ threads) or Raspberry Pi 5
On very constrained systems, streaming encoding may compete too heavily with the capture loop. Disabling it falls back to the PNG-based approach where encoding happens between episodes (blocking, but doesn't interfere with capture). Alternatively, record at a lower throughput to reduce both capture and encoding load. Consider also changing codec to `h264` and using batch encoding.
```bash
# 2camsx 640x480x3 @30fps: Requires some tuning.
# Use H.264, disable streaming, consider batching encoding
lerobot-record --dataset.vcodec=h264 --dataset.streaming_encoding=false ...
```
## 7. Closing note
Performance ultimately depends on your exact setup — frames-per-second, resolution, CPU cores and load, available memory, episode length, and the encoder you choose. Always test with your target workload, be mindful about your CPU & system capabilities and tune `encoder_threads`, `encoder_queue_maxsize`, and
`vcodec` reasonably. That said, a common practical configuration (for many applications) is three cameras at 640×480x3 @30fps; this usually runs fine with the default streaming video encoding settings in modern systems. Always verify your recorded dataset is healthy by comparing the video duration to the CLI episode duration and confirming the row count equals FPS × CLI duration.
docs/source/torch_accelerators.mdx
-42
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@@ -1,42 +0,0 @@
# PyTorch accelerators
LeRobot supports multiple hardware acceleration options for both training and inference.
These options include:
- **CPU**: CPU executes all computations, no dedicated accelerator is used
- **CUDA**: acceleration with NVIDIA & AMD GPUs
- **MPS**: acceleration with Apple Silicon GPUs
- **XPU**: acceleration with Intel integrated and discrete GPUs
## Getting Started
To use particular accelerator, a suitable version of PyTorch should be installed.
For CPU, CUDA, and MPS backends follow instructions provided on [PyTorch installation page](https://pytorch.org/get-started/locally).
For XPU backend, follow instructions from [PyTorch documentation](https://docs.pytorch.org/docs/stable/notes/get_start_xpu.html).
### Verifying the installation
After installation, accelerator availability can be verified by running
```python
import torch
print(torch.<backend_name>.is_available()) # <backend_name> is cuda, mps, or xpu
```
## How to run training or evaluation
To select the desired accelerator, use the `--policy.device` flag when running `lerobot-train` or `lerobot-eval`. For example, to use MPS on Apple Silicon, run:
```bash
lerobot-train
--policy.device=mps ...
```
```bash
lerobot-eval \
--policy.device=mps ...
```
However, in most cases, presence of an accelerator is detected automatically and `policy.device` parameter can be omitted from CLI commands.
docs/source/unitree_g1.mdx
+97 -155
View File
@@ -1,49 +1,22 @@
# Unitree G1
# Unitree G1 Robot Setup and Control
<img
src="https://huggingface.co/datasets/huggingface/documentation-images/resolve/main/lerobot/unitree_thumbnail.jpg"
alt="Unitree G1 locomanipulation demo"
style={{ width: "100%" }}
/>
This guide covers the complete setup process for the Unitree G1 humanoid, from initial connection to running gr00t_wbc locomotion.
The Unitree G1 humanoid is now supported in LeRobot! You can teleoperate, train locomanipulation policies, test in sim, and more. Both 29 and 23 DoF variants are supported.
## About the Unitree G1
We offer support for both 29 and 23 DOF G1. In this first PR we introduce:
- **`unitree g1` robot class, handling low level communication with the humanoid**
- **ZMQ socket bridge** for remote communication over WiFi, allowing one to deploy policies remotely instead of over ethernet or directly on the Orin
- **GR00T locomotion policy** for bipedal walking and balance
---
## Part 1: Getting Started
## Part 1: Connect to Robot over Ethernet
### Install LeRobot on Your Machine
### Step 1: Configure Your Computer's Ethernet Interface
```bash
conda create -y -n lerobot python=3.12
conda activate lerobot
git clone https://github.com/unitreerobotics/unitree_sdk2_python.git
cd unitree_sdk2_python && pip install -e .
git clone https://github.com/huggingface/lerobot.git
cd lerobot
pip install -e '.[unitree_g1]'
```
### Test the Installation (Simulation)
```bash
lerobot-teleoperate \
--robot.type=unitree_g1 \
--robot.is_simulation=true \
--teleop.type=unitree_g1 \
--teleop.id=wbc_unitree \
--robot.cameras='{"global_view": {"type": "zmq", "server_address": "localhost", "port": 5555, "camera_name": "head_camera", "width": 640, "height": 480, "fps": 30}}' \
--display_data=true
```
This will launch a [MuJoCo sim instance](https://huggingface.co/lerobot/unitree-g1-mujoco/tree/main) for the G1.
- Press `9` to release the robot
- Press `7` / `8` to increase / decrease waist height
### Connect to the Robot
The G1's Ethernet IP is fixed at `192.168.123.164`. Your machine must have a static IP on the same subnet: `192.168.123.x` where `x ≠ 164`.
Set a static IP on the same subnet as the robot:
```bash
# Replace 'enp131s0' with your ethernet interface name (check with `ip a`)
@@ -52,210 +25,179 @@ sudo ip addr add 192.168.123.200/24 dev enp131s0
sudo ip link set enp131s0 up
```
### SSH into the Robot
**Note**: The robot's Ethernet IP is fixed at `192.168.123.164`. Your computer must use `192.168.123.x` where x ≠ 164.
### Step 2: SSH into the Robot
```bash
ssh unitree@192.168.123.164
# Password: 123
```
### Install LeRobot on the G1
From the robot:
```bash
conda create -y -n lerobot python=3.12
conda activate lerobot
git clone https://github.com/unitreerobotics/unitree_sdk2_python.git
cd unitree_sdk2_python && pip install -e .
git clone https://github.com/huggingface/lerobot.git
cd lerobot
pip install -e '.[unitree_g1]'
```
> **Note:** The Unitree SDK requires CycloneDDS v0.10.2. See the [Unitree SDK docs](https://github.com/unitreerobotics/unitree_sdk2_python) for details.
You should now be connected to the robot's onboard computer.
---
## Part 2: Enable WiFi on the Robot
Wi-Fi connectivity is blocked by default on the G1. To activate:
Once connected via Ethernet, follow these steps to enable WiFi:
### Step 1: Enable WiFi Hardware
```bash
# Unblock WiFi radio
sudo rfkill unblock wifi
sudo rfkill unblock all
# Bring up WiFi interface
sudo ip link set wlan0 up
# Enable NetworkManager control
sudo nmcli radio wifi on
sudo nmcli device set wlan0 managed yes
sudo systemctl restart NetworkManager
```
**On your laptop** (share internet via Ethernet):
### Step 2: Enable Internet Forwarding
**On your laptop:**
```bash
# Enable IP forwarding
sudo sysctl -w net.ipv4.ip_forward=1
# Replace wlp132s0f0 with your WiFi interface name
# Set up NAT (replace wlp132s0f0 with your WiFi interface)
sudo iptables -t nat -A POSTROUTING -o wlp132s0f0 -s 192.168.123.0/24 -j MASQUERADE
sudo iptables -A FORWARD -i wlp132s0f0 -o enp131s0 -m state --state RELATED,ESTABLISHED -j ACCEPT
sudo iptables -A FORWARD -i enp131s0 -o wlp132s0f0 -j ACCEPT
```
**On the G1** (set default route through your laptop):
**On the robot:**
```bash
# Add laptop as default gateway
sudo ip route del default 2>/dev/null || true
sudo ip route add default via 192.168.123.200 dev eth0
echo "nameserver 8.8.8.8" | sudo tee /etc/resolv.conf
# Verify
# Test connection
ping -c 3 8.8.8.8
```
**Connect to a WiFi network:**
### Step 3: Connect to WiFi Network
```bash
# List available networks
nmcli device wifi list
# Connect to your WiFi (example)
sudo nmcli connection add type wifi ifname wlan0 con-name "YourNetwork" ssid "YourNetwork"
sudo nmcli connection modify "YourNetwork" wifi-sec.key-mgmt wpa-psk
sudo nmcli connection modify "YourNetwork" wifi-sec.psk "YourPassword"
sudo nmcli connection modify "YourNetwork" connection.autoconnect yes
sudo nmcli connection up "YourNetwork"
# Check WiFi IP address
ip a show wlan0
```
You can now SSH over WiFi:
### Step 4: SSH Over WiFi
Once connected to WiFi, note the robot's IP address and disconnect the Ethernet cable. You can now SSH over WiFi:
```bash
ssh unitree@<ROBOT_WIFI_IP>
ssh unitree@<YOUR_ROBOT_IP>
# Password: 123
```
Replace `<YOUR_ROBOT_IP>` with your robot's actual WiFi IP address (e.g., `172.18.129.215`).
---
## Part 3: Teleoperation & Locomotion
## Part 3: Robot Server Setup
### Run the Robot Server
### Step 1: Install LeRobot on the Orin
SSH into the robot and install LeRobot:
```bash
ssh unitree@<YOUR_ROBOT_IP>
conda create -y -n lerobot python=3.10
conda activate lerobot
git clone https://github.com/huggingface/lerobot.git
cd lerobot
pip install -e '.[unitree_g1]'
git clone https://github.com/unitreerobotics/unitree_sdk2_python.git
cd unitree_sdk2_python && pip install -e .
```
**Note**: The Unitree SDK requires CycloneDDS v0.10.2 to be installed. See the [Unitree SDK documentation](https://github.com/unitreerobotics/unitree_sdk2_python) for details.
### Step 2: Run the Robot Server
On the robot:
```bash
python src/lerobot/robots/unitree_g1/run_g1_server.py --camera
python src/lerobot/robots/unitree_g1/run_g1_server.py
```
### Run the Locomotion Policy
```bash
lerobot-teleoperate \
--robot.type=unitree_g1 \
--robot.is_simulation=false \
--robot.robot_ip=<ROBOT_IP> \
--teleop.type=unitree_g1 \
--teleop.id=wbc_unitree \
--robot.cameras='{"global_view": {"type": "zmq", "server_address": "<ROBOT_IP>", "port": 5555, "camera_name": "head_camera", "width": 640, "height": 480, "fps": 30}}' \
--display_data=true \
--robot.controller=HolosomaLocomotionController
```
We support both [HolosomaLocomotionController](https://github.com/amazon-far/holosoma) and [GrootLocomotionController](https://github.com/NVlabs/GR00T-WholeBodyControl).
**Important**: Keep this terminal running. The server must be active for remote control.
---
## Part 4: Loco-Manipulation with the Homunculus Exoskeleton
## Part 4: Running GR00T Locomotion
We provide a loco-manipulation solution via the Homunculus Exoskeleton — an open-source 7 DoF exoskeleton for whole-body control. Assembly instructions [here](https://github.com/nepyope/hmc_exo).
With the robot server running, you can now control the robot from your laptop.
### Calibrate
### Step 1: Install LeRobot on your machine
```bash
lerobot-calibrate \
--teleop.type=unitree_g1 \
--teleop.left_arm_config.port=/dev/ttyACM1 \
--teleop.right_arm_config.port=/dev/ttyACM0 \
--teleop.id=exo
conda create -y -n lerobot python=3.10
conda activate lerobot
git clone https://github.com/huggingface/lerobot.git
cd lerobot
pip install -e '.[unitree_g1]'
git clone https://github.com/unitreerobotics/unitree_sdk2_python.git
cd unitree_sdk2_python && pip install -e .
```
During calibration move each joint through its entire range. After fitting, move the joint in a neutral position and press `n` to advance.
### Step 2: Update Robot IP in Config
### Record a Dataset
Edit the config file to match your robot's WiFi IP:
```python
# In src/lerobot/robots/unitree_g1/config_unitree_g1.py
robot_ip: str = "<YOUR_ROBOT_IP>" # Replace with your robot's WiFi IP.
```
**Note**: When running directly on the G1 (not remotely), set `robot_ip: str = "127.0.0.1"` instead.
### Step 3: Run the Locomotion Policy
```bash
lerobot-record \
--robot.type=unitree_g1 \
--robot.is_simulation=true \
--robot.cameras='{"global_view": {"type": "zmq", "server_address": "localhost", "port": 5555, "camera_name": "head_camera", "width": 640, "height": 480, "fps": 30}}' \
--teleop.type=unitree_g1 \
--teleop.left_arm_config.port=/dev/ttyACM1 \
--teleop.right_arm_config.port=/dev/ttyACM0 \
--teleop.id=exo \
--dataset.repo_id=your-username/dataset-name \
--dataset.single_task="Test" \
--dataset.num_episodes=2 \
--dataset.episode_time_s=5 \
--dataset.reset_time_s=5 \
--dataset.push_to_hub=true \
--dataset.streaming_encoding=true \
--dataset.encoder_threads=2
# Run GR00T locomotion controller
python examples/unitree_g1/gr00t_locomotion.py --repo-id "nepyope/GR00T-WholeBodyControl_g1"
```
> **Note:** Omit `--teleop.left_arm_config.port` and `--teleop.right_arm_config.port` if you're only using the joystick.
### Step 4: Control with Remote
Example dataset: [nepyope/unitree_box_move_blue_full](https://huggingface.co/datasets/nepyope/unitree_box_move_blue_full)
- **Left stick**: Forward/backward and left/right movement
- **Right stick**: Rotation
- **R1 button**: Raise waist height
- **R2 button**: Lower waist height
---
## Part 5: Training & Inference
### Train
```bash
python src/lerobot/scripts/lerobot_train.py \
--dataset.repo_id=your-username/dataset-name \
--policy.type=pi05 \
--output_dir=./outputs/pi05_training \
--job_name=pi05_training \
--policy.repo_id=your-username/your-repo-id \
--policy.pretrained_path=lerobot/pi05_base \
--policy.compile_model=true \
--policy.gradient_checkpointing=true \
--wandb.enable=true \
--policy.dtype=bfloat16 \
--policy.freeze_vision_encoder=false \
--policy.train_expert_only=false \
--steps=3000 \
--policy.device=cuda \
--batch_size=32
```
### Inference with RTC
Once trained, we recommend deploying policies using inference-time RTC:
```bash
python examples/rtc/eval_with_real_robot.py \
--policy.path=your-username/your-repo-id \
--policy.device=cuda \
--robot.type=unitree_g1 \
--robot.is_simulation=false \
--robot.controller=HolosomaLocomotionController \
--robot.cameras='{"global_view": {"type": "zmq", "server_address": "<ROBOT_IP>", "port": 5555, "camera_name": "head_camera", "width": 640, "height": 480, "fps": 30}}' \
--task="task_description" \
--duration=1000 \
--fps=30 \
--rtc.enabled=true
```
Press `Ctrl+C` to stop the policy.
---
## Additional Resources
- [Unitree SDK Documentation](https://github.com/unitreerobotics/unitree_sdk2_python)
- [GR00T-WholeBodyControl](https://github.com/NVlabs/GR00T-WholeBodyControl)
- [Holosoma](https://github.com/amazon-far/holosoma)
- [GR00T Policy Repository](https://huggingface.co/nepyope/GR00T-WholeBodyControl_g1)
- [LeRobot Documentation](https://github.com/huggingface/lerobot)
- [Unitree IL LeRobot](https://github.com/unitreerobotics/unitree_IL_lerobot)
- [Unitree_IL_Lerobot](https://github.com/unitreerobotics/unitree_IL_lerobot)
---
_Last updated: March 2026_
_Last updated: December 2025_
docs/source/using_dataset_tools.mdx
+3 -136
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@@ -11,15 +11,13 @@ LeRobot provides several utilities for manipulating datasets:
3. **Merge Datasets** - Combine multiple datasets into one. The datasets must have identical features, and episodes are concatenated in the order specified in `repo_ids`
4. **Add Features** - Add new features to a dataset
5. **Remove Features** - Remove features from a dataset
6. **Convert to Video** - Convert image-based datasets to video format for efficient storage
7. **Show the Info of Datasets** - Show the summary of datasets information such as number of episode etc.
The core implementation is in `lerobot.datasets.dataset_tools`.
An example script detailing how to use the tools API is available in `examples/dataset/use_dataset_tools.py`.
## Command-Line Tool: lerobot-edit-dataset
`lerobot-edit-dataset` is a command-line script for editing datasets. It can be used to delete episodes, split datasets, merge datasets, add features, remove features, and convert image datasets to video format.
`lerobot-edit-dataset` is a command-line script for editing datasets. It can be used to delete episodes, split datasets, merge datasets, add features, and remove features.
Run `lerobot-edit-dataset --help` for more information on the configuration of each operation.
@@ -88,102 +86,9 @@ lerobot-edit-dataset \
--operation.feature_names "['observation.images.top']"
```
#### Convert to Video
Convert an image-based dataset to video format, creating a new LeRobotDataset where images are stored as videos. This is useful for reducing storage requirements and improving data loading performance. The new dataset will have the exact same structure as the original, but with images encoded as MP4 videos in the proper LeRobot format.
```bash
# Local-only: Save to a custom output directory (no hub push)
lerobot-edit-dataset \
--repo_id lerobot/pusht_image \
--operation.type convert_image_to_video \
--operation.output_dir /path/to/output/pusht_video
# Save with new repo_id (local storage)
lerobot-edit-dataset \
--repo_id lerobot/pusht_image \
--new_repo_id lerobot/pusht_video \
--operation.type convert_image_to_video
# Convert and push to Hugging Face Hub
lerobot-edit-dataset \
--repo_id lerobot/pusht_image \
--new_repo_id lerobot/pusht_video \
--operation.type convert_image_to_video \
--push_to_hub true
# Convert with custom video codec and quality settings
lerobot-edit-dataset \
--repo_id lerobot/pusht_image \
--operation.type convert_image_to_video \
--operation.output_dir outputs/pusht_video \
--operation.vcodec libsvtav1 \
--operation.pix_fmt yuv420p \
--operation.g 2 \
--operation.crf 30
# Convert only specific episodes
lerobot-edit-dataset \
--repo_id lerobot/pusht_image \
--operation.type convert_image_to_video \
--operation.output_dir outputs/pusht_video \
--operation.episode_indices "[0, 1, 2, 5, 10]"
# Convert with multiple workers for parallel processing
lerobot-edit-dataset \
--repo_id lerobot/pusht_image \
--operation.type convert_image_to_video \
--operation.output_dir outputs/pusht_video \
--operation.num_workers 8
# For memory-constrained systems, users can now specify limits:
lerobot-edit-dataset \
--repo_id lerobot/pusht_image \
--operation.type convert_to_video \
--operation.max_episodes_per_batch 50 \
--operation.max_frames_per_batch 10000
```
**Parameters:**
- `output_dir`: Custom output directory (optional - by default uses `new_repo_id` or `{repo_id}_video`)
- `vcodec`: Video codec to use - options: `h264`, `hevc`, `libsvtav1` (default: `libsvtav1`)
- `pix_fmt`: Pixel format - options: `yuv420p`, `yuv444p` (default: `yuv420p`)
- `g`: Group of pictures (GOP) size - lower values give better quality but larger files (default: 2)
- `crf`: Constant rate factor - lower values give better quality but larger files, 0 is lossless (default: 30)
- `fast_decode`: Fast decode tuning option (default: 0)
- `episode_indices`: List of specific episodes to convert (default: all episodes)
- `num_workers`: Number of parallel workers for processing (default: 4)
**Note:** The resulting dataset will be a proper LeRobotDataset with all cameras encoded as videos in the `videos/` directory, with parquet files containing only metadata (no raw image data). All episodes, stats, and tasks are preserved.
### Show the information of datasets
Show the information of datasets such as number of episode, number of frame, File size and so on.
No change will be made to the dataset
```bash
# Show dataset information without feature details
lerobot-edit-dataset \
--repo_id lerobot/pusht_image \
--operation.type info \
# Show dataset information with feature details
lerobot-edit-dataset \
--repo_id lerobot/pusht_image \
--operation.type info \
--operation.show_features true
```
**Parameters:**
- `parameters`: The flag to control show or no show dataset information with feature details.(default=false)
### Push to Hub
Add the `--push_to_hub true` flag to any command to automatically upload the resulting dataset to the Hugging Face Hub:
Add the `--push_to_hub` flag to any command to automatically upload the resulting dataset to the Hugging Face Hub:
```bash
lerobot-edit-dataset \
@@ -191,45 +96,7 @@ lerobot-edit-dataset \
--new_repo_id lerobot/pusht_after_deletion \
--operation.type delete_episodes \
--operation.episode_indices "[0, 2, 5]" \
--push_to_hub true
--push_to_hub
```
There is also a tool for adding features to a dataset that is not yet covered in `lerobot-edit-dataset`.
# Dataset Visualization
## Online Visualization
When you record a dataset using `lerobot`, it automatically uploads to the Hugging Face Hub unless you specify otherwise. To view the dataset online, use our **LeRobot Dataset Visualizer**, available at:
https://huggingface.co/spaces/lerobot/visualize_dataset
## Local Visualization
You can also visualize episodes from a dataset locally using our command-line tool.
**From the Hugging Face Hub:**
```bash
lerobot-dataset-viz \
--repo-id lerobot/pusht \
--episode-index 0
```
**From a local folder:**
Add the `--root` option and set `--mode local`. For example, to search in `./my_local_data_dir/lerobot/pusht`:
```bash
lerobot-dataset-viz \
--repo-id lerobot/pusht \
--root ./my_local_data_dir \
--mode local \
--episode-index 0
```
Once executed, the tool opens `rerun.io` and displays the camera streams, robot states, and actions for the selected episode.
For advanced usage—including visualizing datasets stored on a remote server—run:
```bash
lerobot-dataset-viz --help
```
docs/source/walloss.mdx
-80
View File
@@ -1,80 +0,0 @@
# WALL-OSS
WALL-OSS is an open-source foundation model for embodied intelligence, proposed by the [XSquare Robot](https://x2robot.com/en/research/68bc2cde8497d7f238dde690) team in 2025. The LeRobot implementation is adapted from their open-source [WallX](https://github.com/X-Square-Robot/wall-x) repository.
X Square Robots WALL-OSS is now integrated into Hugging Faces LeRobot ecosystem. This is an exciting collaborative project between the LeRobot and X Square Robot teams. You can now post-train, evaluate, and deploy WALL-OSS directly through LeRobot. With this, were aiming to make it easier for the open-source robotics community to customize and deploy WALL-OSS foundation models. Read and explore WALL-OSS [paper](https://arxiv.org/pdf/2509.11766) and [code](https://github.com/X-Square-Robot/wall-x).
## Model Overview
The WALL-OSS team is building the embodied foundation model to capture and compress the world's most valuable data: the continuous, high-fidelity stream of physical interaction. By creating a direct feedback loop between the model's decisions and the body's lived experience, the emergence of a truly generalizable intelligence is enabled—one that understands not just how the world works, but how to act effectively within it.
<img
src="https://huggingface.co/datasets/huggingface/documentation-images/resolve/main/lerobot/walloss-lerobot-paper.png"
alt="An overview of WALL-OSS"
width="85%"
/>
Technically, WALL-OSS introduces a tightly coupled multimodal architecture (tightly-coupled MoE structure) that integrates both discrete and continuous action modeling strategies. Through a two-stage training pipeline (Inspiration → Integration), the model gradually unifies semantic reasoning and high-frequency action generation. Its core innovations include:
- **Embodied perceptionenhanced multimodal pretraining**: Large-scale training on unified visionlanguageaction data to strengthen spatial, causal, and manipulation understanding.
- **Unified Cross-Level Chain-of-Thought (Uni-CoT)**: A single differentiable framework that unifies high-level instruction reasoning, sub-task decomposition, and fine-grained action synthesis, forming a continuous chain from “understanding” to “execution.”
- **Mixture-of-Experts (MoE) action heads**: Dynamically activating experts depending on the task phase and modeling actions in discrete or continuous space to maintain stable VLM priors.
- **Two-stage training paradigm**:
- **Inspiration stage**: Injecting discrete action priors to strengthen spatial understanding and semantic-action alignment.
- **Integration stage**: Using flow matching to achieve high-frequency continuous control.
## Installation Requirements
1. Install LeRobot by following our [Installation Guide](./installation).
2. Install WallX dependencies by running:
```bash
pip install -e ".[wallx]"
```
## Usage
To use WallX in LeRobot, specify the policy type as:
```python
policy.type=wall_x
```
## Training
For training WallX, you can use the standard LeRobot training script with the appropriate configuration:
```bash
lerobot-train \
--dataset.repo_id=your_dataset \
--policy.type=wall_x \
--output_dir=./outputs/wallx_training \
--job_name=wallx_training \
--policy.repo_id=your_repo_id \
--policy.pretrained_name_or_path=x-square-robot/wall-oss-flow \
--policy.prediction_mode=diffusion \
--policy.attn_implementation=eager \
--steps=3000 \
--policy.device=cuda \
--batch_size=32
```
### Training Arguments
| Argument | Description |
| ------------------------------ | ------------------------------------------------------------------------------------------------------------------------------------------------------------- |
| `--dataset.repo_id` | The Hugging Face Hub repository ID for your training dataset (e.g., `lerobot/aloha_sim_insertion_human`) |
| `--policy.type` | Specifies using the WallX policy architecture |
| `--output_dir` | Local directory where training checkpoints and logs will be saved |
| `--job_name` | A name identifier for this training run (used in logging/tracking) |
| `--policy.repo_id` | Your Hugging Face Hub repo ID where the trained model will be pushed |
| `--policy.pretrained_path` | Path to pretrained WallX weights to initialize from (the official WALL-OSS checkpoint) |
| `--policy.prediction_mode` | The action prediction strategy: `diffusion` or `fast` - `diffusion` uses iterative denoising for action generation, `fast` uses next token prediction instead |
| `--policy.attn_implementation` | Attention implementation backend - `eager` uses standard PyTorch attention (alternatives include `flash_attention_2` or `sdpa`) |
| `--steps` | Total number of training steps to run |
| `--policy.device` | Device to train on (`cuda` for GPU, `cpu` for CPU) |
| `--batch_size` | Number of samples per training batch |
## License
This model follows the **Apache 2.0 License**, consistent with the original [WallX repository](https://github.com/X-Square-Robot/wall-x).
docs/source/xvla.mdx
-528
View File
@@ -1,528 +0,0 @@
# X-VLA: The First Soft-Prompted Robot Foundation Model for Any Robot, Any Task
## Overview
For years, robotics has aspired to build agents that can follow natural human instructions and operate dexterously across many environments and robot bodies. Recent breakthroughs in LLMs and VLMs suggest a path forward: extend these foundation-model architectures to embodied control by grounding them in actions. This has led to the rise of Vision-Language-Action (VLA) models, with the hope that a single generalist model could combine broad semantic understanding with robust manipulation skills.
But training such models is difficult. Robot data is fragmented across platforms, sensors, embodiments, and collection protocols. Heterogeneity appears everywhere: different arm configurations, different action spaces, different camera setups, different visual domains, and different task distributions. These inconsistencies create major distribution shifts that make pretraining unstable and adaptation unreliable.
Inspired by meta-learning and prompt learning, we ask: **"What if a VLA model could learn the structure of each robot and dataset the same way LLMs learn tasks, through prompts?"**
**X-VLA** is a soft-prompted, flow-matching VLA framework that treats each hardware setup as a "task" and encodes it using a small set of learnable embeddings. These **Soft Prompts** capture embodiment and domain-specific variations, guiding the Transformer from the earliest stages of multimodal fusion. With this mechanism, X-VLA can reconcile diverse robot morphologies, data types, and sensor setups within a single unified architecture.
<p align="center">
<img
src="https://huggingface.co/datasets/huggingface/documentation-images/resolve/main/lerobot/xvla-architecture.png"
alt="XVLA Architecture"
style="max-width: 100%; height: auto; width: 800px;"
/>
</p>
Built from pure Transformer encoders, X-VLA scales naturally with model size and dataset diversity. Across 6 simulation benchmarks and 3 real robots, Soft Prompts consistently outperform existing methods in handling hardware and domain differences. X-VLA-0.9B, trained on 290K episodes spanning seven robotic platforms, learns an embodiment-agnostic generalist policy in Phase I, and adapts efficiently to new robots in Phase II simply by learning a new set of prompts, while keeping the backbone frozen.
<p align="center">
<img
src="https://huggingface.co/datasets/huggingface/documentation-images/resolve/main/lerobot/xvla-architecture2.png"
alt="XVLA Architecture 2"
style="width: 60%; height: auto;"
/>
</p>
With only 1% of parameters tuned (9M), X-VLA-0.9B achieves near-π₀ performance on LIBERO and Simpler-WidowX, despite using **300× fewer trainable parameters**. It also demonstrates strong real-world dexterity with minimal demonstrations, including folding cloths in under two minutes.
<p align="center">
<img
src="https://huggingface.co/datasets/huggingface/documentation-images/resolve/main/lerobot/xvla-fold.png"
alt="XVLA fold visualization"
style="width: 95%; max-width: 1100px; height: auto;"
/>
</p>
X-VLA shows that generalist robot intelligence does not require increasingly complex architectures, only the right way to absorb heterogeneity. Soft Prompts offer a simple, scalable mechanism for unifying diverse robotic data, paving the way toward adaptable, cross-embodiment robot foundation models.
## Installation
After installing LeRobot, install the X-VLA dependencies:
```bash
pip install -e .[xvla]
```
After the new release, you'll be able to do:
```bash
pip install lerobot[xvla]
```
## Quick Start
### Basic Usage
To use X-VLA in your LeRobot configuration, specify the policy type as:
```bash
policy.type=xvla
```
### Evaluating Pre-trained Checkpoints
Example evaluation with LIBERO:
```bash
lerobot-eval \
--policy.path="lerobot/xvla-libero" \
--env.type=libero \
--env.task=libero_spatial,libero_goal,libero_10 \
--env.control_mode=absolute \
--eval.batch_size=1 \
--eval.n_episodes=1 \
--env.episode_length=800 \
--seed=142
```
## Available Checkpoints
### 🎯 Base Model
**[lerobot/xvla-base](https://huggingface.co/lerobot/xvla-base)**
A 0.9B parameter instantiation of X-VLA, trained with a carefully designed data processing and learning recipe. The training pipeline consists of two phases:
- **Phase I: Pretraining** - Pretrained on 290K episodes from Droid, Robomind, and Agibot, spanning seven platforms across five types of robotic arms (single-arm to bi-manual setups). By leveraging soft prompts to absorb embodiment-specific variations, the model learns an embodiment-agnostic generalist policy.
- **Phase II: Domain Adaptation** - Adapted to deployable policies for target domains. A new set of soft prompts is introduced and optimized to encode the hardware configuration of the novel domain, while the pretrained backbone remains frozen.
### Simulation Checkpoints
**[lerobot/xvla-libero](https://huggingface.co/lerobot/xvla-libero)**
Achieves 93% success rate on LIBERO benchmarks. Fine-tuned from the base model for simulation tasks.
**[lerobot/xvla-widowx](https://huggingface.co/lerobot/xvla-widowx)**
Fine-tuned on BridgeData for pick-and-place experiments on compact WidowX platforms. Demonstrates robust manipulation capabilities.
### 🤖 Real-World Checkpoints
**[lerobot/xvla-folding](https://huggingface.co/lerobot/xvla-folding)**
A fine-tuned dexterous manipulation model trained on the high-quality Soft-FOLD cloth folding dataset. Achieves 100% success rate over 2 hours of continuous cloth folding.
**[lerobot/xvla-agibot-world](https://huggingface.co/lerobot/xvla-agibot-world)**
Optimized for AgileX robot dexterous manipulation tasks.
**[lerobot/xvla-google-robot](https://huggingface.co/lerobot/xvla-google-robot)**
Adapted for Google Robot platforms.
## Training X-VLA
### Recommended Training Configuration
When fine-tuning X-VLA for a new embodiment or task, we recommend not freezing the VLM, and also setting the `policy.dtype=bfloat16` to not hit OOM errors.
```bash
lerobot-train \
--dataset.repo_id=YOUR_DATASET \
--output_dir=./outputs/xvla_training \
--job_name=xvla_training \
--policy.path="lerobot/xvla-base" \
--policy.repo_id="HF_USER/xvla-your-robot" \
--policy.dtype=bfloat16 \
--policy.action_mode=auto \
--steps=20000 \
--policy.device=cuda \
--policy.freeze_vision_encoder=false \
--policy.freeze_language_encoder=false \
--policy.train_policy_transformer=true \
--policy.train_soft_prompts=true \
```
### Training Parameters Explained
| Parameter | Default | Description |
| -------------------------- | ------- | ---------------------------------------------- |
| `freeze_vision_encoder` | `false` | Do not freeze the VLM vision encoder weights |
| `freeze_language_encoder` | `false` | Do not freeze the VLM language encoder weights |
| `train_policy_transformer` | `true` | Allow policy transformer layers to train |
| `train_soft_prompts` | `true` | Allow soft prompts to train |
**💡 Best Practice**: For Phase II adaptation to new embodiments, do not freeze the VLM encoders and also train the policy transformer and soft prompts.
### Example: Training on Bimanual Robot
```bash
lerobot-train \
--dataset.repo_id=<USER>/bimanual-so100-handover-cube \
--output_dir=./outputs/xvla_bimanual \
--job_name=xvla_so101_training \
--policy.path="lerobot/xvla-base" \
--policy.dtype=bfloat16 \
--policy.repo_id="YOUR_USERNAME/xvla-biso101" \
--steps=3000 \
--policy.device=cuda \
--policy.action_mode=so101_bimanual \
--policy.freeze_vision_encoder=false \
--policy.freeze_language_encoder=false \
--policy.train_policy_transformer=true \
--policy.train_soft_prompts=true
```
💡 **Best Performance:** If you have sufficient computational resources and want to achieve best X-VLA finetuning performance, you should follow the official finetuning strategy:
**🔥 Full-finetune all components with a custom learning-rate scheme**
To ensure stable optimization, the Vision-Language Model (VLM) must be trained with only 1/10 of the base learning rate, while all other components use the full LR.
This LR ratio is crucial for achieving strong and stable finetuning performance. This is already done for you by default.
❕Note
Completely matching the official reported performance may require an additional warm-up LR schedule for soft-prompts, which can bring minor improvements.
We encourage implementing this in your customized training pipeline for optimal results.
## Core Concepts
### 1. Action Modes
X-VLA uses an **Action Registry** system to handle different action spaces and embodiments. The `action_mode` parameter defines how actions are processed, what loss functions are used, and how predictions are post-processed.
#### Available Action Modes
| Action Mode | Action Dim | Description | Use Case |
| ---------------- | ----------------------- | ------------------------------------------- | ------------------------------------ |
| `ee6d` | 20 | End-effector with xyz, 6D rotation, gripper | Dual-arm setups with spatial control |
| `joint` | 14 | Joint-space with gripper | Direct joint control robots |
| `agibot_ee6d` | 20 | AGI-bot variant with MSE loss | AGI-bot platforms |
| `so101_bimanual` | 20 (model), 12 (real) | SO101 bimanual robot | Bimanual manipulation tasks |
| `auto` | 20 (model), auto (real) | Auto-detects action dim from dataset | **Recommended** for new robots |
#### Why Action Modes Matter
When you have a pretrained checkpoint like `lerobot/xvla-base` trained with `action_dim=20`, and you want to train on a dataset with a different action dimension (e.g., 14 for bimanual arms), you can't simply trim the action dimension. The action mode orchestrates:
1. **Loss Computation**: Different loss functions for different action components (MSE for joints, BCE for grippers, etc.)
2. **Preprocessing**: Zeroing out gripper channels, padding dimensions
3. **Postprocessing**: Applying sigmoid to gripper logits, trimming padding
#### Example: BimanualSO101 Action Space
The `so101_bimanual` action mode handles the mismatch between model output (20D) and real robot control (12D):
```python
# Model outputs 20 dimensions for compatibility
dim_action = 20
# Real robot only needs 12 dimensions
# [left_arm (6), right_arm (6)] = [joints (5) + gripper (1)] × 2
REAL_DIM = 12
# Preprocessing: Pad 12D actions to 20D for training
# Postprocessing: Trim 20D predictions to 12D for deployment
```
See the [action_hub.py](/home/jade_choghari/robot/lerobot/src/lerobot/policies/xvla/action_hub.py) implementation for details.
#### Auto Action Mode (Recommended)
The `auto` action mode is the easiest way to use X-VLA with any robot. It automatically detects your dataset's action dimension and handles padding/trimming:
```bash
lerobot-train \
--policy.path="lerobot/xvla-base" \
--policy.action_mode=auto \
--policy.max_action_dim=20 \
...
```
**How it works:**
- Reads `action_feature.shape[-1]` from your dataset (e.g., 7 for Franka)
- Model outputs `max_action_dim` (default 20) for pretrained compatibility
- Loss is computed **only on the real dimensions**: `MSE(pred[:,:,:real_dim], target[:,:,:real_dim])`
- Postprocess trims output back to `real_dim` for robot control
This eliminates the need to create custom action modes for most robots.
### 2. Domain IDs
Domain IDs are learnable identifiers for different robot configurations and camera setups. They allow X-VLA to distinguish between:
- Different robots (Robot 1 vs Robot 2)
- Different camera configurations (cam1 vs cam2)
- Different combinations (Robot1-cam1-cam2 vs Robot1-cam1 vs Robot2-cam1)
#### Setting Domain IDs
**During Training**: By default, domain_id is set to 0 for general training.
**During Evaluation**: Specify the domain_id that matches your checkpoint's training configuration.
```python
# Example: LIBERO checkpoint uses domain_id=3
domain_id = 3
```
The domain_id is automatically added to observations by the `XVLAAddDomainIdProcessorStep` in the preprocessing pipeline.
The `lerobot/xvla-base` model has been trained on the following domain IDs. It is recommended to choose one that most resembles your robot/configuration:
#### Fine-tuning Datasets
| Dataset Name | Domain ID |
| ---------------- | --------- |
| Bridge | 0 |
| RT1 | 1 |
| Calvin | 2 |
| libero | 3 |
| widowx-air | 4 |
| AIR-AGILEX-HQ | 5 |
| robotwin2_abs_ee | 6 |
| robotwin2_clean | 6 |
| robocasa-human | 7 |
| VLABench | 8 |
| AGIBOT-challenge | 9 |
| AIR-AGILEX | 10 |
| AIRBOT | 18 |
### 3. Processor Steps
X-VLA requires specific preprocessing and postprocessing steps for proper operation.
#### Required Preprocessing Steps
1. **XVLAImageToFloatProcessorStep**: Converts images from [0, 255] to [0, 1] range
2. **XVLAImageNetNormalizeProcessorStep**: Applies ImageNet normalization (required for VLM backbone)
3. **XVLAAddDomainIdProcessorStep**: Adds domain_id to observations
#### Example Custom Processor
For LIBERO environments, a custom processor handles the specific observation format:
```python
from lerobot.policies.xvla.processor_xvla import LiberoProcessorStep
processor = LiberoProcessorStep()
# Handles robot_state dictionary, converts rotation matrices to 6D representation
# Applies 180° image rotation for camera convention
```
### 4. Configuration Parameters
Key configuration parameters for X-VLA:
```python
# Observation and action
n_obs_steps: int = 1 # Number of observation timesteps
chunk_size: int = 32 # Action sequence length
n_action_steps: int = 32 # Number of action steps to execute
# Model architecture
hidden_size: int = 1024 # Transformer hidden dimension
depth: int = 24 # Number of transformer layers
num_heads: int = 16 # Number of attention heads
num_domains: int = 30 # Maximum number of domain IDs
len_soft_prompts: int = 32 # Length of soft prompt embeddings
# Action space
action_mode: str = "ee6d" # Action space type (use "auto" for auto-detection)
use_proprio: bool = True # Use proprioceptive state
max_state_dim: int = 32 # Maximum state dimension
max_action_dim: int = 20 # Max action dim for padding (used by "auto" mode)
# Vision
num_image_views: int | None # Number of camera views
resize_imgs_with_padding: tuple[int, int] | None # Target image size with padding
# Training
num_denoising_steps: int = 10 # Flow matching denoising steps
```
## Creating Custom Action Modes
If your robot has a unique action space, you can create a custom action mode:
### Step 1: Define Your Action Space
```python
from lerobot.policies.xvla.action_hub import BaseActionSpace, register_action
import torch.nn as nn
@register_action("my_custom_robot")
class MyCustomActionSpace(BaseActionSpace):
"""Custom action space for my robot."""
dim_action = 15 # Your robot's action dimension
gripper_idx = (7, 14) # Gripper channel indices
def __init__(self):
super().__init__()
self.mse = nn.MSELoss()
self.bce = nn.BCEWithLogitsLoss()
def compute_loss(self, pred, target):
"""Define your loss computation."""
# Example: MSE for joints, BCE for grippers
joints_loss = self.mse(pred[:, :, :7], target[:, :, :7])
gripper_loss = self.bce(pred[:, :, self.gripper_idx],
target[:, :, self.gripper_idx])
return {
"joints_loss": joints_loss,
"gripper_loss": gripper_loss,
}
def preprocess(self, proprio, action, mode="train"):
"""Preprocess actions before training."""
# Example: Zero out grippers in proprioception
proprio_m = proprio.clone()
action_m = action.clone() if action is not None else None
proprio_m[..., self.gripper_idx] = 0.0
if action_m is not None:
action_m[..., self.gripper_idx] = 0.0
return proprio_m, action_m
def postprocess(self, action):
"""Post-process predictions for deployment."""
# Example: Apply sigmoid to gripper logits
action[..., self.gripper_idx] = torch.sigmoid(action[..., self.gripper_idx])
return action
```
### Step 2: Use Your Custom Action Mode
```bash
lerobot-train \
--policy.action_mode=my_custom_robot \
--dataset.repo_id=YOUR_DATASET \
--policy.path="lerobot/xvla-base" \
...
```
## Advanced Topics
### Multi-Camera Support
X-VLA supports multiple camera views through the `num_image_views` parameter:
```python
# Configure for 3 camera views
policy.num_image_views=3
# Add empty cameras if you have fewer physical cameras
policy.empty_cameras=1 # Adds 1 zero-padded camera view
```
### Custom Preprocessing Pipeline
Create a custom preprocessing pipeline for your environment:
```python
from lerobot.processor import PolicyProcessorPipeline
from lerobot.policies.xvla.processor_xvla import (
XVLAImageToFloatProcessorStep,
XVLAImageNetNormalizeProcessorStep,
XVLAAddDomainIdProcessorStep,
)
# Build custom pipeline
preprocessor = PolicyProcessorPipeline(
steps=[
YourCustomProcessorStep(), # Your custom processing
XVLAImageToFloatProcessorStep(), # Required: convert to float
XVLAImageNetNormalizeProcessorStep(), # Required: ImageNet norm
XVLAAddDomainIdProcessorStep(domain_id=5), # Your domain ID
]
)
```
### Handling Different Action Dimensions
When your dataset has fewer action dimensions than the pretrained model:
**Option 1 (Recommended)**: Use `auto` action mode
```bash
# Automatically detects your dataset's action dimension
# Works with any robot without custom code
policy.action_mode=auto
policy.max_action_dim=20 # Match pretrained model
```
**Option 2**: Use a predefined action mode with built-in padding
```python
# Model expects 20D, dataset has 12D
# Action mode handles padding internally
action_mode = "so101_bimanual" # Pads 12 → 20
```
**Option 2**: Create a custom action mode that maps dimensions explicitly
```python
@register_action("my_mapped_action")
class MappedActionSpace(BaseActionSpace):
dim_action = 20
REAL_DIM = 12
def _pad_to_model_dim(self, x):
# Custom padding logic
...
```
## Troubleshooting
### Common Issues
**Issue**: "Action dimension mismatch"
- **Solution**: Check that your `action_mode` matches your robot's action space. Create a custom action mode if needed.
**Issue**: "Image values outside [0, 1] range"
- **Solution**: Ensure images are preprocessed with `XVLAImageToFloatProcessorStep` before normalization.
**Issue**: "Domain ID not found"
- **Solution**: Make sure `XVLAAddDomainIdProcessorStep` is in your preprocessing pipeline with the correct domain_id.
**Issue**: "Low success rate on new embodiment"
- **Solution**:
1. Verify your action_mode is correct
2. Check that soft prompts are being trained (`train_soft_prompts=True`)
3. Ensure proper preprocessing (ImageNet normalization, domain_id)
4. Consider increasing training steps
**Issue**: "Out of memory during training"
- **Solution**:
1. Reduce `chunk_size` (e.g., from 32 to 16)
2. Enable gradient checkpointing
3. Reduce batch size
4. Freeze more components
## Citation
If you use X-VLA in your research, please cite:
```bibtex
@article{zheng2025x,
title = {X-VLA: Soft-Prompted Transformer as Scalable Cross-Embodiment Vision-Language-Action Model},
author = {Zheng, Jinliang and Li, Jianxiong and Wang, Zhihao and Liu, Dongxiu and Kang, Xirui
and Feng, Yuchun and Zheng, Yinan and Zou, Jiayin and Chen, Yilun and Zeng, Jia and others},
journal = {arXiv preprint arXiv:2510.10274},
year = {2025}
}
```
## Additional Resources
- [X-VLA Paper](https://arxiv.org/pdf/2510.10274)
- [LeRobot Documentation](https://github.com/huggingface/lerobot)
- [Action Registry Implementation](https://github.com/huggingface/lerobot/src/lerobot/policies/xvla/action_hub.py)
- [Processor Implementation](https://github.com/huggingface/lerobot/src/lerobot/policies/xvla/processor_xvla.py)
- [Model Configuration](https://github.com/huggingface/lerobot/src/lerobot/policies/xvla/configuration_xvla.py)
## Contributing
We welcome contributions! If you've implemented a new action mode or processor for your robot, please consider submitting a PR to help the community.
examples/backward_compatibility/replay.py
+19 -19
View File
@@ -22,7 +22,7 @@ lerobot-replay \
--robot.type=so100_follower \
--robot.port=/dev/tty.usbmodem58760431541 \
--robot.id=black \
--dataset.repo_id=<USER>/record-test \
--dataset.repo_id=aliberts/record-test \
--dataset.episode=2
```
"""
@@ -41,7 +41,8 @@ from lerobot.robots import ( # noqa: F401
RobotConfig,
koch_follower,
make_robot_from_config,
so_follower,
so100_follower,
so101_follower,
)
from lerobot.utils.constants import ACTION
from lerobot.utils.robot_utils import precise_sleep
@@ -57,7 +58,7 @@ class DatasetReplayConfig:
repo_id: str
# Episode to replay.
episode: int
# Root directory where the dataset will be stored (e.g. 'dataset/path'). If None, defaults to $HF_LEROBOT_HOME/repo_id.
# Root directory where the dataset will be stored (e.g. 'dataset/path').
root: str | Path | None = None
# Limit the frames per second. By default, uses the policy fps.
fps: int = 30
@@ -81,25 +82,24 @@ def replay(cfg: ReplayConfig):
actions = dataset.hf_dataset.select_columns(ACTION)
robot.connect()
try:
log_say("Replaying episode", cfg.play_sounds, blocking=True)
for idx in range(dataset.num_frames):
start_episode_t = time.perf_counter()
log_say("Replaying episode", cfg.play_sounds, blocking=True)
for idx in range(dataset.num_frames):
start_episode_t = time.perf_counter()
action_array = actions[idx][ACTION]
action = {}
for i, name in enumerate(dataset.features[ACTION]["names"]):
key = f"{name.removeprefix('main_')}.pos"
action[key] = action_array[i].item()
action_array = actions[idx][ACTION]
action = {}
for i, name in enumerate(dataset.features[ACTION]["names"]):
key = f"{name.removeprefix('main_')}.pos"
action[key] = action_array[i].item()
action["shoulder_lift.pos"] = -(action["shoulder_lift.pos"] - 90)
action["elbow_flex.pos"] -= 90
robot.send_action(action)
action["shoulder_lift.pos"] = -(action["shoulder_lift.pos"] - 90)
action["elbow_flex.pos"] -= 90
robot.send_action(action)
dt_s = time.perf_counter() - start_episode_t
precise_sleep(max(1 / dataset.fps - dt_s, 0.0))
finally:
robot.disconnect()
dt_s = time.perf_counter() - start_episode_t
precise_sleep(1 / dataset.fps - dt_s)
robot.disconnect()
if __name__ == "__main__":
examples/dataset/slurm_compute_rabc.py
-490
View File
@@ -1,490 +0,0 @@
#!/usr/bin/env python
# Copyright 2025 The HuggingFace Inc. team. All rights reserved.
#
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
#
# http://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.
"""
SLURM-distributed SARM RA-BC annotation pipeline.
Computes SARM progress values for all frames in a dataset, distributed across
SLURM workers, then merges the shards into a single sarm_progress.parquet.
Two subcommands, each a separate SLURM submission:
compute N workers, each computes progress for a subset of episodes
aggregate 1 worker, merges N shards into sarm_progress.parquet, pushes to hub
Usage:
python slurm_compute_rabc.py compute \\
--repo-id user/dataset --reward-model-path user/sarm_model \\
--stride 10 --device cpu --workers 50 --partition cpu
python slurm_compute_rabc.py aggregate \\
--repo-id user/dataset --reward-model-path user/sarm_model \\
--partition cpu --push-to-hub
"""
import argparse
from pathlib import Path
from datatrove.executor import LocalPipelineExecutor
from datatrove.executor.slurm import SlurmPipelineExecutor
from datatrove.pipeline.base import PipelineStep
class ComputeProgressShards(PipelineStep):
"""Each worker computes SARM progress for its assigned episodes."""
def __init__(
self, repo_id, reward_model_path, stride=1, head_mode="sparse", device="cpu", shard_dir="rabc_shards"
):
super().__init__()
if stride < 1:
raise ValueError(f"stride must be >= 1, got {stride}")
self.repo_id = repo_id
self.reward_model_path = reward_model_path
self.stride = stride
self.head_mode = head_mode
self.device = device
self.shard_dir = shard_dir
def run(self, data=None, rank: int = 0, world_size: int = 1):
import logging
from pathlib import Path
import numpy as np
import pyarrow as pa
import pyarrow.parquet as pq
import torch
from tqdm import tqdm
from lerobot.policies.sarm.compute_rabc_weights import (
generate_all_frame_indices,
interpolate_progress,
load_sarm_resources,
)
from lerobot.utils.utils import init_logging
init_logging()
dataset, reward_model, preprocess = load_sarm_resources(
self.repo_id,
self.reward_model_path,
self.device,
)
if hasattr(preprocess, "eval"):
preprocess.eval()
for step in preprocess.steps:
if hasattr(step, "eval"):
step.eval()
image_key = reward_model.config.image_key
state_key = reward_model.config.state_key
frame_gap = reward_model.config.frame_gap
center_idx = reward_model.config.n_obs_steps // 2
dual_mode = reward_model.config.uses_dual_heads
compute_sparse = self.head_mode in ("sparse", "both") or not dual_mode
compute_dense = self.head_mode in ("dense", "both") and dual_mode
my_episodes = list(range(dataset.num_episodes))[rank::world_size]
if not my_episodes:
logging.info(f"Rank {rank}: no episodes assigned")
return
logging.info(f"Rank {rank}: {len(my_episodes)} / {dataset.num_episodes} episodes")
all_rows = []
for ep_idx in tqdm(my_episodes, desc=f"Rank {rank}"):
ep = dataset.meta.episodes[ep_idx]
ep_start, ep_end = ep["dataset_from_index"], ep["dataset_to_index"]
task = dataset[ep_start].get("task", "perform the task")
all_ep_indices = generate_all_frame_indices(ep_start, ep_end, frame_gap)
if self.stride > 1:
compute_indices = [i for i in all_ep_indices if (i - ep_start) % self.stride == 0]
if (ep_end - 1) not in compute_indices:
compute_indices.append(ep_end - 1)
compute_indices = sorted(set(compute_indices))
else:
compute_indices = all_ep_indices
frame_results = {}
for qi in tqdm(compute_indices, desc=f" Ep {ep_idx}", leave=False):
try:
sample = dataset[qi]
batch = {
image_key: sample[image_key],
"task": task,
"index": qi,
"episode_index": ep_idx,
}
if state_key in sample:
batch[state_key] = sample[state_key]
with torch.no_grad():
processed = preprocess(batch)
vf = processed["video_features"].to(self.device)
tf = processed["text_features"].to(self.device)
sf = processed.get("state_features")
if sf is not None:
sf = sf.to(self.device)
lengths = processed.get("lengths")
sparse_val = dense_val = np.nan
if compute_sparse:
r = reward_model.calculate_rewards(
text_embeddings=tf,
video_embeddings=vf,
state_features=sf,
lengths=lengths,
return_all_frames=True,
head_mode="sparse",
)
sparse_val = float(r[0, center_idx] if r.ndim == 2 else r[center_idx])
if compute_dense:
r = reward_model.calculate_rewards(
text_embeddings=tf,
video_embeddings=vf,
state_features=sf,
lengths=lengths,
return_all_frames=True,
head_mode="dense",
)
dense_val = float(r[0, center_idx] if r.ndim == 2 else r[center_idx])
frame_results[qi] = (sparse_val, dense_val)
except Exception as e:
logging.warning(f"Failed frame {qi}: {e}")
if not frame_results:
logging.warning(f"Episode {ep_idx}: all frames failed, skipping")
continue
# Interpolate to all frames in this episode
computed_idx = np.array(sorted(frame_results.keys()))
all_frame_arr = np.arange(ep_start, ep_end)
sparse_vals = np.array([frame_results[i][0] for i in computed_idx]) if compute_sparse else None
dense_vals = np.array([frame_results[i][1] for i in computed_idx]) if compute_dense else None
if self.stride > 1 and len(computed_idx) > 1:
if compute_sparse:
sparse_vals = interpolate_progress(computed_idx, sparse_vals, all_frame_arr)
if compute_dense:
dense_vals = interpolate_progress(computed_idx, dense_vals, all_frame_arr)
output_frames = all_frame_arr
else:
# Use only successfully computed frames to avoid indexing mismatch on failures
output_frames = computed_idx
for i, fi in enumerate(output_frames):
row = {"index": int(fi), "episode_index": ep_idx, "frame_index": int(fi - ep_start)}
if compute_sparse:
row["progress_sparse"] = float(sparse_vals[i])
if compute_dense:
row["progress_dense"] = float(dense_vals[i])
all_rows.append(row)
if all_rows:
import pandas as pd
df = pd.DataFrame(all_rows).sort_values("index").reset_index(drop=True)
table = pa.Table.from_pandas(df, preserve_index=False)
table = table.replace_schema_metadata({b"reward_model_path": self.reward_model_path.encode()})
shard_dir = Path(self.shard_dir)
shard_dir.mkdir(parents=True, exist_ok=True)
out = shard_dir / f"shard_{rank:05d}.parquet"
pq.write_table(table, out)
logging.info(f"Rank {rank}: saved {len(df)} rows to {out}")
class AggregateProgress(PipelineStep):
"""Merge all shard parquets into final sarm_progress.parquet."""
def __init__(self, repo_id, reward_model_path, shard_dir="rabc_shards", push_to_hub=False):
super().__init__()
self.repo_id = repo_id
self.reward_model_path = reward_model_path
self.shard_dir = shard_dir
self.push_to_hub = push_to_hub
def run(self, data=None, rank: int = 0, world_size: int = 1):
import datetime
import logging
import os
from pathlib import Path
import pandas as pd
import pyarrow as pa
import pyarrow.parquet as pq
from lerobot.datasets.lerobot_dataset import LeRobotDataset
from lerobot.utils.utils import init_logging
init_logging()
if rank != 0:
return
shard_dir = Path(self.shard_dir)
shards = sorted(shard_dir.glob("shard_*.parquet"))
if not shards:
raise FileNotFoundError(f"No shards found in {shard_dir}")
# Log shard modification time range to help detect stale files
mtimes = [os.path.getmtime(s) for s in shards]
oldest = datetime.datetime.fromtimestamp(min(mtimes)).isoformat(timespec="seconds")
newest = datetime.datetime.fromtimestamp(max(mtimes)).isoformat(timespec="seconds")
logging.info(f"Aggregating {len(shards)} shards (oldest: {oldest}, newest: {newest})")
df = pd.concat([pd.read_parquet(s) for s in shards], ignore_index=True)
df = df.sort_values("index").reset_index(drop=True)
table = pa.Table.from_pandas(df, preserve_index=False)
table = table.replace_schema_metadata({b"reward_model_path": self.reward_model_path.encode()})
temp_ds = LeRobotDataset(self.repo_id, download_videos=False)
out_path = Path(temp_ds.root) / "sarm_progress.parquet"
out_path.parent.mkdir(parents=True, exist_ok=True)
pq.write_table(table, out_path)
logging.info(f"Saved {len(df)} rows to {out_path}")
for col in ["progress_sparse", "progress_dense"]:
if col in df.columns:
v = df[col].dropna()
logging.info(
f"{col}: mean={v.mean():.4f} std={v.std():.4f} min={v.min():.4f} max={v.max():.4f}"
)
if self.push_to_hub:
from huggingface_hub import HfApi
api = HfApi()
hub_path = "sarm_progress.parquet"
logging.info(f"Uploading to {self.repo_id}/{hub_path}")
api.upload_file(
path_or_fileobj=str(out_path),
path_in_repo=hub_path,
repo_id=self.repo_id,
repo_type="dataset",
)
logging.info(f"Uploaded: https://huggingface.co/datasets/{self.repo_id}/blob/main/{hub_path}")
def make_compute_executor(
repo_id,
reward_model_path,
stride,
head_mode,
device,
shard_dir,
logs_dir,
job_name,
slurm,
workers,
partition,
cpus_per_task,
mem_per_cpu,
):
kwargs = {
"pipeline": [
ComputeProgressShards(repo_id, reward_model_path, stride, head_mode, device, str(shard_dir)),
],
"logging_dir": str(logs_dir / job_name),
}
if slurm:
kwargs.update(
{
"job_name": job_name,
"tasks": workers,
"workers": workers,
"time": "24:00:00",
"partition": partition,
"cpus_per_task": cpus_per_task,
"sbatch_args": {"mem-per-cpu": mem_per_cpu},
}
)
return SlurmPipelineExecutor(**kwargs)
kwargs.update({"tasks": workers, "workers": 1})
return LocalPipelineExecutor(**kwargs)
def make_aggregate_executor(
repo_id,
reward_model_path,
shard_dir,
logs_dir,
job_name,
slurm,
partition,
cpus_per_task,
mem_per_cpu,
push_to_hub,
):
kwargs = {
"pipeline": [
AggregateProgress(repo_id, reward_model_path, str(shard_dir), push_to_hub),
],
"logging_dir": str(logs_dir / job_name),
}
if slurm:
kwargs.update(
{
"job_name": job_name,
"tasks": 1,
"workers": 1,
"time": "02:00:00",
"partition": partition,
"cpus_per_task": cpus_per_task,
"sbatch_args": {"mem-per-cpu": mem_per_cpu},
}
)
return SlurmPipelineExecutor(**kwargs)
kwargs.update({"tasks": 1, "workers": 1})
return LocalPipelineExecutor(**kwargs)
def _add_shared_args(p):
p.add_argument(
"--repo-id",
type=str,
required=True,
help="Hugging Face repository identifier, e.g. 'user/dataset'.",
)
p.add_argument(
"--shard-dir",
type=Path,
default=Path("rabc_shards"),
help="Directory to read/write per-rank parquet shards.",
)
p.add_argument(
"--logs-dir",
type=Path,
default=Path("logs"),
help="Directory for datatrove logs.",
)
p.add_argument(
"--job-name",
type=str,
default=None,
help="SLURM job name (defaults to rabc_<subcommand>).",
)
p.add_argument(
"--slurm",
type=int,
default=1,
help="1 = submit via SLURM; 0 = run locally (useful for debugging).",
)
p.add_argument(
"--partition",
type=str,
default=None,
help="SLURM partition to submit to.",
)
p.add_argument(
"--cpus-per-task",
type=int,
default=4,
help="Number of CPUs per SLURM task.",
)
p.add_argument(
"--mem-per-cpu",
type=str,
default="4G",
help="Memory per CPU, e.g. '4G' or '1950M'.",
)
def main():
parser = argparse.ArgumentParser(
description="SLURM-distributed SARM RA-BC annotation pipeline",
formatter_class=argparse.RawDescriptionHelpFormatter,
)
sub = parser.add_subparsers(dest="command", required=True)
# compute subcommand
cp = sub.add_parser(
"compute",
help="Distribute progress computation across SLURM workers.",
)
_add_shared_args(cp)
cp.add_argument(
"--reward-model-path",
type=str,
required=True,
help="Path or HF repo id of the SARM reward model.",
)
cp.add_argument(
"--stride",
type=int,
default=1,
help="Compute every Nth frame; intermediate frames are interpolated (must be >= 1).",
)
cp.add_argument(
"--head-mode",
type=str,
default="sparse",
choices=["sparse", "dense", "both"],
help="Which reward head(s) to compute.",
)
cp.add_argument(
"--device",
type=str,
default="cpu",
help="Device for reward model inference, e.g. 'cpu' or 'cuda'.",
)
cp.add_argument(
"--workers",
type=int,
default=50,
help="Number of parallel SLURM tasks (one shard per worker).",
)
# aggregate subcommand
ap = sub.add_parser(
"aggregate",
help="Merge per-rank shards into a single sarm_progress.parquet.",
)
_add_shared_args(ap)
ap.add_argument(
"--reward-model-path",
type=str,
required=True,
help="Path or HF repo id of the SARM reward model (stored in parquet metadata).",
)
ap.add_argument(
"--push-to-hub",
action="store_true",
help="Upload sarm_progress.parquet to the Hugging Face Hub after aggregation.",
)
args = parser.parse_args()
job_name = args.job_name or f"rabc_{args.command}"
kwargs = vars(args)
kwargs["slurm"] = kwargs.pop("slurm") == 1
kwargs["job_name"] = job_name
command = kwargs.pop("command")
executor = make_compute_executor(**kwargs) if command == "compute" else make_aggregate_executor(**kwargs)
executor.run()
if __name__ == "__main__":
main()
examples/lekiwi/evaluate.py
+43 -45
View File
@@ -78,24 +78,40 @@ def main():
listener, events = init_keyboard_listener()
init_rerun(session_name="lekiwi_evaluate")
try:
if not robot.is_connected:
raise ValueError("Robot is not connected!")
if not robot.is_connected:
raise ValueError("Robot is not connected!")
print("Starting evaluate loop...")
recorded_episodes = 0
while recorded_episodes < NUM_EPISODES and not events["stop_recording"]:
log_say(f"Running inference, recording eval episode {recorded_episodes} of {NUM_EPISODES}")
print("Starting evaluate loop...")
recorded_episodes = 0
while recorded_episodes < NUM_EPISODES and not events["stop_recording"]:
log_say(f"Running inference, recording eval episode {recorded_episodes} of {NUM_EPISODES}")
# Main record loop
# Main record loop
record_loop(
robot=robot,
events=events,
fps=FPS,
policy=policy,
preprocessor=preprocessor, # Pass the pre and post policy processors
postprocessor=postprocessor,
dataset=dataset,
control_time_s=EPISODE_TIME_SEC,
single_task=TASK_DESCRIPTION,
display_data=True,
teleop_action_processor=teleop_action_processor,
robot_action_processor=robot_action_processor,
robot_observation_processor=robot_observation_processor,
)
# Reset the environment if not stopping or re-recording
if not events["stop_recording"] and (
(recorded_episodes < NUM_EPISODES - 1) or events["rerecord_episode"]
):
log_say("Reset the environment")
record_loop(
robot=robot,
events=events,
fps=FPS,
policy=policy,
preprocessor=preprocessor, # Pass the pre and post policy processors
postprocessor=postprocessor,
dataset=dataset,
control_time_s=EPISODE_TIME_SEC,
single_task=TASK_DESCRIPTION,
display_data=True,
@@ -104,42 +120,24 @@ def main():
robot_observation_processor=robot_observation_processor,
)
# Reset the environment if not stopping or re-recording
if not events["stop_recording"] and (
(recorded_episodes < NUM_EPISODES - 1) or events["rerecord_episode"]
):
log_say("Reset the environment")
record_loop(
robot=robot,
events=events,
fps=FPS,
control_time_s=EPISODE_TIME_SEC,
single_task=TASK_DESCRIPTION,
display_data=True,
teleop_action_processor=teleop_action_processor,
robot_action_processor=robot_action_processor,
robot_observation_processor=robot_observation_processor,
)
if events["rerecord_episode"]:
log_say("Re-record episode")
events["rerecord_episode"] = False
events["exit_early"] = False
dataset.clear_episode_buffer()
continue
if events["rerecord_episode"]:
log_say("Re-record episode")
events["rerecord_episode"] = False
events["exit_early"] = False
dataset.clear_episode_buffer()
continue
# Save episode
dataset.save_episode()
recorded_episodes += 1
# Save episode
dataset.save_episode()
recorded_episodes += 1
# Clean up
log_say("Stop recording")
robot.disconnect()
listener.stop()
finally:
# Clean up
log_say("Stop recording")
robot.disconnect()
listener.stop()
dataset.finalize()
dataset.push_to_hub()
dataset.finalize()
dataset.push_to_hub()
if __name__ == "__main__":
examples/lekiwi/record.py
+45 -46
View File
@@ -21,7 +21,7 @@ from lerobot.robots.lekiwi.config_lekiwi import LeKiwiClientConfig
from lerobot.robots.lekiwi.lekiwi_client import LeKiwiClient
from lerobot.scripts.lerobot_record import record_loop
from lerobot.teleoperators.keyboard import KeyboardTeleop, KeyboardTeleopConfig
from lerobot.teleoperators.so_leader import SO100Leader, SO100LeaderConfig
from lerobot.teleoperators.so100_leader import SO100Leader, SO100LeaderConfig
from lerobot.utils.constants import ACTION, OBS_STR
from lerobot.utils.control_utils import init_keyboard_listener
from lerobot.utils.utils import log_say
@@ -74,23 +74,40 @@ def main():
listener, events = init_keyboard_listener()
init_rerun(session_name="lekiwi_record")
try:
if not robot.is_connected or not leader_arm.is_connected or not keyboard.is_connected:
raise ValueError("Robot or teleop is not connected!")
if not robot.is_connected or not leader_arm.is_connected or not keyboard.is_connected:
raise ValueError("Robot or teleop is not connected!")
print("Starting record loop...")
recorded_episodes = 0
while recorded_episodes < NUM_EPISODES and not events["stop_recording"]:
log_say(f"Recording episode {recorded_episodes}")
print("Starting record loop...")
recorded_episodes = 0
while recorded_episodes < NUM_EPISODES and not events["stop_recording"]:
log_say(f"Recording episode {recorded_episodes}")
# Main record loop
# Main record loop
record_loop(
robot=robot,
events=events,
fps=FPS,
dataset=dataset,
teleop=[leader_arm, keyboard],
control_time_s=EPISODE_TIME_SEC,
single_task=TASK_DESCRIPTION,
display_data=True,
teleop_action_processor=teleop_action_processor,
robot_action_processor=robot_action_processor,
robot_observation_processor=robot_observation_processor,
)
# Reset the environment if not stopping or re-recording
if not events["stop_recording"] and (
(recorded_episodes < NUM_EPISODES - 1) or events["rerecord_episode"]
):
log_say("Reset the environment")
record_loop(
robot=robot,
events=events,
fps=FPS,
dataset=dataset,
teleop=[leader_arm, keyboard],
control_time_s=EPISODE_TIME_SEC,
control_time_s=RESET_TIME_SEC,
single_task=TASK_DESCRIPTION,
display_data=True,
teleop_action_processor=teleop_action_processor,
@@ -98,44 +115,26 @@ def main():
robot_observation_processor=robot_observation_processor,
)
# Reset the environment if not stopping or re-recording
if not events["stop_recording"] and (
(recorded_episodes < NUM_EPISODES - 1) or events["rerecord_episode"]
):
log_say("Reset the environment")
record_loop(
robot=robot,
events=events,
fps=FPS,
teleop=[leader_arm, keyboard],
control_time_s=RESET_TIME_SEC,
single_task=TASK_DESCRIPTION,
display_data=True,
teleop_action_processor=teleop_action_processor,
robot_action_processor=robot_action_processor,
robot_observation_processor=robot_observation_processor,
)
if events["rerecord_episode"]:
log_say("Re-record episode")
events["rerecord_episode"] = False
events["exit_early"] = False
dataset.clear_episode_buffer()
continue
if events["rerecord_episode"]:
log_say("Re-record episode")
events["rerecord_episode"] = False
events["exit_early"] = False
dataset.clear_episode_buffer()
continue
# Save episode
dataset.save_episode()
recorded_episodes += 1
# Save episode
dataset.save_episode()
recorded_episodes += 1
finally:
# Clean up
log_say("Stop recording")
robot.disconnect()
leader_arm.disconnect()
keyboard.disconnect()
listener.stop()
# Clean up
log_say("Stop recording")
robot.disconnect()
leader_arm.disconnect()
keyboard.disconnect()
listener.stop()
dataset.finalize()
dataset.push_to_hub()
dataset.finalize()
dataset.push_to_hub()
if __name__ == "__main__":
examples/lekiwi/replay.py
+15 -17
View File
@@ -42,27 +42,25 @@ def main():
# Connect to the robot
robot.connect()
try:
if not robot.is_connected:
raise ValueError("Robot is not connected!")
if not robot.is_connected:
raise ValueError("Robot is not connected!")
print("Starting replay loop...")
log_say(f"Replaying episode {EPISODE_IDX}")
for idx in range(len(episode_frames)):
t0 = time.perf_counter()
print("Starting replay loop...")
log_say(f"Replaying episode {EPISODE_IDX}")
for idx in range(len(episode_frames)):
t0 = time.perf_counter()
# Get recorded action from dataset
action = {
name: float(actions[idx][ACTION][i])
for i, name in enumerate(dataset.features[ACTION]["names"])
}
# Get recorded action from dataset
action = {
name: float(actions[idx][ACTION][i]) for i, name in enumerate(dataset.features[ACTION]["names"])
}
# Send action to robot
_ = robot.send_action(action)
# Send action to robot
_ = robot.send_action(action)
precise_sleep(max(1.0 / dataset.fps - (time.perf_counter() - t0), 0.0))
finally:
robot.disconnect()
precise_sleep(max(1.0 / dataset.fps - (time.perf_counter() - t0), 0.0))
robot.disconnect()
if __name__ == "__main__":
examples/lekiwi/teleoperate.py
+1 -1
View File
@@ -18,7 +18,7 @@ import time
from lerobot.robots.lekiwi import LeKiwiClient, LeKiwiClientConfig
from lerobot.teleoperators.keyboard.teleop_keyboard import KeyboardTeleop, KeyboardTeleopConfig
from lerobot.teleoperators.so_leader import SO100Leader, SO100LeaderConfig
from lerobot.teleoperators.so100_leader import SO100Leader, SO100LeaderConfig
from lerobot.utils.robot_utils import precise_sleep
from lerobot.utils.visualization_utils import init_rerun, log_rerun_data
examples/phone_to_so100/evaluate.py
+44 -46
View File
@@ -34,11 +34,12 @@ from lerobot.processor.converters import (
transition_to_observation,
transition_to_robot_action,
)
from lerobot.robots.so_follower import SO100Follower, SO100FollowerConfig
from lerobot.robots.so_follower.robot_kinematic_processor import (
from lerobot.robots.so100_follower.config_so100_follower import SO100FollowerConfig
from lerobot.robots.so100_follower.robot_kinematic_processor import (
ForwardKinematicsJointsToEE,
InverseKinematicsEEToJoints,
)
from lerobot.robots.so100_follower.so100_follower import SO100Follower
from lerobot.scripts.lerobot_record import record_loop
from lerobot.utils.control_utils import init_keyboard_listener
from lerobot.utils.utils import log_say
@@ -142,24 +143,38 @@ def main():
listener, events = init_keyboard_listener()
init_rerun(session_name="phone_so100_evaluate")
try:
if not robot.is_connected:
raise ValueError("Robot is not connected!")
if not robot.is_connected:
raise ValueError("Robot is not connected!")
print("Starting evaluate loop...")
episode_idx = 0
for episode_idx in range(NUM_EPISODES):
log_say(f"Running inference, recording eval episode {episode_idx + 1} of {NUM_EPISODES}")
print("Starting evaluate loop...")
episode_idx = 0
for episode_idx in range(NUM_EPISODES):
log_say(f"Running inference, recording eval episode {episode_idx + 1} of {NUM_EPISODES}")
# Main record loop
# Main record loop
record_loop(
robot=robot,
events=events,
fps=FPS,
policy=policy,
preprocessor=preprocessor, # Pass the pre and post policy processors
postprocessor=postprocessor,
dataset=dataset,
control_time_s=EPISODE_TIME_SEC,
single_task=TASK_DESCRIPTION,
display_data=True,
teleop_action_processor=make_default_teleop_action_processor(),
robot_action_processor=robot_ee_to_joints_processor,
robot_observation_processor=robot_joints_to_ee_pose_processor,
)
# Reset the environment if not stopping or re-recording
if not events["stop_recording"] and ((episode_idx < NUM_EPISODES - 1) or events["rerecord_episode"]):
log_say("Reset the environment")
record_loop(
robot=robot,
events=events,
fps=FPS,
policy=policy,
preprocessor=preprocessor, # Pass the pre and post policy processors
postprocessor=postprocessor,
dataset=dataset,
control_time_s=EPISODE_TIME_SEC,
single_task=TASK_DESCRIPTION,
display_data=True,
@@ -168,41 +183,24 @@ def main():
robot_observation_processor=robot_joints_to_ee_pose_processor,
)
# Reset the environment if not stopping or re-recording
if not events["stop_recording"] and (
(episode_idx < NUM_EPISODES - 1) or events["rerecord_episode"]
):
log_say("Reset the environment")
record_loop(
robot=robot,
events=events,
fps=FPS,
control_time_s=EPISODE_TIME_SEC,
single_task=TASK_DESCRIPTION,
display_data=True,
teleop_action_processor=make_default_teleop_action_processor(),
robot_action_processor=robot_ee_to_joints_processor,
robot_observation_processor=robot_joints_to_ee_pose_processor,
)
if events["rerecord_episode"]:
log_say("Re-record episode")
events["rerecord_episode"] = False
events["exit_early"] = False
dataset.clear_episode_buffer()
continue
if events["rerecord_episode"]:
log_say("Re-record episode")
events["rerecord_episode"] = False
events["exit_early"] = False
dataset.clear_episode_buffer()
continue
# Save episode
dataset.save_episode()
episode_idx += 1
# Save episode
dataset.save_episode()
episode_idx += 1
finally:
# Clean up
log_say("Stop recording")
robot.disconnect()
listener.stop()
# Clean up
log_say("Stop recording")
robot.disconnect()
listener.stop()
dataset.finalize()
dataset.push_to_hub()
dataset.finalize()
dataset.push_to_hub()
if __name__ == "__main__":
examples/phone_to_so100/record.py
+44 -46
View File
@@ -26,14 +26,15 @@ from lerobot.processor.converters import (
transition_to_observation,
transition_to_robot_action,
)
from lerobot.robots.so_follower import SO100Follower, SO100FollowerConfig
from lerobot.robots.so_follower.robot_kinematic_processor import (
from lerobot.robots.so100_follower.config_so100_follower import SO100FollowerConfig
from lerobot.robots.so100_follower.robot_kinematic_processor import (
EEBoundsAndSafety,
EEReferenceAndDelta,
ForwardKinematicsJointsToEE,
GripperVelocityToJoint,
InverseKinematicsEEToJoints,
)
from lerobot.robots.so100_follower.so100_follower import SO100Follower
from lerobot.scripts.lerobot_record import record_loop
from lerobot.teleoperators.phone.config_phone import PhoneConfig, PhoneOS
from lerobot.teleoperators.phone.phone_processor import MapPhoneActionToRobotAction
@@ -149,23 +150,38 @@ def main():
listener, events = init_keyboard_listener()
init_rerun(session_name="phone_so100_record")
try:
if not robot.is_connected or not phone.is_connected:
raise ValueError("Robot or teleop is not connected!")
if not robot.is_connected or not phone.is_connected:
raise ValueError("Robot or teleop is not connected!")
print("Starting record loop. Move your phone to teleoperate the robot...")
episode_idx = 0
while episode_idx < NUM_EPISODES and not events["stop_recording"]:
log_say(f"Recording episode {episode_idx + 1} of {NUM_EPISODES}")
print("Starting record loop. Move your phone to teleoperate the robot...")
episode_idx = 0
while episode_idx < NUM_EPISODES and not events["stop_recording"]:
log_say(f"Recording episode {episode_idx + 1} of {NUM_EPISODES}")
# Main record loop
# Main record loop
record_loop(
robot=robot,
events=events,
fps=FPS,
teleop=phone,
dataset=dataset,
control_time_s=EPISODE_TIME_SEC,
single_task=TASK_DESCRIPTION,
display_data=True,
teleop_action_processor=phone_to_robot_ee_pose_processor,
robot_action_processor=robot_ee_to_joints_processor,
robot_observation_processor=robot_joints_to_ee_pose,
)
# Reset the environment if not stopping or re-recording
if not events["stop_recording"] and (episode_idx < NUM_EPISODES - 1 or events["rerecord_episode"]):
log_say("Reset the environment")
record_loop(
robot=robot,
events=events,
fps=FPS,
teleop=phone,
dataset=dataset,
control_time_s=EPISODE_TIME_SEC,
control_time_s=RESET_TIME_SEC,
single_task=TASK_DESCRIPTION,
display_data=True,
teleop_action_processor=phone_to_robot_ee_pose_processor,
@@ -173,43 +189,25 @@ def main():
robot_observation_processor=robot_joints_to_ee_pose,
)
# Reset the environment if not stopping or re-recording
if not events["stop_recording"] and (
episode_idx < NUM_EPISODES - 1 or events["rerecord_episode"]
):
log_say("Reset the environment")
record_loop(
robot=robot,
events=events,
fps=FPS,
teleop=phone,
control_time_s=RESET_TIME_SEC,
single_task=TASK_DESCRIPTION,
display_data=True,
teleop_action_processor=phone_to_robot_ee_pose_processor,
robot_action_processor=robot_ee_to_joints_processor,
robot_observation_processor=robot_joints_to_ee_pose,
)
if events["rerecord_episode"]:
log_say("Re-recording episode")
events["rerecord_episode"] = False
events["exit_early"] = False
dataset.clear_episode_buffer()
continue
if events["rerecord_episode"]:
log_say("Re-recording episode")
events["rerecord_episode"] = False
events["exit_early"] = False
dataset.clear_episode_buffer()
continue
# Save episode
dataset.save_episode()
episode_idx += 1
# Save episode
dataset.save_episode()
episode_idx += 1
finally:
# Clean up
log_say("Stop recording")
robot.disconnect()
phone.disconnect()
listener.stop()
# Clean up
log_say("Stop recording")
robot.disconnect()
phone.disconnect()
listener.stop()
dataset.finalize()
dataset.push_to_hub()
dataset.finalize()
dataset.push_to_hub()
if __name__ == "__main__":
examples/phone_to_so100/replay.py
+23 -24
View File
@@ -23,10 +23,11 @@ from lerobot.processor.converters import (
robot_action_observation_to_transition,
transition_to_robot_action,
)
from lerobot.robots.so_follower import SO100Follower, SO100FollowerConfig
from lerobot.robots.so_follower.robot_kinematic_processor import (
from lerobot.robots.so100_follower.config_so100_follower import SO100FollowerConfig
from lerobot.robots.so100_follower.robot_kinematic_processor import (
InverseKinematicsEEToJoints,
)
from lerobot.robots.so100_follower.so100_follower import SO100Follower
from lerobot.utils.constants import ACTION
from lerobot.utils.robot_utils import precise_sleep
from lerobot.utils.utils import log_say
@@ -73,34 +74,32 @@ def main():
# Connect to the robot
robot.connect()
try:
if not robot.is_connected:
raise ValueError("Robot is not connected!")
if not robot.is_connected:
raise ValueError("Robot is not connected!")
print("Starting replay loop...")
log_say(f"Replaying episode {EPISODE_IDX}")
for idx in range(len(episode_frames)):
t0 = time.perf_counter()
print("Starting replay loop...")
log_say(f"Replaying episode {EPISODE_IDX}")
for idx in range(len(episode_frames)):
t0 = time.perf_counter()
# Get recorded action from dataset
ee_action = {
name: float(actions[idx][ACTION][i])
for i, name in enumerate(dataset.features[ACTION]["names"])
}
# Get recorded action from dataset
ee_action = {
name: float(actions[idx][ACTION][i]) for i, name in enumerate(dataset.features[ACTION]["names"])
}
# Get robot observation
robot_obs = robot.get_observation()
# Get robot observation
robot_obs = robot.get_observation()
# Dataset EE -> robot joints
joint_action = robot_ee_to_joints_processor((ee_action, robot_obs))
# Dataset EE -> robot joints
joint_action = robot_ee_to_joints_processor((ee_action, robot_obs))
# Send action to robot
_ = robot.send_action(joint_action)
# Send action to robot
_ = robot.send_action(joint_action)
precise_sleep(max(1.0 / dataset.fps - (time.perf_counter() - t0), 0.0))
finally:
# Clean up
robot.disconnect()
precise_sleep(1.0 / dataset.fps - (time.perf_counter() - t0))
# Clean up
robot.disconnect()
if __name__ == "__main__":
examples/phone_to_so100/teleoperate.py
+3 -2
View File
@@ -21,13 +21,14 @@ from lerobot.processor.converters import (
robot_action_observation_to_transition,
transition_to_robot_action,
)
from lerobot.robots.so_follower import SO100Follower, SO100FollowerConfig
from lerobot.robots.so_follower.robot_kinematic_processor import (
from lerobot.robots.so100_follower.config_so100_follower import SO100FollowerConfig
from lerobot.robots.so100_follower.robot_kinematic_processor import (
EEBoundsAndSafety,
EEReferenceAndDelta,
GripperVelocityToJoint,
InverseKinematicsEEToJoints,
)
from lerobot.robots.so100_follower.so100_follower import SO100Follower
from lerobot.teleoperators.phone.config_phone import PhoneConfig, PhoneOS
from lerobot.teleoperators.phone.phone_processor import MapPhoneActionToRobotAction
from lerobot.teleoperators.phone.teleop_phone import Phone
examples/rtc/eval_dataset.py
+10 -10
View File
@@ -27,8 +27,8 @@ measuring consistency and ground truth alignment.
Usage:
# Basic usage with smolvla policy
uv run python examples/rtc/eval_dataset.py \
--policy.path=<USER>/smolvla_check_rtc_last3 \
--dataset.repo_id=<USER>/check_rtc \
--policy.path=helper2424/smolvla_check_rtc_last3 \
--dataset.repo_id=helper2424/check_rtc \
--rtc.execution_horizon=8 \
--device=mps \
--rtc.max_guidance_weight=10.0 \
@@ -58,16 +58,16 @@ Usage:
--device=cuda
uv run python examples/rtc/eval_dataset.py \
--policy.path=<USER>/reuben_pi0 \
--dataset.repo_id=<USER>/so101_cube_in_cup \
--policy.path=lipsop/reuben_pi0 \
--dataset.repo_id=ReubenLim/so101_cube_in_cup \
--rtc.execution_horizon=8 \
--device=cuda
# With torch.compile for faster inference (PyTorch 2.0+)
# Note: CUDA graphs disabled by default due to in-place ops in denoising loop
uv run python examples/rtc/eval_dataset.py \
--policy.path=<USER>/smolvla_check_rtc_last3 \
--dataset.repo_id=<USER>/check_rtc \
--policy.path=helper2424/smolvla_check_rtc_last3 \
--dataset.repo_id=helper2424/check_rtc \
--rtc.execution_horizon=8 \
--device=mps \
--use_torch_compile=true \
@@ -75,8 +75,8 @@ Usage:
# With torch.compile on CUDA (CUDA graphs disabled by default)
uv run python examples/rtc/eval_dataset.py \
--policy.path=<USER>/smolvla_check_rtc_last3 \
--dataset.repo_id=<USER>/check_rtc \
--policy.path=helper2424/smolvla_check_rtc_last3 \
--dataset.repo_id=helper2424/check_rtc \
--rtc.execution_horizon=8 \
--device=cuda \
--use_torch_compile=true \
@@ -84,8 +84,8 @@ Usage:
# Enable CUDA graphs (advanced - may cause tensor aliasing errors)
uv run python examples/rtc/eval_dataset.py \
--policy.path=<USER>/smolvla_check_rtc_last3 \
--dataset.repo_id=<USER>/check_rtc \
--policy.path=helper2424/smolvla_check_rtc_last3 \
--dataset.repo_id=helper2424/check_rtc \
--use_torch_compile=true \
--torch_compile_backend=inductor \
--torch_compile_mode=max-autotune \
examples/rtc/eval_with_real_robot.py
+6 -19
View File
@@ -28,7 +28,7 @@ For simulation environments, see eval_with_simulation.py
Usage:
# Run RTC with Real robot with RTC
uv run examples/rtc/eval_with_real_robot.py \
--policy.path=<USER>/smolvla_check_rtc_last3 \
--policy.path=helper2424/smolvla_check_rtc_last3 \
--policy.device=mps \
--rtc.enabled=true \
--rtc.execution_horizon=20 \
@@ -41,7 +41,7 @@ Usage:
# Run RTC with Real robot without RTC
uv run examples/rtc/eval_with_real_robot.py \
--policy.path=<USER>/smolvla_check_rtc_last3 \
--policy.path=helper2424/smolvla_check_rtc_last3 \
--policy.device=mps \
--rtc.enabled=false \
--robot.type=so100_follower \
@@ -53,7 +53,7 @@ Usage:
# Run RTC with Real robot with pi0.5 policy
uv run examples/rtc/eval_with_real_robot.py \
--policy.path=<USER>/pi05_check_rtc \
--policy.path=helper2424/pi05_check_rtc \
--policy.device=mps \
--rtc.enabled=true \
--rtc.execution_horizon=20 \
@@ -78,7 +78,6 @@ from torch import Tensor
from lerobot.cameras.opencv.configuration_opencv import OpenCVCameraConfig # noqa: F401
from lerobot.cameras.realsense.configuration_realsense import RealSenseCameraConfig # noqa: F401
from lerobot.cameras.zmq.configuration_zmq import ZMQCameraConfig # noqa: F401
from lerobot.configs import parser
from lerobot.configs.policies import PreTrainedConfig
from lerobot.configs.types import RTCAttentionSchedule
@@ -95,10 +94,9 @@ from lerobot.rl.process import ProcessSignalHandler
from lerobot.robots import ( # noqa: F401
Robot,
RobotConfig,
bi_so_follower,
koch_follower,
so_follower,
unitree_g1,
so100_follower,
so101_follower,
)
from lerobot.robots.utils import make_robot_from_config
from lerobot.utils.constants import OBS_IMAGES
@@ -457,18 +455,7 @@ def demo_cli(cfg: RTCDemoConfig):
if cfg.policy.type == "pi05" or cfg.policy.type == "pi0":
config.compile_model = cfg.use_torch_compile
if config.use_peft:
from peft import PeftConfig, PeftModel
peft_pretrained_path = cfg.policy.pretrained_path
peft_config = PeftConfig.from_pretrained(peft_pretrained_path)
policy = policy_class.from_pretrained(
pretrained_name_or_path=peft_config.base_model_name_or_path, config=config
)
policy = PeftModel.from_pretrained(policy, peft_pretrained_path, config=peft_config)
else:
policy = policy_class.from_pretrained(cfg.policy.pretrained_path, config=config)
policy = policy_class.from_pretrained(cfg.policy.pretrained_path, config=config)
# Turn on RTC
policy.config.rtc_config = cfg.rtc
examples/so100_to_so100_EE/evaluate.py
+44 -46
View File
@@ -34,11 +34,12 @@ from lerobot.processor.converters import (
transition_to_observation,
transition_to_robot_action,
)
from lerobot.robots.so_follower import SO100Follower, SO100FollowerConfig
from lerobot.robots.so_follower.robot_kinematic_processor import (
from lerobot.robots.so100_follower.config_so100_follower import SO100FollowerConfig
from lerobot.robots.so100_follower.robot_kinematic_processor import (
ForwardKinematicsJointsToEE,
InverseKinematicsEEToJoints,
)
from lerobot.robots.so100_follower.so100_follower import SO100Follower
from lerobot.scripts.lerobot_record import record_loop
from lerobot.utils.control_utils import init_keyboard_listener
from lerobot.utils.utils import log_say
@@ -142,24 +143,38 @@ def main():
listener, events = init_keyboard_listener()
init_rerun(session_name="so100_so100_evaluate")
try:
if not robot.is_connected:
raise ValueError("Robot is not connected!")
if not robot.is_connected:
raise ValueError("Robot is not connected!")
print("Starting evaluate loop...")
episode_idx = 0
for episode_idx in range(NUM_EPISODES):
log_say(f"Running inference, recording eval episode {episode_idx + 1} of {NUM_EPISODES}")
print("Starting evaluate loop...")
episode_idx = 0
for episode_idx in range(NUM_EPISODES):
log_say(f"Running inference, recording eval episode {episode_idx + 1} of {NUM_EPISODES}")
# Main record loop
# Main record loop
record_loop(
robot=robot,
events=events,
fps=FPS,
policy=policy,
preprocessor=preprocessor, # Pass the pre and post policy processors
postprocessor=postprocessor,
dataset=dataset,
control_time_s=EPISODE_TIME_SEC,
single_task=TASK_DESCRIPTION,
display_data=True,
teleop_action_processor=make_default_teleop_action_processor(),
robot_action_processor=robot_ee_to_joints_processor,
robot_observation_processor=robot_joints_to_ee_pose_processor,
)
# Reset the environment if not stopping or re-recording
if not events["stop_recording"] and ((episode_idx < NUM_EPISODES - 1) or events["rerecord_episode"]):
log_say("Reset the environment")
record_loop(
robot=robot,
events=events,
fps=FPS,
policy=policy,
preprocessor=preprocessor, # Pass the pre and post policy processors
postprocessor=postprocessor,
dataset=dataset,
control_time_s=EPISODE_TIME_SEC,
single_task=TASK_DESCRIPTION,
display_data=True,
@@ -168,41 +183,24 @@ def main():
robot_observation_processor=robot_joints_to_ee_pose_processor,
)
# Reset the environment if not stopping or re-recording
if not events["stop_recording"] and (
(episode_idx < NUM_EPISODES - 1) or events["rerecord_episode"]
):
log_say("Reset the environment")
record_loop(
robot=robot,
events=events,
fps=FPS,
control_time_s=EPISODE_TIME_SEC,
single_task=TASK_DESCRIPTION,
display_data=True,
teleop_action_processor=make_default_teleop_action_processor(),
robot_action_processor=robot_ee_to_joints_processor,
robot_observation_processor=robot_joints_to_ee_pose_processor,
)
if events["rerecord_episode"]:
log_say("Re-record episode")
events["rerecord_episode"] = False
events["exit_early"] = False
dataset.clear_episode_buffer()
continue
if events["rerecord_episode"]:
log_say("Re-record episode")
events["rerecord_episode"] = False
events["exit_early"] = False
dataset.clear_episode_buffer()
continue
# Save episode
dataset.save_episode()
episode_idx += 1
# Save episode
dataset.save_episode()
episode_idx += 1
finally:
# Clean up
log_say("Stop recording")
robot.disconnect()
listener.stop()
# Clean up
log_say("Stop recording")
robot.disconnect()
listener.stop()
dataset.finalize()
dataset.push_to_hub()
dataset.finalize()
dataset.push_to_hub()
if __name__ == "__main__":
examples/so100_to_so100_EE/record.py
+46 -48
View File
@@ -27,14 +27,16 @@ from lerobot.processor.converters import (
transition_to_observation,
transition_to_robot_action,
)
from lerobot.robots.so_follower import SO100Follower, SO100FollowerConfig
from lerobot.robots.so_follower.robot_kinematic_processor import (
from lerobot.robots.so100_follower.config_so100_follower import SO100FollowerConfig
from lerobot.robots.so100_follower.robot_kinematic_processor import (
EEBoundsAndSafety,
ForwardKinematicsJointsToEE,
InverseKinematicsEEToJoints,
)
from lerobot.robots.so100_follower.so100_follower import SO100Follower
from lerobot.scripts.lerobot_record import record_loop
from lerobot.teleoperators.so_leader import SO100Leader, SO100LeaderConfig
from lerobot.teleoperators.so100_leader.config_so100_leader import SO100LeaderConfig
from lerobot.teleoperators.so100_leader.so100_leader import SO100Leader
from lerobot.utils.control_utils import init_keyboard_listener
from lerobot.utils.utils import log_say
from lerobot.utils.visualization_utils import init_rerun
@@ -146,23 +148,38 @@ def main():
listener, events = init_keyboard_listener()
init_rerun(session_name="recording_phone")
try:
if not leader.is_connected or not follower.is_connected:
raise ValueError("Robot or teleop is not connected!")
if not leader.is_connected or not follower.is_connected:
raise ValueError("Robot or teleop is not connected!")
print("Starting record loop...")
episode_idx = 0
while episode_idx < NUM_EPISODES and not events["stop_recording"]:
log_say(f"Recording episode {episode_idx + 1} of {NUM_EPISODES}")
print("Starting record loop...")
episode_idx = 0
while episode_idx < NUM_EPISODES and not events["stop_recording"]:
log_say(f"Recording episode {episode_idx + 1} of {NUM_EPISODES}")
# Main record loop
# Main record loop
record_loop(
robot=follower,
events=events,
fps=FPS,
teleop=leader,
dataset=dataset,
control_time_s=EPISODE_TIME_SEC,
single_task=TASK_DESCRIPTION,
display_data=True,
teleop_action_processor=leader_joints_to_ee,
robot_action_processor=ee_to_follower_joints,
robot_observation_processor=follower_joints_to_ee,
)
# Reset the environment if not stopping or re-recording
if not events["stop_recording"] and (episode_idx < NUM_EPISODES - 1 or events["rerecord_episode"]):
log_say("Reset the environment")
record_loop(
robot=follower,
events=events,
fps=FPS,
teleop=leader,
dataset=dataset,
control_time_s=EPISODE_TIME_SEC,
control_time_s=RESET_TIME_SEC,
single_task=TASK_DESCRIPTION,
display_data=True,
teleop_action_processor=leader_joints_to_ee,
@@ -170,44 +187,25 @@ def main():
robot_observation_processor=follower_joints_to_ee,
)
# Reset the environment if not stopping or re-recording
if not events["stop_recording"] and (
episode_idx < NUM_EPISODES - 1 or events["rerecord_episode"]
):
log_say("Reset the environment")
record_loop(
robot=follower,
events=events,
fps=FPS,
teleop=leader,
control_time_s=RESET_TIME_SEC,
single_task=TASK_DESCRIPTION,
display_data=True,
teleop_action_processor=leader_joints_to_ee,
robot_action_processor=ee_to_follower_joints,
robot_observation_processor=follower_joints_to_ee,
)
if events["rerecord_episode"]:
log_say("Re-recording episode")
events["rerecord_episode"] = False
events["exit_early"] = False
dataset.clear_episode_buffer()
continue
if events["rerecord_episode"]:
log_say("Re-recording episode")
events["rerecord_episode"] = False
events["exit_early"] = False
dataset.clear_episode_buffer()
continue
# Save episode
dataset.save_episode()
episode_idx += 1
# Save episode
dataset.save_episode()
episode_idx += 1
# Clean up
log_say("Stop recording")
leader.disconnect()
follower.disconnect()
listener.stop()
finally:
# Clean up
log_say("Stop recording")
leader.disconnect()
follower.disconnect()
listener.stop()
dataset.finalize()
dataset.push_to_hub()
dataset.finalize()
dataset.push_to_hub()
if __name__ == "__main__":
examples/so100_to_so100_EE/replay.py
+22 -24
View File
@@ -24,10 +24,11 @@ from lerobot.processor.converters import (
robot_action_observation_to_transition,
transition_to_robot_action,
)
from lerobot.robots.so_follower import SO100Follower, SO100FollowerConfig
from lerobot.robots.so_follower.robot_kinematic_processor import (
from lerobot.robots.so100_follower.config_so100_follower import SO100FollowerConfig
from lerobot.robots.so100_follower.robot_kinematic_processor import (
InverseKinematicsEEToJoints,
)
from lerobot.robots.so100_follower.so100_follower import SO100Follower
from lerobot.utils.constants import ACTION
from lerobot.utils.robot_utils import precise_sleep
from lerobot.utils.utils import log_say
@@ -74,35 +75,32 @@ def main():
# Connect to the robot
robot.connect()
try:
if not robot.is_connected:
raise ValueError("Robot is not connected!")
if not robot.is_connected:
raise ValueError("Robot is not connected!")
print("Starting replay loop...")
log_say(f"Replaying episode {EPISODE_IDX}")
for idx in range(len(episode_frames)):
t0 = time.perf_counter()
print("Starting replay loop...")
log_say(f"Replaying episode {EPISODE_IDX}")
for idx in range(len(episode_frames)):
t0 = time.perf_counter()
# Get recorded action from dataset
ee_action = {
name: float(actions[idx][ACTION][i])
for i, name in enumerate(dataset.features[ACTION]["names"])
}
# Get recorded action from dataset
ee_action = {
name: float(actions[idx][ACTION][i]) for i, name in enumerate(dataset.features[ACTION]["names"])
}
# Get robot observation
robot_obs = robot.get_observation()
# Get robot observation
robot_obs = robot.get_observation()
# Dataset EE -> robot joints
joint_action = robot_ee_to_joints_processor((ee_action, robot_obs))
# Dataset EE -> robot joints
joint_action = robot_ee_to_joints_processor((ee_action, robot_obs))
# Send action to robot
_ = robot.send_action(joint_action)
# Send action to robot
_ = robot.send_action(joint_action)
precise_sleep(max(1.0 / dataset.fps - (time.perf_counter() - t0), 0.0))
precise_sleep(1.0 / dataset.fps - (time.perf_counter() - t0))
finally:
# Clean up
robot.disconnect()
# Clean up
robot.disconnect()
if __name__ == "__main__":
examples/so100_to_so100_EE/teleoperate.py
+5 -3
View File
@@ -23,13 +23,15 @@ from lerobot.processor.converters import (
robot_action_to_transition,
transition_to_robot_action,
)
from lerobot.robots.so_follower import SO100Follower, SO100FollowerConfig
from lerobot.robots.so_follower.robot_kinematic_processor import (
from lerobot.robots.so100_follower.config_so100_follower import SO100FollowerConfig
from lerobot.robots.so100_follower.robot_kinematic_processor import (
EEBoundsAndSafety,
ForwardKinematicsJointsToEE,
InverseKinematicsEEToJoints,
)
from lerobot.teleoperators.so_leader import SO100Leader, SO100LeaderConfig
from lerobot.robots.so100_follower.so100_follower import SO100Follower
from lerobot.teleoperators.so100_leader.config_so100_leader import SO100LeaderConfig
from lerobot.teleoperators.so100_leader.so100_leader import SO100Leader
from lerobot.utils.robot_utils import precise_sleep
from lerobot.utils.visualization_utils import init_rerun, log_rerun_data
examples/tutorial/act/act_using_example.py
+2 -1
View File
@@ -5,7 +5,8 @@ from lerobot.datasets.lerobot_dataset import LeRobotDatasetMetadata
from lerobot.policies.act.modeling_act import ACTPolicy
from lerobot.policies.factory import make_pre_post_processors
from lerobot.policies.utils import build_inference_frame, make_robot_action
from lerobot.robots.so_follower import SO100Follower, SO100FollowerConfig
from lerobot.robots.so100_follower.config_so100_follower import SO100FollowerConfig
from lerobot.robots.so100_follower.so100_follower import SO100Follower
MAX_EPISODES = 5
MAX_STEPS_PER_EPISODE = 20
examples/tutorial/async-inf/robot_client.py
+1 -2
View File
@@ -4,7 +4,7 @@ from lerobot.async_inference.configs import RobotClientConfig
from lerobot.async_inference.helpers import visualize_action_queue_size
from lerobot.async_inference.robot_client import RobotClient
from lerobot.cameras.opencv.configuration_opencv import OpenCVCameraConfig
from lerobot.robots.so_follower import SO100FollowerConfig
from lerobot.robots.so100_follower import SO100FollowerConfig
def main():
@@ -30,7 +30,6 @@ def main():
robot=robot_cfg,
server_address=server_address,
policy_device="mps",
client_device="cpu",
policy_type="act",
pretrained_name_or_path="<user>/robot_learning_tutorial_act",
chunk_size_threshold=0.5, # g
examples/tutorial/diffusion/diffusion_using_example.py
+2 -1
View File
@@ -5,7 +5,8 @@ from lerobot.datasets.lerobot_dataset import LeRobotDatasetMetadata
from lerobot.policies.diffusion.modeling_diffusion import DiffusionPolicy
from lerobot.policies.factory import make_pre_post_processors
from lerobot.policies.utils import build_inference_frame, make_robot_action
from lerobot.robots.so_follower import SO100Follower, SO100FollowerConfig
from lerobot.robots.so100_follower.config_so100_follower import SO100FollowerConfig
from lerobot.robots.so100_follower.so100_follower import SO100Follower
MAX_EPISODES = 5
MAX_STEPS_PER_EPISODE = 20
examples/tutorial/pi0/using_pi0_example.py
+2 -1
View File
@@ -5,7 +5,8 @@ from lerobot.datasets.utils import hw_to_dataset_features
from lerobot.policies.factory import make_pre_post_processors
from lerobot.policies.pi0.modeling_pi0 import PI0Policy
from lerobot.policies.utils import build_inference_frame, make_robot_action
from lerobot.robots.so_follower import SO100Follower, SO100FollowerConfig
from lerobot.robots.so100_follower.config_so100_follower import SO100FollowerConfig
from lerobot.robots.so100_follower.so100_follower import SO100Follower
MAX_EPISODES = 5
MAX_STEPS_PER_EPISODE = 20
examples/tutorial/rl/hilserl_example.py
+2 -2
View File
@@ -14,8 +14,8 @@ from lerobot.policies.sac.modeling_sac import SACPolicy
from lerobot.policies.sac.reward_model.modeling_classifier import Classifier
from lerobot.rl.buffer import ReplayBuffer
from lerobot.rl.gym_manipulator import make_robot_env
from lerobot.robots.so_follower import SO100FollowerConfig
from lerobot.teleoperators.so_leader import SO100LeaderConfig
from lerobot.robots.so100_follower import SO100FollowerConfig
from lerobot.teleoperators.so100_leader import SO100LeaderConfig
from lerobot.teleoperators.utils import TeleopEvents
LOG_EVERY = 10
examples/tutorial/smolvla/using_smolvla_example.py
+2 -1
View File
@@ -5,7 +5,8 @@ from lerobot.datasets.utils import hw_to_dataset_features
from lerobot.policies.factory import make_pre_post_processors
from lerobot.policies.smolvla.modeling_smolvla import SmolVLAPolicy
from lerobot.policies.utils import build_inference_frame, make_robot_action
from lerobot.robots.so_follower import SO100Follower, SO100FollowerConfig
from lerobot.robots.so100_follower.config_so100_follower import SO100FollowerConfig
from lerobot.robots.so100_follower.so100_follower import SO100Follower
MAX_EPISODES = 5
MAX_STEPS_PER_EPISODE = 20
examples/unitree_g1/gr00t_locomotion.py
+347
View File
@@ -0,0 +1,347 @@
#!/usr/bin/env python
# Copyright 2025 The HuggingFace Inc. team. All rights reserved.
#
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
#
# http://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.
"""
Example: GR00T Locomotion with Pre-loaded Policies
This example demonstrates the NEW pattern for loading GR00T policies externally
and passing them to the robot class.
"""
import argparse
import logging
import threading
import time
from collections import deque
import numpy as np
import onnxruntime as ort
from huggingface_hub import hf_hub_download
from lerobot.robots.unitree_g1.config_unitree_g1 import UnitreeG1Config
from lerobot.robots.unitree_g1.unitree_g1 import UnitreeG1
logger = logging.getLogger(__name__)
GROOT_DEFAULT_ANGLES = np.zeros(29, dtype=np.float32)
GROOT_DEFAULT_ANGLES[[0, 6]] = -0.1 # hip pitch
GROOT_DEFAULT_ANGLES[[3, 9]] = 0.3 # knee
GROOT_DEFAULT_ANGLES[[4, 10]] = -0.2 # ankle pitch
MISSING_JOINTS = []
G1_MODEL = "g1_23" # or "g1_29"
if G1_MODEL == "g1_23":
MISSING_JOINTS = [12, 14, 20, 21, 27, 28] # waist yaw/pitch, wrist pitch/yaw
LOCOMOTION_ACTION_SCALE = 0.25
LOCOMOTION_CONTROL_DT = 0.02
ANG_VEL_SCALE: float = 0.25
DOF_POS_SCALE: float = 1.0
DOF_VEL_SCALE: float = 0.05
CMD_SCALE: list = [2.0, 2.0, 0.25]
DEFAULT_GROOT_REPO_ID = "nepyope/GR00T-WholeBodyControl_g1"
def load_groot_policies(
repo_id: str = DEFAULT_GROOT_REPO_ID,
) -> tuple[ort.InferenceSession, ort.InferenceSession]:
"""Load GR00T dual-policy system (Balance + Walk) from Hugging Face Hub.
Args:
repo_id: Hugging Face Hub repository ID containing the ONNX policies.
"""
logger.info(f"Loading GR00T dual-policy system from Hugging Face Hub ({repo_id})...")
# Download ONNX policies from Hugging Face Hub
balance_path = hf_hub_download(
repo_id=repo_id,
filename="GR00T-WholeBodyControl-Balance.onnx",
)
walk_path = hf_hub_download(
repo_id=repo_id,
filename="GR00T-WholeBodyControl-Walk.onnx",
)
# Load ONNX policies
policy_balance = ort.InferenceSession(balance_path)
policy_walk = ort.InferenceSession(walk_path)
logger.info("GR00T policies loaded successfully")
return policy_balance, policy_walk
class GrootLocomotionController:
"""
Handles GR00T-style locomotion control for the Unitree G1 robot.
This controller manages:
- Dual-policy system (Balance + Walk)
- 29-joint observation processing
- 15D action output (legs + waist)
- Policy inference and motor command generation
"""
def __init__(self, policy_balance, policy_walk, robot, config):
self.policy_balance = policy_balance
self.policy_walk = policy_walk
self.robot = robot
self.config = config
self.locomotion_cmd = np.array([0.0, 0.0, 0.0], dtype=np.float32) # vx, vy, theta_dot
# GR00T-specific state
self.groot_qj_all = np.zeros(29, dtype=np.float32)
self.groot_dqj_all = np.zeros(29, dtype=np.float32)
self.groot_action = np.zeros(15, dtype=np.float32)
self.groot_obs_single = np.zeros(86, dtype=np.float32)
self.groot_obs_history = deque(maxlen=6)
self.groot_obs_stacked = np.zeros(516, dtype=np.float32)
self.groot_height_cmd = 0.74 # Default base height
self.groot_orientation_cmd = np.array([0.0, 0.0, 0.0], dtype=np.float32)
# input to gr00t is 6 frames (6*86D=516)
for _ in range(6):
self.groot_obs_history.append(np.zeros(86, dtype=np.float32))
# Thread management
self.locomotion_running = False
self.locomotion_thread = None
logger.info("GrootLocomotionController initialized")
def groot_locomotion_run(self):
# get current observation
robot_state = self.robot.get_observation()
if robot_state is None:
return
# get command from remote controller
if robot_state.wireless_remote is not None:
self.robot.remote_controller.set(robot_state.wireless_remote)
if self.robot.remote_controller.button[0]: # R1 - raise waist
self.groot_height_cmd += 0.001
self.groot_height_cmd = np.clip(self.groot_height_cmd, 0.50, 1.00)
if self.robot.remote_controller.button[4]: # R2 - lower waist
self.groot_height_cmd -= 0.001
self.groot_height_cmd = np.clip(self.groot_height_cmd, 0.50, 1.00)
else:
self.robot.remote_controller.lx = 0.0
self.robot.remote_controller.ly = 0.0
self.robot.remote_controller.rx = 0.0
self.robot.remote_controller.ry = 0.0
self.locomotion_cmd[0] = self.robot.remote_controller.ly # forward/backward
self.locomotion_cmd[1] = self.robot.remote_controller.lx * -1 # left/right
self.locomotion_cmd[2] = self.robot.remote_controller.rx * -1 # rotation rate
for i in range(29):
self.groot_qj_all[i] = robot_state.motor_state[i].q
self.groot_dqj_all[i] = robot_state.motor_state[i].dq
# adapt observation for g1_23dof
for idx in MISSING_JOINTS:
self.groot_qj_all[idx] = 0.0
self.groot_dqj_all[idx] = 0.0
# Scale joint positions and velocities
qj_obs = self.groot_qj_all.copy()
dqj_obs = self.groot_dqj_all.copy()
# express imu data in gravity frame of reference
quat = robot_state.imu_state.quaternion
ang_vel = np.array(robot_state.imu_state.gyroscope, dtype=np.float32)
gravity_orientation = self.robot.get_gravity_orientation(quat)
# scale joint positions and velocities before policy inference
qj_obs = (qj_obs - GROOT_DEFAULT_ANGLES) * DOF_POS_SCALE
dqj_obs = dqj_obs * DOF_VEL_SCALE
ang_vel_scaled = ang_vel * ANG_VEL_SCALE
# build single frame observation
self.groot_obs_single[:3] = self.locomotion_cmd * np.array(CMD_SCALE)
self.groot_obs_single[3] = self.groot_height_cmd
self.groot_obs_single[4:7] = self.groot_orientation_cmd
self.groot_obs_single[7:10] = ang_vel_scaled
self.groot_obs_single[10:13] = gravity_orientation
self.groot_obs_single[13:42] = qj_obs
self.groot_obs_single[42:71] = dqj_obs
self.groot_obs_single[71:86] = self.groot_action # 15D previous actions
# Add to history and stack observations (6 frames × 86D = 516D)
self.groot_obs_history.append(self.groot_obs_single.copy())
# Stack all 6 frames into 516D vector
for i, obs_frame in enumerate(self.groot_obs_history):
start_idx = i * 86
end_idx = start_idx + 86
self.groot_obs_stacked[start_idx:end_idx] = obs_frame
# Run policy inference (ONNX) with 516D stacked observation
cmd_magnitude = np.linalg.norm(self.locomotion_cmd)
selected_policy = (
self.policy_balance if cmd_magnitude < 0.05 else self.policy_walk
) # balance/standing policy for small commands, walking policy for movement commands
# run policy inference
ort_inputs = {selected_policy.get_inputs()[0].name: np.expand_dims(self.groot_obs_stacked, axis=0)}
ort_outs = selected_policy.run(None, ort_inputs)
self.groot_action = ort_outs[0].squeeze()
# transform action back to target joint positions
target_dof_pos_15 = GROOT_DEFAULT_ANGLES[:15] + self.groot_action * LOCOMOTION_ACTION_SCALE
# command motors
for i in range(15):
motor_idx = i
self.robot.msg.motor_cmd[motor_idx].q = target_dof_pos_15[i]
self.robot.msg.motor_cmd[motor_idx].qd = 0
self.robot.msg.motor_cmd[motor_idx].kp = self.robot.kp[motor_idx]
self.robot.msg.motor_cmd[motor_idx].kd = self.robot.kd[motor_idx]
self.robot.msg.motor_cmd[motor_idx].tau = 0
# adapt action for g1_23dof
for joint_idx in MISSING_JOINTS:
self.robot.msg.motor_cmd[joint_idx].q = 0.0
self.robot.msg.motor_cmd[joint_idx].qd = 0
self.robot.msg.motor_cmd[joint_idx].kp = self.robot.kp[joint_idx]
self.robot.msg.motor_cmd[joint_idx].kd = self.robot.kd[joint_idx]
self.robot.msg.motor_cmd[joint_idx].tau = 0
# send action to robot
self.robot.send_action(self.robot.msg)
def _locomotion_thread_loop(self):
"""Background thread that runs the locomotion policy at specified rate."""
logger.info("Locomotion thread started")
while self.locomotion_running:
start_time = time.time()
try:
self.groot_locomotion_run()
except Exception as e:
logger.error(f"Error in locomotion loop: {e}")
# Sleep to maintain control rate
elapsed = time.time() - start_time
sleep_time = max(0, LOCOMOTION_CONTROL_DT - elapsed)
time.sleep(sleep_time)
logger.info("Locomotion thread stopped")
def start_locomotion_thread(self):
if self.locomotion_running:
logger.warning("Locomotion thread already running")
return
logger.info("Starting locomotion control thread...")
self.locomotion_running = True
self.locomotion_thread = threading.Thread(target=self._locomotion_thread_loop, daemon=True)
self.locomotion_thread.start()
logger.info("Locomotion control thread started!")
def stop_locomotion_thread(self):
if not self.locomotion_running:
return
logger.info("Stopping locomotion control thread...")
self.locomotion_running = False
if self.locomotion_thread:
self.locomotion_thread.join(timeout=2.0)
logger.info("Locomotion control thread stopped")
def reset_robot(self):
"""Move robot legs to default standing position over 2 seconds (arms are not moved)."""
total_time = 3.0
num_step = int(total_time / self.robot.control_dt)
# Only control legs, not arms (first 12 joints)
default_pos = GROOT_DEFAULT_ANGLES # First 12 values are leg angles
dof_size = len(default_pos)
# Get current lowstate
robot_state = self.robot.get_observation()
# Record the current leg positions
init_dof_pos = np.zeros(dof_size, dtype=np.float32)
for i in range(dof_size):
init_dof_pos[i] = robot_state.motor_state[i].q
# Move legs to default pos
for i in range(num_step):
alpha = i / num_step
for motor_idx in range(dof_size):
target_pos = default_pos[motor_idx]
self.robot.msg.motor_cmd[motor_idx].q = (
init_dof_pos[motor_idx] * (1 - alpha) + target_pos * alpha
)
self.robot.msg.motor_cmd[motor_idx].qd = 0
self.robot.msg.motor_cmd[motor_idx].kp = self.robot.kp[motor_idx]
self.robot.msg.motor_cmd[motor_idx].kd = self.robot.kd[motor_idx]
self.robot.msg.motor_cmd[motor_idx].tau = 0
self.robot.msg.crc = self.robot.crc.Crc(self.robot.msg)
self.robot.lowcmd_publisher.Write(self.robot.msg)
time.sleep(self.robot.control_dt)
logger.info("Reached default position (legs only)")
if __name__ == "__main__":
parser = argparse.ArgumentParser(description="GR00T Locomotion Controller for Unitree G1")
parser.add_argument(
"--repo-id",
type=str,
default=DEFAULT_GROOT_REPO_ID,
help=f"Hugging Face Hub repo ID for GR00T policies (default: {DEFAULT_GROOT_REPO_ID})",
)
args = parser.parse_args()
# load policies
policy_balance, policy_walk = load_groot_policies(repo_id=args.repo_id)
# initialize robot
config = UnitreeG1Config()
robot = UnitreeG1(config)
# initialize gr00t locomotion controller
groot_controller = GrootLocomotionController(
policy_balance=policy_balance,
policy_walk=policy_walk,
robot=robot,
config=config,
)
# reset legs and start locomotion thread
try:
groot_controller.reset_robot()
groot_controller.start_locomotion_thread()
# log status
logger.info("Robot initialized with GR00T locomotion policies")
logger.info("Locomotion controller running in background thread")
logger.info("Press Ctrl+C to stop")
# keep robot alive
while True:
time.sleep(1.0)
except KeyboardInterrupt:
print("\nStopping locomotion...")
groot_controller.stop_locomotion_thread()
print("Done!")
examples/unitree_g1/holosoma_locomotion.py
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#!/usr/bin/env python
# Copyright 2025 The HuggingFace Inc. team. All rights reserved.
#
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
#
# http://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.
"""
Example: Holosoma Whole-Body Locomotion (23-DOF and 29-DOF)
This example demonstrates loading Holosoma whole-body locomotion policies
and running them on the Unitree G1 robot.
Supports both:
- 23-DOF native policies (82D observations, 23D actions)
- 29-DOF policies (100D observations, 29D actions)
"""
import argparse
import logging
import threading
import time
import numpy as np
import onnxruntime as ort
from huggingface_hub import hf_hub_download
from lerobot.robots.unitree_g1.config_unitree_g1 import UnitreeG1Config
from lerobot.robots.unitree_g1.unitree_g1 import UnitreeG1
logging.basicConfig(level=logging.INFO)
logger = logging.getLogger(__name__)
# =============================================================================
# 29-DOF Configuration
# =============================================================================
# fmt: off
HOLOSOMA_29DOF_DEFAULT_ANGLES = np.array([
-0.312, 0.0, 0.0, 0.669, -0.363, 0.0, # left leg
-0.312, 0.0, 0.0, 0.669, -0.363, 0.0, # right leg
0.0, 0.0, 0.0, # waist (yaw, roll, pitch)
0.2, 0.2, 0.0, 0.6, 0.0, 0.0, 0.0, # left arm
0.2, -0.2, 0.0, 0.6, 0.0, 0.0, 0.0, # right arm
], dtype=np.float32)
HOLOSOMA_29DOF_KP = np.array([
40.179238471, 99.098427777, 40.179238471, 99.098427777, 28.501246196, 28.501246196, # left leg
40.179238471, 99.098427777, 40.179238471, 99.098427777, 28.501246196, 28.501246196, # right leg
40.179238471, 28.501246196, 28.501246196, # waist
14.250623098, 14.250623098, 14.250623098, 14.250623098, 14.250623098, 16.778327481, 16.778327481, # left arm
14.250623098, 14.250623098, 14.250623098, 14.250623098, 14.250623098, 16.778327481, 16.778327481, # right arm
], dtype=np.float32)
HOLOSOMA_29DOF_KD = np.array([
2.557889765, 6.308801854, 2.557889765, 6.308801854, 1.814445687, 1.814445687, # left leg
2.557889765, 6.308801854, 2.557889765, 6.308801854, 1.814445687, 1.814445687, # right leg
2.557889765, 1.814445687, 1.814445687, # waist
0.907222843, 0.907222843, 0.907222843, 0.907222843, 0.907222843, 1.068141502, 1.068141502, # left arm
0.907222843, 0.907222843, 0.907222843, 0.907222843, 0.907222843, 1.068141502, 1.068141502, # right arm
], dtype=np.float32)
# =============================================================================
# 23-DOF Configuration (native G1-23: no waist_roll/pitch, no wrist_pitch/yaw)
# Derived from 29-DOF Holosoma values
# =============================================================================
# Joint order: 6 left leg, 6 right leg, 1 waist_yaw, 5 left arm, 5 right arm
HOLOSOMA_23DOF_DEFAULT_ANGLES = np.array([
-0.312, 0.0, 0.0, 0.669, -0.363, 0.0, # left leg (from 29-DOF)
-0.312, 0.0, 0.0, 0.669, -0.363, 0.0, # right leg (from 29-DOF)
0.0, # waist_yaw only (from 29-DOF)
0.2, 0.2, 0.0, 0.6, 0.0, # left arm first 5 joints (from 29-DOF)
0.2, -0.2, 0.0, 0.6, 0.0, # right arm first 5 joints (from 29-DOF)
], dtype=np.float32)
HOLOSOMA_23DOF_KP = np.array([
40.179238471, 99.098427777, 40.179238471, 99.098427777, 28.501246196, 28.501246196, # left leg
40.179238471, 99.098427777, 40.179238471, 99.098427777, 28.501246196, 28.501246196, # right leg
40.179238471, # waist_yaw
14.250623098, 14.250623098, 14.250623098, 14.250623098, 14.250623098, # left arm
14.250623098, 14.250623098, 14.250623098, 14.250623098, 14.250623098, # right arm
], dtype=np.float32)
HOLOSOMA_23DOF_KD = np.array([
2.557889765, 6.308801854, 2.557889765, 6.308801854, 1.814445687, 1.814445687, # left leg
2.557889765, 6.308801854, 2.557889765, 6.308801854, 1.814445687, 1.814445687, # right leg
2.557889765, # waist_yaw
0.907222843, 0.907222843, 0.907222843, 0.907222843, 0.907222843, # left arm
0.907222843, 0.907222843, 0.907222843, 0.907222843, 0.907222843, # right arm
], dtype=np.float32)
# Maps 23-DOF policy index → 29-DOF motor index
# 23-DOF: legs(0-11), waist_yaw(12), L_arm(13-17), R_arm(18-22)
# 29-DOF: legs(0-11), waist(12-14), L_arm(15-21), R_arm(22-28)
DOF_23_TO_MOTOR_MAP = [
0, 1, 2, 3, 4, 5, # left leg → motor 0-5
6, 7, 8, 9, 10, 11, # right leg → motor 6-11
12, # waist_yaw → motor 12
15, 16, 17, 18, 19, # left arm (skip wrist_pitch/yaw) → motor 15-19
22, 23, 24, 25, 26, # right arm (skip wrist_pitch/yaw) → motor 22-26
]
# fmt: on
# Control parameters
LOCOMOTION_CONTROL_DT = 0.02 # 50Hz
LOCOMOTION_ACTION_SCALE = 0.25
ANG_VEL_SCALE = 0.25
DOF_POS_SCALE = 1.0
DOF_VEL_SCALE = 0.05
GAIT_PERIOD = 1.0
DEFAULT_HOLOSOMA_REPO_ID = "nepyope/holosoma_locomotion"
def load_holosoma_policy(
repo_id: str = DEFAULT_HOLOSOMA_REPO_ID,
policy_name: str = "fastsac",
local_path: str | None = None,
) -> tuple[ort.InferenceSession, int]:
"""Load Holosoma policy and detect observation dimension.
Returns:
(policy, obs_dim) tuple where obs_dim is 82 (23-DOF) or 100 (29-DOF)
"""
if local_path is not None:
logger.info(f"Loading policy from local path: {local_path}")
policy_path = local_path
else:
logger.info(f"Loading policy from Hugging Face Hub: {repo_id}")
policy_path = hf_hub_download(repo_id=repo_id, filename=f"{policy_name}_g1_29dof.onnx")
policy = ort.InferenceSession(policy_path)
# Detect observation dimension from model input shape
input_shape = policy.get_inputs()[0].shape
obs_dim = input_shape[1] if len(input_shape) > 1 else input_shape[0]
logger.info(f"Policy loaded successfully")
logger.info(f" Input: {policy.get_inputs()[0].name}, shape: {input_shape} → obs_dim={obs_dim}")
logger.info(f" Output: {policy.get_outputs()[0].name}, shape: {policy.get_outputs()[0].shape}")
return policy, obs_dim
class HolosomaLocomotionController:
"""
Handles Holosoma whole-body locomotion for Unitree G1.
Supports both 23-DOF (82D obs) and 29-DOF (100D obs) policies.
"""
def __init__(self, policy, robot, config, obs_dim: int = 100):
self.policy = policy
self.robot = robot
self.config = config
self.obs_dim = obs_dim
# Detect policy type from observation dimension
self.is_23dof = (obs_dim == 82)
self.num_dof = 23 if self.is_23dof else 29
# Velocity commands
self.locomotion_cmd = np.array([0.0, 0.0, 0.0], dtype=np.float32)
# State variables sized for policy type
self.qj = np.zeros(self.num_dof, dtype=np.float32)
self.dqj = np.zeros(self.num_dof, dtype=np.float32)
self.locomotion_action = np.zeros(self.num_dof, dtype=np.float32)
self.locomotion_obs = np.zeros(obs_dim, dtype=np.float32)
self.last_unscaled_action = np.zeros(self.num_dof, dtype=np.float32)
# Select config based on DOF
if self.is_23dof:
self.default_angles = HOLOSOMA_23DOF_DEFAULT_ANGLES
self.kp = HOLOSOMA_23DOF_KP
self.kd = HOLOSOMA_23DOF_KD
self.motor_map = DOF_23_TO_MOTOR_MAP
else:
self.default_angles = HOLOSOMA_29DOF_DEFAULT_ANGLES
self.kp = HOLOSOMA_29DOF_KP
self.kd = HOLOSOMA_29DOF_KD
self.motor_map = list(range(29)) # Identity map for 29-DOF
# Phase state for gait
self.phase = np.zeros((1, 2), dtype=np.float32)
self.phase[0, 0] = 0.0
self.phase[0, 1] = np.pi
self.phase_dt = 2 * np.pi / (50.0 * GAIT_PERIOD)
self.is_standing = False
self.counter = 0
self.locomotion_running = False
self.locomotion_thread = None
logger.info(f"HolosomaLocomotionController initialized")
logger.info(f" Mode: {'23-DOF (82D obs)' if self.is_23dof else '29-DOF (100D obs)'}")
logger.info(f" Action dim: {self.num_dof}")
def holosoma_locomotion_run(self):
"""Main locomotion loop - handles both 23-DOF and 29-DOF."""
self.counter += 1
if self.counter == 1:
print("\n" + "=" * 60)
print(f"🚀 RUNNING HOLOSOMA {self.num_dof}-DOF LOCOMOTION POLICY")
print(f" {self.obs_dim}D observations → {self.num_dof}D actions")
print("=" * 60 + "\n")
robot_state = self.robot.get_observation()
if robot_state is None:
return
# Remote controller
if robot_state.wireless_remote is not None:
self.robot.remote_controller.set(robot_state.wireless_remote)
else:
self.robot.remote_controller.lx = 0.0
self.robot.remote_controller.ly = 0.0
self.robot.remote_controller.rx = 0.0
self.robot.remote_controller.ry = 0.0
# Deadzone
ly = self.robot.remote_controller.ly if abs(self.robot.remote_controller.ly) > 0.1 else 0.0
lx = self.robot.remote_controller.lx if abs(self.robot.remote_controller.lx) > 0.1 else 0.0
rx = self.robot.remote_controller.rx if abs(self.robot.remote_controller.rx) > 0.1 else 0.0
self.locomotion_cmd[0] = ly
self.locomotion_cmd[1] = -lx
self.locomotion_cmd[2] = -rx
# Read joint states using motor map
for i in range(self.num_dof):
motor_idx = self.motor_map[i]
self.qj[i] = robot_state.motor_state[motor_idx].q
self.dqj[i] = robot_state.motor_state[motor_idx].dq
# IMU
quat = robot_state.imu_state.quaternion
ang_vel = np.array(robot_state.imu_state.gyroscope, dtype=np.float32)
gravity_orientation = self.robot.get_gravity_orientation(quat)
# Scale observations
qj_obs = (self.qj - self.default_angles) * DOF_POS_SCALE
dqj_obs = self.dqj * DOF_VEL_SCALE
ang_vel_scaled = ang_vel * ANG_VEL_SCALE
# Phase update
cmd_norm = np.linalg.norm(self.locomotion_cmd[:2])
ang_cmd_norm = np.abs(self.locomotion_cmd[2])
if cmd_norm < 0.01 and ang_cmd_norm < 0.01:
self.phase[0, :] = np.pi * np.ones(2)
self.is_standing = True
elif self.is_standing:
self.phase = np.array([[0.0, np.pi]], dtype=np.float32)
self.is_standing = False
else:
phase_tp1 = self.phase + self.phase_dt
self.phase = np.fmod(phase_tp1 + np.pi, 2 * np.pi) - np.pi
sin_phase = np.sin(self.phase[0, :])
cos_phase = np.cos(self.phase[0, :])
# Build observation (format depends on DOF)
if self.is_23dof:
# 82D: [23 actions, 3 ang_vel, 1 cmd_yaw, 2 cmd_lin, 2 cos, 23 pos, 23 vel, 3 grav, 2 sin]
self.locomotion_obs[0:23] = self.last_unscaled_action
self.locomotion_obs[23:26] = ang_vel_scaled
self.locomotion_obs[26] = self.locomotion_cmd[2]
self.locomotion_obs[27:29] = self.locomotion_cmd[:2]
self.locomotion_obs[29:31] = cos_phase
self.locomotion_obs[31:54] = qj_obs
self.locomotion_obs[54:77] = dqj_obs
self.locomotion_obs[77:80] = gravity_orientation
self.locomotion_obs[80:82] = sin_phase
else:
# 100D: [29 actions, 3 ang_vel, 1 cmd_yaw, 2 cmd_lin, 2 cos, 29 pos, 29 vel, 3 grav, 2 sin]
self.locomotion_obs[0:29] = self.last_unscaled_action
self.locomotion_obs[29:32] = ang_vel_scaled
self.locomotion_obs[32] = self.locomotion_cmd[2]
self.locomotion_obs[33:35] = self.locomotion_cmd[:2]
self.locomotion_obs[35:37] = cos_phase
self.locomotion_obs[37:66] = qj_obs
self.locomotion_obs[66:95] = dqj_obs
self.locomotion_obs[95:98] = gravity_orientation
self.locomotion_obs[98:100] = sin_phase
# Policy inference
obs_input = self.locomotion_obs.reshape(1, -1).astype(np.float32)
ort_inputs = {self.policy.get_inputs()[0].name: obs_input}
ort_outs = self.policy.run(None, ort_inputs)
raw_action = ort_outs[0].squeeze()
clipped_action = np.clip(raw_action, -100.0, 100.0)
self.last_unscaled_action = clipped_action.copy()
self.locomotion_action = clipped_action * LOCOMOTION_ACTION_SCALE
# Debug
if self.counter <= 3:
print(f"\n[Holosoma Debug #{self.counter}]")
print(f" Phase: ({self.phase[0, 0]:.3f}, {self.phase[0, 1]:.3f})")
print(f" Cmd: ({self.locomotion_cmd[0]:.2f}, {self.locomotion_cmd[1]:.2f}, {self.locomotion_cmd[2]:.2f})")
print(f" Action range: [{raw_action.min():.3f}, {raw_action.max():.3f}]")
# Compute target positions
target_dof_pos = self.default_angles + self.locomotion_action
# Send commands to motors via motor map
for i in range(self.num_dof):
motor_idx = self.motor_map[i]
self.robot.msg.motor_cmd[motor_idx].q = target_dof_pos[i]
self.robot.msg.motor_cmd[motor_idx].qd = 0
self.robot.msg.motor_cmd[motor_idx].kp = self.kp[i]
self.robot.msg.motor_cmd[motor_idx].kd = self.kd[i]
self.robot.msg.motor_cmd[motor_idx].tau = 0
# For 23-DOF: zero out missing joints (waist_roll/pitch, wrist_pitch/yaw)
if self.is_23dof:
missing_motors = [13, 14, 20, 21, 27, 28] # waist_roll, waist_pitch, wrist_pitch/yaw
for motor_idx in missing_motors:
self.robot.msg.motor_cmd[motor_idx].q = 0.0
self.robot.msg.motor_cmd[motor_idx].qd = 0
self.robot.msg.motor_cmd[motor_idx].kp = 40.0
self.robot.msg.motor_cmd[motor_idx].kd = 2.0
self.robot.msg.motor_cmd[motor_idx].tau = 0
self.robot.send_action(self.robot.msg)
def _locomotion_thread_loop(self):
logger.info("Locomotion thread started")
while self.locomotion_running:
start_time = time.time()
try:
self.holosoma_locomotion_run()
except Exception as e:
logger.error(f"Error in locomotion loop: {e}")
import traceback
traceback.print_exc()
elapsed = time.time() - start_time
sleep_time = max(0, LOCOMOTION_CONTROL_DT - elapsed)
time.sleep(sleep_time)
logger.info("Locomotion thread stopped")
def start_locomotion_thread(self):
if self.locomotion_running:
logger.warning("Locomotion thread already running")
return
logger.info("Starting locomotion control thread...")
self.locomotion_running = True
self.locomotion_thread = threading.Thread(target=self._locomotion_thread_loop, daemon=True)
self.locomotion_thread.start()
logger.info("Locomotion control thread started!")
def stop_locomotion_thread(self):
if not self.locomotion_running:
return
logger.info("Stopping locomotion control thread...")
self.locomotion_running = False
if self.locomotion_thread:
self.locomotion_thread.join(timeout=2.0)
logger.info("Locomotion control thread stopped")
def reset_robot(self):
"""Move joints to default position."""
logger.info(f"Moving {self.num_dof} joints to default position...")
total_time = 3.0
num_step = int(total_time / self.robot.control_dt)
robot_state = self.robot.get_observation()
# Record current positions
init_dof_pos = np.zeros(self.num_dof, dtype=np.float32)
for i in range(self.num_dof):
motor_idx = self.motor_map[i]
init_dof_pos[i] = robot_state.motor_state[motor_idx].q
# Interpolate to target
for step in range(num_step):
alpha = step / num_step
for i in range(self.num_dof):
motor_idx = self.motor_map[i]
target = self.default_angles[i]
self.robot.msg.motor_cmd[motor_idx].q = init_dof_pos[i] * (1 - alpha) + target * alpha
self.robot.msg.motor_cmd[motor_idx].qd = 0
self.robot.msg.motor_cmd[motor_idx].kp = self.kp[i]
self.robot.msg.motor_cmd[motor_idx].kd = self.kd[i]
self.robot.msg.motor_cmd[motor_idx].tau = 0
# Zero missing joints for 23-DOF
if self.is_23dof:
for motor_idx in [13, 14, 20, 21, 27, 28]:
self.robot.msg.motor_cmd[motor_idx].q = 0.0
self.robot.msg.motor_cmd[motor_idx].qd = 0
self.robot.msg.motor_cmd[motor_idx].kp = 40.0
self.robot.msg.motor_cmd[motor_idx].kd = 2.0
self.robot.msg.motor_cmd[motor_idx].tau = 0
self.robot.msg.crc = self.robot.crc.Crc(self.robot.msg)
self.robot.lowcmd_publisher.Write(self.robot.msg)
time.sleep(self.robot.control_dt)
logger.info(f"Reached default position ({self.num_dof} joints)")
# Hold for 2 seconds
logger.info("Holding default position for 2 seconds...")
hold_steps = int(2.0 / self.robot.control_dt)
for _ in range(hold_steps):
for i in range(self.num_dof):
motor_idx = self.motor_map[i]
self.robot.msg.motor_cmd[motor_idx].q = self.default_angles[i]
self.robot.msg.motor_cmd[motor_idx].qd = 0
self.robot.msg.motor_cmd[motor_idx].kp = self.kp[i]
self.robot.msg.motor_cmd[motor_idx].kd = self.kd[i]
self.robot.msg.motor_cmd[motor_idx].tau = 0
if self.is_23dof:
for motor_idx in [13, 14, 20, 21, 27, 28]:
self.robot.msg.motor_cmd[motor_idx].q = 0.0
self.robot.msg.motor_cmd[motor_idx].qd = 0
self.robot.msg.motor_cmd[motor_idx].kp = 40.0
self.robot.msg.motor_cmd[motor_idx].kd = 2.0
self.robot.msg.motor_cmd[motor_idx].tau = 0
self.robot.msg.crc = self.robot.crc.Crc(self.robot.msg)
self.robot.lowcmd_publisher.Write(self.robot.msg)
time.sleep(self.robot.control_dt)
logger.info("Ready to start locomotion!")
if __name__ == "__main__":
parser = argparse.ArgumentParser(description="Holosoma Locomotion Controller for Unitree G1")
parser.add_argument("--repo-id", type=str, default=DEFAULT_HOLOSOMA_REPO_ID)
parser.add_argument("--policy", type=str, default="fastsac", choices=["fastsac", "ppo"])
parser.add_argument("--local-path", type=str, default=None, help="Path to local ONNX file")
args = parser.parse_args()
# Load policy and detect dimensions
policy, obs_dim = load_holosoma_policy(
repo_id=args.repo_id,
policy_name=args.policy,
local_path=args.local_path,
)
# Initialize robot
config = UnitreeG1Config()
robot = UnitreeG1(config)
# Initialize controller with detected obs_dim
controller = HolosomaLocomotionController(
policy=policy,
robot=robot,
config=config,
obs_dim=obs_dim,
)
try:
controller.reset_robot()
controller.start_locomotion_thread()
logger.info(f"Robot initialized with Holosoma {'23-DOF' if obs_dim == 82 else '29-DOF'} policy")
logger.info("Use remote controller: LY=fwd/back, LX=left/right, RX=rotate")
logger.info("Press Ctrl+C to stop")
while True:
time.sleep(1.0)
except KeyboardInterrupt:
print("\nStopping locomotion...")
controller.stop_locomotion_thread()
print("Done!")
examples/unitree_g1/unitree_rl_locomotion.py
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#!/usr/bin/env python
# Copyright 2025 The HuggingFace Inc. team. All rights reserved.
#
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
#
# http://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.
"""
Example: Unitree RL 12-DOF Legs-Only Locomotion (TorchScript)
This example demonstrates loading a 12-DOF legs-only locomotion policy
(TorchScript .pt format) and running it on the Unitree G1 robot.
Key characteristics:
- Single TorchScript policy (.pt)
- 47D observations, 12D actions (legs only)
- Phase-based gait timing
- Arms and waist held at fixed positions
"""
import argparse
import logging
import threading
import time
import numpy as np
import torch
from huggingface_hub import hf_hub_download
from scipy.spatial.transform import Rotation as R
from lerobot.robots.unitree_g1.config_unitree_g1 import UnitreeG1Config
from lerobot.robots.unitree_g1.unitree_g1 import UnitreeG1
logging.basicConfig(level=logging.INFO)
logger = logging.getLogger(__name__)
# 12-DOF leg joint configuration
# Joint order: [L_hip_pitch, L_hip_roll, L_hip_yaw, L_knee, L_ankle_pitch, L_ankle_roll,
# R_hip_pitch, R_hip_roll, R_hip_yaw, R_knee, R_ankle_pitch, R_ankle_roll]
LEG_JOINT_INDICES = [0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11]
# Default leg angles for standing
DEFAULT_LEG_ANGLES = np.array([
-0.1, 0.0, 0.0, 0.3, -0.2, 0.0, # left leg
-0.1, 0.0, 0.0, 0.3, -0.2, 0.0, # right leg
], dtype=np.float32)
# KP/KD for leg joints
LEG_KPS = np.array([150, 150, 150, 300, 40, 40, 150, 150, 150, 300, 40, 40], dtype=np.float32)
LEG_KDS = np.array([6, 6, 6, 4, 2, 2, 6, 6, 6, 4, 2, 2], dtype=np.float32)
# Waist configuration (held at zero)
WAIST_JOINT_INDICES = [12, 13, 14] # yaw, roll, pitch
WAIST_KPS = np.array([250, 250, 250], dtype=np.float32)
WAIST_KDS = np.array([5, 5, 5], dtype=np.float32)
# Arm configuration (indices 15-28, held at initial position)
ARM_JOINT_INDICES = list(range(15, 29))
ARM_KPS = np.array([80, 80, 80, 80, 40, 40, 40, # left arm (shoulder + wrist)
80, 80, 80, 80, 40, 40, 40], dtype=np.float32) # right arm
ARM_KDS = np.array([3, 3, 3, 3, 1.5, 1.5, 1.5,
3, 3, 3, 3, 1.5, 1.5, 1.5], dtype=np.float32)
# Control parameters
LOCOMOTION_CONTROL_DT = 0.02 # 50Hz control rate
LOCOMOTION_ACTION_SCALE = 0.25
ANG_VEL_SCALE = 0.25
DOF_POS_SCALE = 1.0
DOF_VEL_SCALE = 0.05
CMD_SCALE = np.array([2.0, 2.0, 0.25], dtype=np.float32)
MAX_CMD = np.array([0.8, 0.5, 1.57], dtype=np.float32) # max vx, vy, yaw_rate
# Gait parameters
GAIT_PERIOD = 0.8 # seconds
DEFAULT_REPO_ID = "nepyope/unitree_rl_locomotion"
def load_torchscript_policy(
repo_id: str = DEFAULT_REPO_ID,
filename: str = "motion.pt",
) -> torch.jit.ScriptModule:
"""Load TorchScript locomotion policy from Hugging Face Hub.
Args:
repo_id: Hugging Face Hub repository ID containing the policy.
filename: Policy filename (default: motion.pt).
"""
logger.info(f"Loading TorchScript policy from Hugging Face Hub ({repo_id}/{filename})...")
policy_path = hf_hub_download(
repo_id=repo_id,
filename=filename,
)
policy = torch.jit.load(policy_path)
policy.eval()
logger.info("TorchScript policy loaded successfully")
return policy
class UnitreeRLLocomotionController:
"""
Handles 12-DOF legs-only locomotion control for the Unitree G1 robot.
This controller manages:
- Single TorchScript policy
- 47D observations (single frame)
- 12D action output (legs only)
- Arms and waist held at fixed positions
- Phase-based gait timing
"""
def __init__(self, policy, robot, config):
self.policy = policy
self.robot = robot
self.config = config
# Velocity commands (vx, vy, yaw_rate)
self.locomotion_cmd = np.array([0.0, 0.0, 0.0], dtype=np.float32)
# State variables (12 DOF legs)
self.qj = np.zeros(12, dtype=np.float32)
self.dqj = np.zeros(12, dtype=np.float32)
self.locomotion_action = np.zeros(12, dtype=np.float32)
self.locomotion_obs = np.zeros(47, dtype=np.float32)
# Initial arm positions (captured on reset)
self.initial_arm_positions = np.zeros(14, dtype=np.float32)
# Counter for phase calculation
self.counter = 0
# Thread management
self.locomotion_running = False
self.locomotion_thread = None
logger.info("UnitreeRLLocomotionController initialized")
logger.info(" Observation dim: 47, Action dim: 12 (legs only)")
def locomotion_run(self):
"""12-DOF legs-only locomotion policy loop."""
self.counter += 1
if self.counter == 1:
print("\n" + "=" * 60)
print("🚀 RUNNING UNITREE RL 12-DOF LOCOMOTION POLICY")
print(" 47D observations → 12D actions (legs only)")
print(" Arms and waist held at fixed positions")
print("=" * 60 + "\n")
# Get current observation
robot_state = self.robot.get_observation()
if robot_state is None:
return
# Get command from remote controller
if robot_state.wireless_remote is not None:
self.robot.remote_controller.set(robot_state.wireless_remote)
else:
self.robot.remote_controller.lx = 0.0
self.robot.remote_controller.ly = 0.0
self.robot.remote_controller.rx = 0.0
self.robot.remote_controller.ry = 0.0
self.locomotion_cmd[0] = self.robot.remote_controller.ly # forward/backward
self.locomotion_cmd[1] = self.robot.remote_controller.lx * -1 # left/right (inverted)
self.locomotion_cmd[2] = self.robot.remote_controller.rx * -1 # yaw (inverted)
# Get leg joint positions and velocities (12 DOF)
for i, motor_idx in enumerate(LEG_JOINT_INDICES):
self.qj[i] = robot_state.motor_state[motor_idx].q
self.dqj[i] = robot_state.motor_state[motor_idx].dq
# Get IMU data
quat = robot_state.imu_state.quaternion
ang_vel = np.array(robot_state.imu_state.gyroscope, dtype=np.float32)
# Scale observations
gravity_orientation = self.robot.get_gravity_orientation(quat)
qj_obs = (self.qj - DEFAULT_LEG_ANGLES) * DOF_POS_SCALE
dqj_obs = self.dqj * DOF_VEL_SCALE
ang_vel_scaled = ang_vel * ANG_VEL_SCALE
# Calculate phase
count = self.counter * LOCOMOTION_CONTROL_DT
phase = (count % GAIT_PERIOD) / GAIT_PERIOD
sin_phase = np.sin(2 * np.pi * phase)
cos_phase = np.cos(2 * np.pi * phase)
# Build 47D observation vector
# [0:3] - angular velocity (scaled)
# [3:6] - gravity orientation
# [6:9] - velocity command (scaled)
# [9:21] - joint positions (12D, relative to default)
# [21:33] - joint velocities (12D, scaled)
# [33:45] - previous actions (12D)
# [45] - sin_phase
# [46] - cos_phase
self.locomotion_obs[0:3] = ang_vel_scaled
self.locomotion_obs[3:6] = gravity_orientation
self.locomotion_obs[6:9] = self.locomotion_cmd * CMD_SCALE * MAX_CMD
self.locomotion_obs[9:21] = qj_obs
self.locomotion_obs[21:33] = dqj_obs
self.locomotion_obs[33:45] = self.locomotion_action
self.locomotion_obs[45] = sin_phase
self.locomotion_obs[46] = cos_phase
# Run policy inference (TorchScript)
obs_tensor = torch.from_numpy(self.locomotion_obs).unsqueeze(0).float()
with torch.no_grad():
action_tensor = self.policy(obs_tensor)
self.locomotion_action = action_tensor.squeeze().numpy()
# Transform action to target joint positions
target_leg_pos = DEFAULT_LEG_ANGLES + self.locomotion_action * LOCOMOTION_ACTION_SCALE
# Debug logging (first 3 iterations)
if self.counter <= 3:
print(f"\n[Unitree RL Debug #{self.counter}]")
print(f" Phase: {phase:.3f} (sin={sin_phase:.3f}, cos={cos_phase:.3f})")
print(f" Cmd (vx, vy, yaw): ({self.locomotion_cmd[0]:.2f}, {self.locomotion_cmd[1]:.2f}, {self.locomotion_cmd[2]:.2f})")
print(f" Action range: [{self.locomotion_action.min():.3f}, {self.locomotion_action.max():.3f}]")
# Send commands to LEG motors (0-11)
for i, motor_idx in enumerate(LEG_JOINT_INDICES):
self.robot.msg.motor_cmd[motor_idx].q = target_leg_pos[i]
self.robot.msg.motor_cmd[motor_idx].qd = 0
self.robot.msg.motor_cmd[motor_idx].kp = LEG_KPS[i]
self.robot.msg.motor_cmd[motor_idx].kd = LEG_KDS[i]
self.robot.msg.motor_cmd[motor_idx].tau = 0
# Hold WAIST motors at zero (12, 13, 14)
for i, motor_idx in enumerate(WAIST_JOINT_INDICES):
self.robot.msg.motor_cmd[motor_idx].q = 0.0
self.robot.msg.motor_cmd[motor_idx].qd = 0
self.robot.msg.motor_cmd[motor_idx].kp = WAIST_KPS[i]
self.robot.msg.motor_cmd[motor_idx].kd = WAIST_KDS[i]
self.robot.msg.motor_cmd[motor_idx].tau = 0
# Hold ARM motors at initial position (15-28)
for i, motor_idx in enumerate(ARM_JOINT_INDICES):
self.robot.msg.motor_cmd[motor_idx].q = self.initial_arm_positions[i]
self.robot.msg.motor_cmd[motor_idx].qd = 0
self.robot.msg.motor_cmd[motor_idx].kp = ARM_KPS[i]
self.robot.msg.motor_cmd[motor_idx].kd = ARM_KDS[i]
self.robot.msg.motor_cmd[motor_idx].tau = 0
# Send command
self.robot.send_action(self.robot.msg)
def _locomotion_thread_loop(self):
"""Background thread that runs the locomotion policy at specified rate."""
logger.info("Locomotion thread started")
while self.locomotion_running:
start_time = time.time()
try:
self.locomotion_run()
except Exception as e:
logger.error(f"Error in locomotion loop: {e}")
import traceback
traceback.print_exc()
# Sleep to maintain control rate
elapsed = time.time() - start_time
sleep_time = max(0, LOCOMOTION_CONTROL_DT - elapsed)
time.sleep(sleep_time)
logger.info("Locomotion thread stopped")
def start_locomotion_thread(self):
if self.locomotion_running:
logger.warning("Locomotion thread already running")
return
logger.info("Starting locomotion control thread...")
self.locomotion_running = True
self.locomotion_thread = threading.Thread(target=self._locomotion_thread_loop, daemon=True)
self.locomotion_thread.start()
logger.info("Locomotion control thread started!")
def stop_locomotion_thread(self):
if not self.locomotion_running:
return
logger.info("Stopping locomotion control thread...")
self.locomotion_running = False
if self.locomotion_thread:
self.locomotion_thread.join(timeout=2.0)
logger.info("Locomotion control thread stopped")
def reset_robot(self):
"""Move legs to default standing position over 2 seconds (arms are captured and held)."""
logger.info("Moving legs to default position...")
total_time = 2.0
num_step = int(total_time / self.robot.control_dt)
# Get current state
robot_state = self.robot.get_observation()
# Capture initial arm positions (to hold during locomotion)
for i, motor_idx in enumerate(ARM_JOINT_INDICES):
self.initial_arm_positions[i] = robot_state.motor_state[motor_idx].q
logger.info(f"Captured initial arm positions: {self.initial_arm_positions[:4]}...")
# Record current leg positions
init_leg_pos = np.zeros(12, dtype=np.float32)
for i, motor_idx in enumerate(LEG_JOINT_INDICES):
init_leg_pos[i] = robot_state.motor_state[motor_idx].q
# Interpolate legs to default position
for step in range(num_step):
alpha = step / num_step
# Interpolate leg positions
for i, motor_idx in enumerate(LEG_JOINT_INDICES):
target_pos = DEFAULT_LEG_ANGLES[i]
self.robot.msg.motor_cmd[motor_idx].q = (
init_leg_pos[i] * (1 - alpha) + target_pos * alpha
)
self.robot.msg.motor_cmd[motor_idx].qd = 0
self.robot.msg.motor_cmd[motor_idx].kp = LEG_KPS[i]
self.robot.msg.motor_cmd[motor_idx].kd = LEG_KDS[i]
self.robot.msg.motor_cmd[motor_idx].tau = 0
# Hold waist at zero
for i, motor_idx in enumerate(WAIST_JOINT_INDICES):
self.robot.msg.motor_cmd[motor_idx].q = 0.0
self.robot.msg.motor_cmd[motor_idx].qd = 0
self.robot.msg.motor_cmd[motor_idx].kp = WAIST_KPS[i]
self.robot.msg.motor_cmd[motor_idx].kd = WAIST_KDS[i]
self.robot.msg.motor_cmd[motor_idx].tau = 0
# Hold arms at initial position
for i, motor_idx in enumerate(ARM_JOINT_INDICES):
self.robot.msg.motor_cmd[motor_idx].q = self.initial_arm_positions[i]
self.robot.msg.motor_cmd[motor_idx].qd = 0
self.robot.msg.motor_cmd[motor_idx].kp = ARM_KPS[i]
self.robot.msg.motor_cmd[motor_idx].kd = ARM_KDS[i]
self.robot.msg.motor_cmd[motor_idx].tau = 0
self.robot.msg.crc = self.robot.crc.Crc(self.robot.msg)
self.robot.lowcmd_publisher.Write(self.robot.msg)
time.sleep(self.robot.control_dt)
logger.info("Reached default leg position")
# Hold position for 2 seconds
logger.info("Holding default position for 2 seconds...")
hold_time = 2.0
num_hold_steps = int(hold_time / self.robot.control_dt)
for _ in range(num_hold_steps):
# Hold legs at default
for i, motor_idx in enumerate(LEG_JOINT_INDICES):
self.robot.msg.motor_cmd[motor_idx].q = DEFAULT_LEG_ANGLES[i]
self.robot.msg.motor_cmd[motor_idx].qd = 0
self.robot.msg.motor_cmd[motor_idx].kp = LEG_KPS[i]
self.robot.msg.motor_cmd[motor_idx].kd = LEG_KDS[i]
self.robot.msg.motor_cmd[motor_idx].tau = 0
# Hold waist at zero
for i, motor_idx in enumerate(WAIST_JOINT_INDICES):
self.robot.msg.motor_cmd[motor_idx].q = 0.0
self.robot.msg.motor_cmd[motor_idx].qd = 0
self.robot.msg.motor_cmd[motor_idx].kp = WAIST_KPS[i]
self.robot.msg.motor_cmd[motor_idx].kd = WAIST_KDS[i]
self.robot.msg.motor_cmd[motor_idx].tau = 0
# Hold arms at initial position
for i, motor_idx in enumerate(ARM_JOINT_INDICES):
self.robot.msg.motor_cmd[motor_idx].q = self.initial_arm_positions[i]
self.robot.msg.motor_cmd[motor_idx].qd = 0
self.robot.msg.motor_cmd[motor_idx].kp = ARM_KPS[i]
self.robot.msg.motor_cmd[motor_idx].kd = ARM_KDS[i]
self.robot.msg.motor_cmd[motor_idx].tau = 0
self.robot.msg.crc = self.robot.crc.Crc(self.robot.msg)
self.robot.lowcmd_publisher.Write(self.robot.msg)
time.sleep(self.robot.control_dt)
logger.info("Ready to start locomotion!")
if __name__ == "__main__":
parser = argparse.ArgumentParser(description="Unitree RL 12-DOF Locomotion Controller for Unitree G1")
parser.add_argument(
"--repo-id",
type=str,
default=DEFAULT_REPO_ID,
help=f"Hugging Face Hub repo ID for policy (default: {DEFAULT_REPO_ID})",
)
parser.add_argument(
"--filename",
type=str,
default="motion.pt",
help="Policy filename (default: motion.pt)",
)
args = parser.parse_args()
# Load policy
policy = load_torchscript_policy(repo_id=args.repo_id, filename=args.filename)
# Initialize robot
config = UnitreeG1Config()
robot = UnitreeG1(config)
# Initialize locomotion controller
locomotion_controller = UnitreeRLLocomotionController(
policy=policy,
robot=robot,
config=config,
)
# Reset robot and start locomotion thread
try:
locomotion_controller.reset_robot()
locomotion_controller.start_locomotion_thread()
# Log status
logger.info("Robot initialized with Unitree RL locomotion policy")
logger.info("Locomotion controller running in background thread")
logger.info("Use remote controller to command velocity:")
logger.info(" Left stick Y: forward/backward")
logger.info(" Left stick X: left/right")
logger.info(" Right stick X: rotate")
logger.info("Press Ctrl+C to stop")
# Keep robot alive
while True:
time.sleep(1.0)
except KeyboardInterrupt:
print("\nStopping locomotion...")
locomotion_controller.stop_locomotion_thread()
print("Done!")
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