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base: admin/lerobot:openarms_tmp_rebase
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admin/lerobot:main admin/lerobot:feat/smolvla-on-steerable admin/lerobot:feat/vla-jepa admin/lerobot:feat/add-robometer-rm admin/lerobot:feat/language-annotation-pipeline admin/lerobot:fix/fix-and-maintain-examples admin/lerobot:feat/language-columns admin/lerobot:feat/robometer-rm admin/lerobot:auto/update-uv-lock admin/lerobot:feat/video-re-encode admin/lerobot:feat/clean-can-bus admin/lerobot:pr/3545 admin/lerobot:fix/vlabench-ci-faster admin/lerobot:chore/colored-cli admin/lerobot:feat/depth-frames 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
..
compare: admin/lerobot:feat/unitree_g1
Branches Tags
admin/lerobot:feat/smolvla-on-steerable admin/lerobot:main admin/lerobot:feat/vla-jepa admin/lerobot:feat/add-robometer-rm admin/lerobot:feat/language-annotation-pipeline admin/lerobot:fix/fix-and-maintain-examples admin/lerobot:feat/language-columns admin/lerobot:feat/robometer-rm admin/lerobot:auto/update-uv-lock admin/lerobot:feat/video-re-encode admin/lerobot:feat/clean-can-bus admin/lerobot:pr/3545 admin/lerobot:fix/vlabench-ci-faster admin/lerobot:chore/colored-cli admin/lerobot:feat/depth-frames 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

23 Commits
openarms_tmp_rebase .. feat/unitree_g1

Author SHA1 Message Date
Martino Russi b320530482 add amazon policies 2025-12-02 16:23:52 +01:00
Martino Russi 4bdd2475b0 complete work 2025-11-27 10:22:11 +01:00
Martino Russi 5d9266b024 simplify implementation 2025-11-26 15:37:04 +01:00
Martino Russi c7834c3db8 simplified robot class 2025-11-26 15:11:45 +01:00
Martino Russi c65866ddd8 sync updates 2025-11-26 13:11:01 +01:00
Martino Russi bebf9b8480 mujoco sim viewer integration 2025-11-21 21:41:24 +01:00
Martino Russi 3be342a00d remove leftovers from unitree_il_lerobot 2025-11-21 14:49:03 +01:00
Martino Russi e6c16a60b1 load mujoco sim from hub 2025-11-21 14:42:55 +01:00
Martino Russi 786f4df529 test 2025-11-21 14:38:22 +01:00
Martino Russi 58739f4b7a signed test 2025-11-21 14:13:52 +01:00
Martino Russi b6e606c28d trace test 2025-11-21 14:13:39 +01:00
Martino Russi c477c54e3c move test items to .dev 2025-11-21 14:13:05 +01:00
Martino Russi f30e15d411 move test scripts inside .dev 2025-11-21 14:13:05 +01:00
Martino Russi 8f06c02c17 add robot models xml etc 
remove isaaclab, add test scripts

added simulator to the hub

remove mujoco env
 2025-11-21 14:13:05 +01:00
Martino Russi 9a052566a3 sync recent changes 2025-11-21 14:13:05 +01:00
Martino Russi e5cae6be64 add weighted moving filter, assets 2025-11-21 14:13:04 +01:00
Martino Russi 56b66b9542 add example config for custom teleop class 2025-11-21 14:13:04 +01:00
Martino Russi 30c3bbef7b add custom teleoperator, integrate unitree g1 except for eval 2025-11-21 14:13:04 +01:00
Martino Russi c4bf27772c finish unitree camera integration 2025-11-21 14:13:04 +01:00
Martino Russi 3422f2cb01 find cameras via zmq 2025-11-21 09:55:01 +01:00
Martino Russi c365bcd0a5 begin unitree_g1 integration 2025-11-21 09:55:01 +01:00
resolver101757 2cbd6649f2 bug causes error uploading to huggingface, unicode issue on windows. (#450) 2025-11-21 09:55:00 +01:00
Alexander Soare c749fba0f5 empty commit 2025-11-21 09:55:00 +01:00
271 changed files with 15846 additions and 25139 deletions
Expand all files Collapse all files
.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
+2 -4
View File
@@ -42,9 +42,7 @@ 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.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
@@ -60,7 +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
+1 -7
View File
@@ -45,6 +45,7 @@ permissions:
env:
UV_VERSION: "0.8.0"
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:
@@ -59,19 +60,12 @@ jobs:
runs-on: ubuntu-latest
env:
MUJOCO_GL: egl
HF_HOME: /mnt/cache/.cache/huggingface
HF_LEROBOT_HOME: /mnt/cache/.cache/huggingface/lerobot
steps:
- uses: actions/checkout@v4
with:
persist-credentials: false
lfs: true
# NOTE(Steven): Mount to `/mnt` to avoid the limited storage on `/home`. Consider cleaning default SDKs or using self-hosted runners for more space.
# (As of 2024-06-10, the runner's `/home` has only 6.2 GB free—8% of its 72 GB total.)
- name: Setup /mnt storage
run: sudo chown -R $USER:$USER /mnt
# TODO(Steven): Evaluate the need of these dependencies
- name: Install apt dependencies
run: |
.github/workflows/full_tests.yml
-7
View File
@@ -58,19 +58,12 @@ jobs:
github.event_name == 'workflow_dispatch'
env:
MUJOCO_GL: egl
HF_HOME: /mnt/cache/.cache/huggingface
HF_LEROBOT_HOME: /mnt/cache/.cache/huggingface/lerobot
steps:
- uses: actions/checkout@v4
with:
lfs: true
persist-credentials: false
# NOTE(Steven): Mount to `/mnt` to avoid the limited storage on `/home`. Consider cleaning default SDKs or using self-hosted runners for more space.
# (As of 2024-06-10, the runner's `/home` has only 6.2 GB free—8% of its 72 GB total.)
- name: Setup /mnt storage
run: sudo chown -R $USER:$USER /mnt
- name: Install apt dependencies
run: |
sudo apt-get update && sudo apt-get install -y build-essential \
.github/workflows/nightly.yml
-2
View File
@@ -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:
@@ -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:
.github/workflows/release.yml
-1
View File
@@ -29,7 +29,6 @@ jobs:
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:
.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
-8
View File
@@ -43,22 +43,14 @@ 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
steps:
- uses: actions/checkout@v4
with:
lfs: true
persist-credentials: false
# NOTE(Steven): Mount to `/mnt` to avoid the limited storage on `/home`. Consider cleaning default SDKs or using self-hosted runners for more space.
# (As of 2024-06-10, the runner's `/home` has only 6.2 GB free—8% of its 72 GB total.)
- name: Setup /mnt storage
run: sudo chown -R $USER:$USER /mnt
- name: Install apt dependencies
run: |
sudo apt-get update && sudo apt-get install -y build-essential \
.gitignore
-4
View File
@@ -173,7 +173,3 @@ outputs/
# Dev folders
.cache/*
*.stl
*.urdf
*.xml
*.part
benchmarks/video/benchmark.py
+94
View File
@@ -0,0 +1,94 @@
#!/usr/bin/env python
# Copyright 2024 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.
import threading
import time
from contextlib import ContextDecorator
class TimeBenchmark(ContextDecorator):
"""
Measures execution time using a context manager or decorator.
This class supports both context manager and decorator usage, and is thread-safe for multithreaded
environments.
Args:
print: If True, prints the elapsed time upon exiting the context or completing the function. Defaults
to False.
Examples:
Using as a context manager:
>>> benchmark = TimeBenchmark()
>>> with benchmark:
... time.sleep(1)
>>> print(f"Block took {benchmark.result:.4f} seconds")
Block took approximately 1.0000 seconds
Using with multithreading:
```python
import threading
benchmark = TimeBenchmark()
def context_manager_example():
with benchmark:
time.sleep(0.01)
print(f"Block took {benchmark.result_ms:.2f} milliseconds")
threads = []
for _ in range(3):
t1 = threading.Thread(target=context_manager_example)
threads.append(t1)
for t in threads:
t.start()
for t in threads:
t.join()
```
Expected output:
Block took approximately 10.00 milliseconds
Block took approximately 10.00 milliseconds
Block took approximately 10.00 milliseconds
"""
def __init__(self, print=False):
self.local = threading.local()
self.print_time = print
def __enter__(self):
self.local.start_time = time.perf_counter()
return self
def __exit__(self, *exc):
self.local.end_time = time.perf_counter()
self.local.elapsed_time = self.local.end_time - self.local.start_time
if self.print_time:
print(f"Elapsed time: {self.local.elapsed_time:.4f} seconds")
return False
@property
def result(self):
return getattr(self.local, "elapsed_time", None)
@property
def result_ms(self):
return self.result * 1e3
benchmarks/video/capture_camera_feed.py
Executable
+102
View File
@@ -0,0 +1,102 @@
#!/usr/bin/env python
# Copyright 2024 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.
"""Capture video feed from a camera as raw images."""
import argparse
import datetime as dt
import os
import time
from pathlib import Path
import cv2
import rerun as rr
# see https://rerun.io/docs/howto/visualization/limit-ram
RERUN_MEMORY_LIMIT = os.getenv("LEROBOT_RERUN_MEMORY_LIMIT", "5%")
def display_and_save_video_stream(output_dir: Path, fps: int, width: int, height: int, duration: int):
rr.init("lerobot_capture_camera_feed")
rr.spawn(memory_limit=RERUN_MEMORY_LIMIT)
now = dt.datetime.now()
capture_dir = output_dir / f"{now:%Y-%m-%d}" / f"{now:%H-%M-%S}"
if not capture_dir.exists():
capture_dir.mkdir(parents=True, exist_ok=True)
# Opens the default webcam
cap = cv2.VideoCapture(0)
if not cap.isOpened():
print("Error: Could not open video stream.")
return
cap.set(cv2.CAP_PROP_FPS, fps)
cap.set(cv2.CAP_PROP_FRAME_WIDTH, width)
cap.set(cv2.CAP_PROP_FRAME_HEIGHT, height)
frame_index = 0
start_time = time.time()
while time.time() - start_time < duration:
ret, frame = cap.read()
if not ret:
print("Error: Could not read frame.")
break
rr.log("video/stream", rr.Image(frame), static=True)
cv2.imwrite(str(capture_dir / f"frame_{frame_index:06d}.png"), frame)
frame_index += 1
# Release the capture
cap.release()
# TODO(Steven): Add a graceful shutdown via a close() method for the Viewer context, though not currently supported in the Rerun API.
if __name__ == "__main__":
parser = argparse.ArgumentParser()
parser.add_argument(
"--output-dir",
type=Path,
default=Path("outputs/cam_capture/"),
help="Directory where the capture images are written. A subfolder named with the current date & time will be created inside it for each capture.",
)
parser.add_argument(
"--fps",
type=int,
default=30,
help="Frames Per Second of the capture.",
)
parser.add_argument(
"--width",
type=int,
default=1280,
help="Width of the captured images.",
)
parser.add_argument(
"--height",
type=int,
default=720,
help="Height of the captured images.",
)
parser.add_argument(
"--duration",
type=int,
default=20,
help="Duration in seconds for which the video stream should be captured.",
)
args = parser.parse_args()
display_and_save_video_stream(**vars(args))
benchmarks/video/run_video_benchmark.py
+48 -43
View File
@@ -21,13 +21,11 @@ See the provided README.md or run `python benchmark/video/run_video_benchmark.py
import argparse
import datetime as dt
import itertools
import random
import shutil
from collections import OrderedDict
from concurrent.futures import ThreadPoolExecutor, as_completed
from pathlib import Path
from threading import Lock
import einops
import numpy as np
@@ -37,13 +35,13 @@ import torch
from skimage.metrics import mean_squared_error, peak_signal_noise_ratio, structural_similarity
from tqdm import tqdm
from benchmarks.video.benchmark import TimeBenchmark
from lerobot.datasets.lerobot_dataset import LeRobotDataset
from lerobot.datasets.video_utils import (
decode_video_frames,
decode_video_frames_torchvision,
encode_video_frames,
)
from lerobot.utils.constants import OBS_IMAGE
from lerobot.utils.utils import TimerManager
BASE_ENCODING = OrderedDict(
[
@@ -88,7 +86,7 @@ def load_original_frames(imgs_dir: Path, timestamps: list[float], fps: int) -> t
frames = []
for ts in timestamps:
idx = int(ts * fps)
frame = PIL.Image.open(imgs_dir / f"frame-{idx:06d}.png")
frame = PIL.Image.open(imgs_dir / f"frame_{idx:06d}.png")
frame = torch.from_numpy(np.array(frame))
frame = frame.type(torch.float32) / 255
frame = einops.rearrange(frame, "h w c -> c h w")
@@ -99,21 +97,21 @@ def load_original_frames(imgs_dir: Path, timestamps: list[float], fps: int) -> t
def save_decoded_frames(
imgs_dir: Path, save_dir: Path, frames: torch.Tensor, timestamps: list[float], fps: int
) -> None:
if save_dir.exists() and len(list(save_dir.glob("frame-*.png"))) == len(timestamps):
if save_dir.exists() and len(list(save_dir.glob("frame_*.png"))) == len(timestamps):
return
save_dir.mkdir(parents=True, exist_ok=True)
for i, ts in enumerate(timestamps):
idx = int(ts * fps)
frame_hwc = (frames[i].permute((1, 2, 0)) * 255).type(torch.uint8).cpu().numpy()
PIL.Image.fromarray(frame_hwc).save(save_dir / f"frame-{idx:06d}_decoded.png")
shutil.copyfile(imgs_dir / f"frame-{idx:06d}.png", save_dir / f"frame-{idx:06d}_original.png")
PIL.Image.fromarray(frame_hwc).save(save_dir / f"frame_{idx:06d}_decoded.png")
shutil.copyfile(imgs_dir / f"frame_{idx:06d}.png", save_dir / f"frame_{idx:06d}_original.png")
def save_first_episode(imgs_dir: Path, dataset: LeRobotDataset) -> None:
episode_index = 0
ep_num_images = dataset.meta.episodes["length"][episode_index]
if imgs_dir.exists() and len(list(imgs_dir.glob("frame-*.png"))) == ep_num_images:
if imgs_dir.exists() and len(list(imgs_dir.glob("frame_*.png"))) == ep_num_images:
return
imgs_dir.mkdir(parents=True, exist_ok=True)
@@ -127,7 +125,7 @@ def save_first_episode(imgs_dir: Path, dataset: LeRobotDataset) -> None:
tqdm(imgs_dataset, desc=f"saving {dataset.repo_id} first episode images", leave=False)
):
img = item[img_keys[0]]
img.save(str(imgs_dir / f"frame-{i:06d}.png"), quality=100)
img.save(str(imgs_dir / f"frame_{i:06d}.png"), quality=100)
if i >= ep_num_images - 1:
break
@@ -151,6 +149,18 @@ def sample_timestamps(timestamps_mode: str, ep_num_images: int, fps: int) -> lis
return [idx / fps for idx in frame_indexes]
def decode_video_frames(
video_path: str,
timestamps: list[float],
tolerance_s: float,
backend: str,
) -> torch.Tensor:
if backend in ["pyav", "video_reader"]:
return decode_video_frames_torchvision(video_path, timestamps, tolerance_s, backend)
else:
raise NotImplementedError(backend)
def benchmark_decoding(
imgs_dir: Path,
video_path: Path,
@@ -162,8 +172,8 @@ def benchmark_decoding(
num_workers: int = 4,
save_frames: bool = False,
) -> dict:
def process_sample(sample: int, lock: Lock):
time_benchmark = TimerManager(log=False)
def process_sample(sample: int):
time_benchmark = TimeBenchmark()
timestamps = sample_timestamps(timestamps_mode, ep_num_images, fps)
num_frames = len(timestamps)
result = {
@@ -172,13 +182,13 @@ def benchmark_decoding(
"mse_values": [],
}
with time_benchmark, lock:
with time_benchmark:
frames = decode_video_frames(video_path, timestamps=timestamps, tolerance_s=5e-1, backend=backend)
result["load_time_video_ms"] = (time_benchmark.last * 1000) / num_frames
result["load_time_video_ms"] = time_benchmark.result_ms / num_frames
with time_benchmark:
original_frames = load_original_frames(imgs_dir, timestamps, fps)
result["load_time_images_ms"] = (time_benchmark.last * 1000) / num_frames
result["load_time_images_ms"] = time_benchmark.result_ms / num_frames
frames_np, original_frames_np = frames.numpy(), original_frames.numpy()
for i in range(num_frames):
@@ -205,10 +215,8 @@ def benchmark_decoding(
# A sample is a single set of decoded frames specified by timestamps_mode (e.g. a single frame, 2 frames, etc.).
# For each sample, we record metrics (loading time and quality metrics) which are then averaged over all samples.
# As these samples are independent, we run them in parallel threads to speed up the benchmark.
# Use a single shared lock for all worker threads
shared_lock = Lock()
with ThreadPoolExecutor(max_workers=num_workers) as executor:
futures = [executor.submit(process_sample, i, shared_lock) for i in range(num_samples)]
futures = [executor.submit(process_sample, i) for i in range(num_samples)]
for future in tqdm(as_completed(futures), total=num_samples, desc="samples", leave=False):
result = future.result()
load_times_video_ms.append(result["load_time_video_ms"])
@@ -350,27 +358,24 @@ def main(
imgs_dir = output_dir / "images" / dataset.repo_id.replace("/", "_")
# We only use the first episode
save_first_episode(imgs_dir, dataset)
for duet in [
dict(zip(encoding_benchmarks.keys(), unique_combination, strict=False))
for unique_combination in itertools.product(*encoding_benchmarks.values())
]:
encoding_cfg = BASE_ENCODING.copy()
encoding_cfg["vcodec"] = video_codec
encoding_cfg["pix_fmt"] = pixel_format
for key, value in duet.items():
for key, values in tqdm(encoding_benchmarks.items(), desc="encodings (g, crf)", leave=False):
for value in tqdm(values, desc=f"encodings ({key})", leave=False):
encoding_cfg = BASE_ENCODING.copy()
encoding_cfg["vcodec"] = video_codec
encoding_cfg["pix_fmt"] = pixel_format
encoding_cfg[key] = value
args_path = Path("_".join(str(value) for value in encoding_cfg.values()))
video_path = output_dir / "videos" / args_path / f"{repo_id.replace('/', '_')}.mp4"
benchmark_table += benchmark_encoding_decoding(
dataset,
video_path,
imgs_dir,
encoding_cfg,
decoding_benchmarks,
num_samples,
num_workers,
save_frames,
)
args_path = Path("_".join(str(value) for value in encoding_cfg.values()))
video_path = output_dir / "videos" / args_path / f"{repo_id.replace('/', '_')}.mp4"
benchmark_table += benchmark_encoding_decoding(
dataset,
video_path,
imgs_dir,
encoding_cfg,
decoding_benchmarks,
num_samples,
num_workers,
save_frames,
)
# Save intermediate results
benchmark_df = pd.DataFrame(benchmark_table, columns=headers)
@@ -404,9 +409,9 @@ if __name__ == "__main__":
nargs="*",
default=[
"lerobot/pusht_image",
"lerobot/aloha_mobile_shrimp_image",
"lerobot/paris_street",
"lerobot/kitchen",
"aliberts/aloha_mobile_shrimp_image",
"aliberts/paris_street",
"aliberts/kitchen",
],
help="Datasets repo-ids to test against. First episodes only are used. Must be images.",
)
@@ -414,7 +419,7 @@ if __name__ == "__main__":
"--vcodec",
type=str,
nargs="*",
default=["h264", "hevc", "libsvtav1"],
default=["libx264", "hevc", "libsvtav1"],
help="Video codecs to be tested",
)
parser.add_argument(
@@ -463,7 +468,7 @@ if __name__ == "__main__":
"--backends",
type=str,
nargs="*",
default=["torchcodec", "pyav"],
default=["pyav", "video_reader"],
help="Torchvision decoding backend to be tested.",
)
parser.add_argument(
docs/source/_toctree.yml
+2 -14
View File
@@ -9,8 +9,6 @@
title: Imitation Learning for Robots
- local: cameras
title: Cameras
- local: bring_your_own_policies
title: Bring Your Own Policies
- local: integrate_hardware
title: Bring Your Own Hardware
- local: hilserl
@@ -39,8 +37,6 @@
title: π₀.₅ (Pi05)
- local: groot
title: NVIDIA GR00T N1.5
- local: xvla
title: X-VLA
title: "Policies"
- sections:
- local: async
@@ -51,8 +47,8 @@
- sections:
- local: envhub
title: Environments from the Hub
- local: envhub_leisaac
title: Control & Train Robots in Sim (LeIsaac)
- local: il_sim
title: Imitation Learning in Sim
- local: libero
title: Using Libero
- local: metaworld
@@ -83,19 +79,11 @@
title: Hope Jr
- local: reachy2
title: Reachy 2
- local: unitree_g1
title: Unitree G1
- local: earthrover_mini_plus
title: Earth Rover Mini
title: "Robots"
- sections:
- local: phone_teleop
title: Phone
title: "Teleoperators"
- sections:
- local: torch_accelerators
title: PyTorch accelerators
title: "Supported Hardware"
- sections:
- local: notebooks
title: Notebooks
docs/source/async.mdx
+3 -3
View File
@@ -196,7 +196,7 @@ client_cfg = RobotClientConfig(
server_address="localhost:8080",
policy_device="mps",
policy_type="smolvla",
pretrained_name_or_path="<user>/smolvla_async",
pretrained_name_or_path="fracapuano/smolvla_async",
chunk_size_threshold=0.5,
actions_per_chunk=50, # make sure this is less than the max actions of the policy
)
@@ -278,7 +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
@@ -289,7 +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 = ">= 3.11"
[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 Dict, 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 Dict, 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/earthrover_mini_plus.mdx
-206
View File
@@ -1,206 +0,0 @@
# EarthRover Mini Plus
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 3.10 or newer
- Internet connection
### Setting Up the Frodobots SDK
The robot needs the [Frodobots SDK](https://github.com/Frodobots/earth-rovers-sdk) running on your computer. Here's how:
1. Download and install the SDK:
```bash
git clone https://github.com/Frodobots/earth-rovers-sdk.git
cd earth-rovers-sdk
pip install -r requirements.txt
```
2. Start the SDK:
```bash
hypercorn main:app --reload
```
3. 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
huggingface-cli login --token ${HUGGINGFACE_TOKEN} --add-to-git-credential
```
Store your Hugging Face username:
```bash
HF_USER=$(huggingface-cli whoami | head -n 1)
echo $HF_USER
```
### Start Recording
Use the standard recording command:
```bash
python src/lerobot/scripts/lerobot_record.py \
--robot.type=earthrover_mini_plus \
--teleop.type=keyboard_rover \
--dataset.repo_id=your_username/dataset_name \
--dataset.num_episodes=2 \
--dataset.fps=10 \
--dataset.single_task="Navigate around obstacles" \
--display_data=true
```
Replace `your_username/dataset_name` with your Hugging Face username and a name for your dataset.
### What Gets Saved
Your dataset includes:
**Your Actions (2 things)**:
- How much you moved forward/backward
- How much you turned left/right
**Robot Observations (12 things)**:
- Front camera video
- Rear camera video
- Current speed
- Battery level
- Which way the robot is facing
- GPS location (latitude, longitude, signal strength)
- Network signal strength
- Vibration level
- Lamp status (on/off)
### Where Your Data Goes
On your computer: `~/.cache/huggingface/lerobot/{repo-id}`
After recording, your data automatically uploads to your Hugging Face page:
```bash
echo https://huggingface.co/datasets/${HF_USER}/earthrover-navigation
```
Your dataset will be tagged with `LeRobot` for community discovery.
docs/source/envhub_leisaac.mdx
-301
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@@ -1,301 +0,0 @@
# LeIsaac × LeRobot EnvHub
LeRobot EnvHub now supports **imitation learning in simulation** with LeIsaac.
Spin up everyday manipulation tasks, teleoperate the robot, collect demos, push them to the Hub, and train policies in LeRobot — all in one loop.
[LeIsaac](https://github.com/LightwheelAI/leisaac) integrates with IsaacLab and the SO101 Leader/Follower setup to provide:
- 🕹️ **Teleoperation-first workflows** for data collection
- 📦 **Built-in data conversion** ready for LeRobot training
- 🤖 **Everyday skills** like picking oranges, lifting cubes, cleaning tables, and folding cloth
- ☁️ **Ongoing upgrades** from [LightWheel](https://lightwheel.ai/): cloud simulation, EnvHub support, Sim2Real tooling, and more
Below youll find the currently supported LeIsaac tasks exposed through LeRobot EnvHub.
# Available Environments
The following table lists all available tasks and environments in LeIsaac x LeRobot Envhub. You can also get the latest list of environments by running the following command:
```bash
python scripts/environments/list_envs.py
```
| Task | Environment ID | Task Description | Related Robot |
| :-------------------------------------------------------------------------------------------------------------------------------------------------------------- | :-------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------------- | :------------------------------------------------------------------------------------------------------------------------- | :--------------------------------------------------------- |
| <video src="https://github.com/user-attachments/assets/466eddff-f720-4f99-94d5-5e123e4c302c" autoplay loop muted playsinline style="max-width: 300px;"></video> | [LeIsaac-SO101-PickOrange-v0](https://github.com/LightwheelAI/leisaac/blob/main/source/leisaac/leisaac/tasks/pick_orange/pick_orange_env_cfg.py)<br /><br />[LeIsaac-SO101-PickOrange-Direct-v0](https://github.com/LightwheelAI/leisaac/blob/main/source/leisaac/leisaac/tasks/pick_orange/direct/pick_orange_env.py) | Pick three oranges and put them into the plate, then reset the arm to rest state. | Single-Arm SO101 Follower |
| <video src="https://github.com/user-attachments/assets/1e4eb83a-0b38-40fb-a0b2-ddb0fe201e6d" autoplay loop muted playsinline style="max-width: 300px;"></video> | [LeIsaac-SO101-LiftCube-v0](https://github.com/LightwheelAI/leisaac/blob/main/source/leisaac/leisaac/tasks/lift_cube/lift_cube_env_cfg.py)<br /><br />[LeIsaac-SO101-LiftCube-Direct-v0](https://github.com/LightwheelAI/leisaac/blob/main/source/leisaac/leisaac/tasks/lift_cube/direct/lift_cube_env.py) | Lift the red cube up. | Single-Arm SO101 Follower |
| <video src="https://github.com/user-attachments/assets/e49d8f1c-dcc9-412b-a88f-100680d8a45b" autoplay loop muted playsinline style="max-width: 300px;"></video> | [LeIsaac-SO101-CleanToyTable-v0](https://github.com/LightwheelAI/leisaac/blob/main/source/leisaac/leisaac/tasks/clean_toy_table/clean_toy_table_env_cfg.py)<br /><br />[LeIsaac-SO101-CleanToyTable-BiArm-v0](https://github.com/LightwheelAI/leisaac/blob/main/source/leisaac/leisaac/tasks/clean_toy_table/clean_toy_table_bi_arm_env_cfg.py)<br /><br />[LeIsaac-SO101-CleanToyTable-BiArm-Direct-v0](https://github.com/LightwheelAI/leisaac/blob/main/source/leisaac/leisaac/tasks/clean_toy_table/direct/clean_toy_table_bi_arm_env.py) | Pick two letter e objects into the box, and reset the arm to rest state. | Single-Arm SO101 Follower<br /><br />Bi-Arm SO101 Follower |
| <video src="https://github.com/user-attachments/assets/e29a0f8a-9286-4ce6-b45d-342c3d3ba754" autoplay loop muted playsinline style="max-width: 300px;"></video> | [LeIsaac-SO101-FoldCloth-BiArm-v0](https://github.com/LightwheelAI/leisaac/blob/main/source/leisaac/leisaac/tasks/fold_cloth/fold_cloth_bi_arm_env_cfg.py)<br /><br />[LeIsaac-SO101-FoldCloth-BiArm-Direct-v0](https://github.com/LightwheelAI/leisaac/blob/main/source/leisaac/leisaac/tasks/fold_cloth/direct/fold_cloth_bi_arm_env.py) | Fold the cloth, and reset the arm to rest state.<br /><br />_Note: Only the DirectEnv support check_success in this task._ | Bi-Arm SO101 Follower |
# Load LeIsaac directly in LeRobot with one line of code
> EnvHub: Share LeIsaac environments through HuggingFace
[EnvHub](https://huggingface.co/docs/lerobot/envhub) is our reproducible environment hub, spin up a packaged simulation with one line, experiment immediately, and publish your own tasks for the community.
LeIsaac offers EnvHub support so you can consume or share tasks with only a few commands.
<video
controls
src="https://github.com/user-attachments/assets/687666f5-ebe0-421d-84a0-eb86116ac5f8"
style={{ width: "100%", maxWidth: "960px", borderRadius: "8px" }}
/>
## How to get started, environment Setup
Run the following commands to setup your code environments:
```bash
# Refer to Getting Started/Installation to install leisaac firstly
conda create -n leisaac_envhub python=3.11
conda activate leisaac_envhub
conda install -c "nvidia/label/cuda-12.8.1" cuda-toolkit
pip install -U torch==2.7.0 torchvision==0.22.0 --index-url https://download.pytorch.org/whl/cu128
pip install 'leisaac[isaaclab] @ git+https://github.com/LightwheelAI/leisaac.git#subdirectory=source/leisaac' --extra-index-url https://pypi.nvidia.com
# Install lerobot
pip install lerobot==0.4.1
# Fix numpy version
pip install numpy==1.26.0
```
## Usage Example
EnvHub exposes every LeIsaac-supported task in a uniform interface. The examples below load `so101_pick_orange` and demonstrate a random-action rollout and an interactive teleoperation.
### Random Action
<details>
<summary>Click to expand code example</summary>
```python
# envhub_random_action.py
import torch
from lerobot.envs.factory import make_env
# Load from the hub
envs_dict = make_env("LightwheelAI/leisaac_env:envs/so101_pick_orange.py", n_envs=1, trust_remote_code=True)
# Access the environment
suite_name = next(iter(envs_dict))
sync_vector_env = envs_dict[suite_name][0]
# retrieve the isaac environment from the sync vector env
env = sync_vector_env.envs[0].unwrapped
# Use it like any gym environment
obs, info = env.reset()
while True:
action = torch.tensor(env.action_space.sample())
obs, reward, terminated, truncated, info = env.step(action)
if terminated or truncated:
obs, info = env.reset()
env.close()
```
</details>
```bash
python envhub_random_action.py
```
You should see the SO101 arm swinging under purely random commands.
### Teleoperation
LeRobots teleoperation stack can drive the simulated arm.
Connect the SO101 Leader controller, run the calibration command below.
```bash
lerobot-calibrate \
--teleop.type=so101_leader \
--teleop.port=/dev/ttyACM0 \
--teleop.id=leader
```
And then launch the teleop script.
<details>
<summary>Click to expand code example</summary>
```python
# envhub_teleop_example.py
import logging
import time
import gymnasium as gym
from dataclasses import asdict, dataclass
from pprint import pformat
from lerobot.teleoperators import ( # noqa: F401
Teleoperator,
TeleoperatorConfig,
make_teleoperator_from_config,
so101_leader,
)
from lerobot.utils.robot_utils import precise_sleep
from lerobot.utils.utils import init_logging
from lerobot.envs.factory import make_env
@dataclass
class TeleoperateConfig:
teleop: TeleoperatorConfig
env_name: str = "so101_pick_orange"
fps: int = 60
@dataclass
class EnvWrap:
env: gym.Env
def make_env_from_leisaac(env_name: str = "so101_pick_orange"):
envs_dict = make_env(
f'LightwheelAI/leisaac_env:envs/{env_name}.py',
n_envs=1,
trust_remote_code=True
)
suite_name = next(iter(envs_dict))
sync_vector_env = envs_dict[suite_name][0]
env = sync_vector_env.envs[0].unwrapped
return env
def teleop_loop(teleop: Teleoperator, env: gym.Env, fps: int):
from leisaac.devices.action_process import preprocess_device_action
from leisaac.assets.robots.lerobot import SO101_FOLLOWER_MOTOR_LIMITS
from leisaac.utils.env_utils import dynamic_reset_gripper_effort_limit_sim
env_wrap = EnvWrap(env=env)
obs, info = env.reset()
while True:
loop_start = time.perf_counter()
if env.cfg.dynamic_reset_gripper_effort_limit:
dynamic_reset_gripper_effort_limit_sim(env, 'so101leader')
raw_action = teleop.get_action()
processed_action = preprocess_device_action(
dict(
so101_leader=True,
joint_state={
k.removesuffix(".pos"): v for k, v in raw_action.items()},
motor_limits=SO101_FOLLOWER_MOTOR_LIMITS),
env_wrap
)
obs, reward, terminated, truncated, info = env.step(processed_action)
if terminated or truncated:
obs, info = env.reset()
dt_s = time.perf_counter() - loop_start
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)")
def teleoperate(cfg: TeleoperateConfig):
init_logging()
logging.info(pformat(asdict(cfg)))
teleop = make_teleoperator_from_config(cfg.teleop)
env = make_env_from_leisaac(cfg.env_name)
teleop.connect()
if hasattr(env, 'initialize'):
env.initialize()
try:
teleop_loop(teleop=teleop, env=env, fps=cfg.fps)
except KeyboardInterrupt:
pass
finally:
teleop.disconnect()
env.close()
def main():
teleoperate(TeleoperateConfig(
teleop=so101_leader.SO101LeaderConfig(
port="/dev/ttyACM0",
id='leader',
use_degrees=False,
),
env_name="so101_pick_orange",
fps=60,
))
if __name__ == "__main__":
main()
```
</details>
```bash
python envhub_teleop_example.py
```
Running the script lets you operate the simulated arm using the physical Leader device.
## ☁️ Cloud Simulation (No GPU Required)
Dont have a local GPU or the right drivers? No problem! You can run LeIsaac entirely in the cloud with zero setup.
LeIsaac works out-of-the-box on **NVIDIA Brev**, giving you a fully configured environment directly in your browser.
👉 **Start here:** [https://lightwheelai.github.io/leisaac/docs/cloud_simulation/nvidia_brev](https://lightwheelai.github.io/leisaac/docs/cloud_simulation/nvidia_brev)
Once your instance is deployed, simply open the link for **port 80 (HTTP)** to launch **Visual Studio Code Server** (default password: `password`). From there, you can run simulations, edit code, and visualize IsaacLab environments — all from your web browser.
**No GPU, no drivers, no local installation. Just click and run.**
## Additional Notes
We keep EnvHub coverage aligned with the LeIsaac task. Currently supported:
- `so101_pick_orange`
- `so101_lift_cube`
- `so101_clean_toytable`
- `bi_so101_fold_cloth`
Switch tasks by targeting a different script when calling `make_env`, for example:
```python
envs_dict_pick_orange = make_env("LightwheelAI/leisaac_env:envs/so101_pick_orange.py", n_envs=1, trust_remote_code=True)
envs_dict_lift_cube = make_env("LightwheelAI/leisaac_env:envs/so101_lift_cube.py", n_envs=1, trust_remote_code=True)
envs_dict_clean_toytable = make_env("LightwheelAI/leisaac_env:envs/so101_clean_toytable.py", n_envs=1, trust_remote_code=True)
envs_dict_fold_cloth = make_env("LightwheelAI/leisaac_env:envs/bi_so101_fold_cloth.py", n_envs=1, trust_remote_code=True)
```
Note: when working with `bi_so101_fold_cloth`, call `initialize()` immediately after retrieving the env before performing any other operations:
<details>
<summary>Click to expand code example</summary>
```python
import torch
from lerobot.envs.factory import make_env
# Load from the hub
envs_dict = make_env("LightwheelAI/leisaac_env:envs/bi_so101_fold_cloth.py", n_envs=1, trust_remote_code=True)
# Access the environment
suite_name = next(iter(envs_dict))
sync_vector_env = envs_dict[suite_name][0]
# retrieve the isaac environment from the sync vector env
env = sync_vector_env.envs[0].unwrapped
# NOTE: initialize() first
env.initialize()
# other operation with env...
```
</details>
docs/source/il_robots.mdx
+9 -26
View File
@@ -201,8 +201,7 @@ 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
@@ -210,19 +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)
@@ -251,9 +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}")
@@ -262,9 +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,
@@ -279,9 +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,
@@ -410,7 +393,7 @@ import time
from lerobot.datasets.lerobot_dataset import LeRobotDataset
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.robot_utils import busy_wait
from lerobot.utils.utils import log_say
episode_idx = 0
@@ -432,7 +415,7 @@ for idx in range(dataset.num_frames):
}
robot.send_action(action)
precise_sleep(1.0 / dataset.fps - (time.perf_counter() - t0))
busy_wait(1.0 / dataset.fps - (time.perf_counter() - t0))
robot.disconnect()
```
@@ -445,7 +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 \
@@ -502,7 +485,7 @@ huggingface-cli upload ${HF_USER}/act_so101_test${CKPT} \
## 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">
docs/source/il_sim.mdx
+220
View File
@@ -0,0 +1,220 @@
# Imitation Learning in Sim
This tutorial will explain how to train a neural network to control a robot in simulation with imitation learning.
**You'll learn:**
1. How to record a dataset in simulation with [gym-hil](https://github.com/huggingface/gym-hil) and visualize the dataset.
2. How to train a policy using your data.
3. How to evaluate your policy in simulation and visualize the results.
For the simulation environment we use the same [repo](https://github.com/huggingface/gym-hil) that is also being used by the Human-In-the-Loop (HIL) reinforcement learning algorithm.
This environment is based on [MuJoCo](https://mujoco.org) and allows you to record datasets in LeRobotDataset format.
Teleoperation is easiest with a controller like the Logitech F710, but you can also use your keyboard if you are up for the challenge.
## Installation
First, install the `gym_hil` package within the LeRobot environment, go to your LeRobot folder and run this command:
```bash
pip install -e ".[hilserl]"
```
## Teleoperate and Record a Dataset
To use `gym_hil` with LeRobot, you need to use a configuration file. An example config file can be found [here](https://huggingface.co/datasets/lerobot/config_examples/resolve/main/sim_il/env_config.json).
To teleoperate and collect a dataset, we need to modify this config file. Here's an example configuration for imitation learning data collection:
```json
{
"env": {
"type": "gym_manipulator",
"name": "gym_hil",
"task": "PandaPickCubeGamepad-v0",
"fps": 10
},
"dataset": {
"repo_id": "your_username/il_gym",
"root": null,
"task": "pick_cube",
"num_episodes_to_record": 30,
"replay_episode": null,
"push_to_hub": true
},
"mode": "record",
"device": "cuda"
}
```
Key configuration points:
- Set your `repo_id` in the `dataset` section: `"repo_id": "your_username/il_gym"`
- Set `num_episodes_to_record: 30` to collect 30 demonstration episodes
- Ensure `mode` is set to `"record"`
- If you don't have an NVIDIA GPU, change `"device": "cuda"` to `"mps"` for macOS or `"cpu"`
- To use keyboard instead of gamepad, change `"task"` to `"PandaPickCubeKeyboard-v0"`
Then we can run this command to start:
<hfoptions id="teleop_sim">
<hfoption id="Linux">
```bash
python -m lerobot.rl.gym_manipulator --config_path path/to/env_config_gym_hil_il.json
```
</hfoption>
<hfoption id="MacOS">
```bash
mjpython -m lerobot.rl.gym_manipulator --config_path path/to/env_config_gym_hil_il.json
```
</hfoption>
</hfoptions>
Once rendered you can teleoperate the robot with the gamepad or keyboard, below you can find the gamepad/keyboard controls.
Note that to teleoperate the robot you have to hold the "Human Take Over Pause Policy" Button `RB` to enable control!
**Gamepad Controls**
<p align="center">
<img
src="https://huggingface.co/datasets/huggingface/documentation-images/resolve/main/lerobot/gamepad_guide.jpg?raw=true"
alt="Figure shows the control mappings on a Logitech gamepad."
title="Gamepad Control Mapping"
width="100%"
></img>
</p>
<p align="center">
<i>Gamepad button mapping for robot control and episode management</i>
</p>
**Keyboard controls**
For keyboard controls use the `spacebar` to enable control and the following keys to move the robot:
```bash
Arrow keys: Move in X-Y plane
Shift and Shift_R: Move in Z axis
Right Ctrl and Left Ctrl: Open and close gripper
ESC: Exit
```
## Visualize a dataset
If you uploaded your dataset to the hub you can [visualize your dataset online](https://huggingface.co/spaces/lerobot/visualize_dataset) by copy pasting your repo id.
<p align="center">
<img
src="https://huggingface.co/datasets/huggingface/documentation-images/resolve/main/lerobot/dataset_visualizer_sim.png"
alt="Figure shows the dataset visualizer"
title="Dataset visualization"
width="100%"
></img>
</p>
<p align="center">
<i>Dataset visualizer</i>
</p>
## 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/train.py) script. A few arguments are required. Here is an example command:
```bash
lerobot-train \
--dataset.repo_id=${HF_USER}/il_gym \
--policy.type=act \
--output_dir=outputs/train/il_sim_test \
--job_name=il_sim_test \
--policy.device=cuda \
--wandb.enable=true
```
Let's explain the command:
1. We provided the dataset as argument with `--dataset.repo_id=${HF_USER}/il_gym`.
2. We provided the policy with `policy.type=act`. This loads configurations from [`configuration_act.py`](https://github.com/huggingface/lerobot/blob/main/src/lerobot/policies/act/configuration_act.py). Importantly, this policy will automatically adapt to the number of motor states, motor actions and cameras of your robot (e.g. `laptop` and `phone`) which have been saved in your dataset.
3. We provided `policy.device=cuda` since we are training on a Nvidia GPU, but you could use `policy.device=mps` to train on Apple silicon.
4. We provided `wandb.enable=true` to use [Weights and Biases](https://docs.wandb.ai/quickstart) for visualizing training plots. This is optional but if you use it, make sure you are logged in by running `wandb login`.
Training should take several hours, 100k steps (which is the default) will take about 1h on Nvidia A100. You will find checkpoints in `outputs/train/il_sim_test/checkpoints`.
#### Train using Collab
If your local computer doesn't have a powerful GPU you could utilize Google Collab to train your model by following the [ACT training notebook](./notebooks#training-act).
#### Upload policy checkpoints
Once training is done, upload the latest checkpoint with:
```bash
huggingface-cli upload ${HF_USER}/il_sim_test \
outputs/train/il_sim_test/checkpoints/last/pretrained_model
```
You can also upload intermediate checkpoints with:
```bash
CKPT=010000
huggingface-cli upload ${HF_USER}/il_sim_test${CKPT} \
outputs/train/il_sim_test/checkpoints/${CKPT}/pretrained_model
```
## Evaluate your policy in Sim
To evaluate your policy we have to use a configuration file. An example can be found [here](https://huggingface.co/datasets/lerobot/config_examples/resolve/main/sim_il/eval_config.json).
Here's an example evaluation configuration:
```json
{
"env": {
"type": "gym_manipulator",
"name": "gym_hil",
"task": "PandaPickCubeGamepad-v0",
"fps": 10
},
"dataset": {
"repo_id": "your_username/il_sim_dataset",
"dataset_root": null,
"task": "pick_cube"
},
"pretrained_policy_name_or_path": "your_username/il_sim_model",
"device": "cuda"
}
```
Make sure to replace:
- `repo_id` with the dataset you trained on (e.g., `your_username/il_sim_dataset`)
- `pretrained_policy_name_or_path` with your model ID (e.g., `your_username/il_sim_model`)
Then you can run this command to visualize your trained policy
<hfoptions id="eval_policy">
<hfoption id="Linux">
```bash
python -m lerobot.rl.eval_policy --config_path=path/to/eval_config_gym_hil.json
```
</hfoption>
<hfoption id="MacOS">
```bash
mjpython -m lerobot.rl.eval_policy --config_path=path/to/eval_config_gym_hil.json
```
</hfoption>
</hfoptions>
> [!WARNING]
> While the main workflow of training ACT in simulation is straightforward, there is significant room for exploring how to set up the task, define the initial state of the environment, and determine the type of data required during collection to learn the most effective policy. If your trained policy doesn't perform well, investigate the quality of the dataset it was trained on using our visualizers, as well as the action values and various hyperparameters related to ACT and the simulation.
Congrats 🎉, you have finished this tutorial. If you want to continue with using LeRobot in simulation follow this [Tutorial on reinforcement learning in sim with HIL-SERL](https://huggingface.co/docs/lerobot/hilserl_sim)
> [!TIP]
> If you have any questions or need help, please reach out on [Discord](https://discord.com/invite/s3KuuzsPFb).
docs/source/installation.mdx
+1 -1
View File
@@ -90,7 +90,7 @@ If you encounter build errors, you may need to install additional dependencies:
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)
docs/source/libero.mdx
-5
View File
@@ -62,11 +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/openarms.mdx
-328
View File
@@ -1,328 +0,0 @@
# OpenArms Robot
OpenArms is a 7 DOF robotic arm with a gripper, designed by [Enactic, Inc.](https://www.enactic.com/) It uses Damiao motors controlled via CAN bus communication and MIT control mode for smooth, precise motion.
## Hardware Overview
- **7 DOF per arm** (14 DOF total for dual arm setup)
- **1 gripper per arm** (2 grippers total)
- **Damiao motors** with 4 different types:
- **DM8009** (DM-J8009P-2EC) for shoulders (J1, J2) - high torque
- **DM4340** for shoulder rotation and elbow (J3, J4)
- **DM4310** (DM-J4310-2EC V1.1) for wrist (J5, J6, J7) and gripper (J8)
- **24V power supply** required
- **CAN interface device**:
- **Linux**: Any SocketCAN-compatible adapter
- **macOS**: CANable, PEAK PCAN-USB, or Kvaser USBcan
- Proper CAN wiring (CANH, CANL, 120Ω termination)
## Motor Configuration
Each arm has the following motor configuration based on the [OpenArm setup guide](https://docs.openarm.dev/software/setup/):
| Joint | Motor | Motor Type | Sender CAN ID | Receiver ID | Description |
|-------|-------|------------|---------------|-------------|-------------|
| J1 | joint_1 | DM8009 | 0x01 | 0x11 | Shoulder pan |
| J2 | joint_2 | DM8009 | 0x02 | 0x12 | Shoulder lift |
| J3 | joint_3 | DM4340 | 0x03 | 0x13 | Shoulder rotation |
| J4 | joint_4 | DM4340 | 0x04 | 0x14 | Elbow flex |
| J5 | joint_5 | DM4310 | 0x05 | 0x15 | Wrist roll |
| J6 | joint_6 | DM4310 | 0x06 | 0x16 | Wrist pitch |
| J7 | joint_7 | DM4310 | 0x07 | 0x17 | Wrist rotation |
| J8 | gripper | DM4310 | 0x08 | 0x18 | Gripper |
For dual arm setups, the left arm uses IDs 0x09-0x10 for joints 1-8 with the same motor types.
## Quick Start
```bash
# Install system dependencies
sudo apt install can-utils iproute2
# Install LeRobot with OpenArms support
pip install -e ".[openarms]"
```
## Setup Guide
### Step 1: Motor ID Configuration
**IMPORTANT**: Before using the robot, motors must be configured with the correct CAN IDs.
Refer to the [OpenArm Motor ID Configuration Guide](https://docs.openarm.dev/software/setup/motor-id) for detailed instructions using the Damiao Debugging Tools on Windows.
Key points:
- Each motor needs a unique **Sender CAN ID** (0x01-0x08)
- Each motor needs a unique **Receiver/Master ID** (0x11-0x18)
- Use the Damiao Debugging Tools to set these IDs
### Step 2: Setup CAN Interface
Configure your CAN interface as described in the [OpenArm CAN Setup Guide](https://docs.openarm.dev/software/setup/can-setup):
#### Linux (SocketCAN)
```bash
# Find your CAN interface
ip link show
# Configure can0, 1, 2, 3
sudo ip link set can0 down
sudo ip link set can0 type can bitrate 1000000
sudo ip link set can0 up
sudo ip link set can1 down
sudo ip link set can1 type can bitrate 1000000
sudo ip link set can1 up
sudo ip link set can2 down
sudo ip link set can2 type can bitrate 1000000
sudo ip link set can2 up
sudo ip link set can3 down
sudo ip link set can3 type can bitrate 1000000
sudo ip link set can3 up
# Verify configuration
ip link show can0
```
or run:
`examples/openarms/setup_can.sh`
### Testing canbus and motor connection
Please run this script to check if all motors can be found and to find your can-fd speed: `python examples/openarms/debug_can_communication.py`
## Usage
### Basic Setup
```python
from lerobot.robots.openarms import OpenArmsFollower
from lerobot.robots.openarms.config_openarms_follower import OpenArmsFollowerConfig
# Configure for dual arm setup
config = OpenArmsFollowerConfig(
port="can0",
can_interface="socketcan", # Or "auto" for auto-detection
id="openarms_dual",
is_dual_arm=True,
)
robot = OpenArmsFollower(config)
robot.connect()
```
### Calibration
On first use, you'll need to calibrate the robot:
```python
robot.calibrate()
```
The calibration process will:
1. Disable torque on all motors
2. Ask you to position arms in **hanging position with grippers closed**
3. Set this as the zero position
4. Ask you to move each joint through its full range
5. Record min/max positions for each joint
6. Save calibration to file
### Reading Observations
The robot provides comprehensive state information:
```python
observation = robot.get_observation()
# Observation includes for each motor:
# - {motor_name}.pos: Position in degrees
# - {motor_name}.vel: Velocity in degrees/second
# - {motor_name}.torque: Motor torque
# - {camera_name}: Camera images (if configured)
print(f"Right arm joint 1 position: {observation['right_joint_1.pos']:.1f}°")
print(f"Right arm joint 1 velocity: {observation['right_joint_1.vel']:.1f}°/s")
print(f"Right arm joint 1 torque: {observation['right_joint_1.torque']:.3f} N·m")
```
### Sending Actions
```python
# Send target positions (in degrees)
action = {
"right_joint_1.pos": 45.0,
"right_joint_2.pos": -30.0,
# ... all joints
"right_gripper.pos": 45.0, # Half-closed
}
actual_action = robot.send_action(action)
```
### Gripper Control
```python
# Open gripper
robot.open_gripper(arm="right")
# Close gripper
robot.close_gripper(arm="right")
```
## Safety Features
### 1. Maximum Relative Target
Limits how far a joint can move in a single command to prevent sudden movements:
```python
config = OpenArmsFollowerConfig(
port="can0",
# Limit all joints to 10 degrees per command
max_relative_target=10.0,
# Or set per-motor limits
max_relative_target={
"right_joint_1": 15.0, # Slower moving joint
"right_joint_2": 10.0,
"right_gripper": 5.0, # Very slow gripper
}
)
```
**How it works**: If current position is 50° and you command 80°, with `max_relative_target=10.0`, the robot will only move to 60° in that step.
### 2. Torque Limits
Control maximum torque output, especially important for grippers and teleoperation:
```python
config = OpenArmsFollowerConfig(
port="can0",
# Gripper torque limit (fraction of motor's max torque)
gripper_torque_limit=0.5, # 50% of max torque
)
```
Lower torque limits prevent damage when gripping delicate objects.
### 3. MIT Control Gains
Control responsiveness and stability via PID-like gains:
```python
config = OpenArmsFollowerConfig(
port="can0",
position_kp=10.0, # Position gain (higher = more responsive)
position_kd=0.5, # Velocity damping (higher = more damped)
)
```
**Guidelines**:
- **For following (robot)**: Higher gains for responsiveness
- `position_kp=10.0`, `position_kd=0.5`
- **For teleoperation (leader)**: Lower gains or disable torque for manual movement
- `manual_control=True` (torque disabled)
### 4. Velocity Limits
Velocity limits are enforced by the Damiao motors based on motor type. For DM4310:
- Max velocity: 30 rad/s ≈ 1718°/s
The motors will automatically limit velocity to safe values.
## Teleoperation
### Leader Arm Setup
The leader arm is moved manually (torque disabled) to generate commands:
```python
from lerobot.teleoperators.openarms import OpenArmsLeader
from lerobot.teleoperators.openarms.config_openarms_leader import OpenArmsLeaderConfig
config = OpenArmsLeaderConfig(
port="can1", # Separate CAN interface for leader
id="openarms_leader",
manual_control=True, # Torque disabled for manual movement
is_dual_arm=True,
)
leader = OpenArmsLeader(config)
leader.connect()
# Read current position as action
action = leader.get_action()
# action contains positions for all joints in degrees
```
### Safety Considerations for Teleoperation
1. **Use separate CAN interfaces** for leader and follower to avoid conflicts
2. **Enable max_relative_target** on follower to smooth abrupt movements
3. **Lower torque limits** on follower to prevent damage from tracking errors
4. **Test with one arm** before enabling dual arm teleoperation
5. **Have emergency stop** ready (power switch or CAN disable)
```python
# Recommended follower config for teleoperation
follower_config = OpenArmsFollowerConfig(
port="can0",
max_relative_target=5.0, # Small steps for smooth following
gripper_torque_limit=0.3, # Low torque for safety
position_kp=5.0, # Lower gains for gentler following
position_kd=0.3,
)
```
## Troubleshooting
### Motor Shaking/Unstable
- **Lower control gains**: Reduce `position_kp` and `position_kd`
- **Check calibration**: Re-run calibration procedure
- **Verify power**: Insufficient current can cause instability
- **Check mechanical**: Loose connections, binding, or damaged components
### CAN Bus Errors
```bash
# Check for errors
ip -s link show can0
# Reset CAN interface
sudo ip link set can0 down
sudo ip link set can0 up
```
### Control Mode
OpenArms uses **MIT control mode** which allows simultaneous control of:
- Position (degrees)
- Velocity (degrees/second)
- Torque (N·m)
- Position gain (Kp)
- Velocity damping (Kd)
### Communication
- **Protocol**: CAN 2.0 at 1 Mbps (or CAN-FD at 5 Mbps)
- **Frame format**: Standard 11-bit IDs
- **Update rate**: Typically 50-100 Hz depending on motor count
- **Latency**: ~10-20ms per motor command
## References
- [OpenArm Official Documentation](https://docs.openarm.dev/)
- [OpenArm Setup Guide](https://docs.openarm.dev/software/setup/)
- [Motor ID Configuration](https://docs.openarm.dev/software/setup/motor-id)
- [CAN Interface Setup](https://docs.openarm.dev/software/setup/can-setup)
- [Motor Communication Test](https://docs.openarm.dev/software/setup/configure-test)
- [Damiao Motor Documentation](https://wiki.seeedstudio.com/damiao_series/)
- [Enactic GitHub](https://github.com/enactic/openarm_can)
docs/source/so101.mdx
+125 -125
View File
@@ -30,6 +30,131 @@ The follower arm uses 6x STS3215 motors with 1/345 gearing. The leader, however,
| Wrist Roll | 5 | 1 / 147 |
| Gripper | 6 | 1 / 147 |
### 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.
It is advisable to install one 3-pin cable in the motor after placing them before continuing assembly.
### Joint 1
- Place the first motor into the base.
- Fasten the motor with 4 M2x6mm screws (smallest screws). Two from the top and two from the bottom.
- Slide over the first motor holder and fasten it using two M2x6mm screws (one on each side).
- Install both motor horns, securing the top horn with a M3x6mm screw.
- Attach the shoulder part.
- Tighten the shoulder part with 4 M3x6mm screws on top and 4 M3x6mm screws on the bottom
- Add the shoulder motor holder.
<div class="video-container">
<video controls width="600">
<source
src="https://huggingface.co/datasets/huggingface/documentation-images/resolve/main/lerobot/Joint1_v2.mp4"
type="video/mp4"
/>
</video>
</div>
### Joint 2
- Slide the second motor in from the top.
- Fasten the second motor with 4 M2x6mm screws.
- Attach both motor horns to motor 2, again use the M3x6mm horn screw.
- Attach the upper arm with 4 M3x6mm screws on each side.
<div class="video-container">
<video controls width="600">
<source
src="https://huggingface.co/datasets/huggingface/documentation-images/resolve/main/lerobot/Joint2_v2.mp4"
type="video/mp4"
/>
</video>
</div>
### Joint 3
- Insert motor 3 and fasten using 4 M2x6mm screws
- Attach both motor horns to motor 3 and secure one again with a M3x6mm horn screw.
- Connect the forearm to motor 3 using 4 M3x6mm screws on each side.
<div class="video-container">
<video controls width="600">
<source
src="https://huggingface.co/datasets/huggingface/documentation-images/resolve/main/lerobot/Joint3_v2.mp4"
type="video/mp4"
/>
</video>
</div>
### Joint 4
- Slide over motor holder 4.
- Slide in motor 4.
- Fasten motor 4 with 4 M2x6mm screws and attach its motor horns, use a M3x6mm horn screw.
<div class="video-container">
<video controls width="600">
<source
src="https://huggingface.co/datasets/huggingface/documentation-images/resolve/main/lerobot/Joint4_v2.mp4"
type="video/mp4"
/>
</video>
</div>
### Joint 5
- Insert motor 5 into the wrist holder and secure it with 2 M2x6mm front screws.
- Install only one motor horn on the wrist motor and secure it with a M3x6mm horn screw.
- Secure the wrist to motor 4 using 4 M3x6mm screws on both sides.
<div class="video-container">
<video controls width="600">
<source
src="https://huggingface.co/datasets/huggingface/documentation-images/resolve/main/lerobot/Joint5_v2.mp4"
type="video/mp4"
/>
</video>
</div>
### Gripper / Handle
<hfoptions id="assembly">
<hfoption id="Follower">
- Attach the gripper to motor 5, attach it to the motor horn on the wrist using 4 M3x6mm screws.
- Insert the gripper motor and secure it with 2 M2x6mm screws on each side.
- Attach the motor horns and again use a M3x6mm horn screw.
- Install the gripper claw and secure it with 4 M3x6mm screws on both sides.
<div class="video-container">
<video controls width="600">
<source
src="https://huggingface.co/datasets/huggingface/documentation-images/resolve/main/lerobot/Gripper_v2.mp4"
type="video/mp4"
/>
</video>
</div>
</hfoption>
<hfoption id="Leader">
- Mount the leader holder onto the wrist and secure it with 4 M3x6mm screws.
- Attach the handle to motor 5 using 1 M2x6mm screw.
- Insert the gripper motor, secure it with 2 M2x6mm screws on each side, attach a motor horn using a M3x6mm horn screw.
- Attach the follower trigger with 4 M3x6mm screws.
<div class="video-container">
<video controls width="600">
<source
src="https://huggingface.co/datasets/huggingface/documentation-images/resolve/main/lerobot/Leader_v2.mp4"
type="video/mp4"
/>
</video>
</div>
</hfoption>
</hfoptions>
## Configure the motors
### 1. Find the USB ports associated with each arm
@@ -215,131 +340,6 @@ leader.setup_motors()
</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.
It is advisable to install one 3-pin cable in the motor after placing them before continuing assembly.
### Joint 1
- Place the first motor into the base.
- Fasten the motor with 4 M2x6mm screws (smallest screws). Two from the top and two from the bottom.
- Slide over the first motor holder and fasten it using two M2x6mm screws (one on each side).
- Install both motor horns, securing the top horn with a M3x6mm screw.
- Attach the shoulder part.
- Tighten the shoulder part with 4 M3x6mm screws on top and 4 M3x6mm screws on the bottom
- Add the shoulder motor holder.
<div class="video-container">
<video controls width="600">
<source
src="https://huggingface.co/datasets/huggingface/documentation-images/resolve/main/lerobot/Joint1_v2.mp4"
type="video/mp4"
/>
</video>
</div>
### Joint 2
- Slide the second motor in from the top.
- Fasten the second motor with 4 M2x6mm screws.
- Attach both motor horns to motor 2, again use the M3x6mm horn screw.
- Attach the upper arm with 4 M3x6mm screws on each side.
<div class="video-container">
<video controls width="600">
<source
src="https://huggingface.co/datasets/huggingface/documentation-images/resolve/main/lerobot/Joint2_v2.mp4"
type="video/mp4"
/>
</video>
</div>
### Joint 3
- Insert motor 3 and fasten using 4 M2x6mm screws
- Attach both motor horns to motor 3 and secure one again with a M3x6mm horn screw.
- Connect the forearm to motor 3 using 4 M3x6mm screws on each side.
<div class="video-container">
<video controls width="600">
<source
src="https://huggingface.co/datasets/huggingface/documentation-images/resolve/main/lerobot/Joint3_v2.mp4"
type="video/mp4"
/>
</video>
</div>
### Joint 4
- Slide over motor holder 4.
- Slide in motor 4.
- Fasten motor 4 with 4 M2x6mm screws and attach its motor horns, use a M3x6mm horn screw.
<div class="video-container">
<video controls width="600">
<source
src="https://huggingface.co/datasets/huggingface/documentation-images/resolve/main/lerobot/Joint4_v2.mp4"
type="video/mp4"
/>
</video>
</div>
### Joint 5
- Insert motor 5 into the wrist holder and secure it with 2 M2x6mm front screws.
- Install only one motor horn on the wrist motor and secure it with a M3x6mm horn screw.
- Secure the wrist to motor 4 using 4 M3x6mm screws on both sides.
<div class="video-container">
<video controls width="600">
<source
src="https://huggingface.co/datasets/huggingface/documentation-images/resolve/main/lerobot/Joint5_v2.mp4"
type="video/mp4"
/>
</video>
</div>
### Gripper / Handle
<hfoptions id="assembly">
<hfoption id="Follower">
- Attach the gripper to motor 5, attach it to the motor horn on the wrist using 4 M3x6mm screws.
- Insert the gripper motor and secure it with 2 M2x6mm screws on each side.
- Attach the motor horns and again use a M3x6mm horn screw.
- Install the gripper claw and secure it with 4 M3x6mm screws on both sides.
<div class="video-container">
<video controls width="600">
<source
src="https://huggingface.co/datasets/huggingface/documentation-images/resolve/main/lerobot/Gripper_v2.mp4"
type="video/mp4"
/>
</video>
</div>
</hfoption>
<hfoption id="Leader">
- Mount the leader holder onto the wrist and secure it with 4 M3x6mm screws.
- Attach the handle to motor 5 using 1 M2x6mm screw.
- Insert the gripper motor, secure it with 2 M2x6mm screws on each side, attach a motor horn using a M3x6mm horn screw.
- Attach the follower trigger with 4 M3x6mm screws.
<div class="video-container">
<video controls width="600">
<source
src="https://huggingface.co/datasets/huggingface/documentation-images/resolve/main/lerobot/Leader_v2.mp4"
type="video/mp4"
/>
</video>
</div>
</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.
docs/source/torch_accelerators.mdx
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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
-208
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@@ -1,208 +0,0 @@
# Unitree G1 Robot Setup and Control
This guide covers the complete setup process for the Unitree G1 humanoid, from initial connection to running gr00t_wbc locomotion.
## About the Unitree G1
We offer support for both 29 and 23 DOF G1. 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
- **MuJoCo simulation mode** for testing policies without the physical robot
---
## Part 1: Connect to Robot over Ethernet
### Step 1: Configure Your Computer's Ethernet Interface
Set a static IP on the same subnet as the robot:
```bash
# Replace 'enp131s0' with your ethernet interface name (check with `ip a`)
sudo ip addr flush dev enp131s0
sudo ip addr add 192.168.123.200/24 dev enp131s0
sudo ip link set enp131s0 up
```
**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
```
You should now be connected to the robot's onboard computer.
---
## Part 2: Enable WiFi on the Robot
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
```
### Step 2: Enable Internet Forwarding
**On your laptop:**
```bash
# Enable IP forwarding
sudo sysctl -w net.ipv4.ip_forward=1
# 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 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
# Test connection
ping -c 3 8.8.8.8
```
### 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
```
### 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@<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: Robot Server Setup
### 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
```
**Important**: Keep this terminal running. The server must be active for remote control.
---
## Part 4: Running GR00T Locomotion
With the robot server running, you can now control the robot from your laptop.
### Step 1: Install LeRobot on your machine
```bash
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 .
```
### Step 2: Update Robot IP in Config
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
# Run GR00T locomotion controller
python examples/unitree_g1/gr00t_locomotion.py --repo-id "nepyope/GR00T-WholeBodyControl_g1"
```
### Step 4: Control with Remote
- **Left stick**: Forward/backward and left/right movement
- **Right stick**: Rotation
- **R1 button**: Raise waist height
- **R2 button**: Lower waist height
Press `Ctrl+C` to stop the policy.
---
## Extra: Running in Simulation Mode (MuJoCo)
You can now test and develop policies without a physical robot using MuJoCo. to do so set `is_simulation=True` in config.
## Additional Resources
- [Unitree SDK Documentation](https://github.com/unitreerobotics/unitree_sdk2_python)
- [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)
---
_Last updated: December 2025_
docs/source/using_dataset_tools.mdx
+3 -104
View File
@@ -11,14 +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
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.
@@ -87,71 +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_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_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_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_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_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_to_video \
--operation.output_dir outputs/pusht_video \
--operation.num_workers 8
```
**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.
### 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 \
@@ -159,45 +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/xvla.mdx
-528
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@@ -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=pepijn223/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
+2 -2
View File
@@ -45,7 +45,7 @@ from lerobot.robots import ( # noqa: F401
so101_follower,
)
from lerobot.utils.constants import ACTION
from lerobot.utils.robot_utils import precise_sleep
from lerobot.utils.robot_utils import busy_wait
from lerobot.utils.utils import (
init_logging,
log_say,
@@ -97,7 +97,7 @@ def replay(cfg: ReplayConfig):
robot.send_action(action)
dt_s = time.perf_counter() - start_episode_t
precise_sleep(1 / dataset.fps - dt_s)
busy_wait(1 / dataset.fps - dt_s)
robot.disconnect()
examples/dataset/load_lerobot_dataset.py
+81 -86
View File
@@ -34,106 +34,105 @@ from huggingface_hub import HfApi
import lerobot
from lerobot.datasets.lerobot_dataset import LeRobotDataset, LeRobotDatasetMetadata
# We ported a number of existing datasets ourselves, use this to see the list:
print("List of available datasets:")
pprint(lerobot.available_datasets)
def main():
# We ported a number of existing datasets ourselves, use this to see the list:
print("List of available datasets:")
pprint(lerobot.available_datasets)
# You can also browse through the datasets created/ported by the community on the hub using the hub api:
hub_api = HfApi()
repo_ids = [info.id for info in hub_api.list_datasets(task_categories="robotics", tags=["LeRobot"])]
pprint(repo_ids)
# You can also browse through the datasets created/ported by the community on the hub using the hub api:
hub_api = HfApi()
repo_ids = [info.id for info in hub_api.list_datasets(task_categories="robotics", tags=["LeRobot"])]
pprint(repo_ids)
# Or simply explore them in your web browser directly at:
# https://huggingface.co/datasets?other=LeRobot
# Or simply explore them in your web browser directly at:
# https://huggingface.co/datasets?other=LeRobot
# Let's take this one for this example
repo_id = "lerobot/aloha_mobile_cabinet"
# We can have a look and fetch its metadata to know more about it:
ds_meta = LeRobotDatasetMetadata(repo_id)
# Let's take this one for this example
repo_id = "lerobot/aloha_mobile_cabinet"
# We can have a look and fetch its metadata to know more about it:
ds_meta = LeRobotDatasetMetadata(repo_id)
# By instantiating just this class, you can quickly access useful information about the content and the
# structure of the dataset without downloading the actual data yet (only metadata files — which are
# lightweight).
print(f"Total number of episodes: {ds_meta.total_episodes}")
print(f"Average number of frames per episode: {ds_meta.total_frames / ds_meta.total_episodes:.3f}")
print(f"Frames per second used during data collection: {ds_meta.fps}")
print(f"Robot type: {ds_meta.robot_type}")
print(f"keys to access images from cameras: {ds_meta.camera_keys=}\n")
# By instantiating just this class, you can quickly access useful information about the content and the
# structure of the dataset without downloading the actual data yet (only metadata files — which are
# lightweight).
print(f"Total number of episodes: {ds_meta.total_episodes}")
print(f"Average number of frames per episode: {ds_meta.total_frames / ds_meta.total_episodes:.3f}")
print(f"Frames per second used during data collection: {ds_meta.fps}")
print(f"Robot type: {ds_meta.robot_type}")
print(f"keys to access images from cameras: {ds_meta.camera_keys=}\n")
print("Tasks:")
print(ds_meta.tasks)
print("Features:")
pprint(ds_meta.features)
print("Tasks:")
print(ds_meta.tasks)
print("Features:")
pprint(ds_meta.features)
# You can also get a short summary by simply printing the object:
print(ds_meta)
# You can also get a short summary by simply printing the object:
print(ds_meta)
# You can then load the actual dataset from the hub.
# Either load any subset of episodes:
dataset = LeRobotDataset(repo_id, episodes=[0, 10, 11, 23])
# You can then load the actual dataset from the hub.
# Either load any subset of episodes:
dataset = LeRobotDataset(repo_id, episodes=[0, 10, 11, 23])
# And see how many frames you have:
print(f"Selected episodes: {dataset.episodes}")
print(f"Number of episodes selected: {dataset.num_episodes}")
print(f"Number of frames selected: {dataset.num_frames}")
# And see how many frames you have:
print(f"Selected episodes: {dataset.episodes}")
print(f"Number of episodes selected: {dataset.num_episodes}")
print(f"Number of frames selected: {dataset.num_frames}")
# Or simply load the entire dataset:
dataset = LeRobotDataset(repo_id)
print(f"Number of episodes selected: {dataset.num_episodes}")
print(f"Number of frames selected: {dataset.num_frames}")
# Or simply load the entire dataset:
dataset = LeRobotDataset(repo_id)
print(f"Number of episodes selected: {dataset.num_episodes}")
print(f"Number of frames selected: {dataset.num_frames}")
# The previous metadata class is contained in the 'meta' attribute of the dataset:
print(dataset.meta)
# The previous metadata class is contained in the 'meta' attribute of the dataset:
print(dataset.meta)
# LeRobotDataset actually wraps an underlying Hugging Face dataset
# (see https://huggingface.co/docs/datasets for more information).
print(dataset.hf_dataset)
# LeRobotDataset actually wraps an underlying Hugging Face dataset
# (see https://huggingface.co/docs/datasets for more information).
print(dataset.hf_dataset)
# LeRobot datasets also subclasses PyTorch datasets so you can do everything you know and love from working
# with the latter, like iterating through the dataset.
# The __getitem__ iterates over the frames of the dataset. Since our datasets are also structured by
# episodes, you can access the frame indices of any episode using dataset.meta.episodes. Here, we access
# frame indices associated to the first episode:
episode_index = 0
from_idx = dataset.meta.episodes["dataset_from_index"][episode_index]
to_idx = dataset.meta.episodes["dataset_to_index"][episode_index]
# LeRobot datasets also subclasses PyTorch datasets so you can do everything you know and love from working
# with the latter, like iterating through the dataset.
# The __getitem__ iterates over the frames of the dataset. Since our datasets are also structured by
# episodes, you can access the frame indices of any episode using dataset.meta.episodes. Here, we access
# frame indices associated to the first episode:
episode_index = 0
from_idx = dataset.meta.episodes["dataset_from_index"][episode_index]
to_idx = dataset.meta.episodes["dataset_to_index"][episode_index]
# Then we grab all the image frames from the first camera:
camera_key = dataset.meta.camera_keys[0]
frames = [dataset[idx][camera_key] for idx in range(from_idx, to_idx)]
# Then we grab all the image frames from the first camera:
camera_key = dataset.meta.camera_keys[0]
frames = [dataset[idx][camera_key] for idx in range(from_idx, to_idx)]
# The objects returned by the dataset are all torch.Tensors
print(type(frames[0]))
print(frames[0].shape)
# The objects returned by the dataset are all torch.Tensors
print(type(frames[0]))
print(frames[0].shape)
# Since we're using pytorch, the shape is in pytorch, channel-first convention (c, h, w).
# We can compare this shape with the information available for that feature
pprint(dataset.features[camera_key])
# In particular:
print(dataset.features[camera_key]["shape"])
# The shape is in (h, w, c) which is a more universal format.
# Since we're using pytorch, the shape is in pytorch, channel-first convention (c, h, w).
# We can compare this shape with the information available for that feature
pprint(dataset.features[camera_key])
# In particular:
print(dataset.features[camera_key]["shape"])
# The shape is in (h, w, c) which is a more universal format.
# For many machine learning applications we need to load the history of past observations or trajectories of
# future actions. Our datasets can load previous and future frames for each key/modality, using timestamps
# differences with the current loaded frame. For instance:
delta_timestamps = {
# loads 4 images: 1 second before current frame, 500 ms before, 200 ms before, and current frame
camera_key: [-1, -0.5, -0.20, 0],
# loads 6 state vectors: 1.5 seconds before, 1 second before, ... 200 ms, 100 ms, and current frame
"observation.state": [-1.5, -1, -0.5, -0.20, -0.10, 0],
# loads 64 action vectors: current frame, 1 frame in the future, 2 frames, ... 63 frames in the future
"action": [t / dataset.fps for t in range(64)],
}
# Note that in any case, these delta_timestamps values need to be multiples of (1/fps) so that added to any
# timestamp, you still get a valid timestamp.
# For many machine learning applications we need to load the history of past observations or trajectories of
# future actions. Our datasets can load previous and future frames for each key/modality, using timestamps
# differences with the current loaded frame. For instance:
delta_timestamps = {
# loads 4 images: 1 second before current frame, 500 ms before, 200 ms before, and current frame
camera_key: [-1, -0.5, -0.20, 0],
# loads 6 state vectors: 1.5 seconds before, 1 second before, ... 200 ms, 100 ms, and current frame
"observation.state": [-1.5, -1, -0.5, -0.20, -0.10, 0],
# loads 64 action vectors: current frame, 1 frame in the future, 2 frames, ... 63 frames in the future
"action": [t / dataset.fps for t in range(64)],
}
# Note that in any case, these delta_timestamps values need to be multiples of (1/fps) so that added to any
# timestamp, you still get a valid timestamp.
dataset = LeRobotDataset(repo_id, delta_timestamps=delta_timestamps)
print(f"\n{dataset[0][camera_key].shape=}") # (4, c, h, w)
print(f"{dataset[0]['observation.state'].shape=}") # (6, c)
print(f"{dataset[0]['action'].shape=}\n") # (64, c)
dataset = LeRobotDataset(repo_id, delta_timestamps=delta_timestamps)
print(f"\n{dataset[0][camera_key].shape=}") # (4, c, h, w)
print(f"{dataset[0]['observation.state'].shape=}") # (6, c)
print(f"{dataset[0]['action'].shape=}\n") # (64, c)
if __name__ == "__main__":
dataloader = torch.utils.data.DataLoader(
dataset,
num_workers=4,
@@ -145,7 +144,3 @@ def main():
print(f"{batch['observation.state'].shape=}") # (32, 6, c)
print(f"{batch['action'].shape=}") # (32, 64, c)
break
if __name__ == "__main__":
main()
examples/lekiwi/evaluate.py
+80 -86
View File
@@ -33,68 +33,83 @@ TASK_DESCRIPTION = "My task description"
HF_MODEL_ID = "<hf_username>/<model_repo_id>"
HF_DATASET_ID = "<hf_username>/<eval_dataset_repo_id>"
# Create the robot configuration & robot
robot_config = LeKiwiClientConfig(remote_ip="172.18.134.136", id="lekiwi")
def main():
# Create the robot configuration & robot
robot_config = LeKiwiClientConfig(remote_ip="172.18.134.136", id="lekiwi")
robot = LeKiwiClient(robot_config)
robot = LeKiwiClient(robot_config)
# Create policy
policy = ACTPolicy.from_pretrained(HF_MODEL_ID)
# Create policy
policy = ACTPolicy.from_pretrained(HF_MODEL_ID)
# Configure the dataset features
action_features = hw_to_dataset_features(robot.action_features, ACTION)
obs_features = hw_to_dataset_features(robot.observation_features, OBS_STR)
dataset_features = {**action_features, **obs_features}
# Configure the dataset features
action_features = hw_to_dataset_features(robot.action_features, ACTION)
obs_features = hw_to_dataset_features(robot.observation_features, OBS_STR)
dataset_features = {**action_features, **obs_features}
# Create the dataset
dataset = LeRobotDataset.create(
repo_id=HF_DATASET_ID,
fps=FPS,
features=dataset_features,
robot_type=robot.name,
use_videos=True,
image_writer_threads=4,
)
# Create the dataset
dataset = LeRobotDataset.create(
repo_id=HF_DATASET_ID,
# Build Policy Processors
preprocessor, postprocessor = make_pre_post_processors(
policy_cfg=policy,
pretrained_path=HF_MODEL_ID,
dataset_stats=dataset.meta.stats,
# The inference device is automatically set to match the detected hardware, overriding any previous device settings from training to ensure compatibility.
preprocessor_overrides={"device_processor": {"device": str(policy.config.device)}},
)
# Connect the robot
# To connect you already should have this script running on LeKiwi: `python -m lerobot.robots.lekiwi.lekiwi_host --robot.id=my_awesome_kiwi`
robot.connect()
# TODO(Steven): Update this example to use pipelines
teleop_action_processor, robot_action_processor, robot_observation_processor = make_default_processors()
# Initialize the keyboard listener and rerun visualization
listener, events = init_keyboard_listener()
init_rerun(session_name="lekiwi_evaluate")
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}")
# Main record loop
record_loop(
robot=robot,
events=events,
fps=FPS,
features=dataset_features,
robot_type=robot.name,
use_videos=True,
image_writer_threads=4,
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,
)
# Build Policy Processors
preprocessor, postprocessor = make_pre_post_processors(
policy_cfg=policy,
pretrained_path=HF_MODEL_ID,
dataset_stats=dataset.meta.stats,
# The inference device is automatically set to match the detected hardware, overriding any previous device settings from training to ensure compatibility.
preprocessor_overrides={"device_processor": {"device": str(policy.config.device)}},
)
# Connect the robot
# To connect you already should have this script running on LeKiwi: `python -m lerobot.robots.lekiwi.lekiwi_host --robot.id=my_awesome_kiwi`
robot.connect()
# TODO(Steven): Update this example to use pipelines
teleop_action_processor, robot_action_processor, robot_observation_processor = make_default_processors()
# Initialize the keyboard listener and rerun visualization
listener, events = init_keyboard_listener()
init_rerun(session_name="lekiwi_evaluate")
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}")
# Main record loop
# 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,
@@ -103,42 +118,21 @@ 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()
# Clean up
log_say("Stop recording")
robot.disconnect()
listener.stop()
dataset.finalize()
dataset.push_to_hub()
if __name__ == "__main__":
main()
dataset.finalize()
dataset.push_to_hub()
examples/lekiwi/record.py
+76 -82
View File
@@ -34,62 +34,78 @@ RESET_TIME_SEC = 10
TASK_DESCRIPTION = "My task description"
HF_REPO_ID = "<hf_username>/<dataset_repo_id>"
# Create the robot and teleoperator configurations
robot_config = LeKiwiClientConfig(remote_ip="172.18.134.136", id="lekiwi")
leader_arm_config = SO100LeaderConfig(port="/dev/tty.usbmodem585A0077581", id="my_awesome_leader_arm")
keyboard_config = KeyboardTeleopConfig()
def main():
# Create the robot and teleoperator configurations
robot_config = LeKiwiClientConfig(remote_ip="172.18.134.136", id="lekiwi")
leader_arm_config = SO100LeaderConfig(port="/dev/tty.usbmodem585A0077581", id="my_awesome_leader_arm")
keyboard_config = KeyboardTeleopConfig()
# Initialize the robot and teleoperator
robot = LeKiwiClient(robot_config)
leader_arm = SO100Leader(leader_arm_config)
keyboard = KeyboardTeleop(keyboard_config)
# Initialize the robot and teleoperator
robot = LeKiwiClient(robot_config)
leader_arm = SO100Leader(leader_arm_config)
keyboard = KeyboardTeleop(keyboard_config)
# TODO(Steven): Update this example to use pipelines
teleop_action_processor, robot_action_processor, robot_observation_processor = make_default_processors()
# TODO(Steven): Update this example to use pipelines
teleop_action_processor, robot_action_processor, robot_observation_processor = make_default_processors()
# Configure the dataset features
action_features = hw_to_dataset_features(robot.action_features, ACTION)
obs_features = hw_to_dataset_features(robot.observation_features, OBS_STR)
dataset_features = {**action_features, **obs_features}
# Configure the dataset features
action_features = hw_to_dataset_features(robot.action_features, ACTION)
obs_features = hw_to_dataset_features(robot.observation_features, OBS_STR)
dataset_features = {**action_features, **obs_features}
# Create the dataset
dataset = LeRobotDataset.create(
repo_id=HF_REPO_ID,
fps=FPS,
features=dataset_features,
robot_type=robot.name,
use_videos=True,
image_writer_threads=4,
)
# Create the dataset
dataset = LeRobotDataset.create(
repo_id=HF_REPO_ID,
# Connect the robot and teleoperator
# To connect you already should have this script running on LeKiwi: `python -m lerobot.robots.lekiwi.lekiwi_host --robot.id=my_awesome_kiwi`
robot.connect()
leader_arm.connect()
keyboard.connect()
# Initialize the keyboard listener and rerun visualization
listener, events = init_keyboard_listener()
init_rerun(session_name="lekiwi_record")
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}")
# Main record loop
record_loop(
robot=robot,
events=events,
fps=FPS,
features=dataset_features,
robot_type=robot.name,
use_videos=True,
image_writer_threads=4,
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,
)
# Connect the robot and teleoperator
# To connect you already should have this script running on LeKiwi: `python -m lerobot.robots.lekiwi.lekiwi_host --robot.id=my_awesome_kiwi`
robot.connect()
leader_arm.connect()
keyboard.connect()
# Initialize the keyboard listener and rerun visualization
listener, events = init_keyboard_listener()
init_rerun(session_name="lekiwi_record")
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}")
# Main record loop
# 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,
@@ -97,45 +113,23 @@ 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
# 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()
if __name__ == "__main__":
main()
dataset.finalize()
dataset.push_to_hub()
examples/lekiwi/replay.py
+26 -32
View File
@@ -20,48 +20,42 @@ from lerobot.datasets.lerobot_dataset import LeRobotDataset
from lerobot.robots.lekiwi.config_lekiwi import LeKiwiClientConfig
from lerobot.robots.lekiwi.lekiwi_client import LeKiwiClient
from lerobot.utils.constants import ACTION
from lerobot.utils.robot_utils import precise_sleep
from lerobot.utils.robot_utils import busy_wait
from lerobot.utils.utils import log_say
EPISODE_IDX = 0
# Initialize the robot config
robot_config = LeKiwiClientConfig(remote_ip="172.18.134.136", id="lekiwi")
def main():
# Initialize the robot config
robot_config = LeKiwiClientConfig(remote_ip="172.18.134.136", id="lekiwi")
# Initialize the robot
robot = LeKiwiClient(robot_config)
# Initialize the robot
robot = LeKiwiClient(robot_config)
# Fetch the dataset to replay
dataset = LeRobotDataset("<hf_username>/<dataset_repo_id>", episodes=[EPISODE_IDX])
# Filter dataset to only include frames from the specified episode since episodes are chunked in dataset V3.0
episode_frames = dataset.hf_dataset.filter(lambda x: x["episode_index"] == EPISODE_IDX)
actions = episode_frames.select_columns(ACTION)
# Fetch the dataset to replay
dataset = LeRobotDataset("<hf_username>/<dataset_repo_id>", episodes=[EPISODE_IDX])
# Filter dataset to only include frames from the specified episode since episodes are chunked in dataset V3.0
episode_frames = dataset.hf_dataset.filter(lambda x: x["episode_index"] == EPISODE_IDX)
actions = episode_frames.select_columns(ACTION)
# Connect to the robot
robot.connect()
# Connect to the robot
robot.connect()
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)
busy_wait(max(1.0 / dataset.fps - (time.perf_counter() - t0), 0.0))
precise_sleep(max(1.0 / dataset.fps - (time.perf_counter() - t0), 0.0))
robot.disconnect()
if __name__ == "__main__":
main()
robot.disconnect()
examples/lekiwi/teleoperate.py
+36 -42
View File
@@ -19,60 +19,54 @@ import time
from lerobot.robots.lekiwi import LeKiwiClient, LeKiwiClientConfig
from lerobot.teleoperators.keyboard.teleop_keyboard import KeyboardTeleop, KeyboardTeleopConfig
from lerobot.teleoperators.so100_leader import SO100Leader, SO100LeaderConfig
from lerobot.utils.robot_utils import precise_sleep
from lerobot.utils.robot_utils import busy_wait
from lerobot.utils.visualization_utils import init_rerun, log_rerun_data
FPS = 30
# Create the robot and teleoperator configurations
robot_config = LeKiwiClientConfig(remote_ip="172.18.134.136", id="my_lekiwi")
teleop_arm_config = SO100LeaderConfig(port="/dev/tty.usbmodem585A0077581", id="my_awesome_leader_arm")
keyboard_config = KeyboardTeleopConfig(id="my_laptop_keyboard")
def main():
# Create the robot and teleoperator configurations
robot_config = LeKiwiClientConfig(remote_ip="172.18.134.136", id="my_lekiwi")
teleop_arm_config = SO100LeaderConfig(port="/dev/tty.usbmodem585A0077581", id="my_awesome_leader_arm")
keyboard_config = KeyboardTeleopConfig(id="my_laptop_keyboard")
# Initialize the robot and teleoperator
robot = LeKiwiClient(robot_config)
leader_arm = SO100Leader(teleop_arm_config)
keyboard = KeyboardTeleop(keyboard_config)
# Initialize the robot and teleoperator
robot = LeKiwiClient(robot_config)
leader_arm = SO100Leader(teleop_arm_config)
keyboard = KeyboardTeleop(keyboard_config)
# Connect to the robot and teleoperator
# To connect you already should have this script running on LeKiwi: `python -m lerobot.robots.lekiwi.lekiwi_host --robot.id=my_awesome_kiwi`
robot.connect()
leader_arm.connect()
keyboard.connect()
# Connect to the robot and teleoperator
# To connect you already should have this script running on LeKiwi: `python -m lerobot.robots.lekiwi.lekiwi_host --robot.id=my_awesome_kiwi`
robot.connect()
leader_arm.connect()
keyboard.connect()
# Init rerun viewer
init_rerun(session_name="lekiwi_teleop")
# Init rerun viewer
init_rerun(session_name="lekiwi_teleop")
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 teleop loop...")
while True:
t0 = time.perf_counter()
print("Starting teleop loop...")
while True:
t0 = time.perf_counter()
# Get robot observation
observation = robot.get_observation()
# Get robot observation
observation = robot.get_observation()
# Get teleop action
# Arm
arm_action = leader_arm.get_action()
arm_action = {f"arm_{k}": v for k, v in arm_action.items()}
# Keyboard
keyboard_keys = keyboard.get_action()
base_action = robot._from_keyboard_to_base_action(keyboard_keys)
# Get teleop action
# Arm
arm_action = leader_arm.get_action()
arm_action = {f"arm_{k}": v for k, v in arm_action.items()}
# Keyboard
keyboard_keys = keyboard.get_action()
base_action = robot._from_keyboard_to_base_action(keyboard_keys)
action = {**arm_action, **base_action} if len(base_action) > 0 else arm_action
action = {**arm_action, **base_action} if len(base_action) > 0 else arm_action
# Send action to robot
_ = robot.send_action(action)
# Send action to robot
_ = robot.send_action(action)
# Visualize
log_rerun_data(observation=observation, action=action)
# Visualize
log_rerun_data(observation=observation, action=action)
precise_sleep(max(1.0 / FPS - (time.perf_counter() - t0), 0.0))
if __name__ == "__main__":
main()
busy_wait(max(1.0 / FPS - (time.perf_counter() - t0), 0.0))
examples/openarms/debug_can_communication.py
-416
View File
@@ -1,416 +0,0 @@
#!/usr/bin/env python3
"""
Comprehensive debug script for OpenArms CAN FD communication.
Tests all 4 CAN interfaces with CAN FD support.
"""
import can
import time
import sys
import subprocess
def check_can_interface(port):
"""Check if CAN interface is UP and configured."""
try:
result = subprocess.run(['ip', 'link', 'show', port],
capture_output=True, text=True)
if result.returncode != 0:
return False, "Interface not found", None
output = result.stdout
if 'UP' not in output:
return False, "Interface is DOWN", None
# Check if CAN FD is enabled
is_fd = 'fd on' in output.lower() or 'canfd' in output.lower()
return True, "Interface is UP", is_fd
except FileNotFoundError:
return None, "Cannot check (ip command not found)", None
def test_motor_on_interface(bus, motor_id, timeout=2.0, use_fd=False):
"""
Test a single motor and return all responses.
Returns:
list of (arbitration_id, data) tuples for all responses received
"""
# Send enable command
enable_msg = can.Message(
arbitration_id=motor_id,
data=[0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFC],
is_extended_id=False,
is_fd=use_fd
)
try:
bus.send(enable_msg)
except Exception as e:
return None, f"Send error: {e}"
# Listen for responses
responses = []
start_time = time.time()
while time.time() - start_time < timeout:
msg = bus.recv(timeout=0.1)
if msg:
responses.append((msg.arbitration_id, msg.data, msg.is_fd if hasattr(msg, 'is_fd') else False))
# Send disable command
disable_msg = can.Message(
arbitration_id=motor_id,
data=[0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFD],
is_extended_id=False,
is_fd=use_fd
)
try:
bus.send(disable_msg)
except:
pass
return responses, None
def test_interface(port, interface_type="socketcan", use_can_fd=True):
"""Test all 8 motors on a single CAN interface."""
results = {
'interface': port,
'status': None,
'is_fd': use_can_fd,
'motors': {}
}
# Check interface status
status_ok, status_msg, interface_has_fd = check_can_interface(port)
if interface_has_fd is not None:
results['interface_fd_enabled'] = interface_has_fd
if use_can_fd and not interface_has_fd:
status_msg += " (CAN FD NOT enabled on interface!)"
elif interface_has_fd:
status_msg += " (CAN FD enabled)"
results['status'] = status_msg
if status_ok is False:
return results
# Try to connect
try:
if use_can_fd:
print(f" Connecting to {port} with CAN FD (1 Mbps / 5 Mbps)...")
bus = can.interface.Bus(
channel=port,
interface=interface_type,
bitrate=1000000,
data_bitrate=5000000,
fd=True
)
else:
print(f" Connecting to {port} with CAN 2.0 (1 Mbps)...")
bus = can.interface.Bus(
channel=port,
interface=interface_type,
bitrate=1000000
)
except Exception as e:
results['status'] = f"Connection failed: {e}"
return results
try:
# Clear any pending messages
while bus.recv(timeout=0.01):
pass
# Test each motor (0x01 to 0x08)
for motor_id in range(0x01, 0x09):
responses, error = test_motor_on_interface(bus, motor_id, timeout=1.0, use_fd=use_can_fd)
if error:
results['motors'][motor_id] = {'error': error}
elif responses:
results['motors'][motor_id] = {
'found': True,
'responses': responses
}
else:
results['motors'][motor_id] = {
'found': False,
'responses': []
}
time.sleep(0.05) # Small delay between motors
finally:
bus.shutdown()
return results
def print_results(all_results):
"""Print formatted results for all interfaces."""
print("SUMMARY - Motors Found on Each Interface")
motor_names = {
0x01: "joint_1 (Shoulder pan)",
0x02: "joint_2 (Shoulder lift)",
0x03: "joint_3 (Shoulder rotation)",
0x04: "joint_4 (Elbow flex)",
0x05: "joint_5 (Wrist roll)",
0x06: "joint_6 (Wrist pitch)",
0x07: "joint_7 (Wrist rotation)",
0x08: "gripper",
}
total_found = 0
for result in all_results:
interface = result['interface']
status = result['status']
print(f"{interface}: {status}")
if result.get('is_fd'):
print(f" Mode: CAN FD")
else:
print(f" Mode: CAN 2.0")
if 'Connection failed' in status or 'DOWN' in status:
print(f" ⚠ Cannot test {interface}")
continue
motors_found = 0
for motor_id in range(0x01, 0x09):
motor_data = result['motors'].get(motor_id, {})
motor_name = motor_names.get(motor_id, "Unknown")
if motor_data.get('error'):
print(f" Motor 0x{motor_id:02X} ({motor_name}): ✗ {motor_data['error']}")
elif motor_data.get('found'):
motors_found += 1
total_found += 1
responses = motor_data['responses']
print(f" Motor 0x{motor_id:02X} ({motor_name}): ✓ FOUND")
for resp_id, data, is_fd in responses:
data_hex = data.hex()
fd_flag = " [FD]" if is_fd else " [2.0]"
print(f" → Response from 0x{resp_id:02X}{fd_flag}: {data_hex}")
else:
print(f" Motor 0x{motor_id:02X} ({motor_name}): ✗ No response")
print(f"\n Summary: {motors_found}/8 motors found on {interface}")
# Overall summary
print("OVERALL SUMMARY")
print(f"Total motors found across all interfaces: {total_found}")
# Analyze configuration
print("DIAGNOSIS")
for result in all_results:
interface = result['interface']
motors_found = sum(1 for m in result['motors'].values() if m.get('found'))
if motors_found == 0:
print(f"\n{interface}: NO MOTORS FOUND")
print(" Possible issues:")
print(" 1. CAN FD mode mismatch (interface vs motor configuration)")
print(" 2. Missing 120Ω termination resistors at BOTH cable ends")
print(" 3. Motor timeout parameter set incorrectly (should NOT be 0)")
print(" 4. CANH/CANL wiring issue")
print(" 5. Cable too long (>40m for CAN FD at 5Mbps)")
# Check FD mismatch
if result.get('is_fd') and not result.get('interface_fd_enabled'):
print(" ⚠️ CRITICAL: Trying CAN FD but interface NOT configured for FD!")
print(f" Fix: sudo ip link set {interface} type can bitrate 1000000 dbitrate 5000000 fd on")
elif motors_found < 8:
print(f"\n{interface}: Only {motors_found}/8 motors responding")
print(" Check power and connections for missing motors")
else:
print(f"\n{interface}: All 8 motors responding correctly!")
# Check for unexpected response IDs
print("RESPONSE ID ANALYSIS")
for result in all_results:
interface = result['interface']
unexpected = []
for motor_id, motor_data in result['motors'].items():
if motor_data.get('found'):
expected_id = motor_id + 0x10
actual_ids = [resp[0] for resp in motor_data['responses']]
if expected_id not in actual_ids:
unexpected.append((motor_id, actual_ids))
if unexpected:
print(f"\n{interface}: Unexpected response IDs detected")
for motor_id, actual_ids in unexpected:
expected_id = motor_id + 0x10
print(f" Motor 0x{motor_id:02X}: Expected 0x{expected_id:02X}, "
f"got {[f'0x{id:02X}' for id in actual_ids]}")
print(" → Motor Master IDs need reconfiguration")
else:
motors_found = sum(1 for m in result['motors'].values() if m.get('found'))
if motors_found > 0:
print(f"\n{interface}: All responding motors use correct IDs")
def test_communication_speed(interface, motor_id, num_iterations=100):
"""
Test communication speed with a motor.
Returns:
tuple: (hz, avg_latency_ms) or (None, None) if test failed
"""
try:
# Connect to interface
bus = can.interface.Bus(
channel=interface,
interface="socketcan",
bitrate=1000000,
data_bitrate=5000000,
fd=True
)
# Send refresh commands and measure round-trip time
latencies = []
successful = 0
for _ in range(num_iterations):
start = time.perf_counter()
# Send enable command (lightweight operation)
enable_msg = can.Message(
arbitration_id=motor_id,
data=[0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFF, 0xFC],
is_extended_id=False,
is_fd=True
)
bus.send(enable_msg)
# Wait for response
msg = bus.recv(timeout=0.1)
if msg:
latency = (time.perf_counter() - start) * 1000 # Convert to ms
latencies.append(latency)
successful += 1
bus.shutdown()
if successful > 0:
avg_latency = sum(latencies) / len(latencies)
hz = 1000.0 / avg_latency if avg_latency > 0 else 0
return hz, avg_latency
return None, None
except Exception as e:
print(f" Speed test error: {e}")
return None, None
def main():
"""Main function to test all CAN interfaces with CAN FD."""
print("\nThis will test all 4 CAN interfaces (can0-can3) with CAN FD")
print("Testing motors 0x01-0x08 on each interface")
print()
print("Make sure:")
print(" ✓ Motors are powered (24V)")
print(" ✓ CAN interfaces configured with FD mode:")
print(" ./examples/openarms/setup_can.sh")
print(" ✓ Motor 'timeout' parameter NOT set to 0 (use Damiao tools)")
print(" ✓ CAN wiring includes 120Ω termination at BOTH ends")
print()
input("Press ENTER to start testing...")
# Test all 4 interfaces with CAN FD
all_results = []
for i in range(4):
interface = f"can{i}"
print(f"Testing {interface}...")
result = test_interface(interface, use_can_fd=True)
all_results.append(result)
# Quick status
if 'Connection failed' in result['status'] or 'DOWN' in result['status']:
print(f"{interface}: {result['status']}")
else:
motors_found = sum(1 for m in result['motors'].values() if m.get('found'))
print(f" {interface}: {motors_found}/8 motors found")
time.sleep(0.2)
# Print detailed results
print_results(all_results)
print("Testing Complete!")
all_found = sum(sum(1 for m in r['motors'].values() if m.get('found')) for r in all_results)
if all_found == 0:
print("\n⚠️ CRITICAL: No motors found on any interface!")
print("\nTop issues to check:")
print(" 1. Motor 'timeout' parameter (use Damiao tools to set > 0)")
print(" 2. CAN FD not enabled (run ./examples/openarms/setup_can.sh)")
print(" 3. Missing termination resistors")
print("\nTry:")
print(" a) Check motor parameters with Damiao Debugging Tools")
print(" b) Verify CAN FD is enabled: ip -d link show can0 | grep fd")
print(" c) Run setup script: ./examples/openarms/setup_can.sh")
else:
# Run speed test on interfaces with motors
print("COMMUNICATION SPEED TEST")
print("\nTesting maximum communication frequency...")
for result in all_results:
interface = result['interface']
# Find first responding motor
responding_motor = None
for motor_id, motor_data in result['motors'].items():
if motor_data.get('found'):
responding_motor = motor_id
break
if responding_motor:
print(f"\n{interface}: Testing with motor 0x{responding_motor:02X}...")
hz, latency = test_communication_speed(interface, responding_motor, num_iterations=100)
if hz:
print(f" ✓ Max frequency: {hz:.1f} Hz")
print(f" ✓ Avg latency: {latency:.2f} ms")
print(f" ✓ Commands per second: ~{int(hz)}")
else:
print(f" ✗ Speed test failed")
else:
print(f"\n{interface}: No motors found, skipping speed test")
print()
if __name__ == "__main__":
try:
main()
except KeyboardInterrupt:
print("\n\nTesting interrupted by user.")
sys.exit(1)
except Exception as e:
print(f"\nUnexpected error: {e}")
import traceback
traceback.print_exc()
sys.exit(1)
examples/openarms/evaluate.py
-360
View File
@@ -1,360 +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.
"""
OpenArms Policy Evaluation
Evaluates a trained policy on the OpenArms robot by running inference and recording
the evaluation episodes to a dataset. Supports optional leader arm for manual resets.
Example usage:
python examples/openarms/evaluate.py
"""
import time
from pathlib import Path
from lerobot.cameras.opencv.configuration_opencv import OpenCVCameraConfig
from lerobot.configs.policies import PreTrainedConfig
from lerobot.datasets.lerobot_dataset import LeRobotDataset
from lerobot.datasets.pipeline_features import aggregate_pipeline_dataset_features, create_initial_features
from lerobot.datasets.utils import combine_feature_dicts
from lerobot.policies.factory import make_policy, make_pre_post_processors
from lerobot.processor import make_default_processors
from lerobot.robots.openarms.config_openarms_follower import OpenArmsFollowerConfig
from lerobot.robots.openarms.openarms_follower import OpenArmsFollower
from lerobot.scripts.lerobot_record import record_loop
from lerobot.teleoperators.openarms.config_openarms_leader import OpenArmsLeaderConfig
from lerobot.teleoperators.openarms.openarms_leader import OpenArmsLeader
from lerobot.utils.control_utils import init_keyboard_listener
from lerobot.utils.utils import log_say
from lerobot.utils.visualization_utils import init_rerun
HF_MODEL_ID = "lerobot-data-collection/three-folds-pi0" # TODO: Replace with your trained model
HF_EVAL_DATASET_ID = "lerobot-data-collection/three-folds-pi0_eval7" # TODO: Replace with your eval dataset name
TASK_DESCRIPTION = "three-folds-dataset" # TODO: Replace with your task, this should match!!
NUM_EPISODES = 1
FPS = 30
EPISODE_TIME_SEC = 300
RESET_TIME_SEC = 60
# Robot CAN interfaces
FOLLOWER_LEFT_PORT = "can0"
FOLLOWER_RIGHT_PORT = "can1"
# If enabled, you can manually reset the environment between evaluation episodes
USE_LEADER_FOR_RESETS = True # Set to False if you don't want to use leader
LEADER_LEFT_PORT = "can2"
LEADER_RIGHT_PORT = "can3"
# Camera configuration
CAMERA_CONFIG = {
"left_wrist": OpenCVCameraConfig(index_or_path="/dev/video5", width=640, height=480, fps=FPS),
"right_wrist": OpenCVCameraConfig(index_or_path="/dev/video1", width=640, height=480, fps=FPS),
"base": OpenCVCameraConfig(index_or_path="/dev/video3", width=640, height=480, fps=FPS),
}
def main():
"""Main evaluation function."""
print("OpenArms Policy Evaluation")
print(f"\nModel: {HF_MODEL_ID}")
print(f"Evaluation Dataset: {HF_EVAL_DATASET_ID}")
print(f"Task: {TASK_DESCRIPTION}")
print(f"Episodes: {NUM_EPISODES}")
print(f"Episode Duration: {EPISODE_TIME_SEC}s")
print(f"Reset Duration: {RESET_TIME_SEC}s")
print(f"Use Leader for Resets: {USE_LEADER_FOR_RESETS}")
follower_config = OpenArmsFollowerConfig(
port_left=FOLLOWER_LEFT_PORT,
port_right=FOLLOWER_RIGHT_PORT,
can_interface="socketcan",
id="openarms_follower",
disable_torque_on_disconnect=True,
max_relative_target=10.0,
cameras=CAMERA_CONFIG,
)
follower = OpenArmsFollower(follower_config)
follower.connect(calibrate=False)
if not follower.is_connected:
raise RuntimeError("Follower robot failed to connect!")
leader = None
if USE_LEADER_FOR_RESETS:
leader_config = OpenArmsLeaderConfig(
port_left=LEADER_LEFT_PORT,
port_right=LEADER_RIGHT_PORT,
can_interface="socketcan",
id="openarms_leader",
manual_control=False, # Enable torque control for gravity compensation
)
leader = OpenArmsLeader(leader_config)
leader.connect(calibrate=False)
if not leader.is_connected:
raise RuntimeError("Leader robot failed to connect!")
# Enable gravity compensation
if leader.pin_robot is not None:
leader.bus_right.enable_torque()
leader.bus_left.enable_torque()
time.sleep(0.1)
print(f"Leader connected with gravity compensation ({LEADER_LEFT_PORT}, {LEADER_RIGHT_PORT})")
else:
print(f"Leader connected but gravity compensation unavailable (no URDF)")
# Build default processors for action and observation
teleop_action_processor, robot_action_processor, robot_observation_processor = make_default_processors()
# Build dataset features from robot features and processors
# For actions, only include positions (no velocity or torque)
action_features_hw = {}
for key, value in follower.action_features.items():
if key.endswith(".pos"):
action_features_hw[key] = value
dataset_features = combine_feature_dicts(
aggregate_pipeline_dataset_features(
pipeline=teleop_action_processor,
initial_features=create_initial_features(action=action_features_hw),
use_videos=True,
),
aggregate_pipeline_dataset_features(
pipeline=robot_observation_processor,
initial_features=create_initial_features(observation=follower.observation_features),
use_videos=True,
),
)
# Check if dataset already exists
dataset_path = Path.home() / ".cache" / "huggingface" / "lerobot" / HF_EVAL_DATASET_ID
if dataset_path.exists():
print(f"Evaluation dataset already exists at: {dataset_path}")
print("This will append new episodes to the existing dataset.")
choice = input(" Continue? (y/n): ").strip().lower()
if choice != 'y':
print(" Aborting evaluation.")
follower.disconnect()
if leader:
leader.disconnect()
return
# Create dataset
dataset = LeRobotDataset.create(
repo_id=HF_EVAL_DATASET_ID,
fps=FPS,
features=dataset_features,
robot_type=follower.name,
use_videos=True,
image_writer_processes=0,
image_writer_threads=12,
)
# Load policy config from pretrained model and create policy using factory
policy_config = PreTrainedConfig.from_pretrained(HF_MODEL_ID)
policy_config.pretrained_path = HF_MODEL_ID
policy = make_policy(policy_config, ds_meta=dataset.meta)
preprocessor, postprocessor = make_pre_post_processors(
policy_cfg=policy.config,
pretrained_path=HF_MODEL_ID,
dataset_stats=dataset.meta.stats,
preprocessor_overrides={
"device_processor": {"device": str(policy.config.device)}
},
)
print(f"\nRunning evaluation...")
# Initialize keyboard listener and visualization
listener, events = init_keyboard_listener()
init_rerun(session_name="openarms_evaluation")
episode_idx = 0
try:
while episode_idx < NUM_EPISODES and not events["stop_recording"]:
log_say(f"Evaluating episode {episode_idx + 1} of {NUM_EPISODES}")
print(f"\nRunning inference for episode {episode_idx + 1}...")
# Run inference with policy
record_loop(
robot=follower,
events=events,
fps=FPS,
teleop_action_processor=teleop_action_processor,
robot_action_processor=robot_action_processor,
robot_observation_processor=robot_observation_processor,
policy=policy,
preprocessor=preprocessor,
postprocessor=postprocessor,
dataset=dataset,
control_time_s=EPISODE_TIME_SEC,
single_task=TASK_DESCRIPTION,
display_data=True,
)
# Handle re-recording
if events["rerecord_episode"]:
log_say("Re-recording episode")
events["rerecord_episode"] = False
events["exit_early"] = False
dataset.clear_episode_buffer()
continue
# Save episode
if dataset.episode_buffer is not None and dataset.episode_buffer.get("size", 0) > 0:
print(f"Saving episode {episode_idx + 1} ({dataset.episode_buffer['size']} frames)...")
dataset.save_episode()
episode_idx += 1
# Reset environment between episodes (if not last episode)
if not events["stop_recording"] and episode_idx < NUM_EPISODES:
if USE_LEADER_FOR_RESETS and leader:
log_say("Reset the environment using leader arms")
print(f"\nManual reset period ({RESET_TIME_SEC}s)...")
# Use leader for manual reset with gravity compensation
import numpy as np
dt = 1 / FPS
reset_start_time = time.perf_counter()
while time.perf_counter() - reset_start_time < RESET_TIME_SEC:
if events["exit_early"] or events["stop_recording"]:
break
loop_start = time.perf_counter()
# Get leader state
leader_action = leader.get_action()
# Extract positions and velocities
leader_positions_deg = {}
leader_velocities_deg_per_sec = {}
for motor in leader.bus_right.motors:
pos_key = f"right_{motor}.pos"
vel_key = f"right_{motor}.vel"
if pos_key in leader_action:
leader_positions_deg[f"right_{motor}"] = leader_action[pos_key]
if vel_key in leader_action:
leader_velocities_deg_per_sec[f"right_{motor}"] = leader_action[vel_key]
for motor in leader.bus_left.motors:
pos_key = f"left_{motor}.pos"
vel_key = f"left_{motor}.vel"
if pos_key in leader_action:
leader_positions_deg[f"left_{motor}"] = leader_action[pos_key]
if vel_key in leader_action:
leader_velocities_deg_per_sec[f"left_{motor}"] = leader_action[vel_key]
# Calculate gravity and friction torques
leader_positions_rad = {k: np.deg2rad(v) for k, v in leader_positions_deg.items()}
leader_gravity_torques_nm = leader._gravity_from_q(leader_positions_rad)
leader_velocities_rad_per_sec = {k: np.deg2rad(v) for k, v in leader_velocities_deg_per_sec.items()}
leader_friction_torques_nm = leader._friction_from_velocity(
leader_velocities_rad_per_sec,
friction_scale=1.0
)
# Combine torques
leader_total_torques_nm = {}
for motor_name in leader_gravity_torques_nm:
gravity = leader_gravity_torques_nm.get(motor_name, 0.0)
friction = leader_friction_torques_nm.get(motor_name, 0.0)
leader_total_torques_nm[motor_name] = gravity + friction
# Apply compensation
for motor in leader.bus_right.motors:
full_name = f"right_{motor}"
position = leader_positions_deg.get(full_name, 0.0)
torque = leader_total_torques_nm.get(full_name, 0.0)
kd = leader.get_damping_kd(motor)
leader.bus_right._mit_control(
motor=motor, kp=0.0, kd=kd,
position_degrees=position,
velocity_deg_per_sec=0.0,
torque=torque,
)
for motor in leader.bus_left.motors:
full_name = f"left_{motor}"
position = leader_positions_deg.get(full_name, 0.0)
torque = leader_total_torques_nm.get(full_name, 0.0)
kd = leader.get_damping_kd(motor)
leader.bus_left._mit_control(
motor=motor, kp=0.0, kd=kd,
position_degrees=position,
velocity_deg_per_sec=0.0,
torque=torque,
)
# Send leader positions to follower
follower_action = {}
for joint in leader_positions_deg.keys():
pos_key = f"{joint}.pos"
if pos_key in leader_action:
follower_action[pos_key] = leader_action[pos_key]
if follower_action:
follower.send_action(follower_action)
# Maintain loop rate
loop_duration = time.perf_counter() - loop_start
sleep_time = dt - loop_duration
if sleep_time > 0:
time.sleep(sleep_time)
print("Reset complete")
else:
log_say("Waiting for manual reset")
print(f"Manually reset the environment and press ENTER to continue")
input("Press ENTER when ready...")
print(f"Evaluation complete! {episode_idx} episodes recorded")
log_say("Evaluation complete", blocking=True)
except KeyboardInterrupt:
print("\n\nEvaluation interrupted by user")
finally:
if leader:
leader.bus_right.disable_torque()
leader.bus_left.disable_torque()
time.sleep(0.1)
leader.disconnect()
follower.disconnect()
if listener is not None:
listener.stop()
dataset.finalize()
print("\nUploading to Hugging Face Hub...")
dataset.push_to_hub(private=True)
if __name__ == "__main__":
main()
examples/openarms/evaluate_with_rtc.py
-653
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@@ -1,653 +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.
"""
OpenArms Policy Evaluation with Real-Time Chunking (RTC)
Evaluates a trained policy on the OpenArms robot using RTC for smooth, continuous motion.
RTC enables large flow-matching policies (Pi0, Pi0.5, SmolVLA) to produce reactive motion
despite high inference latency by asynchronously generating action chunks.
Features:
- Thread-based asynchronous action generation and execution
- RTC for smooth transitions between action chunks
- Dataset recording for evaluation episodes
Example usage:
python examples/openarms/evaluate_with_rtc.py
# With custom RTC parameters
python examples/openarms/evaluate_with_rtc.py \
--rtc.execution_horizon=12 \
--rtc.max_guidance_weight=10.0
"""
import logging
import math
import sys
import time
import traceback
from dataclasses import dataclass, field
from pathlib import Path
from threading import Event, Lock, Thread
import torch
from torch import Tensor
from lerobot.cameras.opencv.configuration_opencv import OpenCVCameraConfig
from lerobot.configs import parser
from lerobot.configs.policies import PreTrainedConfig
from lerobot.configs.types import RTCAttentionSchedule
from lerobot.datasets.lerobot_dataset import LeRobotDataset
from lerobot.datasets.pipeline_features import aggregate_pipeline_dataset_features, create_initial_features
from lerobot.datasets.utils import build_dataset_frame, combine_feature_dicts, hw_to_dataset_features
from lerobot.policies.factory import get_policy_class, make_pre_post_processors
from lerobot.policies.rtc.action_queue import ActionQueue
from lerobot.policies.rtc.configuration_rtc import RTCConfig
from lerobot.policies.rtc.latency_tracker import LatencyTracker
from lerobot.processor import make_default_processors
from lerobot.rl.process import ProcessSignalHandler
from lerobot.robots.openarms.config_openarms_follower import OpenArmsFollowerConfig
from lerobot.robots.openarms.openarms_follower import OpenArmsFollower
from lerobot.utils.hub import HubMixin
from lerobot.utils.utils import init_logging, log_say
logging.basicConfig(level=logging.INFO)
logger = logging.getLogger(__name__)
# ============================================================================
# Default Configuration Constants
# ============================================================================
DEFAULT_HF_MODEL_ID = "lerobot-data-collection/three-folds-pi0"
DEFAULT_HF_EVAL_DATASET_ID = "lerobot-data-collection/three-folds-pi0_eval_rtc"
DEFAULT_TASK_DESCRIPTION = "three-folds-dataset"
DEFAULT_NUM_EPISODES = 1
DEFAULT_FPS = 30
DEFAULT_EPISODE_TIME_SEC = 300
DEFAULT_RESET_TIME_SEC = 60
DEFAULT_FOLLOWER_LEFT_PORT = "can0"
DEFAULT_FOLLOWER_RIGHT_PORT = "can1"
DEFAULT_CAMERA_CONFIG = {
"left_wrist": OpenCVCameraConfig(index_or_path="/dev/video5", width=640, height=480, fps=DEFAULT_FPS),
"right_wrist": OpenCVCameraConfig(index_or_path="/dev/video1", width=640, height=480, fps=DEFAULT_FPS),
"base": OpenCVCameraConfig(index_or_path="/dev/video3", width=640, height=480, fps=DEFAULT_FPS),
}
# ============================================================================
# Thread-Safe Robot Wrapper
# ============================================================================
class RobotWrapper:
"""Thread-safe wrapper for robot operations."""
def __init__(self, robot: OpenArmsFollower):
self.robot = robot
self.lock = Lock()
def get_observation(self) -> dict[str, Tensor]:
with self.lock:
return self.robot.get_observation()
def send_action(self, action: dict) -> None:
with self.lock:
self.robot.send_action(action)
@property
def observation_features(self) -> dict:
with self.lock:
return self.robot.observation_features
@property
def action_features(self) -> dict:
with self.lock:
return self.robot.action_features
@property
def name(self) -> str:
return self.robot.name
# ============================================================================
# Configuration
# ============================================================================
@dataclass
class OpenArmsRTCEvalConfig(HubMixin):
"""Configuration for OpenArms evaluation with RTC."""
policy: PreTrainedConfig | None = None
rtc: RTCConfig = field(
default_factory=lambda: RTCConfig(
enabled=True,
execution_horizon=10,
max_guidance_weight=10.0,
prefix_attention_schedule=RTCAttentionSchedule.EXP,
)
)
model_id: str = DEFAULT_HF_MODEL_ID
eval_dataset_id: str = DEFAULT_HF_EVAL_DATASET_ID
task: str = DEFAULT_TASK_DESCRIPTION
num_episodes: int = DEFAULT_NUM_EPISODES
fps: float = DEFAULT_FPS
episode_time_sec: float = DEFAULT_EPISODE_TIME_SEC
reset_time_sec: float = DEFAULT_RESET_TIME_SEC
follower_left_port: str = DEFAULT_FOLLOWER_LEFT_PORT
follower_right_port: str = DEFAULT_FOLLOWER_RIGHT_PORT
device: str = "cuda"
# Should be higher than inference_delay + execution_horizon
action_queue_size_to_get_new_actions: int = 30
record_dataset: bool = True
push_to_hub: bool = True
use_torch_compile: bool = False
torch_compile_backend: str = "inductor"
torch_compile_mode: str = "default"
torch_compile_disable_cudagraphs: bool = True
def __post_init__(self):
policy_path = parser.get_path_arg("policy")
if policy_path:
cli_overrides = parser.get_cli_overrides("policy")
self.policy = PreTrainedConfig.from_pretrained(policy_path, cli_overrides=cli_overrides)
self.policy.pretrained_path = policy_path
self.model_id = policy_path
elif self.model_id:
self.policy = PreTrainedConfig.from_pretrained(self.model_id)
self.policy.pretrained_path = self.model_id
@classmethod
def __get_path_fields__(cls) -> list[str]:
return ["policy"]
# ============================================================================
# Action Generation Thread
# ============================================================================
def get_actions_thread(
policy,
robot: RobotWrapper,
robot_observation_processor,
action_queue: ActionQueue,
shutdown_event: Event,
cfg: OpenArmsRTCEvalConfig,
episode_active: Event,
):
"""Thread function to asynchronously generate action chunks from the policy."""
try:
logger.info("[GET_ACTIONS] Starting action generation thread")
latency_tracker = LatencyTracker()
time_per_chunk = 1.0 / cfg.fps
hw_features = hw_to_dataset_features(robot.observation_features, "observation")
policy_device = policy.config.device
logger.info(f"[GET_ACTIONS] Loading preprocessor/postprocessor from {cfg.policy.pretrained_path}")
preprocessor, postprocessor = make_pre_post_processors(
policy_cfg=cfg.policy,
pretrained_path=cfg.policy.pretrained_path,
dataset_stats=None,
preprocessor_overrides={
"device_processor": {"device": cfg.device},
},
)
logger.info("[GET_ACTIONS] Preprocessor/postprocessor loaded successfully")
get_actions_threshold = cfg.action_queue_size_to_get_new_actions
if not cfg.rtc.enabled:
get_actions_threshold = 0
while not shutdown_event.is_set():
if not episode_active.is_set():
time.sleep(0.01)
continue
if action_queue.qsize() <= get_actions_threshold:
current_time = time.perf_counter()
action_index_before_inference = action_queue.get_action_index()
prev_actions = action_queue.get_left_over()
inference_latency = latency_tracker.max()
inference_delay = math.ceil(inference_latency / time_per_chunk) if inference_latency else 0
obs = robot.get_observation()
obs_processed = robot_observation_processor(obs)
obs_with_policy_features = build_dataset_frame(
hw_features, obs_processed, prefix="observation"
)
for name in obs_with_policy_features:
obs_with_policy_features[name] = torch.from_numpy(obs_with_policy_features[name])
if "image" in name:
obs_with_policy_features[name] = (
obs_with_policy_features[name].type(torch.float32) / 255
)
obs_with_policy_features[name] = (
obs_with_policy_features[name].permute(2, 0, 1).contiguous()
)
obs_with_policy_features[name] = obs_with_policy_features[name].unsqueeze(0)
obs_with_policy_features[name] = obs_with_policy_features[name].to(policy_device)
obs_with_policy_features["task"] = [cfg.task]
obs_with_policy_features["robot_type"] = robot.name
preprocessed_obs = preprocessor(obs_with_policy_features)
actions = policy.predict_action_chunk(
preprocessed_obs,
inference_delay=inference_delay,
prev_chunk_left_over=prev_actions,
)
original_actions = actions.squeeze(0).clone()
postprocessed_actions = postprocessor(actions).squeeze(0)
new_latency = time.perf_counter() - current_time
new_delay = math.ceil(new_latency / time_per_chunk)
latency_tracker.add(new_latency)
if cfg.action_queue_size_to_get_new_actions < cfg.rtc.execution_horizon + new_delay:
logger.warning(
"[GET_ACTIONS] action_queue_size_to_get_new_actions too small. "
"Should be higher than inference delay + execution horizon."
)
action_queue.merge(
original_actions, postprocessed_actions, new_delay, action_index_before_inference
)
logger.debug(
f"[GET_ACTIONS] Generated chunk, latency={new_latency:.3f}s, "
f"delay={new_delay}, queue_size={action_queue.qsize()}"
)
else:
time.sleep(0.01)
logger.info("[GET_ACTIONS] Action generation thread shutting down")
except Exception as e:
logger.error(f"[GET_ACTIONS] Fatal exception: {e}")
logger.error(traceback.format_exc())
shutdown_event.set()
sys.exit(1)
# ============================================================================
# Action Execution Thread
# ============================================================================
def actor_thread(
robot: RobotWrapper,
robot_action_processor,
action_queue: ActionQueue,
shutdown_event: Event,
cfg: OpenArmsRTCEvalConfig,
episode_active: Event,
dataset: LeRobotDataset | None,
dataset_lock: Lock,
teleop_action_processor,
robot_observation_processor,
):
"""Thread function to execute actions on the robot."""
try:
logger.info("[ACTOR] Starting actor thread")
action_count = 0
action_interval = 1.0 / cfg.fps
action_keys = [k for k in robot.action_features.keys() if k.endswith(".pos")]
while not shutdown_event.is_set():
if not episode_active.is_set():
time.sleep(0.01)
continue
start_time = time.perf_counter()
action = action_queue.get()
if action is not None:
action = action.cpu()
action_dict = {}
for i, key in enumerate(action_keys):
if i < len(action):
action_dict[key] = action[i].item()
action_processed = robot_action_processor((action_dict, None))
robot.send_action(action_processed)
if cfg.record_dataset and dataset is not None:
with dataset_lock:
obs = robot.get_observation()
obs_processed = robot_observation_processor(obs)
action_for_dataset = teleop_action_processor((action_dict, None))
frame = {}
for key, value in obs_processed.items():
frame[f"observation.{key}"] = value
for key, value in action_for_dataset.items():
frame[f"action.{key}"] = value
frame["task"] = cfg.task
dataset.add_frame(frame)
action_count += 1
dt_s = time.perf_counter() - start_time
sleep_time = max(0, action_interval - dt_s - 0.001)
if sleep_time > 0:
time.sleep(sleep_time)
logger.info(f"[ACTOR] Actor thread shutting down. Total actions executed: {action_count}")
except Exception as e:
logger.error(f"[ACTOR] Fatal exception: {e}")
logger.error(traceback.format_exc())
shutdown_event.set()
sys.exit(1)
# ============================================================================
# Main Evaluation Function
# ============================================================================
def _apply_torch_compile(policy, cfg: OpenArmsRTCEvalConfig):
"""Apply torch.compile to the policy's predict_action_chunk method."""
if policy.name in ["pi05", "pi0"]:
return policy
try:
if not hasattr(torch, "compile"):
logger.warning(
f"torch.compile not available. Requires PyTorch 2.0+. "
f"Current version: {torch.__version__}. Skipping compilation."
)
return policy
logger.info("Applying torch.compile to predict_action_chunk...")
compile_kwargs = {
"backend": cfg.torch_compile_backend,
"mode": cfg.torch_compile_mode,
}
if cfg.torch_compile_disable_cudagraphs:
compile_kwargs["options"] = {"triton.cudagraphs": False}
original_method = policy.predict_action_chunk
compiled_method = torch.compile(original_method, **compile_kwargs)
policy.predict_action_chunk = compiled_method
logger.info("Successfully compiled predict_action_chunk")
except Exception as e:
logger.error(f"Failed to apply torch.compile: {e}")
logger.warning("Continuing without torch.compile")
return policy
@parser.wrap()
def main(cfg: OpenArmsRTCEvalConfig):
"""Main evaluation function with RTC."""
init_logging()
print("=" * 60)
print("OpenArms Policy Evaluation with RTC")
print("=" * 60)
print(f"\nModel: {cfg.model_id}")
print(f"Evaluation Dataset: {cfg.eval_dataset_id}")
print(f"Task: {cfg.task}")
print(f"Episodes: {cfg.num_episodes}")
print(f"Episode Duration: {cfg.episode_time_sec}s")
print(f"RTC Enabled: {cfg.rtc.enabled}")
print(f"RTC Execution Horizon: {cfg.rtc.execution_horizon}")
print(f"RTC Max Guidance Weight: {cfg.rtc.max_guidance_weight}")
print(f"Device: {cfg.device}")
print("=" * 60)
signal_handler = ProcessSignalHandler(use_threads=True, display_pid=False)
shutdown_event = signal_handler.shutdown_event
episode_active = Event()
# Initialize Robot
follower_config = OpenArmsFollowerConfig(
port_left=cfg.follower_left_port,
port_right=cfg.follower_right_port,
can_interface="socketcan",
id="openarms_follower",
disable_torque_on_disconnect=True,
max_relative_target=10.0,
cameras=DEFAULT_CAMERA_CONFIG,
)
follower = OpenArmsFollower(follower_config)
follower.connect(calibrate=False)
if not follower.is_connected:
raise RuntimeError("Follower robot failed to connect!")
robot = RobotWrapper(follower)
logger.info("Follower robot connected")
# Build Processors and Dataset Features
teleop_action_processor, robot_action_processor, robot_observation_processor = make_default_processors()
action_features_hw = {}
for key, value in follower.action_features.items():
if key.endswith(".pos"):
action_features_hw[key] = value
dataset_features = combine_feature_dicts(
aggregate_pipeline_dataset_features(
pipeline=teleop_action_processor,
initial_features=create_initial_features(action=action_features_hw),
use_videos=True,
),
aggregate_pipeline_dataset_features(
pipeline=robot_observation_processor,
initial_features=create_initial_features(observation=follower.observation_features),
use_videos=True,
),
)
# Create or Load Dataset
dataset = None
dataset_lock = Lock()
if cfg.record_dataset:
dataset_path = Path.home() / ".cache" / "huggingface" / "lerobot" / cfg.eval_dataset_id
if dataset_path.exists():
logger.info(f"Evaluation dataset exists at: {dataset_path}")
logger.info("New episodes will be appended.")
choice = input("Continue? (y/n): ").strip().lower()
if choice != "y":
logger.info("Aborting evaluation.")
follower.disconnect()
return
dataset = LeRobotDataset.create(
repo_id=cfg.eval_dataset_id,
fps=int(cfg.fps),
features=dataset_features,
robot_type=follower.name,
use_videos=True,
image_writer_processes=0,
image_writer_threads=12,
)
logger.info(f"Dataset created: {cfg.eval_dataset_id}")
# Load Policy
logger.info(f"Loading policy from: {cfg.model_id}")
policy_class = get_policy_class(cfg.policy.type)
config = PreTrainedConfig.from_pretrained(cfg.policy.pretrained_path)
if cfg.policy.type in ["pi05", "pi0"]:
config.compile_model = cfg.use_torch_compile
policy = policy_class.from_pretrained(cfg.policy.pretrained_path, config=config)
policy.config.rtc_config = cfg.rtc
policy.init_rtc_processor()
assert policy.name in ["smolvla", "pi05", "pi0"], "Only smolvla, pi05, and pi0 are supported for RTC"
policy = policy.to(cfg.device)
policy.eval()
if cfg.use_torch_compile:
policy = _apply_torch_compile(policy, cfg)
logger.info(f"Policy loaded: {policy.name}")
# Create Action Queue and Start Threads
action_queue = ActionQueue(cfg.rtc)
get_actions_t = Thread(
target=get_actions_thread,
args=(
policy,
robot,
robot_observation_processor,
action_queue,
shutdown_event,
cfg,
episode_active,
),
daemon=True,
name="GetActions",
)
get_actions_t.start()
logger.info("Started action generation thread")
actor_t = Thread(
target=actor_thread,
args=(
robot,
robot_action_processor,
action_queue,
shutdown_event,
cfg,
episode_active,
dataset,
dataset_lock,
teleop_action_processor,
robot_observation_processor,
),
daemon=True,
name="Actor",
)
actor_t.start()
logger.info("Started actor thread")
# Run Evaluation Episodes
episode_idx = 0
try:
while episode_idx < cfg.num_episodes and not shutdown_event.is_set():
log_say(f"Evaluating episode {episode_idx + 1} of {cfg.num_episodes}")
logger.info(f"\n{'='*40}")
logger.info(f"Episode {episode_idx + 1} / {cfg.num_episodes}")
logger.info(f"{'='*40}")
action_queue = ActionQueue(cfg.rtc)
episode_active.set()
episode_start_time = time.time()
while (time.time() - episode_start_time) < cfg.episode_time_sec:
if shutdown_event.is_set():
break
elapsed = time.time() - episode_start_time
if int(elapsed) % 10 == 0 and int(elapsed) > 0:
logger.info(
f"[MAIN] Episode progress: {elapsed:.0f}/{cfg.episode_time_sec}s, "
f"queue_size={action_queue.qsize()}"
)
time.sleep(0.5)
episode_active.clear()
logger.info(f"Episode {episode_idx + 1} completed")
if cfg.record_dataset and dataset is not None:
with dataset_lock:
if dataset.episode_buffer is not None and dataset.episode_buffer.get("size", 0) > 0:
logger.info(
f"Saving episode {episode_idx + 1} "
f"({dataset.episode_buffer['size']} frames)"
)
dataset.save_episode()
episode_idx += 1
# Manual reset between episodes
if not shutdown_event.is_set() and episode_idx < cfg.num_episodes:
log_say("Waiting for manual reset")
logger.info("Manually reset the environment and press ENTER to continue")
input("Press ENTER when ready...")
logger.info(f"Evaluation complete! {episode_idx} episodes recorded")
log_say("Evaluation complete", blocking=True)
except KeyboardInterrupt:
logger.info("\n\nEvaluation interrupted by user")
finally:
shutdown_event.set()
episode_active.clear()
if get_actions_t.is_alive():
logger.info("Waiting for action generation thread to finish...")
get_actions_t.join(timeout=5.0)
if actor_t.is_alive():
logger.info("Waiting for actor thread to finish...")
actor_t.join(timeout=5.0)
follower.disconnect()
logger.info("Follower disconnected")
if cfg.record_dataset and dataset is not None:
dataset.finalize()
if cfg.push_to_hub:
logger.info("Uploading to Hugging Face Hub...")
dataset.push_to_hub(private=True)
logger.info("Cleanup completed")
if __name__ == "__main__":
main()
examples/openarms/friction_compensation.py
-216
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@@ -1,216 +0,0 @@
import time
import numpy as np
from lerobot.robots.openarms.openarms_follower import OpenArmsFollower
from lerobot.robots.openarms.config_openarms_follower import OpenArmsFollowerConfig
# Friction model parameters from OpenArms config/follower.yaml
# τ_fric(ω) = Fo + Fv·ω + Fc·tanh(k·ω)
# For 8 motors: [joint_1, joint_2, joint_3, joint_4, joint_5, joint_6, joint_7, gripper]
FRICTION_PARAMS = {
"Fc": [0.306, 0.306, 0.40, 0.166, 0.050, 0.093, 0.172, 0.0512], # Coulomb friction [Nm]
"k": [28.417, 28.417, 29.065, 130.038, 151.771, 242.287, 7.888, 4.000], # tanh steepness
"Fv": [0.063, 0.0630, 0.604, 0.813, 0.029, 0.072, 0.084, 0.084], # Viscous friction [Nm·s/rad]
"Fo": [0.088, 0.088, 0.008, -0.058, 0.005, 0.009, -0.059, -0.050], # Offset torque [Nm]
}
# Constants from OpenArms C++ implementation
AMP_TMP = 1.0
COEF_TMP = 0.1
FRICTION_SCALE = 1.0 # OpenArms C++ uses 0.3 factor in unilateral mode
DAMPING_KD = [0.5, 0.5, 0.5, 0.5, 0.1, 0.1, 0.1, 0.1] # Damping gains for stability
def compute_friction_torque(velocity_rad_per_sec: float, motor_index: int) -> float:
"""
Compute friction torque for a single motor using the tanh friction model.
Args:
velocity_rad_per_sec: Angular velocity in rad/s
motor_index: Index of the motor (0-7)
Returns:
Friction torque in N·m (scaled for stability)
"""
Fc = FRICTION_PARAMS["Fc"][motor_index]
k = FRICTION_PARAMS["k"][motor_index]
Fv = FRICTION_PARAMS["Fv"][motor_index]
Fo = FRICTION_PARAMS["Fo"][motor_index]
# Friction model: τ_fric = amp * Fc * tanh(coef * k * ω) + Fv * ω + Fo
friction_torque = (
AMP_TMP * Fc * np.tanh(COEF_TMP * k * velocity_rad_per_sec) +
Fv * velocity_rad_per_sec +
Fo
)
# Scale down friction compensation for stability at lower control rates
# (OpenArms C++ uses 0.3 factor in unilateral mode)!!
friction_torque *= FRICTION_SCALE
return friction_torque
def main() -> None:
config = OpenArmsFollowerConfig(
port_left="can0",
port_right="can1",
can_interface="socketcan",
id="openarms_follower",
disable_torque_on_disconnect=True,
max_relative_target=5.0,
)
print("Initializing robot...")
follower = OpenArmsFollower(config)
follower.connect(calibrate=True)
print(f"Applying friction compensation")
print(" 1. Support the arm before starting")
print(" 2. The arm will be held in place by friction compensation")
print(" 3. You should be able to move it with gentle force")
print("\nPress ENTER when ready to start...")
input()
print(f"✓ Motors enabled")
print("\nStarting friction compensation loop...")
print("Press Ctrl+C to stop\n")
loop_times = []
last_print_time = time.perf_counter()
# Motor name to index mapping
motor_name_to_index = {
"joint_1": 0,
"joint_2": 1,
"joint_3": 2,
"joint_4": 3,
"joint_5": 4,
"joint_6": 5,
"joint_7": 6,
"gripper": 7,
}
try:
while True:
loop_start = time.perf_counter()
# Get current joint positions and velocities from robot
obs = follower.get_observation()
# Extract velocities in degrees per second
velocities_deg_per_sec = {}
positions_deg = {}
for motor in follower.bus_right.motors:
vel_key = f"right_{motor}.vel"
pos_key = f"right_{motor}.pos"
if vel_key in obs:
velocities_deg_per_sec[f"right_{motor}"] = obs[vel_key]
if pos_key in obs:
positions_deg[f"right_{motor}"] = obs[pos_key]
for motor in follower.bus_left.motors:
vel_key = f"left_{motor}.vel"
pos_key = f"left_{motor}.pos"
if vel_key in obs:
velocities_deg_per_sec[f"left_{motor}"] = obs[vel_key]
if pos_key in obs:
positions_deg[f"left_{motor}"] = obs[pos_key]
# Convert velocities to rad/s and compute friction torques
friction_torques_nm = {}
for motor_full_name, velocity_deg_per_sec in velocities_deg_per_sec.items():
# Extract motor name without arm prefix
if motor_full_name.startswith("right_"):
motor_name = motor_full_name.removeprefix("right_")
elif motor_full_name.startswith("left_"):
motor_name = motor_full_name.removeprefix("left_")
else:
continue
# Get motor index for friction parameters
motor_index = motor_name_to_index.get(motor_name, 0)
# Convert velocity to rad/s
velocity_rad_per_sec = np.deg2rad(velocity_deg_per_sec)
# Compute friction torque
friction_torque = compute_friction_torque(velocity_rad_per_sec, motor_index)
friction_torques_nm[motor_full_name] = friction_torque
# Apply friction compensation to right arm (all joints INCLUDING gripper)
for motor in follower.bus_right.motors:
full_name = f"right_{motor}"
position = positions_deg.get(full_name, 0.0)
torque = friction_torques_nm.get(full_name, 0.0)
# Get motor index for damping gain
motor_index = motor_name_to_index.get(motor, 0)
kd = DAMPING_KD[motor_index]
# Send MIT control command with friction compensation + damping
follower.bus_right._mit_control(
motor=motor,
kp=0.0, # No position control
kd=kd, # Add damping for stability
position_degrees=position,
velocity_deg_per_sec=0.0,
torque=torque
)
# Apply friction compensation to left arm (all joints INCLUDING gripper)
for motor in follower.bus_left.motors:
full_name = f"left_{motor}"
position = positions_deg.get(full_name, 0.0)
torque = friction_torques_nm.get(full_name, 0.0)
# Get motor index for damping gain
motor_index = motor_name_to_index.get(motor, 0)
kd = DAMPING_KD[motor_index]
# Send MIT control command with friction compensation + damping
follower.bus_left._mit_control(
motor=motor,
kp=0.0, # No position control
kd=kd, # Add damping for stability
position_degrees=position,
velocity_deg_per_sec=0.0,
torque=torque
)
# Measure loop time
loop_end = time.perf_counter()
loop_time = loop_end - loop_start
loop_times.append(loop_time)
# Print status every 2 seconds
if loop_end - last_print_time >= 2.0:
if loop_times:
avg_time = sum(loop_times) / len(loop_times)
current_hz = 1.0 / avg_time if avg_time > 0 else 0
print(f"{current_hz:.1f} Hz")
loop_times = []
last_print_time = loop_end
time.sleep(0.001)
except KeyboardInterrupt:
print("\n\nStopping friction compensation...")
finally:
print("\nDisabling all motors and disconnecting...")
follower.bus_right.disable_torque()
follower.bus_left.disable_torque()
time.sleep(0.1)
follower.disconnect()
print("✓ Safe shutdown complete")
if __name__ == "__main__":
main()
examples/openarms/gravity_compensation.py
-142
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@@ -1,142 +0,0 @@
import time
import numpy as np
import pinocchio as pin
from os.path import join, dirname, exists, expanduser
from lerobot.robots.openarms.openarms_follower import OpenArmsFollower
from lerobot.robots.openarms.config_openarms_follower import OpenArmsFollowerConfig
def main() -> None:
config = OpenArmsFollowerConfig(
port_left="can0",
port_right="can1",
can_interface="socketcan",
id="openarms_follower",
disable_torque_on_disconnect=True,
max_relative_target=5.0,
)
print("Initializing robot...")
follower = OpenArmsFollower(config)
follower.connect(calibrate=True)
# Load URDF for Pinocchio dynamics
urdf_path = "/home/croissant/Documents/openarm_description/openarm_bimanual_pybullet.urdf"
pin_robot = pin.RobotWrapper.BuildFromURDF(urdf_path, dirname(urdf_path))
pin_robot.data = pin_robot.model.createData()
print(f"✓ Loaded Pinocchio model with {pin_robot.nq} DoFs")
follower.pin_robot = pin_robot
print(f"Applying gravity compensation")
print(" 1. Support the arm before starting")
print(" 2. The arm will be held in place by gravity compensation")
print(" 3. You should be able to move it with gentle force")
print("\nPress ENTER when ready to start...")
input()
print(f"✓ Motors enabled")
print("\nStarting gravity compensation loop...")
print("Press Ctrl+C to stop\n")
loop_times = []
last_print_time = time.perf_counter()
try:
while True:
loop_start = time.perf_counter()
# Get current joint positions from robot
obs = follower.get_observation()
# Extract positions in degrees
positions_deg = {}
for motor in follower.bus_right.motors:
key = f"right_{motor}.pos"
if key in obs:
positions_deg[f"right_{motor}"] = obs[key]
for motor in follower.bus_left.motors:
key = f"left_{motor}.pos"
if key in obs:
positions_deg[f"left_{motor}"] = obs[key]
# Convert to radians and calculate gravity torques
# Use the built-in method from OpenArmsFollower
positions_rad = {k: np.deg2rad(v) for k, v in positions_deg.items()}
torques_nm = follower._gravity_from_q(positions_rad)
# Apply gravity compensation to right arm (all joints except gripper)
for motor in follower.bus_right.motors:
if motor == "gripper":
continue # Skip gripper
full_name = f"right_{motor}"
position = positions_deg.get(full_name, 0.0)
torque = torques_nm.get(full_name, 0.0)
# Send MIT control command with gravity compensation torque
follower.bus_right._mit_control(
motor=motor,
kp=0.0, # No position control
kd=0.0, # No velocity damping
position_degrees=position,
velocity_deg_per_sec=0.0,
torque=torque
)
# Apply gravity compensation to left arm (all joints except gripper)
for motor in follower.bus_left.motors:
if motor == "gripper":
continue # Skip gripper
full_name = f"left_{motor}"
position = positions_deg.get(full_name, 0.0)
torque = torques_nm.get(full_name, 0.0)
# Send MIT control command with gravity compensation torque
follower.bus_left._mit_control(
motor=motor,
kp=0.0, # No position control
kd=0.0, # No velocity damping
position_degrees=position,
velocity_deg_per_sec=0.0,
torque=torque
)
# Measure loop time
loop_end = time.perf_counter()
loop_time = loop_end - loop_start
loop_times.append(loop_time)
# Print status every 2 seconds
if loop_end - last_print_time >= 2.0:
if loop_times:
avg_time = sum(loop_times) / len(loop_times)
current_hz = 1.0 / avg_time if avg_time > 0 else 0
print(f"{current_hz:.1f} Hz ({avg_time*1000:.1f} ms)")
loop_times = []
last_print_time = loop_end
time.sleep(0.005)
except KeyboardInterrupt:
print("\n\nStopping gravity compensation...")
finally:
print("\nDisabling all motors and disconnecting...")
follower.bus_right.disable_torque()
follower.bus_left.disable_torque()
time.sleep(0.1)
follower.disconnect()
print("✓ Safe shutdown complete")
if __name__ == "__main__":
main()
examples/openarms/record_with_compensation.py
-395
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@@ -1,395 +0,0 @@
"""
OpenArms Dataset Recording with Gravity + Friction Compensation
Records a dataset using OpenArms follower robot with leader teleoperator.
Leader arms have gravity and friction compensation for weightless, easy movement.
Includes 3 cameras: left wrist, right wrist, and base camera.
Uses the same compensation approach as teleop_with_compensation.py
"""
import shutil
import time
from pathlib import Path
import numpy as np
from lerobot.cameras.opencv.configuration_opencv import OpenCVCameraConfig
from lerobot.datasets.lerobot_dataset import LeRobotDataset
from lerobot.datasets.utils import build_dataset_frame, hw_to_dataset_features
from lerobot.robots.openarms.config_openarms_follower import OpenArmsFollowerConfig
from lerobot.robots.openarms.openarms_follower import OpenArmsFollower
from lerobot.teleoperators.openarms.config_openarms_leader import OpenArmsLeaderConfig
from lerobot.teleoperators.openarms.openarms_leader import OpenArmsLeader
from lerobot.utils.control_utils import init_keyboard_listener
from lerobot.utils.utils import log_say
from lerobot.utils.visualization_utils import init_rerun, log_rerun_data
# Recording parameters
NUM_EPISODES = 1
FPS = 30
EPISODE_TIME_SEC = 600
RESET_TIME_SEC = 120
TASK_DESCRIPTION = "OpenArms task description"
# Friction compensation scale factor (1.0 = full, 0.3 = 30% for stability)
FRICTION_SCALE = 1.0
def record_loop_with_compensation(
robot,
leader,
events,
fps,
dataset,
dataset_features,
control_time_s,
single_task,
display_data=True,
):
"""
Custom record loop that applies gravity + friction compensation to leader.
Based on record_loop but with integrated compensation.
"""
dt = 1 / fps
episode_start_time = time.perf_counter()
# All joints (both arms)
all_joints = []
for motor in leader.bus_right.motors:
all_joints.append(f"right_{motor}")
for motor in leader.bus_left.motors:
all_joints.append(f"left_{motor}")
while True:
loop_start = time.perf_counter()
elapsed = loop_start - episode_start_time
# Check if we should exit
if elapsed >= control_time_s or events["exit_early"] or events["stop_recording"]:
break
# Get leader state
leader_action = leader.get_action()
# Extract positions and velocities in degrees
leader_positions_deg = {}
leader_velocities_deg_per_sec = {}
for motor in leader.bus_right.motors:
pos_key = f"right_{motor}.pos"
vel_key = f"right_{motor}.vel"
if pos_key in leader_action:
leader_positions_deg[f"right_{motor}"] = leader_action[pos_key]
if vel_key in leader_action:
leader_velocities_deg_per_sec[f"right_{motor}"] = leader_action[vel_key]
for motor in leader.bus_left.motors:
pos_key = f"left_{motor}.pos"
vel_key = f"left_{motor}.vel"
if pos_key in leader_action:
leader_positions_deg[f"left_{motor}"] = leader_action[pos_key]
if vel_key in leader_action:
leader_velocities_deg_per_sec[f"left_{motor}"] = leader_action[vel_key]
# Calculate gravity torques for leader using built-in method
leader_positions_rad = {k: np.deg2rad(v) for k, v in leader_positions_deg.items()}
leader_gravity_torques_nm = leader._gravity_from_q(leader_positions_rad)
# Calculate friction torques for leader using built-in method
leader_velocities_rad_per_sec = {k: np.deg2rad(v) for k, v in leader_velocities_deg_per_sec.items()}
leader_friction_torques_nm = leader._friction_from_velocity(
leader_velocities_rad_per_sec,
friction_scale=FRICTION_SCALE
)
# Combine gravity + friction torques
leader_total_torques_nm = {}
for motor_name in leader_gravity_torques_nm:
gravity = leader_gravity_torques_nm.get(motor_name, 0.0)
friction = leader_friction_torques_nm.get(motor_name, 0.0)
leader_total_torques_nm[motor_name] = gravity + friction
# Apply gravity + friction compensation to leader RIGHT arm (all joints including gripper)
for motor in leader.bus_right.motors:
full_name = f"right_{motor}"
position = leader_positions_deg.get(full_name, 0.0)
torque = leader_total_torques_nm.get(full_name, 0.0)
# Get damping gain for stability
kd = leader.get_damping_kd(motor)
leader.bus_right._mit_control(
motor=motor,
kp=0.0,
kd=kd, # Add damping for stability
position_degrees=position,
velocity_deg_per_sec=0.0,
torque=torque,
)
# Apply gravity + friction compensation to leader LEFT arm (all joints including gripper)
for motor in leader.bus_left.motors:
full_name = f"left_{motor}"
position = leader_positions_deg.get(full_name, 0.0)
torque = leader_total_torques_nm.get(full_name, 0.0)
# Get damping gain for stability
kd = leader.get_damping_kd(motor)
leader.bus_left._mit_control(
motor=motor,
kp=0.0,
kd=kd, # Add damping for stability
position_degrees=position,
velocity_deg_per_sec=0.0,
torque=torque,
)
# Send leader positions to follower (both arms)
follower_action = {}
for joint in all_joints:
pos_key = f"{joint}.pos"
if pos_key in leader_action:
follower_action[pos_key] = leader_action[pos_key]
# Send action to robot
if follower_action:
robot.send_action(follower_action)
# Get observation from robot (includes camera images)
observation = robot.get_observation()
# Add to dataset if we have a dataset
if dataset is not None:
# Build properly formatted observation frame
obs_frame = build_dataset_frame(dataset_features, observation, prefix="observation")
# Build properly formatted action frame (keep .pos suffix - it matches the feature names)
action_frame = build_dataset_frame(dataset_features, follower_action, prefix="action")
# Combine into single frame
frame = {**obs_frame, **action_frame}
# Add metadata (task is required, timestamp will be auto-calculated by add_frame)
frame["task"] = single_task
dataset.add_frame(frame)
# Display data if requested
if display_data:
log_rerun_data(observation=observation, action=follower_action)
# Maintain loop rate
loop_duration = time.perf_counter() - loop_start
sleep_time = dt - loop_duration
if sleep_time > 0:
time.sleep(sleep_time)
def main():
"""Main recording loop with gravity compensation."""
print("=" * 70)
print("OpenArms Dataset Recording with Compensation")
print("=" * 70)
# Create camera configurations (3 cameras: left wrist, right wrist, base)
# Using actual device paths found by lerobot-find-cameras opencv
camera_config = {
"left_wrist": OpenCVCameraConfig(index_or_path="/dev/video0", width=640, height=480, fps=FPS),
"right_wrist": OpenCVCameraConfig(index_or_path="/dev/video1", width=640, height=480, fps=FPS),
"base": OpenCVCameraConfig(index_or_path="/dev/video7", width=640, height=480, fps=FPS),
}
# Configure follower robot with cameras
follower_config = OpenArmsFollowerConfig(
port_left="can2",
port_right="can3",
can_interface="socketcan",
id="openarms_follower",
disable_torque_on_disconnect=True,
max_relative_target=10.0,
cameras=camera_config,
)
# Configure leader teleoperator (no cameras needed)
leader_config = OpenArmsLeaderConfig(
port_left="can0",
port_right="can1",
can_interface="socketcan",
id="openarms_leader",
manual_control=False, # Enable torque control for gravity compensation
)
# Initialize robot and teleoperator
print("\nInitializing devices...")
follower = OpenArmsFollower(follower_config)
leader = OpenArmsLeader(leader_config)
# Connect devices
print("Connecting and calibrating...")
follower.connect(calibrate=True)
leader.connect(calibrate=True)
# Verify URDF is loaded for gravity compensation
if leader.pin_robot is None:
raise RuntimeError("URDF model not loaded on leader. Gravity compensation not available.")
# Configure the dataset features
# For actions, we only want to record positions (not velocity or torque)
action_features_hw = {}
for key, value in follower.action_features.items():
if key.endswith(".pos"):
action_features_hw[key] = value
action_features = hw_to_dataset_features(action_features_hw, "action")
obs_features = hw_to_dataset_features(follower.observation_features, "observation")
dataset_features = {**action_features, **obs_features}
# Create the dataset
print("\nCreating dataset...")
repo_id = "<hf_username>/<dataset_repo_id>" # TODO: Replace with your Hugging Face repo
# Check if dataset already exists and prompt user
dataset_path = Path.home() / ".cache" / "huggingface" / "lerobot" / repo_id
while dataset_path.exists():
print(f"\nDataset already exists at: {dataset_path}")
print("\nOptions:")
print(" 1. Overwrite existing dataset")
print(" 2. Use a different name")
print(" 3. Abort")
choice = input("\nEnter your choice (1/2/3): ").strip()
if choice == '1':
print(f"Removing existing dataset...")
shutil.rmtree(dataset_path)
print("✓ Existing dataset removed")
break
elif choice == '2':
print("\nCurrent repo_id:", repo_id)
new_repo_id = input("Enter new repo_id (format: <username>/<dataset_name>): ").strip()
if new_repo_id and '/' in new_repo_id:
repo_id = new_repo_id
dataset_path = Path.home() / ".cache" / "huggingface" / "lerobot" / repo_id
print(f"✓ Using new repo_id: {repo_id}")
# Loop will continue if this new path also exists
else:
print("Invalid repo_id format. Please use format: <username>/<dataset_name>")
elif choice == '3':
print("Aborting. Please remove the existing dataset manually or restart with a different repo_id.")
follower.disconnect()
leader.disconnect()
return
else:
print("Invalid choice. Please enter 1, 2, or 3.")
dataset = LeRobotDataset.create(
repo_id=repo_id,
fps=FPS,
features=dataset_features,
robot_type=follower.name,
use_videos=True,
image_writer_threads=4,
)
# Initialize keyboard listener and visualization
_, events = init_keyboard_listener()
init_rerun(session_name="openarms_recording")
# Enable motors on both leader arms for gravity compensation
leader.bus_right.enable_torque()
leader.bus_left.enable_torque()
time.sleep(0.1)
print("\n" + "=" * 70)
print(f"Recording {NUM_EPISODES} episodes")
print(f"Task: {TASK_DESCRIPTION}")
print("=" * 70)
print("\nLeader BOTH arms: Gravity + Friction comp | Follower BOTH arms: Teleop")
print("\nKeyboard controls:")
print(" - Press 'q' to stop recording")
print(" - Press 'r' to re-record current episode")
print("=" * 70)
episode_idx = 0
try:
while episode_idx < NUM_EPISODES and not events["stop_recording"]:
log_say(f"Recording episode {episode_idx + 1} of {NUM_EPISODES}")
# Record episode with compensation active
record_loop_with_compensation(
robot=follower,
leader=leader,
events=events,
fps=FPS,
dataset=dataset,
dataset_features=dataset_features,
control_time_s=EPISODE_TIME_SEC,
single_task=TASK_DESCRIPTION,
display_data=True,
)
# 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_with_compensation(
robot=follower,
leader=leader,
events=events,
fps=FPS,
dataset=None, # Don't save reset period
dataset_features=dataset_features,
control_time_s=RESET_TIME_SEC,
single_task=TASK_DESCRIPTION,
display_data=True,
)
# Handle re-recording
if events["rerecord_episode"]:
log_say("Re-recording episode")
events["rerecord_episode"] = False
events["exit_early"] = False
dataset.clear_episode_buffer()
continue
# Only save episode if frames were recorded
if dataset.episode_buffer is not None and dataset.episode_buffer["size"] > 0:
dataset.save_episode()
episode_idx += 1
else:
log_say("No frames recorded, skipping episode save")
# Clear the empty buffer
dataset.episode_buffer = None
except KeyboardInterrupt:
print("\n\nStopping recording...")
finally:
# Clean up
log_say("Stop recording")
try:
leader.bus_right.disable_torque()
leader.bus_left.disable_torque()
time.sleep(0.1)
leader.disconnect()
follower.disconnect()
print("✓ Shutdown complete")
except Exception as e:
print(f"Shutdown error: {e}")
# Upload dataset
print("\nUploading dataset to Hugging Face Hub...")
try:
dataset.push_to_hub()
print("✓ Dataset uploaded successfully")
except Exception as e:
print(f"Warning: Failed to upload dataset: {e}")
print("You can manually upload later using: dataset.push_to_hub()")
print("✓ Recording complete!")
if __name__ == "__main__":
main()
examples/openarms/replay.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.
"""
OpenArms Dataset Replay Example
Replays position actions from a recorded dataset on an OpenArms follower robot.
Only position commands (ending with .pos) are replayed, not velocity or torque.
Example usage:
python examples/openarms/replay.py
"""
import time
from lerobot.datasets.lerobot_dataset import LeRobotDataset
from lerobot.robots.openarms.config_openarms_follower import OpenArmsFollowerConfig
from lerobot.robots.openarms.openarms_follower import OpenArmsFollower
from lerobot.utils.constants import ACTION
from lerobot.utils.robot_utils import busy_wait
from lerobot.utils.utils import log_say
# Configuration
EPISODE_IDX = 0
DATASET_REPO_ID = "lerobot-data-collection/replay-this-2025-11-02-17-58" # TODO: Replace with your dataset
DATASET_ROOT = None # Use default cache location, or specify custom path
# Robot configuration - adjust these to match your setup
ROBOT_CONFIG = OpenArmsFollowerConfig(
port_left="can2", # CAN interface for left arm
port_right="can3", # CAN interface for right arm
can_interface="socketcan",
id="openarms_follower",
disable_torque_on_disconnect=True,
max_relative_target=10.0, # Safety limit: max degrees to move per step
)
def main():
"""Main replay function."""
print("=" * 70)
print("OpenArms Dataset Replay")
print("=" * 70)
print(f"\nDataset: {DATASET_REPO_ID}")
print(f"Episode: {EPISODE_IDX}")
print(f"Robot: {ROBOT_CONFIG.id}")
print(f" Left arm: {ROBOT_CONFIG.port_left}")
print(f" Right arm: {ROBOT_CONFIG.port_right}")
print("\n" + "=" * 70)
# Initialize the robot
print("\n[1/3] Initializing robot...")
robot = OpenArmsFollower(ROBOT_CONFIG)
# Load the dataset
print(f"\n[2/3] Loading dataset '{DATASET_REPO_ID}'...")
dataset = LeRobotDataset(
DATASET_REPO_ID,
root=DATASET_ROOT,
episodes=[EPISODE_IDX]
)
# Filter dataset to only include frames from the specified episode
# (required for dataset V3.0 where episodes are chunked)
episode_frames = dataset.hf_dataset.filter(
lambda x: x["episode_index"] == EPISODE_IDX
)
if len(episode_frames) == 0:
raise ValueError(
f"No frames found for episode {EPISODE_IDX} in dataset {DATASET_REPO_ID}"
)
print(f" Found {len(episode_frames)} frames in episode {EPISODE_IDX}")
# Extract action features from dataset
action_features = dataset.features.get(ACTION, {})
action_names = action_features.get("names", [])
# Filter to only position actions (ending with .pos)
position_action_names = [name for name in action_names if name.endswith(".pos")]
if not position_action_names:
raise ValueError(
f"No position actions found in dataset. Action names: {action_names}"
)
print(f" Found {len(position_action_names)} position actions to replay")
print(f" Actions: {', '.join(position_action_names[:5])}{'...' if len(position_action_names) > 5 else ''}")
# Select only action columns from dataset
actions = episode_frames.select_columns(ACTION)
# Connect to the robot
print(f"\n[3/3] Connecting to robot...")
robot.connect(calibrate=False) # Skip calibration for replay
if not robot.is_connected:
raise RuntimeError("Robot failed to connect!")
print("\n" + "=" * 70)
print("Ready to replay!")
print("=" * 70)
print("\nThe robot will replay the recorded positions.")
print("Press Ctrl+C to stop at any time.\n")
input("Press ENTER to start replaying...")
# Replay loop
log_say(f"Replaying episode {EPISODE_IDX}", blocking=True)
try:
for idx in range(len(episode_frames)):
loop_start = time.perf_counter()
# Extract action array from dataset
action_array = actions[idx][ACTION]
# Build action dictionary, but only include position actions
action = {}
for i, name in enumerate(action_names):
# Only include position actions (ending with .pos)
if name.endswith(".pos"):
action[name] = float(action_array[i])
# Send action to robot
robot.send_action(action)
# Maintain replay rate (use dataset fps)
loop_duration = time.perf_counter() - loop_start
dt_s = 1.0 / dataset.fps - loop_duration
busy_wait(dt_s)
# Progress indicator every 100 frames
if (idx + 1) % 100 == 0:
progress = (idx + 1) / len(episode_frames) * 100
print(f"Progress: {idx + 1}/{len(episode_frames)} frames ({progress:.1f}%)")
print(f"\n✓ Successfully replayed {len(episode_frames)} frames")
log_say("Replay complete", blocking=True)
except KeyboardInterrupt:
print("\n\nReplay interrupted by user")
finally:
# Disconnect robot
print("\nDisconnecting robot...")
robot.disconnect()
print("✓ Replay complete!")
if __name__ == "__main__":
main()
examples/openarms/setup_can.sh
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#!/bin/bash
# Setup all OpenArms CAN interfaces with CAN FD
set -e
echo "=========================================="
echo "OpenArms CAN FD Interface Setup"
echo "=========================================="
echo ""
echo "Mode: CAN FD"
echo " - Nominal bitrate: 1 Mbps"
echo " - Data bitrate: 5 Mbps"
echo ""
echo "Configuring interfaces can0, can1, can2, can3..."
echo ""
# Configure each CAN interface with CAN FD
for i in 0 1 2 3; do
interface="can$i"
# Check if interface exists
if ! ip link show "$interface" &> /dev/null; then
echo "$interface: Not found, skipping"
continue
fi
# Bring down interface
sudo ip link set "$interface" down 2>/dev/null
# Configure CAN FD mode
sudo ip link set "$interface" type can \
bitrate 1000000 \
dbitrate 5000000 \
fd on
# Bring up interface
sudo ip link set "$interface" up
# Verify configuration
if ip link show "$interface" | grep -q "UP"; then
echo "$interface: Configured and UP"
else
echo "$interface: Failed to bring UP"
fi
done
echo ""
echo "=========================================="
echo "Verification"
echo "=========================================="
echo ""
# Show detailed status for each interface
for i in 0 1 2 3; do
interface="can$i"
if ip link show "$interface" &> /dev/null; then
echo "$interface:"
# Show key parameters
ip -d link show "$interface" | grep -E "can|state|bitrate|dbitrate" | head -3
echo ""
fi
done
echo "=========================================="
echo "Setup Complete!"
echo "=========================================="
echo ""
echo "All interfaces configured for CAN FD mode"
echo ""
echo "Next steps:"
echo " 1. Test motors: python debug_can_communication.py"
echo " 2. Run teleoperation: python examples/openarms/teleop.py"
echo ""
examples/openarms/teleop.py
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"""
OpenArms Teleoperation Example - Full Dual Arms
This script demonstrates teleoperation of OpenArms follower robot using an OpenArms leader arm.
It first calibrates both devices, then enters a teleoperation loop for both arms.
"""
import time
from lerobot.robots.openarms.openarms_follower import OpenArmsFollower
from lerobot.robots.openarms.config_openarms_follower import OpenArmsFollowerConfig
from lerobot.teleoperators.openarms.openarms_leader import OpenArmsLeader
from lerobot.teleoperators.openarms.config_openarms_leader import OpenArmsLeaderConfig
follower_config = OpenArmsFollowerConfig(
port_left="can2", # CAN interface for follower left arm
port_right="can3", # CAN interface for follower right arm
can_interface="socketcan", # Linux SocketCAN
id="openarms_follower",
disable_torque_on_disconnect=True,
max_relative_target=5.0, # Safety limit
)
leader_config = OpenArmsLeaderConfig(
port_left="can0", # CAN interface for leader left arm
port_right="can1", # CAN interface for leader right arm
can_interface="socketcan", # Linux SocketCAN
id="openarms_leader",
manual_control=True, # Enable manual control (torque disabled)
)
print("=" * 60)
print("OpenArms Teleoperation - Full Dual Arms")
print("=" * 60)
# Initialize devices
print("\n[1/4] Initializing devices...")
follower = OpenArmsFollower(follower_config)
leader = OpenArmsLeader(leader_config)
# Connect and calibrate follower
print("\n[2/4] Connecting and calibrating follower robot...")
print("Note: If you have existing calibration, just press ENTER to use it.")
follower.connect(calibrate=True)
# Connect and calibrate leader
print("\n[3/4] Connecting and calibrating leader arm...")
print("Note: The leader arm will have torque disabled for manual control.")
leader.connect(calibrate=True)
# Wait for user to be ready
print("\n[4/4] Ready for teleoperation!")
print("\nBoth arms will be controlled (16 motors total):")
print(" RIGHT ARM: joints 1-7 + gripper")
print(" LEFT ARM: joints 1-7 + gripper")
print("\nPress ENTER to start teleoperation...")
input()
print("\nTeleoperation started! Move both leader arms.")
print("Press Ctrl+C to stop.\n")
# All joints for both arms (16 motors total)
all_joints = [
# Right arm
"right_joint_1",
"right_joint_2",
"right_joint_3",
"right_joint_4",
"right_joint_5",
"right_joint_6",
"right_joint_7",
"right_gripper",
# Left arm
"left_joint_1",
"left_joint_2",
"left_joint_3",
"left_joint_4",
"left_joint_5",
"left_joint_6",
"left_joint_7",
"left_gripper",
]
# Performance monitoring
loop_times = []
start_time = time.perf_counter()
last_print_time = start_time
try:
while True:
loop_start = time.perf_counter()
# Get action from leader
leader_action = leader.get_action()
# Filter to only position data for all joints (both arms)
joint_action = {}
for joint in all_joints:
pos_key = f"{joint}.pos"
if pos_key in leader_action:
joint_action[pos_key] = leader_action[pos_key]
# Send action to follower (both arms)
if joint_action:
follower.send_action(joint_action)
# Measure loop time
loop_end = time.perf_counter()
loop_time = loop_end - loop_start
loop_times.append(loop_time)
# Print stats every 2 seconds
if loop_end - last_print_time >= 2.0:
if loop_times:
avg_time = sum(loop_times) / len(loop_times)
current_hz = 1.0 / avg_time if avg_time > 0 else 0
min_time = min(loop_times)
max_time = max(loop_times)
max_hz = 1.0 / min_time if min_time > 0 else 0
min_hz = 1.0 / max_time if max_time > 0 else 0
print(f"[Hz Stats] Avg: {current_hz:.1f} Hz | "
f"Range: {min_hz:.1f}-{max_hz:.1f} Hz | "
f"Avg loop time: {avg_time*1000:.1f} ms")
# Reset for next measurement window
loop_times = []
last_print_time = loop_end
except KeyboardInterrupt:
print("\n\nStopping teleoperation...")
finally:
# Disconnect devices
print("Disconnecting devices...")
try:
follower.disconnect()
except Exception as e:
print(f"Error disconnecting follower: {e}")
try:
leader.disconnect()
except Exception as e:
print(f"Error disconnecting leader: {e}")
print("Done!")
examples/openarms/teleop_openarms_mini.py
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"""
OpenArms Mini Teleoperation Example
This script demonstrates teleoperation of an OpenArms follower robot using
an OpenArms Mini leader (Feetech-based) with dual arms (16 motors total).
The OpenArms Mini has:
- Right arm: 8 motors (joint_1 to joint_7 + gripper)
- Left arm: 8 motors (joint_1 to joint_7 + gripper)
Note on gripper normalization:
- OpenArms Mini gripper: 0-100 scale (0=closed, 100=open)
- OpenArms follower gripper: degrees (0=closed, -65=open)
- This script automatically converts between the two ranges
"""
import time
import os
import sys
from lerobot.robots.openarms.openarms_follower import OpenArmsFollower
from lerobot.robots.openarms.config_openarms_follower import OpenArmsFollowerConfig
from lerobot.teleoperators.openarms_mini.openarms_mini import OpenArmsMini
from lerobot.teleoperators.openarms_mini.config_openarms_mini import OpenArmsMiniConfig
from lerobot.utils.robot_utils import busy_wait
# Target control frequency
TARGET_FPS = 30
# Configure the OpenArms follower (Damiao motors on CAN bus)
follower_config = OpenArmsFollowerConfig(
port_left="can0", # CAN interface for follower left arm
port_right="can1", # CAN interface for follower right arm
can_interface="socketcan", # Linux SocketCAN
id="openarms_follower",
disable_torque_on_disconnect=True,
max_relative_target=10.0, # Safety limit (degrees per step)
)
# Configure the OpenArms Mini leader (Feetech motors on serial)
leader_config = OpenArmsMiniConfig(
port_right="/dev/ttyACM0", # Serial port for right arm
port_left="/dev/ttyACM1", # Serial port for left arm
id="openarms_mini",
use_degrees=True,
)
print("OpenArms Mini → OpenArms Follower Teleoperation")
# Initialize devices
follower = OpenArmsFollower(follower_config)
leader = OpenArmsMini(leader_config)
# Connect and calibrate follower
print("Note: If you have existing calibration, just press ENTER to use it.")
follower.connect(calibrate=True)
# Connect and calibrate leader
print("Note: The leader arms will have torque disabled for manual control.")
leader.connect(calibrate=True)
print("\nPress ENTER to start teleoperation...")
input()
print("Press Ctrl+C to stop.\n")
# All joints for both arms (16 motors total)
all_joints = [
# Right arm
"right_joint_1",
"right_joint_2",
"right_joint_3",
"right_joint_4",
"right_joint_5",
"right_joint_6",
"right_joint_7",
"right_gripper",
# Left arm
"left_joint_1",
"left_joint_2",
"left_joint_3",
"left_joint_4",
"left_joint_5",
"left_joint_6",
"left_joint_7",
"left_gripper",
]
# Performance monitoring
loop_times = []
avg_loop_time = 0.0
min_loop_time = float('inf')
max_loop_time = 0.0
stats_update_interval = 1.0 # Update stats every 1 second
last_stats_update = time.perf_counter()
SWAPPED_JOINTS = {
"right_joint_6": "right_joint_7",
"right_joint_7": "right_joint_6",
"left_joint_6": "left_joint_7",
"left_joint_7": "left_joint_6",
}
try:
while True:
loop_start = time.perf_counter()
# Get actions and observations
leader_action = leader.get_action()
follower_obs = follower.get_observation()
joint_action = {}
for joint in all_joints:
leader_key = f"{joint}.pos"
# Determine which follower joint this leader joint controls
follower_joint = SWAPPED_JOINTS.get(joint, joint)
follower_key = f"{follower_joint}.pos"
# Get leader position (default 0 if missing)
pos = leader_action.get(leader_key, 0.0)
# Convert gripper values: Mini uses 0-100, OpenArms uses 0 to -65 degrees
if "gripper" in joint:
# Map 0-100 (Mini) to 0 to -65 (OpenArms)
# 0 (closed) -> 0°, 100 (open) -> -65°
pos = (pos / 100.0) * -65.0
# Store in action dict for follower
joint_action[follower_key] = pos
follower.send_action(joint_action)
# Loop timing
loop_end = time.perf_counter()
loop_time = loop_end - loop_start
loop_times.append(loop_time)
# Update stats periodically
current_time = time.perf_counter()
if current_time - last_stats_update >= stats_update_interval:
if loop_times:
avg_loop_time = sum(loop_times) / len(loop_times)
min_loop_time = min(loop_times)
max_loop_time = max(loop_times)
loop_times = []
last_stats_update = current_time
# Display everything
sys.stdout.write("\033[H\033[J") # Clear screen
# Show timing stats at the top
if avg_loop_time > 0:
avg_hz = 1.0 / avg_loop_time
min_hz = 1.0 / max_loop_time if max_loop_time > 0 else 0
max_hz = 1.0 / min_loop_time if min_loop_time > 0 and min_loop_time < float('inf') else 0
print(f"[Performance] Target: {TARGET_FPS} Hz | Avg: {avg_hz:.1f} Hz | Range: {min_hz:.1f}-{max_hz:.1f} Hz | Loop: {avg_loop_time*1000:.1f} ms\n")
else:
print(f"[Performance] Target: {TARGET_FPS} Hz | Measuring...\n")
# Show joint positions
print(f"{'Joint':<20} {'Leader':>15} {'Follower':>15}")
print(f"{'':20} {'(0-100/deg)':>15} {'(deg)':>15}")
print("-" * 52)
for joint in all_joints:
leader_key = f"{joint}.pos"
follower_joint = SWAPPED_JOINTS.get(joint, joint)
follower_key = f"{follower_joint}.pos"
leader_pos = leader_action.get(leader_key, 0.0)
follower_pos = follower_obs.get(follower_key, 0.0)
print(f"{joint:<20} {leader_pos:>15.2f} {follower_pos:>15.2f}")
# Smart sleep to maintain target FPS
dt_s = time.perf_counter() - loop_start
busy_wait(max(0, 1.0 / TARGET_FPS - dt_s))
except KeyboardInterrupt:
print("\n\nStopping teleoperation...")
finally:
# Disconnect devices
print("Disconnecting devices...")
try:
follower.disconnect()
except Exception as e:
print(f"Error disconnecting follower: {e}")
try:
leader.disconnect()
except Exception as e:
print(f"Error disconnecting leader: {e}")
print("Done!")
examples/openarms/teleop_with_compensation.py
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"""
OpenArms Teleoperation with Gravity + Friction Compensation
Leader arms (both LEFT and RIGHT): Gravity + Friction compensation (weightless, easy to move)
Follower arms (both LEFT and RIGHT): Mirror leader movements
Uses the URDF file from the lerobot repository.
"""
import time
import numpy as np
from lerobot.robots.openarms.config_openarms_follower import OpenArmsFollowerConfig
from lerobot.robots.openarms.openarms_follower import OpenArmsFollower
from lerobot.teleoperators.openarms.config_openarms_leader import OpenArmsLeaderConfig
from lerobot.teleoperators.openarms.openarms_leader import OpenArmsLeader
# Friction compensation scale factor (1.0 = full, 0.3 = 30% for stability)
FRICTION_SCALE = 1.0
def main():
"""Main teleoperation loop with gravity compensation"""
print("=" * 70)
print("OpenArms Teleoperation with Gravity Compensation")
print("=" * 70)
# Configuration
follower_config = OpenArmsFollowerConfig(
port_left="can2",
port_right="can3",
can_interface="socketcan",
id="openarms_follower",
disable_torque_on_disconnect=True,
max_relative_target=10.0,
)
leader_config = OpenArmsLeaderConfig(
port_left="can0",
port_right="can1",
can_interface="socketcan",
id="openarms_leader",
manual_control=False, # Enable torque control for gravity compensation
)
# Initialize and connect
print("\nInitializing devices...")
follower = OpenArmsFollower(follower_config)
leader = OpenArmsLeader(leader_config)
follower.connect()
leader.connect()
# URDF is automatically loaded in the leader constructor
if leader.pin_robot is None:
raise RuntimeError("URDF model not loaded on leader. Gravity compensation not available.")
print("\nLeader BOTH arms: Gravity + Friction comp | Follower BOTH arms: Teleop")
print("Press ENTER to start...")
input()
# Enable motors on both leader arms for gravity compensation
leader.bus_right.enable_torque()
leader.bus_left.enable_torque()
time.sleep(0.1)
print("Press Ctrl+C to stop\n")
# Main control loop
loop_times = []
last_print_time = time.perf_counter()
# All joints (both arms)
all_joints = []
for motor in leader.bus_right.motors:
all_joints.append(f"right_{motor}")
for motor in leader.bus_left.motors:
all_joints.append(f"left_{motor}")
try:
while True:
loop_start = time.perf_counter()
# Get leader state
leader_action = leader.get_action()
# Extract positions and velocities in degrees
leader_positions_deg = {}
leader_velocities_deg_per_sec = {}
for motor in leader.bus_right.motors:
pos_key = f"right_{motor}.pos"
vel_key = f"right_{motor}.vel"
if pos_key in leader_action:
leader_positions_deg[f"right_{motor}"] = leader_action[pos_key]
if vel_key in leader_action:
leader_velocities_deg_per_sec[f"right_{motor}"] = leader_action[vel_key]
for motor in leader.bus_left.motors:
pos_key = f"left_{motor}.pos"
vel_key = f"left_{motor}.vel"
if pos_key in leader_action:
leader_positions_deg[f"left_{motor}"] = leader_action[pos_key]
if vel_key in leader_action:
leader_velocities_deg_per_sec[f"left_{motor}"] = leader_action[vel_key]
# Calculate gravity torques for leader using built-in method
leader_positions_rad = {k: np.deg2rad(v) for k, v in leader_positions_deg.items()}
leader_gravity_torques_nm = leader._gravity_from_q(leader_positions_rad)
# Calculate friction torques for leader using built-in method
leader_velocities_rad_per_sec = {k: np.deg2rad(v) for k, v in leader_velocities_deg_per_sec.items()}
leader_friction_torques_nm = leader._friction_from_velocity(
leader_velocities_rad_per_sec,
friction_scale=FRICTION_SCALE
)
# Combine gravity + friction torques
leader_total_torques_nm = {}
for motor_name in leader_gravity_torques_nm:
gravity = leader_gravity_torques_nm.get(motor_name, 0.0)
friction = leader_friction_torques_nm.get(motor_name, 0.0)
leader_total_torques_nm[motor_name] = gravity + friction
# Apply gravity + friction compensation to leader RIGHT arm (all joints including gripper)
for motor in leader.bus_right.motors:
full_name = f"right_{motor}"
position = leader_positions_deg.get(full_name, 0.0)
torque = leader_total_torques_nm.get(full_name, 0.0)
# Get damping gain for stability
kd = leader.get_damping_kd(motor)
leader.bus_right._mit_control(
motor=motor,
kp=0.0,
kd=kd, # Add damping for stability
position_degrees=position,
velocity_deg_per_sec=0.0,
torque=torque,
)
# Apply gravity + friction compensation to leader LEFT arm (all joints including gripper)
for motor in leader.bus_left.motors:
full_name = f"left_{motor}"
position = leader_positions_deg.get(full_name, 0.0)
torque = leader_total_torques_nm.get(full_name, 0.0)
# Get damping gain for stability
kd = leader.get_damping_kd(motor)
leader.bus_left._mit_control(
motor=motor,
kp=0.0,
kd=kd, # Add damping for stability
position_degrees=position,
velocity_deg_per_sec=0.0,
torque=torque,
)
# Send leader positions to follower (both arms)
follower_action = {}
for joint in all_joints:
pos_key = f"{joint}.pos"
if pos_key in leader_action:
follower_action[pos_key] = leader_action[pos_key]
if follower_action:
follower.send_action(follower_action)
# Performance monitoring
loop_end = time.perf_counter()
loop_time = loop_end - loop_start
loop_times.append(loop_time)
if loop_end - last_print_time >= 2.0:
if loop_times:
avg_time = sum(loop_times) / len(loop_times)
current_hz = 1.0 / avg_time if avg_time > 0 else 0
print(f"{current_hz:.1f} Hz ({avg_time*1000:.1f} ms)")
loop_times = []
last_print_time = loop_end
except KeyboardInterrupt:
print("\n\nStopping...")
finally:
try:
leader.bus_right.disable_torque()
leader.bus_left.disable_torque()
time.sleep(0.1)
leader.disconnect()
follower.disconnect()
print("✓ Shutdown complete")
except Exception as e:
print(f"Shutdown error: {e}")
if __name__ == "__main__":
main()
examples/openarms_web_interface/App.css
-745
View File
@@ -1,745 +0,0 @@
body {
margin: 0;
padding: 0;
font-family: -apple-system, BlinkMacSystemFont, 'Segoe UI', Roboto, Oxygen, Ubuntu, sans-serif;
background: #f5f5f5;
}
main {
min-height: 100vh;
padding: 2rem;
}
header {
text-align: center;
margin-bottom: 2rem;
}
h1 {
font-size: 2rem;
font-weight: 600;
color: #333;
margin: 0;
}
h2 {
font-size: 1.25rem;
font-weight: 600;
color: #333;
margin: 0 0 1rem 0;
}
h3 {
font-size: 0.875rem;
font-weight: 600;
color: #666;
margin: 0 0 0.5rem 0;
text-transform: uppercase;
letter-spacing: 0.5px;
}
.container {
max-width: 1920px;
margin: 0 auto;
display: grid;
grid-template-columns: minmax(500px, 600px) 1fr;
gap: 2rem;
align-items: start;
}
/* Left column container */
.left-column {
display: flex;
flex-direction: column;
gap: 1.5rem;
}
/* Right column container */
.right-column {
display: flex;
flex-direction: column;
gap: 1.5rem;
}
/* Responsive: Stack on smaller screens */
@media (max-width: 1200px) {
.container {
grid-template-columns: 1fr;
}
}
.panel {
background: white;
border-radius: 8px;
padding: 1.5rem;
box-shadow: 0 1px 3px rgba(0,0,0,0.1);
}
.config-panel {
border: 2px solid #e5e7eb;
}
.config-header {
display: flex;
justify-content: space-between;
align-items: center;
cursor: pointer;
user-select: none;
padding: 0.5rem 0;
}
.config-header:hover {
opacity: 0.7;
}
.toggle-icon {
font-size: 1rem;
color: #6b7280;
transition: transform 0.2s;
}
.config-content {
margin-top: 1rem;
padding-top: 1rem;
border-top: 1px solid #e5e7eb;
}
.robot-setup {
margin-bottom: 0.5rem;
}
.robot-status {
display: flex;
align-items: center;
justify-content: space-between;
padding: 1rem;
border-radius: 6px;
font-weight: 500;
gap: 1rem;
}
.robot-status.ready {
background: linear-gradient(135deg, #d1fae5 0%, #a7f3d0 100%);
color: #065f46;
border: 1px solid #10b981;
}
.robot-status.not-ready {
background: linear-gradient(135deg, #fef3c7 0%, #fde68a 100%);
color: #92400e;
border: 1px solid #f59e0b;
}
.btn-setup {
background: #10b981;
color: white;
border: none;
padding: 0.5rem 1rem;
border-radius: 4px;
font-size: 0.875rem;
font-weight: 500;
cursor: pointer;
transition: background 0.2s;
}
.btn-setup:hover:not(:disabled) {
background: #059669;
}
.btn-setup:disabled {
background: #d1d5db;
cursor: not-allowed;
}
.btn-zero {
background: #8b5cf6;
color: white;
border: none;
padding: 0.5rem 1rem;
border-radius: 4px;
font-size: 0.875rem;
font-weight: 500;
cursor: pointer;
transition: background 0.2s;
}
.btn-zero:hover:not(:disabled) {
background: #7c3aed;
}
.btn-zero:disabled {
background: #d1d5db;
cursor: not-allowed;
}
.zero-position-section {
margin-top: 1rem;
padding-top: 1rem;
border-top: 1px solid #e5e7eb;
}
.btn-zero-large {
width: 100%;
background: #8b5cf6;
color: white;
border: none;
padding: 0.875rem 1.5rem;
border-radius: 8px;
font-size: 1rem;
font-weight: 600;
cursor: pointer;
transition: all 0.2s;
box-shadow: 0 2px 4px rgba(139, 92, 246, 0.2);
}
.btn-zero-large:hover:not(:disabled) {
background: #7c3aed;
box-shadow: 0 4px 8px rgba(139, 92, 246, 0.3);
transform: translateY(-1px);
}
.btn-zero-large:disabled {
background: #d1d5db;
cursor: not-allowed;
box-shadow: none;
transform: none;
}
.delete-episode-section {
margin-top: 1rem;
padding-top: 1rem;
border-top: 1px solid #e5e7eb;
}
.btn-delete {
width: 100%;
background: #ef4444;
color: white;
border: none;
padding: 0.875rem 1.5rem;
border-radius: 8px;
font-size: 1rem;
font-weight: 600;
cursor: pointer;
transition: all 0.2s;
box-shadow: 0 2px 4px rgba(239, 68, 68, 0.2);
}
.btn-delete:hover:not(:disabled) {
background: #dc2626;
box-shadow: 0 4px 8px rgba(239, 68, 68, 0.3);
transform: translateY(-1px);
}
.btn-delete:disabled {
background: #d1d5db;
cursor: not-allowed;
box-shadow: none;
transform: none;
}
.delete-info {
margin-top: 0.5rem;
font-size: 0.875rem;
color: #666;
text-align: center;
font-style: italic;
}
.btn-disconnect {
background: #ef4444;
color: white;
border: none;
padding: 0.5rem 1rem;
border-radius: 4px;
font-size: 0.875rem;
font-weight: 500;
cursor: pointer;
transition: background 0.2s;
}
.btn-disconnect:hover {
background: #dc2626;
}
.btn-refresh {
background: #3b82f6;
color: white;
border: none;
padding: 0.4rem 0.8rem;
border-radius: 4px;
font-size: 0.75rem;
font-weight: 500;
cursor: pointer;
transition: background 0.2s;
}
.btn-refresh:hover:not(:disabled) {
background: #2563eb;
}
.btn-refresh:disabled {
background: #d1d5db;
cursor: not-allowed;
}
.control-panel {
border: 2px solid #10b981;
}
.status-banner {
display: flex;
align-items: center;
gap: 1rem;
padding: 1rem 1.5rem;
border-radius: 6px;
margin-bottom: 1.5rem;
font-weight: 500;
font-size: 0.95rem;
}
.status-banner.initializing {
background: linear-gradient(135deg, #dbeafe 0%, #bfdbfe 100%);
color: #1e40af;
border-left: 4px solid #3b82f6;
}
.status-banner.encoding {
background: linear-gradient(135deg, #fef3c7 0%, #fde68a 100%);
color: #92400e;
border-left: 4px solid #f59e0b;
}
.status-banner.uploading {
background: linear-gradient(135deg, #e0e7ff 0%, #c7d2fe 100%);
color: #3730a3;
border-left: 4px solid #6366f1;
}
.status-banner.success {
background: linear-gradient(135deg, #d1fae5 0%, #a7f3d0 100%);
color: #065f46;
border-left: 4px solid #10b981;
}
.status-banner.warning {
background: linear-gradient(135deg, #fee2e2 0%, #fecaca 100%);
color: #991b1b;
border-left: 4px solid #ef4444;
}
.spinner {
width: 20px;
height: 20px;
border: 3px solid rgba(0, 0, 0, 0.1);
border-top-color: currentColor;
border-radius: 50%;
animation: spin 0.8s linear infinite;
}
@keyframes spin {
to { transform: rotate(360deg); }
}
.control-horizontal {
display: flex;
flex-direction: column;
gap: 1.5rem;
}
.control-left {
display: flex;
flex-direction: column;
gap: 1rem;
}
.control-right {
display: flex;
align-items: center;
justify-content: center;
}
.input-group {
display: flex;
gap: 0.5rem;
margin-bottom: 0;
}
input[type="text"] {
flex: 1;
padding: 0.75rem;
border: 1px solid #ddd;
border-radius: 4px;
font-size: 1rem;
}
input[type="text"]:disabled {
background: #f5f5f5;
cursor: not-allowed;
}
input[type="text"]:focus {
outline: none;
border-color: #10b981;
}
button {
padding: 0.75rem 1.5rem;
border: none;
border-radius: 4px;
font-size: 1rem;
font-weight: 500;
cursor: pointer;
transition: all 0.2s;
}
.btn-set-task {
background: #3b82f6;
color: white;
min-width: 120px;
}
.btn-set-task:hover:not(:disabled) {
background: #2563eb;
}
.btn-set-task:disabled {
background: #d1d5db;
cursor: not-allowed;
}
.btn-start {
background: #10b981;
color: white;
}
.btn-start:hover:not(:disabled) {
background: #059669;
}
.btn-start:disabled {
background: #d1d5db;
cursor: not-allowed;
}
.btn-stop {
background: #ef4444;
color: white;
}
.btn-stop:hover {
background: #dc2626;
}
.btn-reset {
padding: 0.5rem 1rem;
background: #6b7280;
color: white;
font-size: 0.875rem;
}
.btn-reset:hover {
background: #4b5563;
}
.status {
display: flex;
align-items: center;
gap: 0.75rem;
padding: 1rem;
border-radius: 4px;
margin-bottom: 1rem;
}
.status.recording {
background: #fee2e2;
color: #991b1b;
}
.status.recording.recording-active {
display: flex;
flex-direction: column;
gap: 1rem;
background: #dc2626;
color: white;
padding: 1.5rem;
border: 4px solid #991b1b;
box-shadow: 0 4px 12px rgba(220, 38, 38, 0.4);
font-weight: 700;
font-size: 1rem;
}
.status.recording.recording-active .indicator {
width: 20px;
height: 20px;
background: #fef2f2;
animation: pulse-strong 1s ease-in-out infinite;
}
@keyframes pulse-strong {
0%, 100% {
opacity: 1;
transform: scale(1);
}
50% {
opacity: 0.7;
transform: scale(1.1);
}
}
.status.recording.recording-active .time-display {
display: flex;
flex-direction: column;
gap: 0.5rem;
font-size: 1.5rem;
font-weight: 700;
color: white;
}
.fps-display {
font-size: 1rem;
font-weight: 500;
opacity: 0.95;
}
.fps-warning {
color: #fef2f2;
animation: pulse-warning 1s ease-in-out infinite;
}
@keyframes pulse-warning {
0%, 100% { opacity: 1; }
50% { opacity: 0.5; }
}
.status.recording.recording-active .btn-stop {
align-self: stretch;
}
.ramp-up-countdown {
display: flex;
justify-content: center;
margin-bottom: 1rem;
}
.countdown-box {
display: flex;
flex-direction: column;
align-items: center;
justify-content: center;
padding: 2rem 3rem;
background: linear-gradient(135deg, #fef3c7 0%, #fde68a 100%);
border: 4px solid #f59e0b;
border-radius: 16px;
box-shadow: 0 6px 20px rgba(245, 158, 11, 0.4);
min-width: 280px;
animation: pulse-warm 1.5s ease-in-out infinite;
}
@keyframes pulse-warm {
0%, 100% {
box-shadow: 0 6px 20px rgba(245, 158, 11, 0.4);
}
50% {
box-shadow: 0 6px 25px rgba(245, 158, 11, 0.6);
}
}
.countdown-label {
font-size: 1rem;
color: #92400e;
text-transform: uppercase;
letter-spacing: 1.5px;
font-weight: 800;
margin-bottom: 1rem;
text-align: center;
}
.countdown-value {
font-size: 4.5rem;
font-weight: 900;
color: #d97706;
font-family: 'Courier New', monospace;
line-height: 1;
text-shadow: 2px 2px 6px rgba(0, 0, 0, 0.15);
margin-bottom: 0.5rem;
}
.countdown-subtitle {
font-size: 0.875rem;
color: #78350f;
font-weight: 600;
font-style: italic;
text-align: center;
margin-top: 0.5rem;
}
.status.idle {
background: #f3f4f6;
color: #374151;
}
.indicator {
width: 12px;
height: 12px;
border-radius: 50%;
background: #ef4444;
animation: pulse 1.5s ease-in-out infinite;
}
@keyframes pulse {
0%, 100% { opacity: 1; }
50% { opacity: 0.5; }
}
.counter {
display: flex;
flex-direction: column;
align-items: center;
gap: 0.75rem;
padding: 1.5rem;
background: linear-gradient(135deg, #f9fafb 0%, #f3f4f6 100%);
border-radius: 8px;
border: 2px solid #e5e7eb;
min-width: 200px;
}
.counter-label {
font-size: 0.75rem;
color: #6b7280;
text-transform: uppercase;
letter-spacing: 0.5px;
font-weight: 600;
}
.counter-value {
font-size: 3rem;
font-weight: 700;
color: #10b981;
line-height: 1;
}
.time-display {
font-size: 1.5rem;
font-weight: 600;
font-family: 'Courier New', monospace;
}
.error-box {
padding: 1rem;
background: #fee2e2;
color: #991b1b;
border-radius: 4px;
border-left: 4px solid #ef4444;
font-size: 0.875rem;
}
.config-section {
margin-bottom: 1.5rem;
}
.config-section:last-child {
margin-bottom: 0;
}
.config-grid {
display: grid;
grid-template-columns: repeat(auto-fit, minmax(200px, 1fr));
gap: 1rem;
}
label {
display: flex;
flex-direction: column;
gap: 0.5rem;
font-size: 0.875rem;
color: #374151;
font-weight: 500;
}
select {
padding: 0.5rem;
border: 1px solid #ddd;
border-radius: 4px;
font-size: 0.875rem;
background: white;
}
select:disabled {
background: #f5f5f5;
cursor: not-allowed;
}
/* Camera Layout */
.camera-layout {
display: flex;
flex-direction: column;
gap: 1.5rem;
}
.camera-base {
width: 100%;
}
.camera-wrist-container {
display: grid;
grid-template-columns: repeat(2, 1fr);
gap: 1.5rem;
}
.camera-wrist {
width: 100%;
}
.camera {
border: 1px solid #e5e7eb;
border-radius: 4px;
overflow: hidden;
}
.camera h3 {
padding: 0.75rem;
background: #f9fafb;
border-bottom: 1px solid #e5e7eb;
margin: 0;
}
.camera img {
width: 100%;
height: auto;
display: block;
background: #000;
min-height: 300px;
object-fit: cover;
}
.camera-placeholder {
text-align: center;
padding: 4rem 2rem;
background: #f9fafb;
border-radius: 4px;
border: 2px dashed #d1d5db;
}
.camera-placeholder p {
margin: 0.5rem 0;
font-size: 1rem;
color: #6b7280;
}
.camera-placeholder p:first-child {
font-size: 1.25rem;
font-weight: 500;
color: #374151;
}
.hint {
margin-top: 0.5rem;
font-size: 0.75rem;
color: #6b7280;
display: flex;
align-items: center;
gap: 0.5rem;
flex-wrap: wrap;
}
examples/openarms_web_interface/App.jsx
-857
View File
@@ -1,857 +0,0 @@
import { useState, useEffect, useCallback, useRef } from 'react';
import './App.css';
const API_BASE = 'http://localhost:8000/api';
function App() {
// State
const [task, setTask] = useState('');
const [isRecording, setIsRecording] = useState(false);
const [isInitializing, setIsInitializing] = useState(false);
const [isEncoding, setIsEncoding] = useState(false);
const [isUploading, setIsUploading] = useState(false);
const [robotsReady, setRobotsReady] = useState(false);
const [elapsedTime, setElapsedTime] = useState(0);
const [currentFps, setCurrentFps] = useState(0);
const [loopFps, setLoopFps] = useState(0);
const [episodeCount, setEpisodeCount] = useState(0);
const [error, setError] = useState(null);
const [statusMessage, setStatusMessage] = useState('Ready');
const [uploadStatus, setUploadStatus] = useState(null);
const [rampUpRemaining, setRampUpRemaining] = useState(0);
const [movingToZero, setMovingToZero] = useState(false);
const [configExpanded, setConfigExpanded] = useState(false);
const [latestRepoId, setLatestRepoId] = useState(null);
// Configuration
const [config, setConfig] = useState({
leader_type: 'openarms', // 'openarms' or 'openarms_mini'
leader_left: 'can0',
leader_right: 'can1',
follower_left: 'can2',
follower_right: 'can3',
left_wrist: '/dev/video0',
right_wrist: '/dev/video1',
base: '/dev/video4'
});
// Available options
const [availableCameras, setAvailableCameras] = useState([]);
const [availableUsbPorts, setAvailableUsbPorts] = useState([]);
const canInterfaces = ['can0', 'can1', 'can2', 'can3'];
const statusIntervalRef = useRef(null);
const hasInitializedRef = useRef(false);
const loadConfig = () => {
try {
const saved = localStorage.getItem('openarms_config');
if (saved) {
const loadedConfig = JSON.parse(saved);
setConfig(prev => ({ ...prev, ...loadedConfig }));
}
} catch (e) {
console.error('Load config error:', e);
}
};
const saveConfig = (newConfig) => {
try {
localStorage.setItem('openarms_config', JSON.stringify(newConfig || config));
} catch (e) {
console.error('Save config error:', e);
}
};
// Fetch status periodically
const fetchStatus = async () => {
try {
const response = await fetch(`${API_BASE}/status`);
const data = await response.json();
setIsRecording(data.is_recording);
setIsInitializing(data.is_initializing);
setIsEncoding(data.is_encoding);
setIsUploading(data.is_uploading);
setRobotsReady(data.robots_ready);
setElapsedTime(data.elapsed_time);
setCurrentFps(data.current_fps || 0);
setLoopFps(data.loop_fps || 0);
setEpisodeCount(data.episode_count);
setError(data.error);
setStatusMessage(data.status_message || 'Ready');
setUploadStatus(data.upload_status);
setRampUpRemaining(data.ramp_up_remaining || 0);
setMovingToZero(data.moving_to_zero || false);
// Track the latest repo_id from the backend
if (data.latest_repo_id) {
setLatestRepoId(data.latest_repo_id);
}
if (data.config) {
// Only merge server config if we don't have a saved config (first load)
if (!localStorage.getItem('openarms_config')) {
setConfig(prev => {
const merged = { ...data.config, ...prev };
localStorage.setItem('openarms_config', JSON.stringify(merged));
return merged;
});
}
}
} catch (e) {
console.error('Failed to fetch status:', e);
}
};
const setupRobots = async () => {
// Show warning to verify camera positions
const confirmed = window.confirm(
'⚠️ IMPORTANT: Before connecting robots, please verify:\n\n' +
'📹 Check that cameras are correctly positioned:\n' +
' • LEFT wrist camera is actually on the LEFT arm\n' +
' • RIGHT wrist camera is actually on the RIGHT arm\n' +
' • BASE camera is actually the BASE/overhead camera\n\n' +
'Incorrect camera positioning will result in invalid training data!\n\n' +
'Click OK to continue with robot setup, or Cancel to review configuration.'
);
if (!confirmed) {
return; // User cancelled, don't proceed
}
setError(null);
try {
const response = await fetch(`${API_BASE}/robots/setup`, {
method: 'POST',
headers: { 'Content-Type': 'application/json' },
body: JSON.stringify(config)
});
if (!response.ok) {
const data = await response.json();
throw new Error(data.detail || 'Failed to setup robots');
}
await response.json();
saveConfig(config);
} catch (e) {
setError(`Robot setup failed: ${e.message}`);
}
};
// Disconnect robots
const disconnectRobots = async () => {
try {
await fetch(`${API_BASE}/robots/disconnect`, { method: 'POST' });
setRobotsReady(false);
} catch (e) {
console.error('Failed to disconnect robots:', e);
}
};
// Discover cameras
const discoverCameras = async () => {
try {
const response = await fetch(`${API_BASE}/cameras/discover`);
const data = await response.json();
const cameras = data.cameras || [];
setAvailableCameras(cameras);
// Get list of valid camera IDs
const validCameraIds = cameras.map(cam => String(cam.id));
// Auto-fix config if current values are invalid or not set
const updated = { ...config };
let changed = false;
// Auto-fix invalid camera config
if (!config.left_wrist || !validCameraIds.includes(config.left_wrist)) {
if (cameras.length >= 1) {
updated.left_wrist = String(cameras[0].id);
changed = true;
}
}
if (!config.right_wrist || !validCameraIds.includes(config.right_wrist)) {
if (cameras.length >= 2) {
updated.right_wrist = String(cameras[1].id);
changed = true;
}
}
if (!config.base || !validCameraIds.includes(config.base)) {
if (cameras.length >= 3) {
updated.base = String(cameras[2].id);
changed = true;
}
}
if (changed) {
setConfig(updated);
saveConfig(updated);
}
if (cameras.length === 0) {
setError('No cameras detected! Please connect cameras and refresh.');
}
} catch (e) {
console.error('Failed to discover cameras:', e);
setError(`Camera discovery failed: ${e.message}`);
}
};
// Discover USB ports
const discoverUsbPorts = async () => {
try {
const response = await fetch(`${API_BASE}/usb/discover`);
const data = await response.json();
const ports = data.ports || [];
setAvailableUsbPorts(ports);
// Auto-fix config if OpenArms Mini is selected and ports are invalid
if (config.leader_type === 'openarms_mini') {
const updated = { ...config };
let changed = false;
if (ports.length >= 1 && !ports.includes(config.leader_left)) {
updated.leader_left = ports[0];
changed = true;
}
if (ports.length >= 2 && !ports.includes(config.leader_right)) {
updated.leader_right = ports[1];
changed = true;
}
if (changed) {
setConfig(updated);
saveConfig(updated);
}
}
if (ports.length === 0) {
console.warn('No USB ports detected for OpenArms Mini');
}
} catch (e) {
console.error('Failed to discover USB ports:', e);
}
};
// Set task only (for pedal use)
const setTaskOnly = async () => {
if (!task.trim()) {
setError('Please enter a task description');
return;
}
setError(null);
try {
const response = await fetch(`${API_BASE}/recording/set-task`, {
method: 'POST',
headers: { 'Content-Type': 'application/json' },
body: JSON.stringify({ task, ...config })
});
if (!response.ok) {
const data = await response.json();
throw new Error(data.detail || 'Failed to set task');
}
const result = await response.json();
setStatusMessage(result.message || `Task set: ${task}`);
saveConfig(config);
// Clear success message after 3 seconds
setTimeout(() => {
if (!isRecording && !isInitializing) {
setStatusMessage('Ready');
}
}, 3000);
} catch (e) {
setError(e.message);
}
};
// Start recording
const startRecording = async () => {
if (!task.trim()) {
setError('Please enter a task description');
return;
}
setError(null);
try {
const response = await fetch(`${API_BASE}/recording/start`, {
method: 'POST',
headers: { 'Content-Type': 'application/json' },
body: JSON.stringify({ task, ...config })
});
if (!response.ok) {
const data = await response.json();
throw new Error(data.detail || 'Failed to start recording');
}
await response.json();
saveConfig(config);
} catch (e) {
setError(e.message);
}
};
// Stop recording
const stopRecording = async () => {
try {
const response = await fetch(`${API_BASE}/recording/stop`, {
method: 'POST'
});
if (!response.ok) {
const data = await response.json();
throw new Error(data.detail || 'Failed to stop recording');
}
const data = await response.json();
setError(null);
// Update latest repo_id after recording
if (data.dataset_name) {
setLatestRepoId(`lerobot-data-collection/${data.dataset_name}`);
}
} catch (e) {
setError(e.message);
}
};
const deleteLatestEpisode = async () => {
if (!latestRepoId) {
setError('No episode to delete');
return;
}
const confirmed = window.confirm(
`WARNING: This will permanently delete the repository:\n\n${latestRepoId}\n\nThis action cannot be undone. Continue?`
);
if (!confirmed) {
return;
}
try {
const response = await fetch(`${API_BASE}/recording/delete-latest`, { method: 'POST' });
if (!response.ok) {
const data = await response.json();
throw new Error(data.detail || 'Failed to delete episode');
}
const data = await response.json();
setLatestRepoId(null);
setEpisodeCount(Math.max(0, episodeCount - 1));
setStatusMessage(`Deleted: ${data.deleted_repo}`);
setTimeout(() => {
if (!isRecording && !isInitializing) {
setStatusMessage('Ready');
}
}, 3000);
} catch (e) {
setError(`Delete failed: ${e.message}`);
}
};
// Reset counter
const resetCounter = async () => {
try {
await fetch(`${API_BASE}/counter/reset`, { method: 'POST' });
setEpisodeCount(0);
} catch (e) {
console.error('Failed to reset counter:', e);
}
};
// Move robot to zero position
const moveToZero = async () => {
setError(null);
try {
const response = await fetch(`${API_BASE}/robots/move-to-zero`, { method: 'POST' });
if (!response.ok) {
const data = await response.json();
throw new Error(data.detail || 'Failed to move to zero position');
}
await response.json();
} catch (e) {
setError(`Move to zero failed: ${e.message}`);
}
};
// Format time as MM:SS
const formatTime = (seconds) => {
const mins = Math.floor(seconds / 60);
const secs = Math.floor(seconds % 60);
return `${mins.toString().padStart(2, '0')}:${secs.toString().padStart(2, '0')}`;
};
// Update config and save
const updateConfig = (key, value) => {
const updated = { ...config, [key]: value };
setConfig(updated);
saveConfig(updated);
};
// Initialize on mount only
useEffect(() => {
// Prevent double-initialization in development
if (hasInitializedRef.current) {
return;
}
hasInitializedRef.current = true;
loadConfig();
discoverCameras();
discoverUsbPorts();
fetchStatus();
statusIntervalRef.current = setInterval(fetchStatus, 1000);
return () => {
if (statusIntervalRef.current) {
clearInterval(statusIntervalRef.current);
}
};
// eslint-disable-next-line react-hooks/exhaustive-deps
}, []); // Run only once on mount
// Discover USB ports when leader type changes to Mini
useEffect(() => {
if (config.leader_type === 'openarms_mini') {
discoverUsbPorts();
}
// eslint-disable-next-line react-hooks/exhaustive-deps
}, [config.leader_type]);
return (
<main>
<header>
<h1>OpenArms Recording</h1>
</header>
<div className="container">
{/* Left Column: Configuration and Recording Control */}
<div className="left-column">
{/* Configuration Panel */}
<section className="panel config-panel">
<div
className="config-header"
onClick={() => setConfigExpanded(!configExpanded)}
role="button"
tabIndex={0}
onKeyDown={(e) => e.key === 'Enter' && setConfigExpanded(!configExpanded)}
>
<h2> Configuration</h2>
<span className="toggle-icon">{configExpanded ? '▼' : '▶'}</span>
</div>
{configExpanded && (
<div className="config-content">
{/* Robot Setup */}
<div className="config-section">
<h3>🤖 Robot Setup</h3>
<div className="robot-setup">
{robotsReady ? (
<div className="robot-status ready">
<span> Robots Ready - Recording will start instantly</span>
<button onClick={disconnectRobots} className="btn-disconnect">
Disconnect Robots
</button>
</div>
) : (
<div className="robot-status not-ready">
<span> Robots not initialized - Recording will take ~10 seconds</span>
<button
onClick={setupRobots}
disabled={isRecording || isInitializing}
className="btn-setup"
>
🚀 Setup Robots
</button>
</div>
)}
</div>
</div>
{/* Leader Type Selection */}
<div className="config-section">
<h3>🎮 Leader Type</h3>
<div className="config-grid">
<label style={{gridColumn: '1 / -1'}}>
Leader Arm Type
<select
value={config.leader_type}
onChange={(e) => updateConfig('leader_type', e.target.value)}
disabled={isRecording || robotsReady}
>
<option value="openarms">OpenArms (CAN Bus - Damiao Motors)</option>
<option value="openarms_mini">OpenArms Mini (USB - Feetech Motors)</option>
</select>
</label>
</div>
</div>
{/* Leader Interfaces (CAN or USB based on type) */}
<div className="config-section">
<div style={{ display: 'flex', justifyContent: 'space-between', alignItems: 'center', marginBottom: '0.5rem' }}>
<h3>
{config.leader_type === 'openarms_mini'
? `Leader Ports (USB/Serial) ${availableUsbPorts.length > 0 ? `(${availableUsbPorts.length} detected)` : ''}`
: 'Leader Interfaces (CAN)'}
</h3>
{config.leader_type === 'openarms_mini' && (
<button
onClick={discoverUsbPorts}
className="btn-refresh"
disabled={isRecording || robotsReady}
>
🔄 Refresh
</button>
)}
</div>
<div className="config-grid">
<label>
Leader Left
<select
value={config.leader_left}
onChange={(e) => updateConfig('leader_left', e.target.value)}
disabled={isRecording || robotsReady}
>
{config.leader_type === 'openarms_mini' ? (
availableUsbPorts.length > 0 ? (
availableUsbPorts.map((port) => (
<option key={port} value={port}>{port}</option>
))
) : (
<option value="">No USB ports detected</option>
)
) : (
canInterfaces.map((iface) => (
<option key={iface} value={iface}>{iface}</option>
))
)}
</select>
</label>
<label>
Leader Right
<select
value={config.leader_right}
onChange={(e) => updateConfig('leader_right', e.target.value)}
disabled={isRecording || robotsReady}
>
{config.leader_type === 'openarms_mini' ? (
availableUsbPorts.length > 0 ? (
availableUsbPorts.map((port) => (
<option key={port} value={port}>{port}</option>
))
) : (
<option value="">No USB ports detected</option>
)
) : (
canInterfaces.map((iface) => (
<option key={iface} value={iface}>{iface}</option>
))
)}
</select>
</label>
</div>
</div>
{/* Follower CAN Interfaces */}
<div className="config-section">
<h3>Follower Interfaces (CAN)</h3>
<div className="config-grid">
<label>
Follower Left
<select
value={config.follower_left}
onChange={(e) => updateConfig('follower_left', e.target.value)}
disabled={isRecording || robotsReady}
>
{canInterfaces.map((iface) => (
<option key={iface} value={iface}>{iface}</option>
))}
</select>
</label>
<label>
Follower Right
<select
value={config.follower_right}
onChange={(e) => updateConfig('follower_right', e.target.value)}
disabled={isRecording || robotsReady}
>
{canInterfaces.map((iface) => (
<option key={iface} value={iface}>{iface}</option>
))}
</select>
</label>
</div>
</div>
{/* Camera Configuration */}
<div className="config-section">
<div style={{ display: 'flex', justifyContent: 'space-between', alignItems: 'center', marginBottom: '0.5rem' }}>
<h3>Cameras {availableCameras.length > 0 && `(${availableCameras.length} detected)`}</h3>
<button
onClick={discoverCameras}
className="btn-refresh"
disabled={isRecording || robotsReady}
>
🔄 Refresh
</button>
</div>
<div className="config-grid">
<label>
Left Wrist
<select
value={config.left_wrist}
onChange={(e) => updateConfig('left_wrist', e.target.value)}
disabled={isRecording || robotsReady}
>
{availableCameras.map((cam) => (
<option key={cam.id} value={String(cam.id)}>
{cam.name || `Camera @ ${cam.id}`}
</option>
))}
</select>
</label>
<label>
Right Wrist
<select
value={config.right_wrist}
onChange={(e) => updateConfig('right_wrist', e.target.value)}
disabled={isRecording || robotsReady}
>
{availableCameras.map((cam) => (
<option key={cam.id} value={String(cam.id)}>
{cam.name || `Camera @ ${cam.id}`}
</option>
))}
</select>
</label>
<label>
Base Camera
<select
value={config.base}
onChange={(e) => updateConfig('base', e.target.value)}
disabled={isRecording || robotsReady}
>
{availableCameras.map((cam) => (
<option key={cam.id} value={String(cam.id)}>
{cam.name || `Camera @ ${cam.id}`}
</option>
))}
</select>
</label>
</div>
</div>
</div>
)}
</section>
{/* Control Panel */}
<section className="panel control-panel">
<h2>🎬 Recording Control</h2>
{/* Status Banner - Always show important statuses */}
{isInitializing && (
<div className="status-banner initializing">
<div className="spinner"></div>
<span>{statusMessage}</span>
</div>
)}
{isEncoding && (
<div className="status-banner encoding">
<div className="spinner"></div>
<span>📹 {statusMessage}</span>
</div>
)}
{isUploading && (
<div className="status-banner uploading">
<div className="spinner"></div>
<span> {statusMessage}</span>
</div>
)}
{uploadStatus && !isRecording && !isEncoding && !isUploading && (
<div className={`status-banner ${uploadStatus.startsWith('✓') ? 'success' : 'warning'}`}>
<span>{uploadStatus}</span>
</div>
)}
<div className="control-horizontal">
{/* Task Input and Status */}
<div className="control-left">
<div className="input-group">
<input
type="text"
value={task}
onChange={(e) => setTask(e.target.value)}
placeholder="Task description (e.g., 'pick and place')"
disabled={isRecording || isInitializing || isEncoding || isUploading}
onKeyPress={(e) => {
if (e.key === 'Enter' && robotsReady) {
setTaskOnly();
}
}}
/>
<button
onClick={setTaskOnly}
disabled={isRecording || isInitializing || isEncoding || isUploading || !robotsReady}
className="btn-set-task"
title={!robotsReady ? 'Please setup robots first' : 'Store task for pedal use (Enter key)'}
>
💾 Set Task
</button>
<button
onClick={startRecording}
disabled={isRecording || isInitializing || isEncoding || isUploading || !robotsReady}
className="btn-start"
title={!robotsReady ? 'Please setup robots first' : ''}
>
{isInitializing
? '⏳ Initializing...'
: isRecording
? '⏺ Recording...'
: robotsReady
? '⏺ Start Recording'
: '⏺ Setup Robots First'}
</button>
</div>
{/* Ramp-up Countdown */}
{isRecording && rampUpRemaining > 0 && (
<div className="ramp-up-countdown">
<div className="countdown-box">
<div className="countdown-label"> WARMING UP - PID RAMP-UP</div>
<div className="countdown-value">{rampUpRemaining.toFixed(1)}s</div>
<div className="countdown-subtitle">Recording will start automatically...</div>
</div>
</div>
)}
{/* Recording Status - Only show after ramp-up */}
{isRecording && rampUpRemaining <= 0 && (
<div className="status recording recording-active">
<div className="indicator"></div>
<div className="time-display">
<span>{formatTime(elapsedTime)}</span>
<span className="fps-display">
Loop: {loopFps.toFixed(1)} Hz
{loopFps > 0 && loopFps < 29 && <span className="fps-warning"> </span>}
</span>
<span className="fps-display">Recording: {currentFps.toFixed(1)} FPS</span>
</div>
<button onClick={stopRecording} className="btn-stop">
Stop
</button>
</div>
)}
</div>
{/* Episode Counter */}
<div className="control-right">
<div className="counter">
<div className="counter-label">Episodes Recorded</div>
<div className="counter-value">{episodeCount}</div>
<button onClick={resetCounter} className="btn-reset">
Reset
</button>
</div>
</div>
</div>
{/* Delete Latest Episode Button */}
{!isRecording && !isInitializing && latestRepoId && (
<div className="delete-episode-section">
<button
onClick={deleteLatestEpisode}
className="btn-delete"
title="Delete the latest recorded episode from HuggingFace Hub"
>
Delete Latest Episode
</button>
<div className="delete-info">Will delete: {latestRepoId}</div>
</div>
)}
{/* Move to Zero Button */}
{robotsReady && !isRecording && !isInitializing && (
<div className="zero-position-section">
<button
onClick={moveToZero}
disabled={movingToZero}
className="btn-zero-large"
title="Move both leader and follower robots to zero position (2s)"
>
{movingToZero ? '⏳ Moving to Zero Position...' : '🎯 Move to Zero Position (Leader + Follower)'}
</button>
</div>
)}
{/* Error Display */}
{error && (
<div className="error-box">
{error}
</div>
)}
</section>
</div>
{/* Right Column: Camera Feeds */}
<div className="right-column">
<section className="panel cameras">
<h2>📹 Camera Views</h2>
{robotsReady || isRecording || isInitializing ? (
<div className="camera-layout">
{/* Base camera - full width */}
<div className="camera camera-base">
<h3>Base Camera</h3>
<img src={`${API_BASE}/camera/stream/base`} alt="Base Camera" />
</div>
{/* Wrist cameras - side by side */}
<div className="camera-wrist-container">
<div className="camera camera-wrist">
<h3>Left Wrist</h3>
<img src={`${API_BASE}/camera/stream/left_wrist`} alt="Left Wrist Camera" />
</div>
<div className="camera camera-wrist">
<h3>Right Wrist</h3>
<img src={`${API_BASE}/camera/stream/right_wrist`} alt="Right Wrist Camera" />
</div>
</div>
</div>
) : (
<div className="camera-placeholder">
<p>📷 Camera feeds will appear when robots are set up</p>
<p className="hint">Click "Setup Robots" above to preview camera feeds</p>
</div>
)}
</section>
</div>
</div>
</main>
);
}
export default App;
examples/openarms_web_interface/README.md
-41
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@@ -1,41 +0,0 @@
# OpenArms Web Recording Interface
A web interface for recording OpenArms datasets.
## Installation
```bash
cd examples/openarms_web_interface
npm install
```
## Usage
**Start everything with one command:**
```bash
./launch.sh
```
This will:
- Start the FastAPI backend on port 8000
- Start the React frontend on port 5173
- Show live logs from both services
Then open your browser to: **http://localhost:5173**
**Stop with:** `Ctrl+C`
---
## Workflow
1. **Configure CAN interfaces** and **camera paths** in the dropdowns
2. Click **"Setup Robots"** to initialize (once at start)
3. Enter a **task description**
4. Click **"Start Recording"** to begin an episode
5. Click **"Stop Recording"** when done
6. Dataset is automatically encoded and uploaded to HuggingFace Hub as **private**
7. Repeat steps 3-6 for more episodes (no need to re-setup robots!)
---
examples/openarms_web_interface/index.html
-12
View File
@@ -1,12 +0,0 @@
<!doctype html>
<html lang="en">
<head>
<meta charset="UTF-8" />
<meta name="viewport" content="width=device-width, initial-scale=1.0" />
<title>OpenArms Recording Interface</title>
</head>
<body>
<div id="root"></div>
<script type="module" src="/main.jsx"></script>
</body>
</html>
examples/openarms_web_interface/launch.sh
-142
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@@ -1,142 +0,0 @@
#!/bin/bash
# OpenArms Web Interface Launcher
# Starts Rerun viewer, FastAPI backend, and React frontend
set -e
# Colors for output
GREEN='\033[0;32m'
BLUE='\033[0;34m'
YELLOW='\033[1;33m'
RED='\033[0;31m'
NC='\033[0m' # No Color
# Get script directory
SCRIPT_DIR="$( cd "$( dirname "${BASH_SOURCE[0]}" )" && pwd )"
cd "$SCRIPT_DIR"
echo -e "${BLUE}╔════════════════════════════════════════╗${NC}"
echo -e "${BLUE}║ OpenArms Web Recording Interface ║${NC}"
echo -e "${BLUE}╚════════════════════════════════════════╝${NC}"
echo ""
# Function to cleanup on exit
cleanup() {
echo ""
echo -e "${YELLOW}Shutting down services...${NC}"
# Kill all child processes
pkill -P $$ 2>/dev/null || true
# Kill specific services by port
lsof -ti:8000 | xargs kill -9 2>/dev/null || true # Backend
lsof -ti:5173 | xargs kill -9 2>/dev/null || true # Frontend
lsof -ti:9876 | xargs kill -9 2>/dev/null || true # Rerun (if spawned)
echo -e "${GREEN}✓ Services stopped${NC}"
exit 0
}
# Register cleanup on script exit
trap cleanup EXIT INT TERM
# Check if required commands exist
command -v rerun >/dev/null 2>&1 || {
echo -e "${RED}✗ Error: 'rerun' not found. Please install: pip install rerun-sdk${NC}"
exit 1
}
command -v python >/dev/null 2>&1 || {
echo -e "${RED}✗ Error: 'python' not found${NC}"
exit 1
}
command -v npm >/dev/null 2>&1 || {
echo -e "${RED}✗ Error: 'npm' not found${NC}"
exit 1
}
# Check if node_modules exists
if [ ! -d "node_modules" ]; then
echo -e "${YELLOW}⚠ node_modules not found. Running npm install...${NC}"
npm install
echo -e "${GREEN}✓ Dependencies installed${NC}"
echo ""
fi
echo -e "${GREEN}Starting services...${NC}"
echo ""
# 1. Start FastAPI backend (Rerun will start when recording begins)
echo -e "${BLUE}[1/2]${NC} Starting FastAPI backend on port 8000..."
cd "$SCRIPT_DIR"
# Use Python from current environment (if lerobot env is active, it will use that)
# Otherwise, check if we need to use conda run
if [[ "$CONDA_DEFAULT_ENV" == "lerobot" ]]; then
# Already in lerobot environment
echo -e "${GREEN}✓ Using active lerobot environment${NC}"
PYTHON_CMD="python"
elif command -v conda >/dev/null 2>&1 && conda env list | grep -q "^lerobot "; then
# lerobot env exists but not active - use conda run
echo -e "${YELLOW}Using conda run with lerobot environment...${NC}"
PYTHON_CMD="conda run -n lerobot --no-capture-output python"
else
# Fall back to system python
echo -e "${YELLOW}⚠ Warning: lerobot environment not found, using system python${NC}"
PYTHON_CMD="python"
fi
$PYTHON_CMD web_record_server.py > /tmp/openarms_backend.log 2>&1 &
BACKEND_PID=$!
sleep 3
if ps -p $BACKEND_PID > /dev/null; then
echo -e "${GREEN}✓ Backend started${NC} (PID: $BACKEND_PID)"
echo -e " URL: ${BLUE}http://localhost:8000${NC}"
else
echo -e "${RED}✗ Failed to start backend${NC}"
echo -e "${YELLOW}Check logs: tail -f /tmp/openarms_backend.log${NC}"
exit 1
fi
echo ""
# 2. Start React frontend
echo -e "${BLUE}[2/2]${NC} Starting React frontend on port 5173..."
cd "$SCRIPT_DIR"
npm run dev > /tmp/openarms_frontend.log 2>&1 &
FRONTEND_PID=$!
sleep 3
if ps -p $FRONTEND_PID > /dev/null; then
echo -e "${GREEN}✓ Frontend started${NC} (PID: $FRONTEND_PID)"
echo -e " URL: ${BLUE}http://localhost:5173${NC}"
else
echo -e "${RED}✗ Failed to start frontend${NC}"
echo -e "${YELLOW}Check logs: tail -f /tmp/openarms_frontend.log${NC}"
exit 1
fi
echo ""
# Display status
echo -e "${GREEN}╔════════════════════════════════════════╗${NC}"
echo -e "${GREEN}║ All services running! 🚀 ║${NC}"
echo -e "${GREEN}╚════════════════════════════════════════╝${NC}"
echo ""
echo -e "🔧 ${BLUE}Backend:${NC} http://localhost:8000"
echo -e "🌐 ${BLUE}Frontend:${NC} http://localhost:5173"
echo -e "📊 ${BLUE}Rerun:${NC} Will spawn automatically when recording starts"
echo ""
echo -e "${YELLOW}Open your browser to:${NC} ${BLUE}http://localhost:5173${NC}"
echo ""
echo -e "${YELLOW}Logs:${NC}"
echo -e " • Backend: tail -f /tmp/openarms_backend.log"
echo -e " • Frontend: tail -f /tmp/openarms_frontend.log"
echo ""
echo -e "${RED}Press Ctrl+C to stop all services${NC}"
echo ""
# Keep script running and wait for any service to exit
wait
examples/openarms_web_interface/main.jsx
-7
View File
@@ -1,7 +0,0 @@
import { createRoot } from 'react-dom/client'
import App from './App.jsx'
createRoot(document.getElementById('root')).render(
<App />
)
examples/openarms_web_interface/package-lock.json
Generated
-1955
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examples/openarms_web_interface/package.json
-21
View File
@@ -1,21 +0,0 @@
{
"name": "openarms-web-interface",
"private": true,
"version": "0.0.0",
"type": "module",
"scripts": {
"dev": "vite",
"build": "vite build",
"preview": "vite preview"
},
"dependencies": {
"react": "^18.3.1",
"react-dom": "^18.3.1"
},
"devDependencies": {
"@types/react": "^18.3.12",
"@types/react-dom": "^18.3.1",
"@vitejs/plugin-react": "^4.3.4",
"vite": "^6.0.1"
}
}
examples/openarms_web_interface/vite.config.js
-17
View File
@@ -1,17 +0,0 @@
import { defineConfig } from 'vite'
import react from '@vitejs/plugin-react'
// https://vite.dev/config/
export default defineConfig({
plugins: [react()],
server: {
port: 5173,
strictPort: false,
host: true,
open: false
},
build: {
outDir: 'dist',
sourcemap: true
}
})
examples/openarms_web_interface/web_record_server.py
-1533
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examples/phone_to_so100/evaluate.py
+123 -131
View File
@@ -52,114 +52,125 @@ TASK_DESCRIPTION = "My task description"
HF_MODEL_ID = "<hf_username>/<model_repo_id>"
HF_DATASET_ID = "<hf_username>/<dataset_repo_id>"
# Create the robot configuration & robot
camera_config = {"front": OpenCVCameraConfig(index_or_path=0, width=640, height=480, fps=FPS)}
robot_config = SO100FollowerConfig(
port="/dev/tty.usbmodem58760434471",
id="my_awesome_follower_arm",
cameras=camera_config,
use_degrees=True,
)
def main():
# Create the robot configuration & robot
camera_config = {"front": OpenCVCameraConfig(index_or_path=0, width=640, height=480, fps=FPS)}
robot_config = SO100FollowerConfig(
port="/dev/tty.usbmodem58760434471",
id="my_awesome_follower_arm",
cameras=camera_config,
use_degrees=True,
)
robot = SO100Follower(robot_config)
robot = SO100Follower(robot_config)
# Create policy
policy = ACTPolicy.from_pretrained(HF_MODEL_ID)
# Create policy
policy = ACTPolicy.from_pretrained(HF_MODEL_ID)
# NOTE: 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
kinematics_solver = RobotKinematics(
urdf_path="./SO101/so101_new_calib.urdf",
target_frame_name="gripper_frame_link",
joint_names=list(robot.bus.motors.keys()),
)
# NOTE: 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
kinematics_solver = RobotKinematics(
urdf_path="./SO101/so101_new_calib.urdf",
target_frame_name="gripper_frame_link",
joint_names=list(robot.bus.motors.keys()),
)
# Build pipeline to convert EE action to joints action
robot_ee_to_joints_processor = RobotProcessorPipeline[tuple[RobotAction, RobotObservation], RobotAction](
steps=[
InverseKinematicsEEToJoints(
kinematics=kinematics_solver,
motor_names=list(robot.bus.motors.keys()),
initial_guess_current_joints=True,
),
],
to_transition=robot_action_observation_to_transition,
to_output=transition_to_robot_action,
)
# Build pipeline to convert joints observation to EE observation
robot_joints_to_ee_pose_processor = RobotProcessorPipeline[RobotObservation, RobotObservation](
steps=[
ForwardKinematicsJointsToEE(
kinematics=kinematics_solver, motor_names=list(robot.bus.motors.keys())
)
],
to_transition=observation_to_transition,
to_output=transition_to_observation,
)
# Create the dataset
dataset = LeRobotDataset.create(
repo_id=HF_DATASET_ID,
fps=FPS,
features=combine_feature_dicts(
aggregate_pipeline_dataset_features(
pipeline=robot_joints_to_ee_pose_processor,
initial_features=create_initial_features(observation=robot.observation_features),
use_videos=True,
),
# User for now should be explicit on the feature keys that were used for record
# Alternatively, the user can pass the processor step that has the right features
aggregate_pipeline_dataset_features(
pipeline=make_default_teleop_action_processor(),
initial_features=create_initial_features(
action={
f"ee.{k}": PolicyFeature(type=FeatureType.ACTION, shape=(1,))
for k in ["x", "y", "z", "wx", "wy", "wz", "gripper_pos"]
}
),
use_videos=True,
),
# Build pipeline to convert EE action to joints action
robot_ee_to_joints_processor = RobotProcessorPipeline[tuple[RobotAction, RobotObservation], RobotAction](
steps=[
InverseKinematicsEEToJoints(
kinematics=kinematics_solver,
motor_names=list(robot.bus.motors.keys()),
initial_guess_current_joints=True,
),
robot_type=robot.name,
use_videos=True,
image_writer_threads=4,
],
to_transition=robot_action_observation_to_transition,
to_output=transition_to_robot_action,
)
# Build pipeline to convert joints observation to EE observation
robot_joints_to_ee_pose_processor = RobotProcessorPipeline[RobotObservation, RobotObservation](
steps=[
ForwardKinematicsJointsToEE(kinematics=kinematics_solver, motor_names=list(robot.bus.motors.keys()))
],
to_transition=observation_to_transition,
to_output=transition_to_observation,
)
# Create the dataset
dataset = LeRobotDataset.create(
repo_id=HF_DATASET_ID,
fps=FPS,
features=combine_feature_dicts(
aggregate_pipeline_dataset_features(
pipeline=robot_joints_to_ee_pose_processor,
initial_features=create_initial_features(observation=robot.observation_features),
use_videos=True,
),
# User for now should be explicit on the feature keys that were used for record
# Alternatively, the user can pass the processor step that has the right features
aggregate_pipeline_dataset_features(
pipeline=make_default_teleop_action_processor(),
initial_features=create_initial_features(
action={
f"ee.{k}": PolicyFeature(type=FeatureType.ACTION, shape=(1,))
for k in ["x", "y", "z", "wx", "wy", "wz", "gripper_pos"]
}
),
use_videos=True,
),
),
robot_type=robot.name,
use_videos=True,
image_writer_threads=4,
)
# Build Policy Processors
preprocessor, postprocessor = make_pre_post_processors(
policy_cfg=policy,
pretrained_path=HF_MODEL_ID,
dataset_stats=dataset.meta.stats,
# The inference device is automatically set to match the detected hardware, overriding any previous device settings from training to ensure compatibility.
preprocessor_overrides={"device_processor": {"device": str(policy.config.device)}},
)
# Connect the robot
robot.connect()
# Initialize the keyboard listener and rerun visualization
listener, events = init_keyboard_listener()
init_rerun(session_name="phone_so100_evaluate")
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}")
# 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,
)
# Build Policy Processors
preprocessor, postprocessor = make_pre_post_processors(
policy_cfg=policy,
pretrained_path=HF_MODEL_ID,
dataset_stats=dataset.meta.stats,
# The inference device is automatically set to match the detected hardware, overriding any previous device settings from training to ensure compatibility.
preprocessor_overrides={"device_processor": {"device": str(policy.config.device)}},
)
# Connect the robot
robot.connect()
# Initialize the keyboard listener and rerun visualization
listener, events = init_keyboard_listener()
init_rerun(session_name="phone_so100_evaluate")
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}")
# Main record loop
# 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,
@@ -168,40 +179,21 @@ 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
# 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()
if __name__ == "__main__":
main()
dataset.finalize()
dataset.push_to_hub()
examples/phone_to_so100/record.py
+132 -141
View File
@@ -50,122 +50,133 @@ RESET_TIME_SEC = 30
TASK_DESCRIPTION = "My task description"
HF_REPO_ID = "<hf_username>/<dataset_repo_id>"
# Create the robot and teleoperator configurations
camera_config = {"front": OpenCVCameraConfig(index_or_path=0, width=640, height=480, fps=FPS)}
robot_config = SO100FollowerConfig(
port="/dev/tty.usbmodem5A460814411",
id="my_awesome_follower_arm",
cameras=camera_config,
use_degrees=True,
)
teleop_config = PhoneConfig(phone_os=PhoneOS.IOS) # or PhoneOS.ANDROID
def main():
# Create the robot and teleoperator configurations
camera_config = {"front": OpenCVCameraConfig(index_or_path=0, width=640, height=480, fps=FPS)}
robot_config = SO100FollowerConfig(
port="/dev/tty.usbmodem5A460814411",
id="my_awesome_follower_arm",
cameras=camera_config,
use_degrees=True,
)
teleop_config = PhoneConfig(phone_os=PhoneOS.IOS) # or PhoneOS.ANDROID
# Initialize the robot and teleoperator
robot = SO100Follower(robot_config)
phone = Phone(teleop_config)
# Initialize the robot and teleoperator
robot = SO100Follower(robot_config)
phone = Phone(teleop_config)
# NOTE: 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
kinematics_solver = RobotKinematics(
urdf_path="./SO101/so101_new_calib.urdf",
target_frame_name="gripper_frame_link",
joint_names=list(robot.bus.motors.keys()),
)
# NOTE: 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
kinematics_solver = RobotKinematics(
urdf_path="./SO101/so101_new_calib.urdf",
target_frame_name="gripper_frame_link",
joint_names=list(robot.bus.motors.keys()),
)
# Build pipeline to convert phone action to EE action
phone_to_robot_ee_pose_processor = RobotProcessorPipeline[
tuple[RobotAction, RobotObservation], RobotAction
](
steps=[
MapPhoneActionToRobotAction(platform=teleop_config.phone_os),
EEReferenceAndDelta(
kinematics=kinematics_solver,
end_effector_step_sizes={"x": 0.5, "y": 0.5, "z": 0.5},
motor_names=list(robot.bus.motors.keys()),
use_latched_reference=True,
),
EEBoundsAndSafety(
end_effector_bounds={"min": [-1.0, -1.0, -1.0], "max": [1.0, 1.0, 1.0]},
max_ee_step_m=0.20,
),
GripperVelocityToJoint(speed_factor=20.0),
],
to_transition=robot_action_observation_to_transition,
to_output=transition_to_robot_action,
)
# Build pipeline to convert EE action to joints action
robot_ee_to_joints_processor = RobotProcessorPipeline[tuple[RobotAction, RobotObservation], RobotAction](
steps=[
InverseKinematicsEEToJoints(
kinematics=kinematics_solver,
motor_names=list(robot.bus.motors.keys()),
initial_guess_current_joints=True,
),
],
to_transition=robot_action_observation_to_transition,
to_output=transition_to_robot_action,
)
# Build pipeline to convert joint observation to EE observation
robot_joints_to_ee_pose = RobotProcessorPipeline[RobotObservation, RobotObservation](
steps=[
ForwardKinematicsJointsToEE(
kinematics=kinematics_solver, motor_names=list(robot.bus.motors.keys())
)
],
to_transition=observation_to_transition,
to_output=transition_to_observation,
)
# Create the dataset
dataset = LeRobotDataset.create(
repo_id=HF_REPO_ID,
fps=FPS,
features=combine_feature_dicts(
# Run the feature contract of the pipelines
# This tells you how the features would look like after the pipeline steps
aggregate_pipeline_dataset_features(
pipeline=phone_to_robot_ee_pose_processor,
initial_features=create_initial_features(action=phone.action_features),
use_videos=True,
),
aggregate_pipeline_dataset_features(
pipeline=robot_joints_to_ee_pose,
initial_features=create_initial_features(observation=robot.observation_features),
use_videos=True,
),
# Build pipeline to convert phone action to EE action
phone_to_robot_ee_pose_processor = RobotProcessorPipeline[tuple[RobotAction, RobotObservation], RobotAction](
steps=[
MapPhoneActionToRobotAction(platform=teleop_config.phone_os),
EEReferenceAndDelta(
kinematics=kinematics_solver,
end_effector_step_sizes={"x": 0.5, "y": 0.5, "z": 0.5},
motor_names=list(robot.bus.motors.keys()),
use_latched_reference=True,
),
robot_type=robot.name,
use_videos=True,
image_writer_threads=4,
EEBoundsAndSafety(
end_effector_bounds={"min": [-1.0, -1.0, -1.0], "max": [1.0, 1.0, 1.0]},
max_ee_step_m=0.20,
),
GripperVelocityToJoint(speed_factor=20.0),
],
to_transition=robot_action_observation_to_transition,
to_output=transition_to_robot_action,
)
# Build pipeline to convert EE action to joints action
robot_ee_to_joints_processor = RobotProcessorPipeline[tuple[RobotAction, RobotObservation], RobotAction](
steps=[
InverseKinematicsEEToJoints(
kinematics=kinematics_solver,
motor_names=list(robot.bus.motors.keys()),
initial_guess_current_joints=True,
),
],
to_transition=robot_action_observation_to_transition,
to_output=transition_to_robot_action,
)
# Build pipeline to convert joint observation to EE observation
robot_joints_to_ee_pose = RobotProcessorPipeline[RobotObservation, RobotObservation](
steps=[
ForwardKinematicsJointsToEE(kinematics=kinematics_solver, motor_names=list(robot.bus.motors.keys()))
],
to_transition=observation_to_transition,
to_output=transition_to_observation,
)
# Create the dataset
dataset = LeRobotDataset.create(
repo_id=HF_REPO_ID,
fps=FPS,
features=combine_feature_dicts(
# Run the feature contract of the pipelines
# This tells you how the features would look like after the pipeline steps
aggregate_pipeline_dataset_features(
pipeline=phone_to_robot_ee_pose_processor,
initial_features=create_initial_features(action=phone.action_features),
use_videos=True,
),
aggregate_pipeline_dataset_features(
pipeline=robot_joints_to_ee_pose,
initial_features=create_initial_features(observation=robot.observation_features),
use_videos=True,
),
),
robot_type=robot.name,
use_videos=True,
image_writer_threads=4,
)
# Connect the robot and teleoperator
robot.connect()
phone.connect()
# Initialize the keyboard listener and rerun visualization
listener, events = init_keyboard_listener()
init_rerun(session_name="phone_so100_record")
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}")
# 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,
)
# Connect the robot and teleoperator
robot.connect()
phone.connect()
# Initialize the keyboard listener and rerun visualization
listener, events = init_keyboard_listener()
init_rerun(session_name="phone_so100_record")
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}")
# Main record loop
# 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,
@@ -173,42 +184,22 @@ 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
# 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()
if __name__ == "__main__":
main()
dataset.finalize()
dataset.push_to_hub()
examples/phone_to_so100/replay.py
+51 -57
View File
@@ -29,78 +29,72 @@ from lerobot.robots.so100_follower.robot_kinematic_processor import (
)
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.robot_utils import busy_wait
from lerobot.utils.utils import log_say
EPISODE_IDX = 0
HF_REPO_ID = "<hf_username>/<dataset_repo_id>"
# Initialize the robot config
robot_config = SO100FollowerConfig(
port="/dev/tty.usbmodem5A460814411", id="my_awesome_follower_arm", use_degrees=True
)
def main():
# Initialize the robot config
robot_config = SO100FollowerConfig(
port="/dev/tty.usbmodem5A460814411", id="my_awesome_follower_arm", use_degrees=True
)
# Initialize the robot
robot = SO100Follower(robot_config)
# Initialize the robot
robot = SO100Follower(robot_config)
# NOTE: 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
kinematics_solver = RobotKinematics(
urdf_path="./SO101/so101_new_calib.urdf",
target_frame_name="gripper_frame_link",
joint_names=list(robot.bus.motors.keys()),
)
# NOTE: 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
kinematics_solver = RobotKinematics(
urdf_path="./SO101/so101_new_calib.urdf",
target_frame_name="gripper_frame_link",
joint_names=list(robot.bus.motors.keys()),
)
# Build pipeline to convert EE action to joints action
robot_ee_to_joints_processor = RobotProcessorPipeline[tuple[RobotAction, RobotObservation], RobotAction](
steps=[
InverseKinematicsEEToJoints(
kinematics=kinematics_solver,
motor_names=list(robot.bus.motors.keys()),
initial_guess_current_joints=False, # Because replay is open loop
),
],
to_transition=robot_action_observation_to_transition,
to_output=transition_to_robot_action,
)
# Build pipeline to convert EE action to joints action
robot_ee_to_joints_processor = RobotProcessorPipeline[tuple[RobotAction, RobotObservation], RobotAction](
steps=[
InverseKinematicsEEToJoints(
kinematics=kinematics_solver,
motor_names=list(robot.bus.motors.keys()),
initial_guess_current_joints=False, # Because replay is open loop
),
],
to_transition=robot_action_observation_to_transition,
to_output=transition_to_robot_action,
)
# Fetch the dataset to replay
dataset = LeRobotDataset(HF_REPO_ID, episodes=[EPISODE_IDX])
# Filter dataset to only include frames from the specified episode since episodes are chunked in dataset V3.0
episode_frames = dataset.hf_dataset.filter(lambda x: x["episode_index"] == EPISODE_IDX)
actions = episode_frames.select_columns(ACTION)
# Fetch the dataset to replay
dataset = LeRobotDataset(HF_REPO_ID, episodes=[EPISODE_IDX])
# Filter dataset to only include frames from the specified episode since episodes are chunked in dataset V3.0
episode_frames = dataset.hf_dataset.filter(lambda x: x["episode_index"] == EPISODE_IDX)
actions = episode_frames.select_columns(ACTION)
# Connect to the robot
robot.connect()
# Connect to the robot
robot.connect()
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)
busy_wait(1.0 / dataset.fps - (time.perf_counter() - t0))
precise_sleep(1.0 / dataset.fps - (time.perf_counter() - t0))
# Clean up
robot.disconnect()
if __name__ == "__main__":
main()
# Clean up
robot.disconnect()
examples/phone_to_so100/teleoperate.py
+62 -70
View File
@@ -32,90 +32,82 @@ 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
from lerobot.utils.robot_utils import precise_sleep
from lerobot.utils.robot_utils import busy_wait
from lerobot.utils.visualization_utils import init_rerun, log_rerun_data
FPS = 30
# Initialize the robot and teleoperator
robot_config = SO100FollowerConfig(
port="/dev/tty.usbmodem5A460814411", id="my_awesome_follower_arm", use_degrees=True
)
teleop_config = PhoneConfig(phone_os=PhoneOS.IOS) # or PhoneOS.ANDROID
def main():
# Initialize the robot and teleoperator
robot_config = SO100FollowerConfig(
port="/dev/tty.usbmodem5A460814411", id="my_awesome_follower_arm", use_degrees=True
)
teleop_config = PhoneConfig(phone_os=PhoneOS.IOS) # or PhoneOS.ANDROID
# Initialize the robot and teleoperator
robot = SO100Follower(robot_config)
teleop_device = Phone(teleop_config)
# Initialize the robot and teleoperator
robot = SO100Follower(robot_config)
teleop_device = Phone(teleop_config)
# NOTE: 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
kinematics_solver = RobotKinematics(
urdf_path="./SO101/so101_new_calib.urdf",
target_frame_name="gripper_frame_link",
joint_names=list(robot.bus.motors.keys()),
)
# NOTE: 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
kinematics_solver = RobotKinematics(
urdf_path="./SO101/so101_new_calib.urdf",
target_frame_name="gripper_frame_link",
joint_names=list(robot.bus.motors.keys()),
)
# Build pipeline to convert phone action to ee pose action to joint action
phone_to_robot_joints_processor = RobotProcessorPipeline[tuple[RobotAction, RobotObservation], RobotAction](
steps=[
MapPhoneActionToRobotAction(platform=teleop_config.phone_os),
EEReferenceAndDelta(
kinematics=kinematics_solver,
end_effector_step_sizes={"x": 0.5, "y": 0.5, "z": 0.5},
motor_names=list(robot.bus.motors.keys()),
use_latched_reference=True,
),
EEBoundsAndSafety(
end_effector_bounds={"min": [-1.0, -1.0, -1.0], "max": [1.0, 1.0, 1.0]},
max_ee_step_m=0.10,
),
GripperVelocityToJoint(
speed_factor=20.0,
),
InverseKinematicsEEToJoints(
kinematics=kinematics_solver,
motor_names=list(robot.bus.motors.keys()),
initial_guess_current_joints=True,
),
],
to_transition=robot_action_observation_to_transition,
to_output=transition_to_robot_action,
)
# Build pipeline to convert phone action to ee pose action to joint action
phone_to_robot_joints_processor = RobotProcessorPipeline[
tuple[RobotAction, RobotObservation], RobotAction
](
steps=[
MapPhoneActionToRobotAction(platform=teleop_config.phone_os),
EEReferenceAndDelta(
kinematics=kinematics_solver,
end_effector_step_sizes={"x": 0.5, "y": 0.5, "z": 0.5},
motor_names=list(robot.bus.motors.keys()),
use_latched_reference=True,
),
EEBoundsAndSafety(
end_effector_bounds={"min": [-1.0, -1.0, -1.0], "max": [1.0, 1.0, 1.0]},
max_ee_step_m=0.10,
),
GripperVelocityToJoint(
speed_factor=20.0,
),
InverseKinematicsEEToJoints(
kinematics=kinematics_solver,
motor_names=list(robot.bus.motors.keys()),
initial_guess_current_joints=True,
),
],
to_transition=robot_action_observation_to_transition,
to_output=transition_to_robot_action,
)
# Connect to the robot and teleoperator
robot.connect()
teleop_device.connect()
# Connect to the robot and teleoperator
robot.connect()
teleop_device.connect()
# Init rerun viewer
init_rerun(session_name="phone_so100_teleop")
# Init rerun viewer
init_rerun(session_name="phone_so100_teleop")
if not robot.is_connected or not teleop_device.is_connected:
raise ValueError("Robot or teleop is not connected!")
if not robot.is_connected or not teleop_device.is_connected:
raise ValueError("Robot or teleop is not connected!")
print("Starting teleop loop. Move your phone to teleoperate the robot...")
while True:
t0 = time.perf_counter()
print("Starting teleop loop. Move your phone to teleoperate the robot...")
while True:
t0 = time.perf_counter()
# Get robot observation
robot_obs = robot.get_observation()
# Get robot observation
robot_obs = robot.get_observation()
# Get teleop action
phone_obs = teleop_device.get_action()
# Get teleop action
phone_obs = teleop_device.get_action()
# Phone -> EE pose -> Joints transition
joint_action = phone_to_robot_joints_processor((phone_obs, robot_obs))
# Phone -> EE pose -> Joints transition
joint_action = phone_to_robot_joints_processor((phone_obs, robot_obs))
# Send action to robot
_ = robot.send_action(joint_action)
# Send action to robot
_ = robot.send_action(joint_action)
# Visualize
log_rerun_data(observation=phone_obs, action=joint_action)
# Visualize
log_rerun_data(observation=phone_obs, action=joint_action)
precise_sleep(max(1.0 / FPS - (time.perf_counter() - t0), 0.0))
if __name__ == "__main__":
main()
busy_wait(max(1.0 / FPS - (time.perf_counter() - t0), 0.0))
examples/so100_to_so100_EE/evaluate.py
+124 -131
View File
@@ -52,114 +52,126 @@ TASK_DESCRIPTION = "My task description"
HF_MODEL_ID = "<hf_username>/<model_repo_id>"
HF_DATASET_ID = "<hf_username>/<dataset_repo_id>"
# Create the robot configuration & robot
camera_config = {"front": OpenCVCameraConfig(index_or_path=0, width=640, height=480, fps=FPS)}
robot_config = SO100FollowerConfig(
port="/dev/tty.usbmodem5A460814411",
id="my_awesome_follower_arm",
cameras=camera_config,
use_degrees=True,
)
def main():
# Create the robot configuration & robot
camera_config = {"front": OpenCVCameraConfig(index_or_path=0, width=640, height=480, fps=FPS)}
robot_config = SO100FollowerConfig(
port="/dev/tty.usbmodem5A460814411",
id="my_awesome_follower_arm",
cameras=camera_config,
use_degrees=True,
)
robot = SO100Follower(robot_config)
robot = SO100Follower(robot_config)
# Create policy
policy = ACTPolicy.from_pretrained(HF_MODEL_ID)
# Create policy
policy = ACTPolicy.from_pretrained(HF_MODEL_ID)
# NOTE: 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
kinematics_solver = RobotKinematics(
urdf_path="./SO101/so101_new_calib.urdf",
target_frame_name="gripper_frame_link",
joint_names=list(robot.bus.motors.keys()),
)
# NOTE: 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
kinematics_solver = RobotKinematics(
urdf_path="./SO101/so101_new_calib.urdf",
target_frame_name="gripper_frame_link",
joint_names=list(robot.bus.motors.keys()),
)
# Build pipeline to convert EE action to joints action
robot_ee_to_joints_processor = RobotProcessorPipeline[tuple[RobotAction, RobotObservation], RobotAction](
steps=[
InverseKinematicsEEToJoints(
kinematics=kinematics_solver,
motor_names=list(robot.bus.motors.keys()),
initial_guess_current_joints=True,
),
],
to_transition=robot_action_observation_to_transition,
to_output=transition_to_robot_action,
)
# Build pipeline to convert joints observation to EE observation
robot_joints_to_ee_pose_processor = RobotProcessorPipeline[RobotObservation, RobotObservation](
steps=[
ForwardKinematicsJointsToEE(
kinematics=kinematics_solver, motor_names=list(robot.bus.motors.keys())
)
],
to_transition=observation_to_transition,
to_output=transition_to_observation,
)
# Create the dataset
dataset = LeRobotDataset.create(
repo_id=HF_DATASET_ID,
fps=FPS,
features=combine_feature_dicts(
aggregate_pipeline_dataset_features(
pipeline=robot_joints_to_ee_pose_processor,
initial_features=create_initial_features(observation=robot.observation_features),
use_videos=True,
),
# User for now should be explicit on the feature keys that were used for record
# Alternatively, the user can pass the processor step that has the right features
aggregate_pipeline_dataset_features(
pipeline=make_default_teleop_action_processor(),
initial_features=create_initial_features(
action={
f"ee.{k}": PolicyFeature(type=FeatureType.ACTION, shape=(1,))
for k in ["x", "y", "z", "wx", "wy", "wz", "gripper_pos"]
}
),
use_videos=True,
),
# Build pipeline to convert EE action to joints action
robot_ee_to_joints_processor = RobotProcessorPipeline[tuple[RobotAction, RobotObservation], RobotAction](
steps=[
InverseKinematicsEEToJoints(
kinematics=kinematics_solver,
motor_names=list(robot.bus.motors.keys()),
initial_guess_current_joints=True,
),
robot_type=robot.name,
use_videos=True,
image_writer_threads=4,
],
to_transition=robot_action_observation_to_transition,
to_output=transition_to_robot_action,
)
# Build pipeline to convert joints observation to EE observation
robot_joints_to_ee_pose_processor = RobotProcessorPipeline[RobotObservation, RobotObservation](
steps=[
ForwardKinematicsJointsToEE(kinematics=kinematics_solver, motor_names=list(robot.bus.motors.keys()))
],
to_transition=observation_to_transition,
to_output=transition_to_observation,
)
# Create the dataset
dataset = LeRobotDataset.create(
repo_id=HF_DATASET_ID,
fps=FPS,
features=combine_feature_dicts(
aggregate_pipeline_dataset_features(
pipeline=robot_joints_to_ee_pose_processor,
initial_features=create_initial_features(observation=robot.observation_features),
use_videos=True,
),
# User for now should be explicit on the feature keys that were used for record
# Alternatively, the user can pass the processor step that has the right features
aggregate_pipeline_dataset_features(
pipeline=make_default_teleop_action_processor(),
initial_features=create_initial_features(
action={
f"ee.{k}": PolicyFeature(type=FeatureType.ACTION, shape=(1,))
for k in ["x", "y", "z", "wx", "wy", "wz", "gripper_pos"]
}
),
use_videos=True,
),
),
robot_type=robot.name,
use_videos=True,
image_writer_threads=4,
)
# Build Policy Processors
preprocessor, postprocessor = make_pre_post_processors(
policy_cfg=policy,
pretrained_path=HF_MODEL_ID,
dataset_stats=dataset.meta.stats,
# The inference device is automatically set to match the detected hardware, overriding any previous device settings from training to ensure compatibility.
preprocessor_overrides={"device_processor": {"device": str(policy.config.device)}},
)
# Connect the robot and teleoperator
robot.connect()
# Initialize the keyboard listener and rerun visualization
listener, events = init_keyboard_listener()
init_rerun(session_name="so100_so100_evaluate")
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}")
# 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,
)
# Build Policy Processors
preprocessor, postprocessor = make_pre_post_processors(
policy_cfg=policy,
pretrained_path=HF_MODEL_ID,
dataset_stats=dataset.meta.stats,
# The inference device is automatically set to match the detected hardware, overriding any previous device settings from training to ensure compatibility.
preprocessor_overrides={"device_processor": {"device": str(policy.config.device)}},
)
# Connect the robot and teleoperator
robot.connect()
# Initialize the keyboard listener and rerun visualization
listener, events = init_keyboard_listener()
init_rerun(session_name="so100_so100_evaluate")
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}")
# Main record loop
# 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,
@@ -168,40 +180,21 @@ 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
# 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()
if __name__ == "__main__":
main()
dataset.finalize()
dataset.push_to_hub()
examples/so100_to_so100_EE/record.py
+132 -140
View File
@@ -48,122 +48,134 @@ RESET_TIME_SEC = 30
TASK_DESCRIPTION = "My task description"
HF_REPO_ID = "<hf_username>/<dataset_repo_id>"
# Create the robot and teleoperator configurations
camera_config = {"front": OpenCVCameraConfig(index_or_path=0, width=640, height=480, fps=FPS)}
follower_config = SO100FollowerConfig(
port="/dev/tty.usbmodem5A460814411", id="my_awesome_follower_arm", cameras=camera_config, use_degrees=True
)
leader_config = SO100LeaderConfig(port="/dev/tty.usbmodem5A460819811", id="my_awesome_leader_arm")
def main():
# Create the robot and teleoperator configurations
camera_config = {"front": OpenCVCameraConfig(index_or_path=0, width=640, height=480, fps=FPS)}
follower_config = SO100FollowerConfig(
port="/dev/tty.usbmodem5A460814411",
id="my_awesome_follower_arm",
cameras=camera_config,
use_degrees=True,
)
leader_config = SO100LeaderConfig(port="/dev/tty.usbmodem5A460819811", id="my_awesome_leader_arm")
# Initialize the robot and teleoperator
follower = SO100Follower(follower_config)
leader = SO100Leader(leader_config)
# Initialize the robot and teleoperator
follower = SO100Follower(follower_config)
leader = SO100Leader(leader_config)
# NOTE: 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
follower_kinematics_solver = RobotKinematics(
urdf_path="./SO101/so101_new_calib.urdf",
target_frame_name="gripper_frame_link",
joint_names=list(follower.bus.motors.keys()),
)
# NOTE: 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
follower_kinematics_solver = RobotKinematics(
urdf_path="./SO101/so101_new_calib.urdf",
target_frame_name="gripper_frame_link",
joint_names=list(follower.bus.motors.keys()),
)
# NOTE: 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
leader_kinematics_solver = RobotKinematics(
urdf_path="./SO101/so101_new_calib.urdf",
target_frame_name="gripper_frame_link",
joint_names=list(leader.bus.motors.keys()),
)
# NOTE: 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
leader_kinematics_solver = RobotKinematics(
urdf_path="./SO101/so101_new_calib.urdf",
target_frame_name="gripper_frame_link",
joint_names=list(leader.bus.motors.keys()),
)
# Build pipeline to convert follower joints to EE observation
follower_joints_to_ee = RobotProcessorPipeline[RobotObservation, RobotObservation](
steps=[
ForwardKinematicsJointsToEE(
kinematics=follower_kinematics_solver, motor_names=list(follower.bus.motors.keys())
),
],
to_transition=observation_to_transition,
to_output=transition_to_observation,
)
# Build pipeline to convert leader joints to EE action
leader_joints_to_ee = RobotProcessorPipeline[tuple[RobotAction, RobotObservation], RobotAction](
steps=[
ForwardKinematicsJointsToEE(
kinematics=leader_kinematics_solver, motor_names=list(leader.bus.motors.keys())
),
],
to_transition=robot_action_observation_to_transition,
to_output=transition_to_robot_action,
)
# Build pipeline to convert EE action to follower joints
ee_to_follower_joints = RobotProcessorPipeline[tuple[RobotAction, RobotObservation], RobotAction](
[
EEBoundsAndSafety(
end_effector_bounds={"min": [-1.0, -1.0, -1.0], "max": [1.0, 1.0, 1.0]},
max_ee_step_m=0.10,
),
InverseKinematicsEEToJoints(
kinematics=follower_kinematics_solver,
motor_names=list(follower.bus.motors.keys()),
initial_guess_current_joints=True,
),
],
to_transition=robot_action_observation_to_transition,
to_output=transition_to_robot_action,
)
# Create the dataset
dataset = LeRobotDataset.create(
repo_id=HF_REPO_ID,
fps=FPS,
features=combine_feature_dicts(
# Run the feature contract of the pipelines
# This tells you how the features would look like after the pipeline steps
aggregate_pipeline_dataset_features(
pipeline=leader_joints_to_ee,
initial_features=create_initial_features(action=leader.action_features),
use_videos=True,
),
aggregate_pipeline_dataset_features(
pipeline=follower_joints_to_ee,
initial_features=create_initial_features(observation=follower.observation_features),
use_videos=True,
),
# Build pipeline to convert follower joints to EE observation
follower_joints_to_ee = RobotProcessorPipeline[RobotObservation, RobotObservation](
steps=[
ForwardKinematicsJointsToEE(
kinematics=follower_kinematics_solver, motor_names=list(follower.bus.motors.keys())
),
robot_type=follower.name,
use_videos=True,
image_writer_threads=4,
],
to_transition=observation_to_transition,
to_output=transition_to_observation,
)
# Build pipeline to convert leader joints to EE action
leader_joints_to_ee = RobotProcessorPipeline[tuple[RobotAction, RobotObservation], RobotAction](
steps=[
ForwardKinematicsJointsToEE(
kinematics=leader_kinematics_solver, motor_names=list(leader.bus.motors.keys())
),
],
to_transition=robot_action_observation_to_transition,
to_output=transition_to_robot_action,
)
# Build pipeline to convert EE action to follower joints
ee_to_follower_joints = RobotProcessorPipeline[tuple[RobotAction, RobotObservation], RobotAction](
[
EEBoundsAndSafety(
end_effector_bounds={"min": [-1.0, -1.0, -1.0], "max": [1.0, 1.0, 1.0]},
max_ee_step_m=0.10,
),
InverseKinematicsEEToJoints(
kinematics=follower_kinematics_solver,
motor_names=list(follower.bus.motors.keys()),
initial_guess_current_joints=True,
),
],
to_transition=robot_action_observation_to_transition,
to_output=transition_to_robot_action,
)
# Create the dataset
dataset = LeRobotDataset.create(
repo_id=HF_REPO_ID,
fps=FPS,
features=combine_feature_dicts(
# Run the feature contract of the pipelines
# This tells you how the features would look like after the pipeline steps
aggregate_pipeline_dataset_features(
pipeline=leader_joints_to_ee,
initial_features=create_initial_features(action=leader.action_features),
use_videos=True,
),
aggregate_pipeline_dataset_features(
pipeline=follower_joints_to_ee,
initial_features=create_initial_features(observation=follower.observation_features),
use_videos=True,
),
),
robot_type=follower.name,
use_videos=True,
image_writer_threads=4,
)
# Connect the robot and teleoperator
leader.connect()
follower.connect()
# Initialize the keyboard listener and rerun visualization
listener, events = init_keyboard_listener()
init_rerun(session_name="recording_phone")
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}")
# 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,
)
# Connect the robot and teleoperator
leader.connect()
follower.connect()
# Initialize the keyboard listener and rerun visualization
listener, events = init_keyboard_listener()
init_rerun(session_name="recording_phone")
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}")
# Main record loop
# 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,
@@ -171,42 +183,22 @@ 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()
# Clean up
log_say("Stop recording")
leader.disconnect()
follower.disconnect()
listener.stop()
dataset.finalize()
dataset.push_to_hub()
if __name__ == "__main__":
main()
dataset.finalize()
dataset.push_to_hub()
examples/so100_to_so100_EE/replay.py
+51 -57
View File
@@ -30,78 +30,72 @@ from lerobot.robots.so100_follower.robot_kinematic_processor import (
)
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.robot_utils import busy_wait
from lerobot.utils.utils import log_say
EPISODE_IDX = 0
HF_REPO_ID = "<hf_username>/<dataset_repo_id>"
# Initialize the robot config
robot_config = SO100FollowerConfig(
port="/dev/tty.usbmodem5A460814411", id="my_awesome_follower_arm", use_degrees=True
)
def main():
# Initialize the robot config
robot_config = SO100FollowerConfig(
port="/dev/tty.usbmodem5A460814411", id="my_awesome_follower_arm", use_degrees=True
)
# Initialize the robot
robot = SO100Follower(robot_config)
# Initialize the robot
robot = SO100Follower(robot_config)
# NOTE: 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
kinematics_solver = RobotKinematics(
urdf_path="./SO101/so101_new_calib.urdf",
target_frame_name="gripper_frame_link",
joint_names=list(robot.bus.motors.keys()),
)
# NOTE: 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
kinematics_solver = RobotKinematics(
urdf_path="./SO101/so101_new_calib.urdf",
target_frame_name="gripper_frame_link",
joint_names=list(robot.bus.motors.keys()),
)
# Build pipeline to convert EE action to joints action
robot_ee_to_joints_processor = RobotProcessorPipeline[tuple[RobotAction, RobotObservation], RobotAction](
steps=[
InverseKinematicsEEToJoints(
kinematics=kinematics_solver,
motor_names=list(robot.bus.motors.keys()),
initial_guess_current_joints=False, # Because replay is open loop
),
],
to_transition=robot_action_observation_to_transition,
to_output=transition_to_robot_action,
)
# Build pipeline to convert EE action to joints action
robot_ee_to_joints_processor = RobotProcessorPipeline[tuple[RobotAction, RobotObservation], RobotAction](
steps=[
InverseKinematicsEEToJoints(
kinematics=kinematics_solver,
motor_names=list(robot.bus.motors.keys()),
initial_guess_current_joints=False, # Because replay is open loop
),
],
to_transition=robot_action_observation_to_transition,
to_output=transition_to_robot_action,
)
# Fetch the dataset to replay
dataset = LeRobotDataset(HF_REPO_ID, episodes=[EPISODE_IDX])
# Filter dataset to only include frames from the specified episode since episodes are chunked in dataset V3.0
episode_frames = dataset.hf_dataset.filter(lambda x: x["episode_index"] == EPISODE_IDX)
actions = episode_frames.select_columns(ACTION)
# Fetch the dataset to replay
dataset = LeRobotDataset(HF_REPO_ID, episodes=[EPISODE_IDX])
# Filter dataset to only include frames from the specified episode since episodes are chunked in dataset V3.0
episode_frames = dataset.hf_dataset.filter(lambda x: x["episode_index"] == EPISODE_IDX)
actions = episode_frames.select_columns(ACTION)
# Connect to the robot
robot.connect()
# Connect to the robot
robot.connect()
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)
busy_wait(1.0 / dataset.fps - (time.perf_counter() - t0))
precise_sleep(1.0 / dataset.fps - (time.perf_counter() - t0))
# Clean up
robot.disconnect()
if __name__ == "__main__":
main()
# Clean up
robot.disconnect()
examples/so100_to_so100_EE/teleoperate.py
+68 -74
View File
@@ -32,96 +32,90 @@ from lerobot.robots.so100_follower.robot_kinematic_processor import (
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.robot_utils import busy_wait
from lerobot.utils.visualization_utils import init_rerun, log_rerun_data
FPS = 30
# Initialize the robot and teleoperator config
follower_config = SO100FollowerConfig(
port="/dev/tty.usbmodem5A460814411", id="my_awesome_follower_arm", use_degrees=True
)
leader_config = SO100LeaderConfig(port="/dev/tty.usbmodem5A460819811", id="my_awesome_leader_arm")
def main():
# Initialize the robot and teleoperator config
follower_config = SO100FollowerConfig(
port="/dev/tty.usbmodem5A460814411", id="my_awesome_follower_arm", use_degrees=True
)
leader_config = SO100LeaderConfig(port="/dev/tty.usbmodem5A460819811", id="my_awesome_leader_arm")
# Initialize the robot and teleoperator
follower = SO100Follower(follower_config)
leader = SO100Leader(leader_config)
# Initialize the robot and teleoperator
follower = SO100Follower(follower_config)
leader = SO100Leader(leader_config)
# NOTE: 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
follower_kinematics_solver = RobotKinematics(
urdf_path="./SO101/so101_new_calib.urdf",
target_frame_name="gripper_frame_link",
joint_names=list(follower.bus.motors.keys()),
)
# NOTE: 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
follower_kinematics_solver = RobotKinematics(
urdf_path="./SO101/so101_new_calib.urdf",
target_frame_name="gripper_frame_link",
joint_names=list(follower.bus.motors.keys()),
)
# NOTE: 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
leader_kinematics_solver = RobotKinematics(
urdf_path="./SO101/so101_new_calib.urdf",
target_frame_name="gripper_frame_link",
joint_names=list(leader.bus.motors.keys()),
)
# NOTE: 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
leader_kinematics_solver = RobotKinematics(
urdf_path="./SO101/so101_new_calib.urdf",
target_frame_name="gripper_frame_link",
joint_names=list(leader.bus.motors.keys()),
)
# Build pipeline to convert teleop joints to EE action
leader_to_ee = RobotProcessorPipeline[RobotAction, RobotAction](
steps=[
ForwardKinematicsJointsToEE(
kinematics=leader_kinematics_solver, motor_names=list(leader.bus.motors.keys())
),
],
to_transition=robot_action_to_transition,
to_output=transition_to_robot_action,
)
# Build pipeline to convert teleop joints to EE action
leader_to_ee = RobotProcessorPipeline[RobotAction, RobotAction](
steps=[
ForwardKinematicsJointsToEE(
kinematics=leader_kinematics_solver, motor_names=list(leader.bus.motors.keys())
),
],
to_transition=robot_action_to_transition,
to_output=transition_to_robot_action,
)
# build pipeline to convert EE action to robot joints
ee_to_follower_joints = RobotProcessorPipeline[tuple[RobotAction, RobotObservation], RobotAction](
[
EEBoundsAndSafety(
end_effector_bounds={"min": [-1.0, -1.0, -1.0], "max": [1.0, 1.0, 1.0]},
max_ee_step_m=0.10,
),
InverseKinematicsEEToJoints(
kinematics=follower_kinematics_solver,
motor_names=list(follower.bus.motors.keys()),
initial_guess_current_joints=False,
),
],
to_transition=robot_action_observation_to_transition,
to_output=transition_to_robot_action,
)
# build pipeline to convert EE action to robot joints
ee_to_follower_joints = RobotProcessorPipeline[tuple[RobotAction, RobotObservation], RobotAction](
[
EEBoundsAndSafety(
end_effector_bounds={"min": [-1.0, -1.0, -1.0], "max": [1.0, 1.0, 1.0]},
max_ee_step_m=0.10,
),
InverseKinematicsEEToJoints(
kinematics=follower_kinematics_solver,
motor_names=list(follower.bus.motors.keys()),
initial_guess_current_joints=False,
),
],
to_transition=robot_action_observation_to_transition,
to_output=transition_to_robot_action,
)
# Connect to the robot and teleoperator
follower.connect()
leader.connect()
# Connect to the robot and teleoperator
follower.connect()
leader.connect()
# Init rerun viewer
init_rerun(session_name="so100_so100_EE_teleop")
# Init rerun viewer
init_rerun(session_name="so100_so100_EE_teleop")
print("Starting teleop loop...")
while True:
t0 = time.perf_counter()
print("Starting teleop loop...")
while True:
t0 = time.perf_counter()
# Get robot observation
robot_obs = follower.get_observation()
# Get robot observation
robot_obs = follower.get_observation()
# Get teleop observation
leader_joints_obs = leader.get_action()
# Get teleop observation
leader_joints_obs = leader.get_action()
# teleop joints -> teleop EE action
leader_ee_act = leader_to_ee(leader_joints_obs)
# teleop joints -> teleop EE action
leader_ee_act = leader_to_ee(leader_joints_obs)
# teleop EE -> robot joints
follower_joints_act = ee_to_follower_joints((leader_ee_act, robot_obs))
# teleop EE -> robot joints
follower_joints_act = ee_to_follower_joints((leader_ee_act, robot_obs))
# Send action to robot
_ = follower.send_action(follower_joints_act)
# Send action to robot
_ = follower.send_action(follower_joints_act)
# Visualize
log_rerun_data(observation=leader_ee_act, action=follower_joints_act)
# Visualize
log_rerun_data(observation=leader_ee_act, action=follower_joints_act)
precise_sleep(max(1.0 / FPS - (time.perf_counter() - t0), 0.0))
if __name__ == "__main__":
main()
busy_wait(max(1.0 / FPS - (time.perf_counter() - t0), 0.0))
examples/tutorial/act/act_training_example.py
+62 -68
View File
@@ -19,86 +19,80 @@ def make_delta_timestamps(delta_indices: list[int] | None, fps: int) -> list[flo
return [i / fps for i in delta_indices]
def main():
output_directory = Path("outputs/robot_learning_tutorial/act")
output_directory.mkdir(parents=True, exist_ok=True)
output_directory = Path("outputs/robot_learning_tutorial/act")
output_directory.mkdir(parents=True, exist_ok=True)
# Select your device
device = torch.device("mps") # or "cuda" or "cpu"
# Select your device
device = torch.device("mps") # or "cuda" or "cpu"
dataset_id = "lerobot/svla_so101_pickplace"
dataset_id = "lerobot/svla_so101_pickplace"
# This specifies the inputs the model will be expecting and the outputs it will produce
dataset_metadata = LeRobotDatasetMetadata(dataset_id)
features = dataset_to_policy_features(dataset_metadata.features)
# This specifies the inputs the model will be expecting and the outputs it will produce
dataset_metadata = LeRobotDatasetMetadata(dataset_id)
features = dataset_to_policy_features(dataset_metadata.features)
output_features = {key: ft for key, ft in features.items() if ft.type is FeatureType.ACTION}
input_features = {key: ft for key, ft in features.items() if key not in output_features}
output_features = {key: ft for key, ft in features.items() if ft.type is FeatureType.ACTION}
input_features = {key: ft for key, ft in features.items() if key not in output_features}
cfg = ACTConfig(input_features=input_features, output_features=output_features)
policy = ACTPolicy(cfg)
preprocessor, postprocessor = make_pre_post_processors(cfg, dataset_stats=dataset_metadata.stats)
cfg = ACTConfig(input_features=input_features, output_features=output_features)
policy = ACTPolicy(cfg)
preprocessor, postprocessor = make_pre_post_processors(cfg, dataset_stats=dataset_metadata.stats)
policy.train()
policy.to(device)
policy.train()
policy.to(device)
# To perform action chunking, ACT expects a given number of actions as targets
delta_timestamps = {
"action": make_delta_timestamps(cfg.action_delta_indices, dataset_metadata.fps),
}
# To perform action chunking, ACT expects a given number of actions as targets
delta_timestamps = {
"action": make_delta_timestamps(cfg.action_delta_indices, dataset_metadata.fps),
}
# add image features if they are present
delta_timestamps |= {
k: make_delta_timestamps(cfg.observation_delta_indices, dataset_metadata.fps)
for k in cfg.image_features
}
# add image features if they are present
delta_timestamps |= {
k: make_delta_timestamps(cfg.observation_delta_indices, dataset_metadata.fps) for k in cfg.image_features
}
# Instantiate the dataset
dataset = LeRobotDataset(dataset_id, delta_timestamps=delta_timestamps)
# Instantiate the dataset
dataset = LeRobotDataset(dataset_id, delta_timestamps=delta_timestamps)
# Create the optimizer and dataloader for offline training
optimizer = cfg.get_optimizer_preset().build(policy.parameters())
batch_size = 32
dataloader = torch.utils.data.DataLoader(
dataset,
batch_size=batch_size,
shuffle=True,
pin_memory=device.type != "cpu",
drop_last=True,
)
# Create the optimizer and dataloader for offline training
optimizer = cfg.get_optimizer_preset().build(policy.parameters())
batch_size = 32
dataloader = torch.utils.data.DataLoader(
dataset,
batch_size=batch_size,
shuffle=True,
pin_memory=device.type != "cpu",
drop_last=True,
)
# Number of training steps and logging frequency
training_steps = 1
log_freq = 1
# Number of training steps and logging frequency
training_steps = 1
log_freq = 1
# Run training loop
step = 0
done = False
while not done:
for batch in dataloader:
batch = preprocessor(batch)
loss, _ = policy.forward(batch)
loss.backward()
optimizer.step()
optimizer.zero_grad()
# Run training loop
step = 0
done = False
while not done:
for batch in dataloader:
batch = preprocessor(batch)
loss, _ = policy.forward(batch)
loss.backward()
optimizer.step()
optimizer.zero_grad()
if step % log_freq == 0:
print(f"step: {step} loss: {loss.item():.3f}")
step += 1
if step >= training_steps:
done = True
break
if step % log_freq == 0:
print(f"step: {step} loss: {loss.item():.3f}")
step += 1
if step >= training_steps:
done = True
break
# Save the policy checkpoint, alongside the pre/post processors
policy.save_pretrained(output_directory)
preprocessor.save_pretrained(output_directory)
postprocessor.save_pretrained(output_directory)
# Save the policy checkpoint, alongside the pre/post processors
policy.save_pretrained(output_directory)
preprocessor.save_pretrained(output_directory)
postprocessor.save_pretrained(output_directory)
# Save all assets to the Hub
policy.push_to_hub("<user>/robot_learning_tutorial_act")
preprocessor.push_to_hub("<user>/robot_learning_tutorial_act")
postprocessor.push_to_hub("<user>/robot_learning_tutorial_act")
if __name__ == "__main__":
main()
# Save all assets to the Hub
policy.push_to_hub("fracapuano/robot_learning_tutorial_act")
preprocessor.push_to_hub("fracapuano/robot_learning_tutorial_act")
postprocessor.push_to_hub("fracapuano/robot_learning_tutorial_act")
examples/tutorial/act/act_using_example.py
+37 -43
View File
@@ -8,56 +8,50 @@ from lerobot.policies.utils import build_inference_frame, make_robot_action
from lerobot.robots.so100_follower.config_so100_follower import SO100FollowerConfig
from lerobot.robots.so100_follower.so100_follower import SO100Follower
device = torch.device("mps") # or "cuda" or "cpu"
model_id = "fracapuano/robot_learning_tutorial_act"
model = ACTPolicy.from_pretrained(model_id)
dataset_id = "lerobot/svla_so101_pickplace"
# This only downloads the metadata for the dataset, ~10s of MB even for large-scale datasets
dataset_metadata = LeRobotDatasetMetadata(dataset_id)
preprocess, postprocess = make_pre_post_processors(model.config, dataset_stats=dataset_metadata.stats)
# # find ports using lerobot-find-port
follower_port = ... # something like "/dev/tty.usbmodem58760431631"
# # the robot ids are used the load the right calibration files
follower_id = ... # something like "follower_so100"
MAX_EPISODES = 5
MAX_STEPS_PER_EPISODE = 20
# Robot and environment configuration
# Camera keys must match the name and resolutions of the ones used for training!
# You can check the camera keys expected by a model in the info.json card on the model card on the Hub
camera_config = {
"side": OpenCVCameraConfig(index_or_path=0, width=640, height=480, fps=30),
"up": OpenCVCameraConfig(index_or_path=1, width=640, height=480, fps=30),
}
def main():
device = torch.device("mps") # or "cuda" or "cpu"
model_id = "<user>/robot_learning_tutorial_act"
model = ACTPolicy.from_pretrained(model_id)
robot_cfg = SO100FollowerConfig(port=follower_port, id=follower_id, cameras=camera_config)
robot = SO100Follower(robot_cfg)
robot.connect()
dataset_id = "lerobot/svla_so101_pickplace"
# This only downloads the metadata for the dataset, ~10s of MB even for large-scale datasets
dataset_metadata = LeRobotDatasetMetadata(dataset_id)
preprocess, postprocess = make_pre_post_processors(model.config, dataset_stats=dataset_metadata.stats)
for _ in range(MAX_EPISODES):
for _ in range(MAX_STEPS_PER_EPISODE):
obs = robot.get_observation()
obs_frame = build_inference_frame(
observation=obs, ds_features=dataset_metadata.features, device=device
)
# # find ports using lerobot-find-port
follower_port = ... # something like "/dev/tty.usbmodem58760431631"
obs = preprocess(obs_frame)
# # the robot ids are used the load the right calibration files
follower_id = ... # something like "follower_so100"
action = model.select_action(obs)
action = postprocess(action)
# Robot and environment configuration
# Camera keys must match the name and resolutions of the ones used for training!
# You can check the camera keys expected by a model in the info.json card on the model card on the Hub
camera_config = {
"side": OpenCVCameraConfig(index_or_path=0, width=640, height=480, fps=30),
"up": OpenCVCameraConfig(index_or_path=1, width=640, height=480, fps=30),
}
action = make_robot_action(action, dataset_metadata.features)
robot_cfg = SO100FollowerConfig(port=follower_port, id=follower_id, cameras=camera_config)
robot = SO100Follower(robot_cfg)
robot.connect()
robot.send_action(action)
for _ in range(MAX_EPISODES):
for _ in range(MAX_STEPS_PER_EPISODE):
obs = robot.get_observation()
obs_frame = build_inference_frame(
observation=obs, ds_features=dataset_metadata.features, device=device
)
obs = preprocess(obs_frame)
action = model.select_action(obs)
action = postprocess(action)
action = make_robot_action(action, dataset_metadata.features)
robot.send_action(action)
print("Episode finished! Starting new episode...")
if __name__ == "__main__":
main()
print("Episode finished! Starting new episode...")
examples/tutorial/async-inf/policy_server.py
+7 -13
View File
@@ -1,17 +1,11 @@
from lerobot.async_inference.configs import PolicyServerConfig
from lerobot.async_inference.policy_server import serve
host = ... # something like "127.0.0.1" if you're exposing to localhost
port = ... # something like 8080
def main():
host = ... # something like "127.0.0.1" if you're exposing to localhost
port = ... # something like 8080
config = PolicyServerConfig(
host=host,
port=port,
)
serve(config)
if __name__ == "__main__":
main()
config = PolicyServerConfig(
host=host,
port=port,
)
serve(config)
examples/tutorial/async-inf/robot_client.py
+38 -44
View File
@@ -6,56 +6,50 @@ from lerobot.async_inference.robot_client import RobotClient
from lerobot.cameras.opencv.configuration_opencv import OpenCVCameraConfig
from lerobot.robots.so100_follower import SO100FollowerConfig
# these cameras must match the ones expected by the policy - find your cameras with lerobot-find-cameras
# check the config.json on the Hub for the policy you are using to see the expected camera specs
camera_cfg = {
"up": OpenCVCameraConfig(index_or_path=0, width=640, height=480, fps=30),
"side": OpenCVCameraConfig(index_or_path=1, width=640, height=480, fps=30),
}
def main():
# these cameras must match the ones expected by the policy - find your cameras with lerobot-find-cameras
# check the config.json on the Hub for the policy you are using to see the expected camera specs
camera_cfg = {
"up": OpenCVCameraConfig(index_or_path=0, width=640, height=480, fps=30),
"side": OpenCVCameraConfig(index_or_path=1, width=640, height=480, fps=30),
}
# # find ports using lerobot-find-port
follower_port = ... # something like "/dev/tty.usbmodem58760431631"
# # find ports using lerobot-find-port
follower_port = ... # something like "/dev/tty.usbmodem58760431631"
# # the robot ids are used the load the right calibration files
follower_id = ... # something like "follower_so100"
# # the robot ids are used the load the right calibration files
follower_id = ... # something like "follower_so100"
robot_cfg = SO100FollowerConfig(port=follower_port, id=follower_id, cameras=camera_cfg)
robot_cfg = SO100FollowerConfig(port=follower_port, id=follower_id, cameras=camera_cfg)
server_address = ... # something like "127.0.0.1:8080" if using localhost
server_address = ... # something like "127.0.0.1:8080" if using localhost
# 3. Create client configuration
client_cfg = RobotClientConfig(
robot=robot_cfg,
server_address=server_address,
policy_device="mps",
policy_type="act",
pretrained_name_or_path="fracapuano/robot_learning_tutorial_act",
chunk_size_threshold=0.5, # g
actions_per_chunk=50, # make sure this is less than the max actions of the policy
)
# 3. Create client configuration
client_cfg = RobotClientConfig(
robot=robot_cfg,
server_address=server_address,
policy_device="mps",
policy_type="act",
pretrained_name_or_path="<user>/robot_learning_tutorial_act",
chunk_size_threshold=0.5, # g
actions_per_chunk=50, # make sure this is less than the max actions of the policy
)
# 4. Create and start client
client = RobotClient(client_cfg)
# 4. Create and start client
client = RobotClient(client_cfg)
# 5. Provide a textual description of the task
task = ...
# 5. Provide a textual description of the task
task = ...
if client.start():
# Start action receiver thread
action_receiver_thread = threading.Thread(target=client.receive_actions, daemon=True)
action_receiver_thread.start()
if client.start():
# Start action receiver thread
action_receiver_thread = threading.Thread(target=client.receive_actions, daemon=True)
action_receiver_thread.start()
try:
# Run the control loop
client.control_loop(task)
except KeyboardInterrupt:
client.stop()
action_receiver_thread.join()
# (Optionally) plot the action queue size
visualize_action_queue_size(client.action_queue_size)
if __name__ == "__main__":
main()
try:
# Run the control loop
client.control_loop(task)
except KeyboardInterrupt:
client.stop()
action_receiver_thread.join()
# (Optionally) plot the action queue size
visualize_action_queue_size(client.action_queue_size)
examples/tutorial/diffusion/diffusion_training_example.py
+63 -69
View File
@@ -19,87 +19,81 @@ def make_delta_timestamps(delta_indices: list[int] | None, fps: int) -> list[flo
return [i / fps for i in delta_indices]
def main():
output_directory = Path("outputs/robot_learning_tutorial/diffusion")
output_directory.mkdir(parents=True, exist_ok=True)
output_directory = Path("outputs/robot_learning_tutorial/diffusion")
output_directory.mkdir(parents=True, exist_ok=True)
# Select your device
device = torch.device("mps") # or "cuda" or "cpu"
# Select your device
device = torch.device("mps") # or "cuda" or "cpu"
dataset_id = "lerobot/svla_so101_pickplace"
dataset_id = "lerobot/svla_so101_pickplace"
# This specifies the inputs the model will be expecting and the outputs it will produce
dataset_metadata = LeRobotDatasetMetadata(dataset_id)
features = dataset_to_policy_features(dataset_metadata.features)
# This specifies the inputs the model will be expecting and the outputs it will produce
dataset_metadata = LeRobotDatasetMetadata(dataset_id)
features = dataset_to_policy_features(dataset_metadata.features)
output_features = {key: ft for key, ft in features.items() if ft.type is FeatureType.ACTION}
input_features = {key: ft for key, ft in features.items() if key not in output_features}
output_features = {key: ft for key, ft in features.items() if ft.type is FeatureType.ACTION}
input_features = {key: ft for key, ft in features.items() if key not in output_features}
cfg = DiffusionConfig(input_features=input_features, output_features=output_features)
policy = DiffusionPolicy(cfg)
preprocessor, postprocessor = make_pre_post_processors(cfg, dataset_stats=dataset_metadata.stats)
cfg = DiffusionConfig(input_features=input_features, output_features=output_features)
policy = DiffusionPolicy(cfg)
preprocessor, postprocessor = make_pre_post_processors(cfg, dataset_stats=dataset_metadata.stats)
policy.train()
policy.to(device)
policy.train()
policy.to(device)
# To perform action chunking, ACT expects a given number of actions as targets
delta_timestamps = {
"observation.state": make_delta_timestamps(cfg.observation_delta_indices, dataset_metadata.fps),
"action": make_delta_timestamps(cfg.action_delta_indices, dataset_metadata.fps),
}
# To perform action chunking, ACT expects a given number of actions as targets
delta_timestamps = {
"observation.state": make_delta_timestamps(cfg.observation_delta_indices, dataset_metadata.fps),
"action": make_delta_timestamps(cfg.action_delta_indices, dataset_metadata.fps),
}
# add image features if they are present
delta_timestamps |= {
k: make_delta_timestamps(cfg.observation_delta_indices, dataset_metadata.fps)
for k in cfg.image_features
}
# add image features if they are present
delta_timestamps |= {
k: make_delta_timestamps(cfg.observation_delta_indices, dataset_metadata.fps) for k in cfg.image_features
}
# Instantiate the dataset
dataset = LeRobotDataset(dataset_id, delta_timestamps=delta_timestamps)
# Instantiate the dataset
dataset = LeRobotDataset(dataset_id, delta_timestamps=delta_timestamps)
# Create the optimizer and dataloader for offline training
optimizer = cfg.get_optimizer_preset().build(policy.parameters())
batch_size = 32
dataloader = torch.utils.data.DataLoader(
dataset,
batch_size=batch_size,
shuffle=True,
pin_memory=device.type != "cpu",
drop_last=True,
)
# Create the optimizer and dataloader for offline training
optimizer = cfg.get_optimizer_preset().build(policy.parameters())
batch_size = 32
dataloader = torch.utils.data.DataLoader(
dataset,
batch_size=batch_size,
shuffle=True,
pin_memory=device.type != "cpu",
drop_last=True,
)
# Number of training steps and logging frequency
training_steps = 1
log_freq = 1
# Number of training steps and logging frequency
training_steps = 1
log_freq = 1
# Run training loop
step = 0
done = False
while not done:
for batch in dataloader:
batch = preprocessor(batch)
loss, _ = policy.forward(batch)
loss.backward()
optimizer.step()
optimizer.zero_grad()
# Run training loop
step = 0
done = False
while not done:
for batch in dataloader:
batch = preprocessor(batch)
loss, _ = policy.forward(batch)
loss.backward()
optimizer.step()
optimizer.zero_grad()
if step % log_freq == 0:
print(f"step: {step} loss: {loss.item():.3f}")
step += 1
if step >= training_steps:
done = True
break
if step % log_freq == 0:
print(f"step: {step} loss: {loss.item():.3f}")
step += 1
if step >= training_steps:
done = True
break
# Save the policy checkpoint, alongside the pre/post processors
policy.save_pretrained(output_directory)
preprocessor.save_pretrained(output_directory)
postprocessor.save_pretrained(output_directory)
# Save the policy checkpoint, alongside the pre/post processors
policy.save_pretrained(output_directory)
preprocessor.save_pretrained(output_directory)
postprocessor.save_pretrained(output_directory)
# Save all assets to the Hub
policy.push_to_hub("<user>/robot_learning_tutorial_diffusion")
preprocessor.push_to_hub("<user>/robot_learning_tutorial_diffusion")
postprocessor.push_to_hub("<user>/robot_learning_tutorial_diffusion")
if __name__ == "__main__":
main()
# Save all assets to the Hub
policy.push_to_hub("fracapuano/robot_learning_tutorial_diffusion")
preprocessor.push_to_hub("fracapuano/robot_learning_tutorial_diffusion")
postprocessor.push_to_hub("fracapuano/robot_learning_tutorial_diffusion")
examples/tutorial/diffusion/diffusion_using_example.py
+41 -45
View File
@@ -8,57 +8,53 @@ from lerobot.policies.utils import build_inference_frame, make_robot_action
from lerobot.robots.so100_follower.config_so100_follower import SO100FollowerConfig
from lerobot.robots.so100_follower.so100_follower import SO100Follower
device = torch.device("mps") # or "cuda" or "cpu"
model_id = "fracapuano/robot_learning_tutorial_diffusion"
model = DiffusionPolicy.from_pretrained(model_id)
dataset_id = "lerobot/svla_so101_pickplace"
# This only downloads the metadata for the dataset, ~10s of MB even for large-scale datasets
dataset_metadata = LeRobotDatasetMetadata(dataset_id)
preprocess, postprocess = make_pre_post_processors(
model.config, model_id, dataset_stats=dataset_metadata.stats
)
MAX_EPISODES = 5
MAX_STEPS_PER_EPISODE = 20
def main():
device = torch.device("mps") # or "cuda" or "cpu"
model_id = "<user>/robot_learning_tutorial_diffusion"
# # find ports using lerobot-find-port
follower_port = ... # something like "/dev/tty.usbmodem58760431631"
model = DiffusionPolicy.from_pretrained(model_id)
# # the robot ids are used the load the right calibration files
follower_id = ... # something like "follower_so100"
dataset_id = "lerobot/svla_so101_pickplace"
# This only downloads the metadata for the dataset, ~10s of MB even for large-scale datasets
dataset_metadata = LeRobotDatasetMetadata(dataset_id)
preprocess, postprocess = make_pre_post_processors(
model.config, model_id, dataset_stats=dataset_metadata.stats
)
# Robot and environment configuration
# Camera keys must match the name and resolutions of the ones used for training!
# You can check the camera keys expected by a model in the info.json card on the model card on the Hub
camera_config = {
"side": OpenCVCameraConfig(index_or_path=0, width=640, height=480, fps=30),
"up": OpenCVCameraConfig(index_or_path=1, width=640, height=480, fps=30),
}
# # find ports using lerobot-find-port
follower_port = ... # something like "/dev/tty.usbmodem58760431631"
# # the robot ids are used the load the right calibration files
follower_id = ... # something like "follower_so100"
# Robot and environment configuration
# Camera keys must match the name and resolutions of the ones used for training!
# You can check the camera keys expected by a model in the info.json card on the model card on the Hub
camera_config = {
"side": OpenCVCameraConfig(index_or_path=0, width=640, height=480, fps=30),
"up": OpenCVCameraConfig(index_or_path=1, width=640, height=480, fps=30),
}
robot_cfg = SO100FollowerConfig(port=follower_port, id=follower_id, cameras=camera_config)
robot = SO100Follower(robot_cfg)
robot.connect()
for _ in range(MAX_EPISODES):
for _ in range(MAX_STEPS_PER_EPISODE):
obs = robot.get_observation()
obs_frame = build_inference_frame(
observation=obs, ds_features=dataset_metadata.features, device=device
)
obs = preprocess(obs_frame)
action = model.select_action(obs)
action = postprocess(action)
action = make_robot_action(action, dataset_metadata.features)
robot.send_action(action)
print("Episode finished! Starting new episode...")
robot_cfg = SO100FollowerConfig(port=follower_port, id=follower_id, cameras=camera_config)
robot = SO100Follower(robot_cfg)
robot.connect()
if __name__ == "__main__":
main()
for _ in range(MAX_EPISODES):
for _ in range(MAX_STEPS_PER_EPISODE):
obs = robot.get_observation()
obs_frame = build_inference_frame(
observation=obs, ds_features=dataset_metadata.features, device=device
)
obs = preprocess(obs_frame)
action = model.select_action(obs)
action = postprocess(action)
action = make_robot_action(action, dataset_metadata.features)
robot.send_action(action)
print("Episode finished! Starting new episode...")
examples/tutorial/pi0/using_pi0_example.py
+42 -48
View File
@@ -11,63 +11,57 @@ from lerobot.robots.so100_follower.so100_follower import SO100Follower
MAX_EPISODES = 5
MAX_STEPS_PER_EPISODE = 20
device = torch.device("mps") # or "cuda" or "cpu"
model_id = "lerobot/pi0_base"
def main():
device = torch.device("mps") # or "cuda" or "cpu"
model_id = "lerobot/pi0_base"
model = PI0Policy.from_pretrained(model_id)
model = PI0Policy.from_pretrained(model_id)
preprocess, postprocess = make_pre_post_processors(
model.config,
model_id,
# This overrides allows to run on MPS, otherwise defaults to CUDA (if available)
preprocessor_overrides={"device_processor": {"device": str(device)}},
)
preprocess, postprocess = make_pre_post_processors(
model.config,
model_id,
# This overrides allows to run on MPS, otherwise defaults to CUDA (if available)
preprocessor_overrides={"device_processor": {"device": str(device)}},
)
# find ports using lerobot-find-port
follower_port = ... # something like "/dev/tty.usbmodem58760431631"
# find ports using lerobot-find-port
follower_port = ... # something like "/dev/tty.usbmodem58760431631"
# the robot ids are used the load the right calibration files
follower_id = ... # something like "follower_so100"
# the robot ids are used the load the right calibration files
follower_id = ... # something like "follower_so100"
# Robot and environment configuration
# Camera keys must match the name and resolutions of the ones used for training!
# You can check the camera keys expected by a model in the info.json card on the model card on the Hub
camera_config = {
"base_0_rgb": OpenCVCameraConfig(index_or_path=0, width=640, height=480, fps=30),
"left_wrist_0_rgb": OpenCVCameraConfig(index_or_path=1, width=640, height=480, fps=30),
"right_wrist_0_rgb": OpenCVCameraConfig(index_or_path=2, width=640, height=480, fps=30),
}
# Robot and environment configuration
# Camera keys must match the name and resolutions of the ones used for training!
# You can check the camera keys expected by a model in the info.json card on the model card on the Hub
camera_config = {
"base_0_rgb": OpenCVCameraConfig(index_or_path=0, width=640, height=480, fps=30),
"left_wrist_0_rgb": OpenCVCameraConfig(index_or_path=1, width=640, height=480, fps=30),
"right_wrist_0_rgb": OpenCVCameraConfig(index_or_path=2, width=640, height=480, fps=30),
}
robot_cfg = SO100FollowerConfig(port=follower_port, id=follower_id, cameras=camera_config)
robot = SO100Follower(robot_cfg)
robot.connect()
robot_cfg = SO100FollowerConfig(port=follower_port, id=follower_id, cameras=camera_config)
robot = SO100Follower(robot_cfg)
robot.connect()
task = "" # something like "pick the red block"
robot_type = "" # something like "so100_follower" for multi-embodiment datasets
task = "" # something like "pick the red block"
robot_type = "" # something like "so100_follower" for multi-embodiment datasets
# This is used to match the raw observation keys to the keys expected by the policy
action_features = hw_to_dataset_features(robot.action_features, "action")
obs_features = hw_to_dataset_features(robot.observation_features, "observation")
dataset_features = {**action_features, **obs_features}
# This is used to match the raw observation keys to the keys expected by the policy
action_features = hw_to_dataset_features(robot.action_features, "action")
obs_features = hw_to_dataset_features(robot.observation_features, "observation")
dataset_features = {**action_features, **obs_features}
for _ in range(MAX_EPISODES):
for _ in range(MAX_STEPS_PER_EPISODE):
obs = robot.get_observation()
obs_frame = build_inference_frame(
observation=obs, ds_features=dataset_features, device=device, task=task, robot_type=robot_type
)
for _ in range(MAX_EPISODES):
for _ in range(MAX_STEPS_PER_EPISODE):
obs = robot.get_observation()
obs_frame = build_inference_frame(
observation=obs, ds_features=dataset_features, device=device, task=task, robot_type=robot_type
)
obs = preprocess(obs_frame)
obs = preprocess(obs_frame)
action = model.select_action(obs)
action = postprocess(action)
action = make_robot_action(action, dataset_features)
robot.send_action(action)
action = model.select_action(obs)
action = postprocess(action)
action = make_robot_action(action, dataset_features)
robot.send_action(action)
print("Episode finished! Starting new episode...")
if __name__ == "__main__":
main()
print("Episode finished! Starting new episode...")
examples/tutorial/rl/hilserl_example.py
+103 -105
View File
@@ -20,8 +20,6 @@ from lerobot.teleoperators.utils import TeleopEvents
LOG_EVERY = 10
SEND_EVERY = 10
MAX_EPISODES = 5
MAX_STEPS_PER_EPISODE = 20
def run_learner(
@@ -225,123 +223,123 @@ def make_policy_obs(obs, device: torch.device = "cpu"):
}
def main():
"""Main function - coordinates actor and learner processes."""
"""Main function - coordinates actor and learner processes."""
device = "mps" # or "cuda" or "cpu"
output_directory = Path("outputs/robot_learning_tutorial/hil_serl")
output_directory.mkdir(parents=True, exist_ok=True)
device = "mps" # or "cuda" or "cpu"
output_directory = Path("outputs/robot_learning_tutorial/hil_serl")
output_directory.mkdir(parents=True, exist_ok=True)
# find ports using lerobot-find-port
follower_port = ...
leader_port = ...
# find ports using lerobot-find-port
follower_port = ...
leader_port = ...
# the robot ids are used the load the right calibration files
follower_id = ...
leader_id = ...
# the robot ids are used the load the right calibration files
follower_id = ...
leader_id = ...
# A pretrained model (to be used in-distribution!)
reward_classifier_id = "<user>/reward_classifier_hil_serl_example"
reward_classifier = Classifier.from_pretrained(reward_classifier_id)
# A pretrained model (to be used in-distribution!)
reward_classifier_id = "fracapuano/reward_classifier_hil_serl_example"
reward_classifier = Classifier.from_pretrained(reward_classifier_id)
reward_classifier.to(device)
reward_classifier.eval()
reward_classifier.to(device)
reward_classifier.eval()
# Robot and environment configuration
robot_cfg = SO100FollowerConfig(port=follower_port, id=follower_id)
teleop_cfg = SO100LeaderConfig(port=leader_port, id=leader_id)
processor_cfg = HILSerlProcessorConfig(control_mode="leader")
MAX_EPISODES = 5
MAX_STEPS_PER_EPISODE = 20
env_cfg = HILSerlRobotEnvConfig(robot=robot_cfg, teleop=teleop_cfg, processor=processor_cfg)
# Robot and environment configuration
robot_cfg = SO100FollowerConfig(port=follower_port, id=follower_id)
teleop_cfg = SO100LeaderConfig(port=leader_port, id=leader_id)
processor_cfg = HILSerlProcessorConfig(control_mode="leader")
# Create robot environment
env, teleop_device = make_robot_env(env_cfg)
env_cfg = HILSerlRobotEnvConfig(robot=robot_cfg, teleop=teleop_cfg, processor=processor_cfg)
obs_features = hw_to_dataset_features(env.robot.observation_features, "observation")
action_features = hw_to_dataset_features(env.robot.action_features, "action")
# Create robot environment
env, teleop_device = make_robot_env(env_cfg)
# Create SAC policy for action selection
policy_cfg = SACConfig(
device=device,
input_features=obs_features,
output_features=action_features,
)
obs_features = hw_to_dataset_features(env.robot.observation_features, "observation")
action_features = hw_to_dataset_features(env.robot.action_features, "action")
policy_actor = SACPolicy(policy_cfg)
policy_learner = SACPolicy(policy_cfg)
# Create SAC policy for action selection
policy_cfg = SACConfig(
device=device,
input_features=obs_features,
output_features=action_features,
)
demonstrations_repo_id = "lerobot/example_hil_serl_dataset"
offline_dataset = LeRobotDataset(repo_id=demonstrations_repo_id)
policy_actor = SACPolicy(policy_cfg)
policy_learner = SACPolicy(policy_cfg)
# Online buffer: initialized from scratch
online_replay_buffer = ReplayBuffer(device=device, state_keys=list(obs_features.keys()))
# Offline buffer: Created from dataset (pre-populated it with demonstrations)
offline_replay_buffer = ReplayBuffer.from_lerobot_dataset(
lerobot_dataset=offline_dataset, device=device, state_keys=list(obs_features.keys())
)
demonstrations_repo_id = "lerobot/example_hil_serl_dataset"
offline_dataset = LeRobotDataset(repo_id=demonstrations_repo_id)
# Create communication channels between learner and actor processes
transitions_queue = mp.Queue(maxsize=10)
parameters_queue = mp.Queue(maxsize=2)
shutdown_event = mp.Event()
# Online buffer: initialized from scratch
online_replay_buffer = ReplayBuffer(device=device, state_keys=list(obs_features.keys()))
# Offline buffer: Created from dataset (pre-populated it with demonstrations)
offline_replay_buffer = ReplayBuffer.from_lerobot_dataset(
lerobot_dataset=offline_dataset, device=device, state_keys=list(obs_features.keys())
)
# Signal handler for graceful shutdown
def signal_handler(sig):
print(f"\nSignal {sig} received, shutting down...")
shutdown_event.set()
signal.signal(signal.SIGINT, signal_handler)
signal.signal(signal.SIGTERM, signal_handler)
# Create processes
learner_process = mp.Process(
target=run_learner,
args=(
transitions_queue,
parameters_queue,
shutdown_event,
policy_learner,
online_replay_buffer,
offline_replay_buffer,
),
kwargs={"device": device}, # can run on accelerated hardware for training
)
actor_process = mp.Process(
target=run_actor,
args=(
transitions_queue,
parameters_queue,
shutdown_event,
policy_actor,
reward_classifier,
env_cfg,
output_directory,
),
kwargs={"device": "cpu"}, # actor is frozen, can run on CPU or accelerate for inference
)
learner_process.start()
actor_process.start()
try:
# Wait for actor to finish (it controls the episode loop)
actor_process.join()
shutdown_event.set()
learner_process.join(timeout=10)
except KeyboardInterrupt:
print("Main process interrupted")
shutdown_event.set()
actor_process.join(timeout=5)
learner_process.join(timeout=10)
finally:
if learner_process.is_alive():
learner_process.terminate()
if actor_process.is_alive():
actor_process.terminate()
# Create communication channels between learner and actor processes
transitions_queue = mp.Queue(maxsize=10)
parameters_queue = mp.Queue(maxsize=2)
shutdown_event = mp.Event()
if __name__ == "__main__":
main()
# Signal handler for graceful shutdown
def signal_handler(sig):
print(f"\nSignal {sig} received, shutting down...")
shutdown_event.set()
signal.signal(signal.SIGINT, signal_handler)
signal.signal(signal.SIGTERM, signal_handler)
# Create processes
learner_process = mp.Process(
target=run_learner,
args=(
transitions_queue,
parameters_queue,
shutdown_event,
policy_learner,
online_replay_buffer,
offline_replay_buffer,
),
kwargs={"device": device}, # can run on accelerated hardware for training
)
actor_process = mp.Process(
target=run_actor,
args=(
transitions_queue,
parameters_queue,
shutdown_event,
policy_actor,
reward_classifier,
env_cfg,
output_directory,
),
kwargs={"device": "cpu"}, # actor is frozen, can run on CPU or accelerate for inference
)
learner_process.start()
actor_process.start()
try:
# Wait for actor to finish (it controls the episode loop)
actor_process.join()
shutdown_event.set()
learner_process.join(timeout=10)
except KeyboardInterrupt:
print("Main process interrupted")
shutdown_event.set()
actor_process.join(timeout=5)
learner_process.join(timeout=10)
finally:
if learner_process.is_alive():
learner_process.terminate()
if actor_process.is_alive():
actor_process.terminate()
examples/tutorial/rl/reward_classifier_example.py
+50 -55
View File
@@ -4,64 +4,59 @@ from lerobot.datasets.lerobot_dataset import LeRobotDataset
from lerobot.policies.factory import make_policy, make_pre_post_processors
from lerobot.policies.sac.reward_model.configuration_classifier import RewardClassifierConfig
# Device to use for training
device = "mps" # or "cuda", or "cpu"
def main():
# Device to use for training
device = "mps" # or "cuda", or "cpu"
# Load the dataset used for training
repo_id = "lerobot/example_hil_serl_dataset"
dataset = LeRobotDataset(repo_id)
# Load the dataset used for training
repo_id = "lerobot/example_hil_serl_dataset"
dataset = LeRobotDataset(repo_id)
# Configure the policy to extract features from the image frames
camera_keys = dataset.meta.camera_keys
# Configure the policy to extract features from the image frames
camera_keys = dataset.meta.camera_keys
config = RewardClassifierConfig(
num_cameras=len(camera_keys),
device=device,
# backbone model to extract features from the image frames
model_name="microsoft/resnet-18",
)
config = RewardClassifierConfig(
num_cameras=len(camera_keys),
device=device,
# backbone model to extract features from the image frames
model_name="microsoft/resnet-18",
)
# Make policy, preprocessor, and optimizer
policy = make_policy(config, ds_meta=dataset.meta)
optimizer = config.get_optimizer_preset().build(policy.parameters())
preprocessor, _ = make_pre_post_processors(policy_cfg=config, dataset_stats=dataset.meta.stats)
classifier_id = "<user>/reward_classifier_hil_serl_example"
# Instantiate a dataloader
dataloader = torch.utils.data.DataLoader(dataset, batch_size=16, shuffle=True)
# Training loop
num_epochs = 5
for epoch in range(num_epochs):
total_loss = 0
total_accuracy = 0
for batch in dataloader:
# Preprocess the batch and move it to the correct device.
batch = preprocessor(batch)
# Forward pass
loss, output_dict = policy.forward(batch)
# Backward pass and optimization
optimizer.zero_grad()
loss.backward()
optimizer.step()
total_loss += loss.item()
total_accuracy += output_dict["accuracy"]
avg_loss = total_loss / len(dataloader)
avg_accuracy = total_accuracy / len(dataloader)
print(f"Epoch {epoch + 1}/{num_epochs}, Loss: {avg_loss:.4f}, Accuracy: {avg_accuracy:.2f}%")
print("Training finished!")
# You can now save the trained policy.
policy.push_to_hub(classifier_id)
# Make policy, preprocessor, and optimizer
policy = make_policy(config, ds_meta=dataset.meta)
optimizer = config.get_optimizer_preset().build(policy.parameters())
preprocessor, _ = make_pre_post_processors(policy_cfg=config, dataset_stats=dataset.meta.stats)
if __name__ == "__main__":
main()
classifier_id = "fracapuano/reward_classifier_hil_serl_example"
# Instantiate a dataloader
dataloader = torch.utils.data.DataLoader(dataset, batch_size=16, shuffle=True)
# Training loop
num_epochs = 5
for epoch in range(num_epochs):
total_loss = 0
total_accuracy = 0
for batch in dataloader:
# Preprocess the batch and move it to the correct device.
batch = preprocessor(batch)
# Forward pass
loss, output_dict = policy.forward(batch)
# Backward pass and optimization
optimizer.zero_grad()
loss.backward()
optimizer.step()
total_loss += loss.item()
total_accuracy += output_dict["accuracy"]
avg_loss = total_loss / len(dataloader)
avg_accuracy = total_accuracy / len(dataloader)
print(f"Epoch {epoch + 1}/{num_epochs}, Loss: {avg_loss:.4f}, Accuracy: {avg_accuracy:.2f}%")
print("Training finished!")
# You can now save the trained policy.
policy.push_to_hub(classifier_id)
examples/tutorial/smolvla/using_smolvla_example.py
+41 -47
View File
@@ -11,62 +11,56 @@ from lerobot.robots.so100_follower.so100_follower import SO100Follower
MAX_EPISODES = 5
MAX_STEPS_PER_EPISODE = 20
device = torch.device("mps") # or "cuda" or "cpu"
model_id = "lerobot/smolvla_base"
def main():
device = torch.device("mps") # or "cuda" or "cpu"
model_id = "lerobot/smolvla_base"
model = SmolVLAPolicy.from_pretrained(model_id)
model = SmolVLAPolicy.from_pretrained(model_id)
preprocess, postprocess = make_pre_post_processors(
model.config,
model_id,
# This overrides allows to run on MPS, otherwise defaults to CUDA (if available)
preprocessor_overrides={"device_processor": {"device": str(device)}},
)
preprocess, postprocess = make_pre_post_processors(
model.config,
model_id,
# This overrides allows to run on MPS, otherwise defaults to CUDA (if available)
preprocessor_overrides={"device_processor": {"device": str(device)}},
)
# find ports using lerobot-find-port
follower_port = ... # something like "/dev/tty.usbmodem58760431631"
# find ports using lerobot-find-port
follower_port = ... # something like "/dev/tty.usbmodem58760431631"
# the robot ids are used the load the right calibration files
follower_id = ... # something like "follower_so100"
# the robot ids are used the load the right calibration files
follower_id = ... # something like "follower_so100"
# Robot and environment configuration
# Camera keys must match the name and resolutions of the ones used for training!
# You can check the camera keys expected by a model in the info.json card on the model card on the Hub
camera_config = {
"camera1": OpenCVCameraConfig(index_or_path=0, width=640, height=480, fps=30),
"camera2": OpenCVCameraConfig(index_or_path=1, width=640, height=480, fps=30),
}
# Robot and environment configuration
# Camera keys must match the name and resolutions of the ones used for training!
# You can check the camera keys expected by a model in the info.json card on the model card on the Hub
camera_config = {
"camera1": OpenCVCameraConfig(index_or_path=0, width=640, height=480, fps=30),
"camera2": OpenCVCameraConfig(index_or_path=1, width=640, height=480, fps=30),
}
robot_cfg = SO100FollowerConfig(port=follower_port, id=follower_id, cameras=camera_config)
robot = SO100Follower(robot_cfg)
robot.connect()
robot_cfg = SO100FollowerConfig(port=follower_port, id=follower_id, cameras=camera_config)
robot = SO100Follower(robot_cfg)
robot.connect()
task = "" # something like "pick the red block"
robot_type = "" # something like "so100_follower" for multi-embodiment datasets
task = "" # something like "pick the red block"
robot_type = "" # something like "so100_follower" for multi-embodiment datasets
# This is used to match the raw observation keys to the keys expected by the policy
action_features = hw_to_dataset_features(robot.action_features, "action")
obs_features = hw_to_dataset_features(robot.observation_features, "observation")
dataset_features = {**action_features, **obs_features}
# This is used to match the raw observation keys to the keys expected by the policy
action_features = hw_to_dataset_features(robot.action_features, "action")
obs_features = hw_to_dataset_features(robot.observation_features, "observation")
dataset_features = {**action_features, **obs_features}
for _ in range(MAX_EPISODES):
for _ in range(MAX_STEPS_PER_EPISODE):
obs = robot.get_observation()
obs_frame = build_inference_frame(
observation=obs, ds_features=dataset_features, device=device, task=task, robot_type=robot_type
)
for _ in range(MAX_EPISODES):
for _ in range(MAX_STEPS_PER_EPISODE):
obs = robot.get_observation()
obs_frame = build_inference_frame(
observation=obs, ds_features=dataset_features, device=device, task=task, robot_type=robot_type
)
obs = preprocess(obs_frame)
obs = preprocess(obs_frame)
action = model.select_action(obs)
action = postprocess(action)
action = make_robot_action(action, dataset_features)
robot.send_action(action)
action = model.select_action(obs)
action = postprocess(action)
action = make_robot_action(action, dataset_features)
robot.send_action(action)
print("Episode finished! Starting new episode...")
if __name__ == "__main__":
main()
print("Episode finished! Starting new episode...")
examples/unitree_g1/gr00t_locomotion.py
-347
View File
@@ -1,347 +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.
"""
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!")
get_calibration.py
+107
View File
@@ -0,0 +1,107 @@
import json
import time
import math
from pathlib import Path
# ---- key → (section, name, id)
MAP = {
# LEFT
"kLeftShoulderPitch.pos": ("left", "shoulder_pitch", 0),
"kLeftShoulderYaw.pos": ("left", "shoulder_yaw", 1),
"kLeftShoulderRoll.pos": ("left", "shoulder_roll", 2),
"kLeftElbow.pos": ("left", "elbow_flex", 3),
"kLeftWristRoll.pos": ("left", "wrist_roll", 4),
"kLeftWristYaw.pos": ("left", "wrist_yaw", 5),
"kLeftWristyaw.pos": ("left", "wrist_yaw", 5), # tolerate casing variant
"kLeftWristPitch.pos": ("left", "wrist_pitch", 6),
# RIGHT
"kRightShoulderPitch.pos": ("right", "shoulder_pitch", 0),
"kRightShoulderYaw.pos": ("right", "shoulder_yaw", 1),
"kRightShoulderRoll.pos": ("right", "shoulder_roll", 2),
"kRightElbow.pos": ("right", "elbow_flex", 3),
"kRightWristRoll.pos": ("right", "wrist_roll", 4),
"kRightWristYaw.pos": ("right", "wrist_yaw", 5),
"kRightWristPitch.pos": ("right", "wrist_pitch", 6),
}
# Output
CALIB_PATH = Path("calibration.json")
ROUND_TO_INT = False # set True if you want int ranges
# Init tracker: tracker["left"]["shoulder_pitch"] = {...}
tracker = {"left": {}, "right": {}}
for sec, name, idx in MAP.values():
if name not in tracker[sec]:
tracker[sec][name] = {
"id": idx,
"drive_mode": 0,
"homing_offset": 0,
"range_min": math.inf,
"range_max": -math.inf,
}
def _to_float(x):
# unwrap numpy / torch scalars if present
if hasattr(x, "item"):
try:
x = x.item()
except Exception:
pass
return float(x)
def update_tracker(obs: dict):
for k, v in obs.items():
if k not in MAP:
continue
sec, name, _ = MAP[k]
try:
x = _to_float(v)
except Exception:
continue
t = tracker[sec][name]
if x < t["range_min"]:
t["range_min"] = x
if x > t["range_max"]:
t["range_max"] = x
def dump_calibration(path: Path):
out = {"left": {}, "right": {}}
for sec in ("left", "right"):
for name, d in tracker[sec].items():
mn, mx = d["range_min"], d["range_max"]
if ROUND_TO_INT:
mn = None if mn is math.inf else int(round(mn))
mx = None if mx is -math.inf else int(round(mx))
else:
mn = None if mn is math.inf else mn
mx = None if mx is -math.inf else mx
out[sec][name] = {
"id": d["id"],
"drive_mode": d["drive_mode"],
"homing_offset": d["homing_offset"],
"range_min": mn,
"range_max": mx,
}
path.write_text(json.dumps(out, indent=4))
print(f"Saved calibration to {path.resolve()}")
from lerobot.robots.unitree_g1.unitree_g1 import UnitreeG1, G1_29_JointIndex
from lerobot.robots.unitree_g1.config_unitree_g1 import UnitreeG1Config
from lerobot.datasets.lerobot_dataset import LeRobotDataset
import time
config = UnitreeG1Config(
motion_mode=False,
simulation_mode=False
)
robot = UnitreeG1(config)
try:
while True:
observation = robot.get_observation()
update_tracker(observation)
robot.send_action(observation) # mirror, if desired
time.sleep(0.01)
except KeyboardInterrupt:
dump_calibration(CALIB_PATH)
loop_datasets.py
-10
View File
@@ -1,10 +0,0 @@
from huggingface_hub import HfApi, list_datasets
api = HfApi()
datasets = list_datasets(author="lerobot-data-collection")
print('"[', end="")
i=0
for dataset in datasets:
if "three-folds-dataset" in dataset.id:
print("'" + dataset.id + "',", end="")
print(']"',)
pyproject.toml
+4 -14
View File
@@ -25,7 +25,7 @@ discord = "https://discord.gg/s3KuuzsPFb"
[project]
name = "lerobot"
version = "0.4.3"
version = "0.4.2"
description = "🤗 LeRobot: State-of-the-art Machine Learning for Real-World Robotics in Pytorch"
readme = "README.md"
license = { text = "Apache-2.0" }
@@ -102,17 +102,11 @@ grpcio-dep = ["grpcio==1.73.1", "protobuf==6.31.0"] # TODO: Bumb dependency (com
# Motors
feetech = ["feetech-servo-sdk>=1.0.0,<2.0.0"]
dynamixel = ["dynamixel-sdk>=3.7.31,<3.9.0"]
damiao = ["python-can>=4.2.0,<5.0.0"]
# Robots
openarms = ["lerobot[damiao]"]
gamepad = ["lerobot[pygame-dep]", "hidapi>=0.14.0,<0.15.0"]
hopejr = ["lerobot[feetech]", "lerobot[pygame-dep]"]
lekiwi = ["lerobot[feetech]", "pyzmq>=26.2.1,<28.0.0"]
unitree_g1 = [
"pyzmq>=26.2.1,<28.0.0",
"onnxruntime>=1.16.0"
]
reachy2 = ["reachy2_sdk>=1.0.14,<1.1.0"]
kinematics = ["lerobot[placo-dep]"]
intelrealsense = [
@@ -135,7 +129,6 @@ groot = [
"ninja>=1.11.1,<2.0.0",
"flash-attn>=2.5.9,<3.0.0 ; sys_platform != 'darwin'"
]
xvla = ["lerobot[transformers-dep]"]
hilserl = ["lerobot[transformers-dep]", "gym-hil>=0.1.13,<0.2.0", "lerobot[grpcio-dep]", "lerobot[placo-dep]"]
# Features
@@ -155,7 +148,6 @@ metaworld = ["metaworld==3.0.0"]
# All
all = [
"lerobot[dynamixel]",
"lerobot[openarms]",
"lerobot[gamepad]",
"lerobot[hopejr]",
"lerobot[lekiwi]",
@@ -165,7 +157,6 @@ all = [
"lerobot[pi]",
"lerobot[smolvla]",
# "lerobot[groot]", TODO(Steven): Gr00t requires specific installation instructions for flash-attn
"lerobot[xvla]",
"lerobot[hilserl]",
"lerobot[async]",
"lerobot[dev]",
@@ -266,7 +257,6 @@ default.extend-ignore-identifiers-re = [
"ein",
"thw",
"inpt",
"ROBOTIS",
]
# TODO: Uncomment when ready to use
@@ -366,9 +356,9 @@ ignore_errors = false
# module = "lerobot.async_inference.*"
# ignore_errors = false
[[tool.mypy.overrides]]
module = "lerobot.transport.*"
ignore_errors = false
# [[tool.mypy.overrides]]
# module = "lerobot.transport.*"
# ignore_errors = false
# [[tool.mypy.overrides]]
# module = "lerobot.scripts.*"
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src/lerobot/async_inference/constants.py
+1 -1
View File
@@ -26,4 +26,4 @@ DEFAULT_OBS_QUEUE_TIMEOUT = 2
SUPPORTED_POLICIES = ["act", "smolvla", "diffusion", "tdmpc", "vqbet", "pi0", "pi05"]
# TODO: Add all other robots
SUPPORTED_ROBOTS = ["so100_follower", "so101_follower", "bi_so100_follower", "omx_follower"]
SUPPORTED_ROBOTS = ["so100_follower", "so101_follower", "bi_so100_follower"]
src/lerobot/async_inference/robot_client.py
-1
View File
@@ -54,7 +54,6 @@ from lerobot.robots import ( # noqa: F401
bi_so100_follower,
koch_follower,
make_robot_from_config,
omx_follower,
so100_follower,
so101_follower,
)
src/lerobot/cameras/utils.py
+5
View File
@@ -43,6 +43,11 @@ def make_cameras_from_configs(camera_configs: dict[str, CameraConfig]) -> dict[s
cameras[key] = Reachy2Camera(cfg)
elif cfg.type == "zmq":
from .zmq import ZMQCamera
cameras[key] = ZMQCamera(cfg)
else:
try:
cameras[key] = cast(Camera, make_device_from_device_class(cfg))
src/lerobot/teleoperators/omx_leader/__init__.py → src/lerobot/cameras/zmq/__init__.py
+3 -5
View File
@@ -1,6 +1,4 @@
#!/usr/bin/env python
# Copyright 2025 The HuggingFace Inc. team. All rights reserved.
# Copyright 2024 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.
@@ -14,5 +12,5 @@
# See the License for the specific language governing permissions and
# limitations under the License.
from .config_omx_leader import OmxLeaderConfig
from .omx_leader import OmxLeader
from .camera_zmq import ZMQCamera
from .configuration_zmq import ZMQCameraConfig
src/lerobot/cameras/zmq/camera_zmq.py
+623
View File
@@ -0,0 +1,623 @@
# Copyright 2024 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.
"""
Provides the ZMQCamera class for capturing frames from remote cameras via ZeroMQ.
"""
import json
import logging
import os
import threading
import time
from pathlib import Path
from threading import Event, Lock, Thread
from typing import Any
import base64
import cv2
import numpy as np
import zmq
from numpy.typing import NDArray
import base64
import msgpack
import msgpack_numpy as m
from lerobot.utils.errors import DeviceAlreadyConnectedError, DeviceNotConnectedError
from ..camera import Camera
from ..configs import ColorMode
from .configuration_zmq import ZMQCameraConfig
logger = logging.getLogger(__name__)
class ZMQCamera(Camera):
"""
Manages camera interactions using ZeroMQ for remote frame streaming.
This class provides a high-level interface to connect to remote cameras
that stream JPEG-encoded images over ZeroMQ PUB/SUB sockets. It supports
both synchronous and asynchronous frame reading.
The camera server must be running and publishing JPEG images on the specified
address and port. Use the provided utility script to find available ZMQ cameras:
```bash
lerobot-find-cameras zmq
```
Example:
```python
from lerobot.cameras.zmq import ZMQCamera
from lerobot.cameras.zmq.configuration_zmq import ZMQCameraConfig, ColorMode
# Basic usage
config = ZMQCameraConfig(
server_address="192.168.123.164",
port=5554,
camera_name="remote_cam"
)
camera = ZMQCamera(config)
camera.connect()
# Read 1 frame synchronously
color_image = camera.read()
print(color_image.shape)
# Read 1 frame asynchronously
async_image = camera.async_read()
# When done, properly disconnect the camera
camera.disconnect()
```
"""
def __init__(self, config: ZMQCameraConfig):
"""
Initializes the ZMQCamera instance.
Args:
config: The configuration settings for the ZMQ camera.
"""
super().__init__(config)
self.config = config
self.server_address = config.server_address
self.port = config.port
self.camera_name = config.camera_name
self.color_mode = config.color_mode
self.timeout_ms = config.timeout_ms
self.context: zmq.Context | None = None
self.socket: zmq.Socket | None = None
self._connected = False
self.thread: Thread | None = None
self.stop_event: Event | None = None
self.frame_lock: Lock = Lock()
self.latest_frame: NDArray[Any] | None = None
self.new_frame_event: Event = Event()
# Format type detected during connection (msgpack, json, or raw_jpeg)
self._format_type: str | None = None
def __str__(self) -> str:
return f"{self.__class__.__name__}({self.camera_name}@{self.server_address}:{self.port})"
@property
def is_connected(self) -> bool:
"""Checks if the camera is currently connected."""
return self._connected and self.context is not None and self.socket is not None
def connect(self, warmup: bool = True) -> None:
"""
Connects to the ZMQ camera server and configures settings.
Args:
warmup: If True (default), captures a warmup frame before returning.
Raises:
DeviceAlreadyConnectedError: If the camera is already connected.
RuntimeError: If connection to the ZMQ server fails.
"""
if self.is_connected:
raise DeviceAlreadyConnectedError(f"{self} is already connected.")
logger.info(f"Connecting to {self}...")
try:
self.context = zmq.Context()
self.socket = self.context.socket(zmq.SUB)
self.socket.connect(f"tcp://{self.server_address}:{self.port}")
self.socket.setsockopt_string(zmq.SUBSCRIBE, "")
# Set receive timeout
self.socket.setsockopt(zmq.RCVTIMEO, self.timeout_ms)
self._connected = True
# Try to receive one frame to validate connection and detect format
try:
# Try each format until one works
test_frame = None
for format_type in ["msgpack", "json", "raw_jpeg"]:
try:
test_frame = self.read(format=format_type)
self._format_type = format_type
logger.info(f"{self} detected format: {format_type}")
break
except Exception as e:
logger.debug(f"{self} format '{format_type}' failed: {e}")
continue
if test_frame is None:
raise RuntimeError("Failed to decode frame with any supported format (msgpack, json, raw_jpeg)")
# Auto-detect resolution if not specified
if self.width is None or self.height is None:
h, w = test_frame.shape[:2]
self.height = h
self.width = w
logger.info(f"{self} auto-detected resolution: {w}x{h}")
logger.info(f"{self} connected successfully.")
if warmup:
logger.debug(f"Warming up {self}...")
time.sleep(0.1) # Brief warmup period
except Exception as e:
self._connected = False
if self.socket:
self.socket.close()
if self.context:
self.context.term()
self.socket = None
self.context = None
raise RuntimeError(f"Failed to receive initial frame from {self}: {e}")
except Exception as e:
self._connected = False
if self.socket:
self.socket.close()
if self.context:
self.context.term()
self.socket = None
self.context = None
raise RuntimeError(f"Failed to connect to {self}: {e}")
@staticmethod
def find_cameras(
subnet: str | None = None,
ports: list[int] | None = None,
timeout_ms: int = 200,
) -> list[dict[str, Any]]:
"""
Scans the local network for ZMQ cameras (fast parallel scan).
Uses threading to scan multiple hosts simultaneously. Without parallelization,
scanning 254 hosts would take 6+ minutes. With threads, takes ~10-15 seconds.
Args:
subnet: Network subnet to scan (e.g., "192.168.1.0/24"). If None, auto-detects.
ports: List of ports to scan. Defaults to [5554, 5555, 5556].
timeout_ms: Connection timeout per host in milliseconds. Default: 200ms.
Returns:
List of dicts containing camera info (address, port, format, resolution).
Example:
>>> cameras = ZMQCamera.find_cameras()
>>> # Or specify: cameras = ZMQCamera.find_cameras(subnet="10.0.0.0/24", ports=[5554])
"""
import socket
import ipaddress
from concurrent.futures import ThreadPoolExecutor, as_completed
if ports is None:
ports = [5554, 5555, 5556]
# Auto-detect local subnet
if subnet is None:
try:
s = socket.socket(socket.AF_INET, socket.SOCK_DGRAM)
s.connect(("8.8.8.8", 80))
local_ip = s.getsockname()[0]
s.close()
subnet = ".".join(local_ip.split(".")[:-1]) + ".0/24"
logger.info(f"Auto-detected subnet: {subnet}")
except Exception as e:
logger.error(f"Failed to auto-detect subnet: {e}")
return []
# Parse subnet
try:
network = ipaddress.ip_network(subnet, strict=False)
hosts = list(network.hosts())
# Always include localhost (for MuJoCo sim, local servers)
hosts.insert(0, ipaddress.IPv4Address("127.0.0.1"))
except Exception as e:
logger.error(f"Invalid subnet '{subnet}': {e}")
return []
total = len(hosts) * len(ports)
logger.info(f"Scanning {len(hosts)} hosts × {len(ports)} ports = {total} targets (this takes ~10-15s)...")
def test_target(host_ip: str, port: int) -> dict | None:
"""Test one host:port for ZMQ camera."""
ctx = zmq.Context()
sock = ctx.socket(zmq.SUB)
sock.connect(f"tcp://{host_ip}:{port}")
sock.setsockopt_string(zmq.SUBSCRIBE, "")
sock.setsockopt(zmq.RCVTIMEO, timeout_ms)
# Wait for subscription to establish (ZMQ "slow joiner" problem)
time.sleep(0.1)
# Try receiving a few times
msg = None
for _ in range(3):
try:
msg = sock.recv()
break
except zmq.Again:
time.sleep(0.05)
if msg is None:
sock.close()
ctx.term()
return None
# Try formats: msgpack → json → raw_jpeg
frame = fmt = None
# Msgpack
try:
d = msgpack.unpackb(msg, object_hook=m.decode)
if isinstance(d, dict) and "images" in d and len(d["images"]) > 0:
img = next(iter(d["images"].values()))
if isinstance(img, str):
frame = cv2.imdecode(np.frombuffer(base64.b64decode(img), np.uint8), cv2.IMREAD_COLOR)
elif isinstance(img, np.ndarray):
frame = img
if frame is not None:
fmt = "msgpack"
except:
pass
# JSON
if frame is None:
try:
d = json.loads(msg.decode('utf-8'))
if isinstance(d, dict):
for v in d.values():
if isinstance(v, str) and len(v) > 100:
try:
frame = cv2.imdecode(np.frombuffer(base64.b64decode(v), np.uint8), cv2.IMREAD_COLOR)
if frame is not None:
fmt = "json"
break
except:
pass
except:
pass
# Raw JPEG
if frame is None:
try:
frame = cv2.imdecode(np.frombuffer(msg, np.uint8), cv2.IMREAD_COLOR)
if frame is not None:
fmt = "raw_jpeg"
except:
pass
sock.close()
ctx.term()
if frame is not None:
h, w = frame.shape[:2]
return {
"name": f"ZMQ @ {host_ip}:{port}",
"type": "ZMQ",
"id": f"{host_ip}:{port}",
"server_address": host_ip,
"port": port,
"camera_name": f"cam_{host_ip.replace('.', '_')}_{port}",
"format": fmt,
"default_stream_profile": {"width": w, "height": h, "format": fmt.upper()},
}
return None
# Parallel scan with thread pool
found = []
with ThreadPoolExecutor(max_workers=100) as ex:
futures = [ex.submit(test_target, str(h), p) for h in hosts for p in ports]
for i, fut in enumerate(as_completed(futures), 1):
if i % 100 == 0:
logger.info(f" Progress: {i}/{total} ({100*i//total}%)")
res = fut.result()
if res:
found.append(res)
logger.info(f"{res['server_address']}:{res['port']} ({res['format']})")
logger.info(f"Scan complete! Found {len(found)} camera(s).")
return found
def read(self, color_mode: ColorMode | None = None, format: str | None = None) -> NDArray[Any]:
"""
Reads a single frame synchronously from the ZMQ camera.
Supports three message formats:
1. "msgpack": Msgpack with base64 JPEGs: {"timestamps": {...}, "images": {camera_name: "b64"}}
(used by MuJoCo sim)
2. "json": JSON with base64 JPEGs: {"state": 0.0, "camera_name": "b64jpeg"}
(used by LeKiwi-style servers)
3. "raw_jpeg": Raw JPEG bytes (used by Unitree G1 head camera)
Args:
color_mode: Target color mode (RGB or BGR). If None, uses self.color_mode.
format: Message format to use. If None, uses auto-detected format from connect().
One of: "msgpack", "json", "raw_jpeg"
Returns:
np.ndarray: Decoded frame in shape (height, width, 3)
Raises:
DeviceNotConnectedError: If camera is not connected
TimeoutError: If no frame received within timeout_ms
RuntimeError: If frame decoding fails
"""
if not self.is_connected:
raise DeviceNotConnectedError(f"{self} is not connected.")
if self.socket is None:
raise DeviceNotConnectedError(f"{self} socket is not initialized")
# Use detected format if not specified
if format is None:
format = self._format_type
if format is None:
raise RuntimeError(f"{self} format not specified and not auto-detected during connect()")
start_time = time.perf_counter()
try:
message = self.socket.recv()
except zmq.Again:
raise TimeoutError(f"{self} timeout waiting for frame after {self.timeout_ms}ms")
except Exception as e:
raise RuntimeError(f"{self} read failed: {e}")
frame = None
# Decode based on format
if format == "msgpack":
data = msgpack.unpackb(message, object_hook=m.decode)
if not isinstance(data, dict) or "images" not in data:
raise RuntimeError(f"{self} invalid msgpack format: expected dict with 'images' key")
images_dict = data["images"]
# Prefer named camera if present
if self.camera_name in images_dict:
img_data = images_dict[self.camera_name]
elif len(images_dict) > 0:
# Fallback: first available camera
img_data = next(iter(images_dict.values()))
else:
raise RuntimeError(f"{self} no images found in msgpack message")
# Decode the image data
if isinstance(img_data, str):
color_bytes = base64.b64decode(img_data)
np_img = np.frombuffer(color_bytes, dtype=np.uint8)
frame = cv2.imdecode(np_img, cv2.IMREAD_COLOR)
elif isinstance(img_data, np.ndarray):
frame = img_data
else:
raise RuntimeError(f"{self} unknown image payload type: {type(img_data)}")
elif format == "json":
data = json.loads(message.decode('utf-8'))
if not isinstance(data, dict) or self.camera_name not in data:
raise RuntimeError(f"{self} invalid JSON format: expected dict with '{self.camera_name}' key")
img_b64 = data[self.camera_name]
if not isinstance(img_b64, str):
raise RuntimeError(f"{self} expected base64 string in JSON, got {type(img_b64)}")
color_bytes = base64.b64decode(img_b64)
np_img = np.frombuffer(color_bytes, dtype=np.uint8)
frame = cv2.imdecode(np_img, cv2.IMREAD_COLOR)
elif format == "raw_jpeg":
np_img = np.frombuffer(message, dtype=np.uint8)
frame = cv2.imdecode(np_img, cv2.IMREAD_COLOR)
else:
raise ValueError(f"{self} unsupported format: {format}. Use 'msgpack', 'json', or 'raw_jpeg'")
if frame is None or not isinstance(frame, np.ndarray):
raise RuntimeError(f"{self} failed to decode image using format '{format}'")
processed_frame = self._postprocess_image(frame, color_mode)
read_duration_ms = (time.perf_counter() - start_time) * 1e3
logger.debug(f"{self} read took: {read_duration_ms:.1f}ms")
return processed_frame
def _postprocess_image(self, image: NDArray[Any], color_mode: ColorMode | None = None) -> NDArray[Any]:
"""
Applies color conversion to a raw frame.
Args:
image: The raw image frame (BGR format from cv2.imdecode).
color_mode: The target color mode (RGB or BGR). If None, uses self.color_mode.
Returns:
np.ndarray: The processed image frame.
Raises:
ValueError: If the requested color_mode is invalid.
RuntimeError: If the frame dimensions don't match expectations.
"""
requested_color_mode = self.color_mode if color_mode is None else color_mode
if requested_color_mode not in (ColorMode.RGB, ColorMode.BGR):
raise ValueError(
f"Invalid color mode '{requested_color_mode}'. Expected {ColorMode.RGB} or {ColorMode.BGR}."
)
h, w, c = image.shape
# Validate dimensions if they were specified
if self.height is not None and self.width is not None:
if h != self.height or w != self.width:
logger.warning(
f"{self} frame dimensions ({w}x{h}) don't match configured ({self.width}x{self.height}). "
"This might be expected if the server sends different resolutions."
)
if c != 3:
raise RuntimeError(f"{self} frame channels={c} do not match expected 3 channels (RGB/BGR).")
processed_image = image
if requested_color_mode == ColorMode.RGB:
processed_image = cv2.cvtColor(image, cv2.COLOR_BGR2RGB)
return processed_image
def _read_loop(self) -> None:
"""
Internal loop run by the background thread for asynchronous reading.
On each iteration:
1. Reads a frame from ZMQ
2. Stores result in latest_frame (thread-safe)
3. Sets new_frame_event to notify listeners
Stops on DeviceNotConnectedError, logs other errors and continues.
"""
if self.stop_event is None:
raise RuntimeError(f"{self}: stop_event is not initialized before starting read loop.")
while not self.stop_event.is_set():
try:
frame = self.read()
with self.frame_lock:
self.latest_frame = frame
self.new_frame_event.set()
except DeviceNotConnectedError:
break
except TimeoutError:
# Timeout is expected occasionally, just continue
logger.debug(f"{self} read timeout in background thread")
except Exception as e:
logger.warning(f"Error reading frame in background thread for {self}: {e}")
def _start_read_thread(self) -> None:
"""Starts or restarts the background read thread if it's not running."""
if self.thread is not None and self.thread.is_alive():
self.thread.join(timeout=0.1)
if self.stop_event is not None:
self.stop_event.set()
self.stop_event = Event()
self.thread = Thread(target=self._read_loop, args=(), name=f"{self}_read_loop")
self.thread.daemon = True
self.thread.start()
def _stop_read_thread(self) -> None:
"""Signals the background read thread to stop and waits for it to join."""
if self.stop_event is not None:
self.stop_event.set()
if self.thread is not None and self.thread.is_alive():
self.thread.join(timeout=2.0)
self.thread = None
self.stop_event = None
def async_read(self, timeout_ms: float = 10000) -> NDArray[Any]:
"""
Reads the latest available frame asynchronously.
This method retrieves the most recent frame captured by the background
read thread. It does not block waiting for ZMQ directly, but may wait
up to timeout_ms for the background thread to provide a frame.
Args:
timeout_ms: Maximum time in milliseconds to wait for a frame
to become available. Defaults to 2000ms.
Returns:
np.ndarray: The latest captured frame as a NumPy array in the format
(height, width, channels), processed according to configuration.
Raises:
DeviceNotConnectedError: If the camera is not connected.
TimeoutError: If no frame becomes available within the specified timeout.
RuntimeError: If an unexpected error occurs.
"""
if not self.is_connected:
raise DeviceNotConnectedError(f"{self} is not connected.")
if self.thread is None or not self.thread.is_alive():
self._start_read_thread()
if not self.new_frame_event.wait(timeout=timeout_ms / 1000.0):
thread_alive = self.thread is not None and self.thread.is_alive()
raise TimeoutError(
f"Timed out waiting for frame from {self} after {timeout_ms} ms. "
f"Read thread alive: {thread_alive}."
)
with self.frame_lock:
frame = self.latest_frame
self.new_frame_event.clear()
if frame is None:
raise RuntimeError(f"Internal error: Event set but no frame available for {self}.")
return frame
def disconnect(self) -> None:
"""
Disconnects from the ZMQ camera and cleans up resources.
Stops the background read thread (if running) and closes the ZMQ socket.
Raises:
DeviceNotConnectedError: If the camera is already disconnected.
"""
if not self.is_connected and self.thread is None:
raise DeviceNotConnectedError(f"{self} not connected.")
if self.thread is not None:
self._stop_read_thread()
if self.socket is not None:
self.socket.close()
self.socket = None
if self.context is not None:
self.context.term()
self.context = None
self._connected = False
logger.info(f"{self} disconnected.")
src/lerobot/cameras/zmq/configuration_zmq.py
+78
View File
@@ -0,0 +1,78 @@
# Copyright 2024 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.
from dataclasses import dataclass
from ..configs import CameraConfig, ColorMode
__all__ = ["ZMQCameraConfig", "ColorMode"]
@CameraConfig.register_subclass("zmq")
@dataclass
class ZMQCameraConfig(CameraConfig):
"""Configuration class for ZMQ-based remote camera streams.
This class provides configuration options for cameras accessed through ZeroMQ (ZMQ),
supporting remote camera streams over the network. The server must be running and
streaming JPEG-encoded images over a ZMQ PUB socket.
Example configurations:
```python
# Basic configuration
ZMQCameraConfig(
server_address="192.168.123.164",
port=5554,
camera_name="remote_cam_1"
)
# With custom resolution
ZMQCameraConfig(
server_address="10.0.0.100",
port=5555,
camera_name="lab_cam",
width=1280,
height=480,
fps=30
)
```
Attributes:
server_address: IP address or hostname of the ZMQ image server.
port: Port number where the ZMQ server is publishing images.
camera_name: Identifier name for this camera (for logging/debugging).
color_mode: Color mode for image output (RGB or BGR). Defaults to RGB.
timeout_ms: Timeout in milliseconds for receiving frames. Defaults to 1000ms.
"""
server_address: str
port: int = 5554
camera_name: str = "zmq_camera"
color_mode: ColorMode = ColorMode.RGB
timeout_ms: int = 5000
def __post_init__(self) -> None:
if self.color_mode not in (ColorMode.RGB, ColorMode.BGR):
raise ValueError(
f"`color_mode` is expected to be {ColorMode.RGB.value} or {ColorMode.BGR.value}, but {self.color_mode} is provided."
)
if self.timeout_ms <= 0:
raise ValueError(f"`timeout_ms` must be positive, but {self.timeout_ms} is provided.")
if not self.server_address:
raise ValueError("`server_address` cannot be empty.")
if self.port <= 0 or self.port > 65535:
raise ValueError(f"`port` must be between 1 and 65535, but {self.port} is provided.")
src/lerobot/configs/train.py
-1
View File
@@ -56,7 +56,6 @@ class TrainPipelineConfig(HubMixin):
steps: int = 100_000
eval_freq: int = 20_000
log_freq: int = 200
tolerance_s: float = 1e-4
save_checkpoint: bool = True
# Checkpoint is saved every `save_freq` training iterations and after the last training step.
save_freq: int = 20_000
src/lerobot/datasets/aggregate.py
+20 -57
View File
@@ -136,40 +136,21 @@ def update_meta_data(
df["_orig_chunk"] = df[orig_chunk_col].copy()
df["_orig_file"] = df[orig_file_col].copy()
# Get mappings for this video key
# Update chunk and file indices to point to destination
df[orig_chunk_col] = video_idx["chunk"]
df[orig_file_col] = video_idx["file"]
# Apply per-source-file timestamp offsets
src_to_offset = video_idx.get("src_to_offset", {})
src_to_dst = video_idx.get("src_to_dst", {})
# Apply per-source-file mappings
if src_to_dst:
# Map each episode to its correct destination file and apply offset
if src_to_offset:
# Apply offset based on original source file
for idx in df.index:
# Convert to Python int to avoid numpy type mismatch in dict lookup
src_key = (int(df.at[idx, "_orig_chunk"]), int(df.at[idx, "_orig_file"]))
# Get destination chunk/file for this source file
dst_chunk, dst_file = src_to_dst.get(src_key, (video_idx["chunk"], video_idx["file"]))
df.at[idx, orig_chunk_col] = dst_chunk
df.at[idx, orig_file_col] = dst_file
# Apply timestamp offset
offset = src_to_offset.get(src_key, 0)
df.at[idx, f"videos/{key}/from_timestamp"] += offset
df.at[idx, f"videos/{key}/to_timestamp"] += offset
elif src_to_offset:
# Fallback: use same destination for all, but apply per-file offsets
df[orig_chunk_col] = video_idx["chunk"]
df[orig_file_col] = video_idx["file"]
for idx in df.index:
# Convert to Python int to avoid numpy type mismatch in dict lookup
src_key = (int(df.at[idx, "_orig_chunk"]), int(df.at[idx, "_orig_file"]))
src_key = (df.at[idx, "_orig_chunk"], df.at[idx, "_orig_file"])
offset = src_to_offset.get(src_key, 0)
df.at[idx, f"videos/{key}/from_timestamp"] += offset
df.at[idx, f"videos/{key}/to_timestamp"] += offset
else:
# Fallback to simple offset (for backward compatibility)
df[orig_chunk_col] = video_idx["chunk"]
df[orig_file_col] = video_idx["file"]
df[f"videos/{key}/from_timestamp"] = (
df[f"videos/{key}/from_timestamp"] + video_idx["latest_duration"]
)
@@ -287,12 +268,6 @@ def aggregate_videos(src_meta, dst_meta, videos_idx, video_files_size_in_mb, chu
videos_idx[key]["episode_duration"] = 0
# Track offset for each source (chunk, file) pair
videos_idx[key]["src_to_offset"] = {}
# Track destination (chunk, file) for each source (chunk, file) pair
videos_idx[key]["src_to_dst"] = {}
# Initialize dst_file_durations if not present
# dst_file_durations tracks duration of each destination file
if "dst_file_durations" not in videos_idx[key]:
videos_idx[key]["dst_file_durations"] = {}
for key, video_idx in videos_idx.items():
unique_chunk_file_pairs = {
@@ -307,13 +282,9 @@ def aggregate_videos(src_meta, dst_meta, videos_idx, video_files_size_in_mb, chu
chunk_idx = video_idx["chunk"]
file_idx = video_idx["file"]
dst_file_durations = video_idx["dst_file_durations"]
current_offset = video_idx["latest_duration"]
for src_chunk_idx, src_file_idx in unique_chunk_file_pairs:
# Convert to Python int to ensure consistent dict keys
src_chunk_idx = int(src_chunk_idx)
src_file_idx = int(src_file_idx)
src_path = src_meta.root / DEFAULT_VIDEO_PATH.format(
video_key=key,
chunk_index=src_chunk_idx,
@@ -327,17 +298,14 @@ def aggregate_videos(src_meta, dst_meta, videos_idx, video_files_size_in_mb, chu
)
src_duration = get_video_duration_in_s(src_path)
dst_key = (chunk_idx, file_idx)
if not dst_path.exists():
# New destination file: offset is 0
videos_idx[key]["src_to_offset"][(src_chunk_idx, src_file_idx)] = 0
videos_idx[key]["src_to_dst"][(src_chunk_idx, src_file_idx)] = dst_key
# Store offset before incrementing
videos_idx[key]["src_to_offset"][(src_chunk_idx, src_file_idx)] = current_offset
dst_path.parent.mkdir(parents=True, exist_ok=True)
shutil.copy(str(src_path), str(dst_path))
# Track duration of this destination file
dst_file_durations[dst_key] = src_duration
videos_idx[key]["episode_duration"] += src_duration
current_offset += src_duration
continue
# Check file sizes before appending
@@ -345,11 +313,10 @@ def aggregate_videos(src_meta, dst_meta, videos_idx, video_files_size_in_mb, chu
dst_size = get_file_size_in_mb(dst_path)
if dst_size + src_size >= video_files_size_in_mb:
# Rotate to a new file - offset is 0
chunk_idx, file_idx = update_chunk_file_indices(chunk_idx, file_idx, chunk_size)
dst_key = (chunk_idx, file_idx)
# Rotate to a new file, this source becomes start of new destination
# So its offset should be 0
videos_idx[key]["src_to_offset"][(src_chunk_idx, src_file_idx)] = 0
videos_idx[key]["src_to_dst"][(src_chunk_idx, src_file_idx)] = dst_key
chunk_idx, file_idx = update_chunk_file_indices(chunk_idx, file_idx, chunk_size)
dst_path = dst_meta.root / DEFAULT_VIDEO_PATH.format(
video_key=key,
chunk_index=chunk_idx,
@@ -357,20 +324,16 @@ def aggregate_videos(src_meta, dst_meta, videos_idx, video_files_size_in_mb, chu
)
dst_path.parent.mkdir(parents=True, exist_ok=True)
shutil.copy(str(src_path), str(dst_path))
# Track duration of this new destination file
dst_file_durations[dst_key] = src_duration
# Reset offset for next file
current_offset = src_duration
else:
# Append to existing destination file
# Offset is the current duration of this destination file
current_dst_duration = dst_file_durations.get(dst_key, 0)
videos_idx[key]["src_to_offset"][(src_chunk_idx, src_file_idx)] = current_dst_duration
videos_idx[key]["src_to_dst"][(src_chunk_idx, src_file_idx)] = dst_key
# Append to existing video file - use current accumulated offset
videos_idx[key]["src_to_offset"][(src_chunk_idx, src_file_idx)] = current_offset
concatenate_video_files(
[dst_path, src_path],
dst_path,
)
# Update duration of this destination file
dst_file_durations[dst_key] = current_dst_duration + src_duration
current_offset += src_duration
videos_idx[key]["episode_duration"] += src_duration
src/lerobot/datasets/factory.py
-2
View File
@@ -98,7 +98,6 @@ def make_dataset(cfg: TrainPipelineConfig) -> LeRobotDataset | MultiLeRobotDatas
image_transforms=image_transforms,
revision=cfg.dataset.revision,
video_backend=cfg.dataset.video_backend,
tolerance_s=cfg.tolerance_s,
)
else:
dataset = StreamingLeRobotDataset(
@@ -109,7 +108,6 @@ def make_dataset(cfg: TrainPipelineConfig) -> LeRobotDataset | MultiLeRobotDatas
image_transforms=image_transforms,
revision=cfg.dataset.revision,
max_num_shards=cfg.num_workers,
tolerance_s=cfg.tolerance_s,
)
else:
raise NotImplementedError("The MultiLeRobotDataset isn't supported for now.")
src/lerobot/datasets/image_writer.py
+4 -6
View File
@@ -110,8 +110,8 @@ def worker_thread_loop(queue: queue.Queue):
if item is None:
queue.task_done()
break
image_array, fpath, compress_level = item
write_image(image_array, fpath, compress_level)
image_array, fpath = item
write_image(image_array, fpath)
queue.task_done()
@@ -169,13 +169,11 @@ class AsyncImageWriter:
p.start()
self.processes.append(p)
def save_image(
self, image: torch.Tensor | np.ndarray | PIL.Image.Image, fpath: Path, compress_level: int = 1
):
def save_image(self, image: torch.Tensor | np.ndarray | PIL.Image.Image, fpath: Path):
if isinstance(image, torch.Tensor):
# Convert tensor to numpy array to minimize main process time
image = image.cpu().numpy()
self.queue.put((image, fpath, compress_level))
self.queue.put((image, fpath))
def wait_until_done(self):
self.queue.join()
src/lerobot/datasets/lerobot_dataset.py
+14 -92
View File
@@ -13,7 +13,6 @@
# 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.
import concurrent.futures
import contextlib
import logging
import shutil
@@ -23,13 +22,11 @@ from pathlib import Path
import datasets
import numpy as np
import os
import packaging.version
import pandas as pd
import PIL.Image
import pyarrow as pa
import pyarrow.parquet as pq
from concurrent.futures import ProcessPoolExecutor
import torch
import torch.utils
from huggingface_hub import HfApi, snapshot_download
@@ -542,15 +539,6 @@ class LeRobotDatasetMetadata:
return obj
def _encode_video_worker(video_key: str, episode_index: int, root: Path, fps: int) -> Path:
temp_path = Path(tempfile.mkdtemp(dir=root)) / f"{video_key}_{episode_index:03d}.mp4"
fpath = DEFAULT_IMAGE_PATH.format(image_key=video_key, episode_index=episode_index, frame_index=0)
img_dir = (root / fpath).parent
encode_video_frames(img_dir, temp_path, fps, overwrite=True)
shutil.rmtree(img_dir)
return temp_path
class LeRobotDataset(torch.utils.data.Dataset):
def __init__(
self,
@@ -1083,7 +1071,6 @@ class LeRobotDataset(torch.utils.data.Dataset):
ep_buffer[key] = current_ep_idx if key == "episode_index" else []
return ep_buffer
# TODO(Steven): consider move this to utils
def _get_image_file_path(self, episode_index: int, image_key: str, frame_index: int) -> Path:
fpath = DEFAULT_IMAGE_PATH.format(
image_key=image_key, episode_index=episode_index, frame_index=frame_index
@@ -1093,15 +1080,13 @@ class LeRobotDataset(torch.utils.data.Dataset):
def _get_image_file_dir(self, episode_index: int, image_key: str) -> Path:
return self._get_image_file_path(episode_index, image_key, frame_index=0).parent
def _save_image(
self, image: torch.Tensor | np.ndarray | PIL.Image.Image, fpath: Path, compress_level: int = 1
) -> None:
def _save_image(self, image: torch.Tensor | np.ndarray | PIL.Image.Image, fpath: Path) -> None:
if self.image_writer is None:
if isinstance(image, torch.Tensor):
image = image.cpu().numpy()
write_image(image, fpath, compress_level=compress_level)
write_image(image, fpath)
else:
self.image_writer.save_image(image=image, fpath=fpath, compress_level=compress_level)
self.image_writer.save_image(image=image, fpath=fpath)
def add_frame(self, frame: dict) -> None:
"""
@@ -1139,19 +1124,14 @@ class LeRobotDataset(torch.utils.data.Dataset):
)
if frame_index == 0:
img_path.parent.mkdir(parents=True, exist_ok=True)
compress_level = 1 if self.features[key]["dtype"] == "video" else 6
self._save_image(frame[key], img_path, compress_level)
self._save_image(frame[key], img_path)
self.episode_buffer[key].append(str(img_path))
else:
self.episode_buffer[key].append(frame[key])
self.episode_buffer["size"] += 1
def save_episode(
self,
episode_data: dict | None = None,
parallel_encoding: bool = True,
) -> None:
def save_episode(self, episode_data: dict | None = None) -> None:
"""
This will save to disk the current episode in self.episode_buffer.
@@ -1163,8 +1143,6 @@ class LeRobotDataset(torch.utils.data.Dataset):
episode_data (dict | None, optional): Dict containing the episode data to save. If None, this will
save the current episode in self.episode_buffer, which is filled with 'add_frame'. Defaults to
None.
parallel_encoding (bool, optional): If True, encode videos in parallel using ProcessPoolExecutor.
Defaults to True on Linux, False on macOS as it tends to use all the CPU available already.
"""
episode_buffer = episode_data if episode_data is not None else self.episode_buffer
@@ -1201,43 +1179,8 @@ class LeRobotDataset(torch.utils.data.Dataset):
use_batched_encoding = self.batch_encoding_size > 1
if has_video_keys and not use_batched_encoding:
video_paths = self._encode_multiple_temporary_episode_videos(self.meta.video_keys, episode_index)
for (video_key, video_path) in zip(self.meta.video_keys, video_paths):
ep_metadata.update(self._save_episode_video(video_key, episode_index, video_path))
num_cameras = len(self.meta.video_keys)
if parallel_encoding and num_cameras > 1:
# TODO(Steven): Ideally we would like to control the number of threads per encoding such that:
# num_cameras * num_threads = (total_cpu -1)
with concurrent.futures.ProcessPoolExecutor(max_workers=num_cameras) as executor:
future_to_key = {
executor.submit(
_encode_video_worker,
video_key,
episode_index,
self.root,
self.fps,
): video_key
for video_key in self.meta.video_keys
}
results = {}
for future in concurrent.futures.as_completed(future_to_key):
video_key = future_to_key[future]
try:
temp_path = future.result()
results[video_key] = temp_path
except Exception as exc:
logging.error(f"Video encoding failed for {video_key}: {exc}")
raise exc
for video_key in self.meta.video_keys:
temp_path = results[video_key]
ep_metadata.update(
self._save_episode_video(video_key, episode_index, temp_path=temp_path)
)
else:
for video_key in self.meta.video_keys:
ep_metadata.update(self._save_episode_video(video_key, episode_index))
for video_key in self.meta.video_keys:
ep_metadata.update(self._save_episode_video(video_key, episode_index))
# `meta.save_episode` need to be executed after encoding the videos
self.meta.save_episode(episode_index, episode_length, episode_tasks, ep_stats, ep_metadata)
@@ -1402,18 +1345,9 @@ class LeRobotDataset(torch.utils.data.Dataset):
return metadata
def _save_episode_video(
self,
video_key: str,
episode_index: int,
temp_path: Path | None = None,
) -> dict:
def _save_episode_video(self, video_key: str, episode_index: int) -> dict:
# Encode episode frames into a temporary video
if temp_path is None:
ep_path = self._encode_temporary_episode_video(video_key, episode_index)
else:
ep_path = temp_path
ep_path = self._encode_temporary_episode_video(video_key, episode_index)
ep_size_in_mb = get_file_size_in_mb(ep_path)
ep_duration_in_s = get_video_duration_in_s(ep_path)
@@ -1531,23 +1465,11 @@ class LeRobotDataset(torch.utils.data.Dataset):
Note: `encode_video_frames` is a blocking call. Making it asynchronous shouldn't speedup encoding,
since video encoding with ffmpeg is already using multithreading.
"""
return _encode_video_worker(video_key, episode_index, self.root, self.fps)
def _encode_multiple_temporary_episode_videos(self, video_keys, episode_index):
temp_paths = []
img_dirs = []
for video_key in video_keys:
temp_paths.append(Path(tempfile.mkdtemp(dir=self.root)) / f"{video_key}_{episode_index:03d}.mp4")
img_dirs.append(self._get_image_file_dir(episode_index, video_key))
fps = [self.fps]*len(video_keys)
with ProcessPoolExecutor(max_workers=len(video_keys)) as executor:
executor.map(encode_video_frames,img_dirs,temp_paths,fps)
for img_dir in img_dirs:
shutil.rmtree(img_dir)
return temp_paths
temp_path = Path(tempfile.mkdtemp(dir=self.root)) / f"{video_key}_{episode_index:03d}.mp4"
img_dir = self._get_image_file_dir(episode_index, video_key)
encode_video_frames(img_dir, temp_path, self.fps, overwrite=True)
shutil.rmtree(img_dir)
return temp_path
@classmethod
def create(
src/lerobot/datasets/utils.py
+1 -1
View File
@@ -49,7 +49,7 @@ from lerobot.utils.utils import SuppressProgressBars, is_valid_numpy_dtype_strin
DEFAULT_CHUNK_SIZE = 1000 # Max number of files per chunk
DEFAULT_DATA_FILE_SIZE_IN_MB = 100 # Max size per file
DEFAULT_VIDEO_FILE_SIZE_IN_MB = 200 # Max size per file
DEFAULT_VIDEO_FILE_SIZE_IN_MB = 500 # Max size per file
INFO_PATH = "meta/info.json"
STATS_PATH = "meta/stats.json"
src/lerobot/datasets/video_utils.py
+1 -8
View File
@@ -310,8 +310,7 @@ def encode_video_frames(
crf: int | None = 30,
fast_decode: int = 0,
log_level: int | None = av.logging.ERROR,
overwrite: bool = True,
preset: int | None = None,
overwrite: bool = False,
) -> None:
"""More info on ffmpeg arguments tuning on `benchmark/video/README.md`"""
# Check encoder availability
@@ -355,17 +354,11 @@ def encode_video_frames(
if crf is not None:
video_options["crf"] = str(crf)
#TEMPORARY FIX
video_options["preset"] = "12"
if fast_decode:
key = "svtav1-params" if vcodec == "libsvtav1" else "tune"
value = f"fast-decode={fast_decode}" if vcodec == "libsvtav1" else "fastdecode"
video_options[key] = value
if vcodec == "libsvtav1":
video_options["preset"] = str(preset) if preset is not None else "12"
# Set logging level
if log_level is not None:
# "While less efficient, it is generally preferable to modify logging with Python's logging"
src/lerobot/envs/configs.py
+1 -2
View File
@@ -245,7 +245,7 @@ class HILSerlRobotEnvConfig(EnvConfig):
class LiberoEnv(EnvConfig):
task: str = "libero_10" # can also choose libero_spatial, libero_object, etc.
fps: int = 30
episode_length: int | None = None
episode_length: int = 520
obs_type: str = "pixels_agent_pos"
render_mode: str = "rgb_array"
camera_name: str = "agentview_image,robot0_eye_in_hand_image"
@@ -272,7 +272,6 @@ class LiberoEnv(EnvConfig):
LIBERO_KEY_PIXELS_EYE_IN_HAND: f"{OBS_IMAGES}.image2",
}
)
control_mode: str = "relative" # or "absolute"
def __post_init__(self):
if self.obs_type == "pixels":
src/lerobot/envs/factory.py
-10
View File
@@ -19,10 +19,8 @@ from typing import Any
import gymnasium as gym
from gymnasium.envs.registration import registry as gym_registry
from lerobot.configs.policies import PreTrainedConfig
from lerobot.envs.configs import AlohaEnv, EnvConfig, LiberoEnv, PushtEnv
from lerobot.envs.utils import _call_make_env, _download_hub_file, _import_hub_module, _normalize_hub_result
from lerobot.policies.xvla.configuration_xvla import XVLAConfig
from lerobot.processor import ProcessorStep
from lerobot.processor.env_processor import LiberoProcessorStep
from lerobot.processor.pipeline import PolicyProcessorPipeline
@@ -41,7 +39,6 @@ def make_env_config(env_type: str, **kwargs) -> EnvConfig:
def make_env_pre_post_processors(
env_cfg: EnvConfig,
policy_cfg: PreTrainedConfig,
) -> tuple[
PolicyProcessorPipeline[dict[str, Any], dict[str, Any]],
PolicyProcessorPipeline[dict[str, Any], dict[str, Any]],
@@ -64,10 +61,6 @@ def make_env_pre_post_processors(
# Preprocessor and Postprocessor steps are Identity for most environments
preprocessor_steps: list[ProcessorStep] = []
postprocessor_steps: list[ProcessorStep] = []
if isinstance(policy_cfg, XVLAConfig):
from lerobot.policies.xvla.processor_xvla import make_xvla_libero_pre_post_processors
return make_xvla_libero_pre_post_processors()
# For LIBERO environments, add the LiberoProcessorStep to preprocessor
if isinstance(env_cfg, LiberoEnv) or "libero" in env_cfg.type:
@@ -118,7 +111,6 @@ def make_env(
# import and surface clear import errors
module = _import_hub_module(local_file, repo_id)
# call the hub-provided make_env
raw_result = _call_make_env(module, n_envs=n_envs, use_async_envs=use_async_envs)
@@ -143,8 +135,6 @@ def make_env(
init_states=cfg.init_states,
gym_kwargs=cfg.gym_kwargs,
env_cls=env_cls,
control_mode=cfg.control_mode,
episode_length=cfg.episode_length,
)
elif "metaworld" in cfg.type:
from lerobot.envs.metaworld import create_metaworld_envs
src/lerobot/envs/libero.py
+5 -26
View File
@@ -80,7 +80,10 @@ def get_libero_dummy_action():
return [0, 0, 0, 0, 0, 0, -1]
OBS_STATE_DIM = 8
ACTION_DIM = 7
AGENT_POS_LOW = -1000.0
AGENT_POS_HIGH = 1000.0
ACTION_LOW = -1.0
ACTION_HIGH = 1.0
TASK_SUITE_MAX_STEPS: dict[str, int] = {
@@ -100,7 +103,6 @@ class LiberoEnv(gym.Env):
task_suite: Any,
task_id: int,
task_suite_name: str,
episode_length: int | None = None,
camera_name: str | Sequence[str] = "agentview_image,robot0_eye_in_hand_image",
obs_type: str = "pixels",
render_mode: str = "rgb_array",
@@ -112,7 +114,6 @@ class LiberoEnv(gym.Env):
episode_index: int = 0,
camera_name_mapping: dict[str, str] | None = None,
num_steps_wait: int = 10,
control_mode: str = "relative",
):
super().__init__()
self.task_id = task_id
@@ -140,19 +141,14 @@ class LiberoEnv(gym.Env):
self.camera_name_mapping = camera_name_mapping
self.num_steps_wait = num_steps_wait
self.episode_index = episode_index
self.episode_length = episode_length
# Load once and keep
self._init_states = get_task_init_states(task_suite, self.task_id) if self.init_states else None
self._init_state_id = self.episode_index # tie each sub-env to a fixed init state
self._env = self._make_envs_task(task_suite, self.task_id)
default_steps = 500
self._max_episode_steps = (
TASK_SUITE_MAX_STEPS.get(task_suite_name, default_steps)
if self.episode_length is None
else self.episode_length
)
self.control_mode = control_mode
self._max_episode_steps = TASK_SUITE_MAX_STEPS.get(task_suite_name, default_steps)
images = {}
for cam in self.camera_name:
images[self.camera_name_mapping[cam]] = spaces.Box(
@@ -300,15 +296,6 @@ class LiberoEnv(gym.Env):
# Increasing this value can improve determinism and reproducibility across resets.
for _ in range(self.num_steps_wait):
raw_obs, _, _, _ = self._env.step(get_libero_dummy_action())
if self.control_mode == "absolute":
for robot in self._env.robots:
robot.controller.use_delta = False
elif self.control_mode == "relative":
for robot in self._env.robots:
robot.controller.use_delta = True
else:
raise ValueError(f"Invalid control mode: {self.control_mode}")
observation = self._format_raw_obs(raw_obs)
info = {"is_success": False}
return observation, info
@@ -354,10 +341,8 @@ def _make_env_fns(
task_id: int,
n_envs: int,
camera_names: list[str],
episode_length: int | None,
init_states: bool,
gym_kwargs: Mapping[str, Any],
control_mode: str,
) -> list[Callable[[], LiberoEnv]]:
"""Build n_envs factory callables for a single (suite, task_id)."""
@@ -369,9 +354,7 @@ def _make_env_fns(
task_suite_name=suite_name,
camera_name=camera_names,
init_states=init_states,
episode_length=episode_length,
episode_index=episode_index,
control_mode=control_mode,
**local_kwargs,
)
@@ -391,8 +374,6 @@ def create_libero_envs(
camera_name: str | Sequence[str] = "agentview_image,robot0_eye_in_hand_image",
init_states: bool = True,
env_cls: Callable[[Sequence[Callable[[], Any]]], Any] | None = None,
control_mode: str = "relative",
episode_length: int | None = None,
) -> dict[str, dict[int, Any]]:
"""
Create vectorized LIBERO environments with a consistent return shape.
@@ -434,14 +415,12 @@ def create_libero_envs(
for tid in selected:
fns = _make_env_fns(
suite=suite,
episode_length=episode_length,
suite_name=suite_name,
task_id=tid,
n_envs=n_envs,
camera_names=camera_names,
init_states=init_states,
gym_kwargs=gym_kwargs,
control_mode=control_mode,
)
out[suite_name][tid] = env_cls(fns)
print(f"Built vec env | suite={suite_name} | task_id={tid} | n_envs={n_envs}")
src/lerobot/envs/utils.py
+16 -1
View File
@@ -221,7 +221,22 @@ def _load_module_from_path(path: str, module_name: str | None = None):
if spec is None:
raise ImportError(f"Could not load module spec for {module_name} from {path}")
module = importlib.util.module_from_spec(spec)
spec.loader.exec_module(module) # type: ignore
# Add the module's directory to sys.path so it can import local modules
import sys
module_dir = os.path.dirname(os.path.abspath(path))
sys_path_modified = False
if module_dir not in sys.path:
sys.path.insert(0, module_dir)
sys_path_modified = True
try:
spec.loader.exec_module(module) # type: ignore
finally:
# Clean up sys.path after import
if sys_path_modified:
sys.path.remove(module_dir)
return module
src/lerobot/motors/__init__.py
+1 -8
View File
@@ -14,11 +14,4 @@
# See the License for the specific language governing permissions and
# limitations under the License.
from .motors_bus import (
Motor,
MotorCalibration,
MotorNormMode,
MotorsBus, # Backward compatibility (alias for SerialMotorsBus)
MotorsBusBase,
SerialMotorsBus,
)
from .motors_bus import Motor, MotorCalibration, MotorNormMode, MotorsBus
src/lerobot/motors/damiao/damiao.py
-905
View File
@@ -1,905 +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.
# TODO(pepijn): add license of: https://github.com/cmjang/DM_Control_Python?tab=MIT-1-ov-file#readme
import logging
import time
from contextlib import contextmanager
from copy import deepcopy
from functools import cached_property
from typing import Dict, List, Optional, Tuple, Union
import can
import numpy as np
from lerobot.motors import Motor, MotorCalibration, MotorNormMode, MotorsBusBase
from lerobot.utils.errors import DeviceAlreadyConnectedError, DeviceNotConnectedError
from lerobot.utils.utils import enter_pressed, move_cursor_up
from .tables import (
AVAILABLE_BAUDRATES,
CAN_CMD_DISABLE,
CAN_CMD_ENABLE,
CAN_CMD_REFRESH,
CAN_CMD_SET_ZERO,
CAN_PARAM_ID,
DEFAULT_BAUDRATE,
DEFAULT_TIMEOUT_MS,
MODEL_RESOLUTION,
MOTOR_LIMIT_PARAMS,
NORMALIZED_DATA,
MotorType,
)
logger = logging.getLogger(__name__)
NameOrID = Union[str, int]
Value = Union[int, float]
class DamiaoMotorsBus(MotorsBusBase):
"""
The Damiao implementation for a MotorsBus using CAN bus communication.
This class uses python-can for CAN bus communication with Damiao motors.
For more info, see:
- python-can documentation: https://python-can.readthedocs.io/en/stable/
- Seedstudio documentation: https://wiki.seeedstudio.com/damiao_series/
- DM_Control_Python repo: https://github.com/cmjang/DM_Control_Python
"""
# CAN-specific settings
available_baudrates = deepcopy(AVAILABLE_BAUDRATES)
default_baudrate = DEFAULT_BAUDRATE
default_timeout = DEFAULT_TIMEOUT_MS
# Motor configuration
model_resolution_table = deepcopy(MODEL_RESOLUTION)
normalized_data = deepcopy(NORMALIZED_DATA)
def __init__(
self,
port: str,
motors: dict[str, Motor],
calibration: dict[str, MotorCalibration] | None = None,
can_interface: str = "auto",
use_can_fd: bool = True,
bitrate: int = 1000000,
data_bitrate: int | None = 5000000,
):
"""
Initialize the Damiao motors bus.
Args:
port: CAN interface name (e.g., "can0" for Linux, "/dev/cu.usbmodem*" for macOS)
motors: Dictionary mapping motor names to Motor objects
calibration: Optional calibration data
can_interface: CAN interface type - "auto" (default), "socketcan" (Linux), or "slcan" (macOS/serial)
use_can_fd: Whether to use CAN FD mode (default: True for OpenArms)
bitrate: Nominal bitrate in bps (default: 1000000 = 1 Mbps)
data_bitrate: Data bitrate for CAN FD in bps (default: 5000000 = 5 Mbps), ignored if use_can_fd is False
"""
super().__init__(port, motors, calibration)
self.port = port
self.can_interface = can_interface
self.use_can_fd = use_can_fd
self.bitrate = bitrate
self.data_bitrate = data_bitrate
self.canbus = None
self._is_connected = False
# Map motor names to CAN IDs
self._motor_can_ids = {}
self._recv_id_to_motor = {}
# Store motor types and recv IDs
self._motor_types = {}
for name, motor in self.motors.items():
if hasattr(motor, "motor_type"):
self._motor_types[name] = motor.motor_type
else:
# Default to DM4310 if not specified
self._motor_types[name] = MotorType.DM4310
# Map recv_id to motor name for filtering responses
if hasattr(motor, "recv_id"):
self._recv_id_to_motor[motor.recv_id] = name
@property
def is_connected(self) -> bool:
"""Check if the CAN bus is connected."""
return self._is_connected and self.canbus is not None
def connect(self, handshake: bool = True) -> None:
"""
Open the CAN bus and initialize communication.
Args:
handshake: If True, ping all motors to verify they're present
"""
if self.is_connected:
raise DeviceAlreadyConnectedError(
f"{self.__class__.__name__}('{self.port}') is already connected."
)
try:
# Auto-detect interface type based on port name
if self.can_interface == "auto":
if self.port.startswith("/dev/"):
# Serial device (macOS/Windows)
self.can_interface = "slcan"
logger.info(f"Auto-detected slcan interface for port {self.port}")
else:
# Network interface (Linux)
self.can_interface = "socketcan"
logger.info(f"Auto-detected socketcan interface for port {self.port}")
# Connect to CAN bus
if self.can_interface == "socketcan":
# Linux SocketCAN with CAN FD support
if self.use_can_fd and self.data_bitrate is not None:
self.canbus = can.interface.Bus(
channel=self.port,
interface="socketcan",
bitrate=self.bitrate,
data_bitrate=self.data_bitrate,
fd=True
)
logger.info(f"Connected to {self.port} with CAN FD (bitrate={self.bitrate}, data_bitrate={self.data_bitrate})")
else:
self.canbus = can.interface.Bus(
channel=self.port,
interface="socketcan",
bitrate=self.bitrate
)
logger.info(f"Connected to {self.port} with CAN 2.0 (bitrate={self.bitrate})")
elif self.can_interface == "slcan":
# Serial Line CAN (macOS, Windows, or USB adapters)
# Note: SLCAN typically doesn't support CAN FD
self.canbus = can.interface.Bus(
channel=self.port,
interface="slcan",
bitrate=self.bitrate
)
logger.info(f"Connected to {self.port} with SLCAN (bitrate={self.bitrate})")
else:
# Generic interface (vector, pcan, etc.)
if self.use_can_fd and self.data_bitrate is not None:
self.canbus = can.interface.Bus(
channel=self.port,
interface=self.can_interface,
bitrate=self.bitrate,
data_bitrate=self.data_bitrate,
fd=True
)
else:
self.canbus = can.interface.Bus(
channel=self.port,
interface=self.can_interface,
bitrate=self.bitrate
)
self._is_connected = True
if handshake:
self._handshake()
logger.debug(f"{self.__class__.__name__} connected via {self.can_interface}.")
except Exception as e:
self._is_connected = False
raise ConnectionError(f"Failed to connect to CAN bus: {e}")
def _handshake(self) -> None:
"""Verify all motors are present by refreshing their status."""
for motor_name in self.motors:
self._refresh_motor(motor_name)
time.sleep(0.01) # Small delay between motors
def disconnect(self, disable_torque: bool = True) -> None:
"""
Close the CAN bus connection.
Args:
disable_torque: If True, disable torque on all motors before disconnecting
"""
if not self.is_connected:
raise DeviceNotConnectedError(
f"{self.__class__.__name__}('{self.port}') is not connected."
)
if disable_torque:
try:
self.disable_torque()
except Exception as e:
logger.warning(f"Failed to disable torque during disconnect: {e}")
if self.canbus:
self.canbus.shutdown()
self.canbus = None
self._is_connected = False
logger.debug(f"{self.__class__.__name__} disconnected.")
def configure_motors(self) -> None:
"""Configure all motors with default settings."""
# Damiao motors don't require much configuration in MIT mode
# Just ensure they're enabled
for motor in self.motors:
self._enable_motor(motor)
time.sleep(0.01)
def _enable_motor(self, motor: NameOrID) -> None:
"""Enable a single motor."""
motor_id = self._get_motor_id(motor)
recv_id = self._get_motor_recv_id(motor)
data = [0xFF] * 7 + [CAN_CMD_ENABLE]
msg = can.Message(arbitration_id=motor_id, data=data, is_extended_id=False)
self.canbus.send(msg)
self._recv_motor_response(expected_recv_id=recv_id)
def _disable_motor(self, motor: NameOrID) -> None:
"""Disable a single motor."""
motor_id = self._get_motor_id(motor)
recv_id = self._get_motor_recv_id(motor)
data = [0xFF] * 7 + [CAN_CMD_DISABLE]
msg = can.Message(arbitration_id=motor_id, data=data, is_extended_id=False)
self.canbus.send(msg)
self._recv_motor_response(expected_recv_id=recv_id)
def enable_torque(self, motors: str | list[str] | None = None, num_retry: int = 0) -> None:
"""Enable torque on selected motors."""
motors = self._get_motors_list(motors)
for motor in motors:
for _ in range(num_retry + 1):
try:
self._enable_motor(motor)
break
except Exception as e:
if _ == num_retry:
raise e
time.sleep(0.01)
def disable_torque(self, motors: str | list[str] | None = None, num_retry: int = 0) -> None:
"""Disable torque on selected motors."""
motors = self._get_motors_list(motors)
for motor in motors:
for _ in range(num_retry + 1):
try:
self._disable_motor(motor)
break
except Exception as e:
if _ == num_retry:
raise e
time.sleep(0.01)
@contextmanager
def torque_disabled(self, motors: str | list[str] | None = None):
"""
Context manager that guarantees torque is re-enabled.
This helper is useful to temporarily disable torque when configuring motors.
Examples:
>>> with bus.torque_disabled():
... # Safe operations here with torque disabled
... pass
"""
self.disable_torque(motors)
try:
yield
finally:
self.enable_torque(motors)
def set_zero_position(self, motors: str | list[str] | None = None) -> None:
"""Set current position as zero for selected motors."""
motors = self._get_motors_list(motors)
for motor in motors:
motor_id = self._get_motor_id(motor)
recv_id = self._get_motor_recv_id(motor)
data = [0xFF] * 7 + [CAN_CMD_SET_ZERO]
msg = can.Message(arbitration_id=motor_id, data=data, is_extended_id=False)
self.canbus.send(msg)
self._recv_motor_response(expected_recv_id=recv_id)
time.sleep(0.01)
def _refresh_motor(self, motor: NameOrID) -> Optional[can.Message]:
"""Refresh motor status and return the response."""
motor_id = self._get_motor_id(motor)
recv_id = self._get_motor_recv_id(motor)
data = [motor_id & 0xFF, (motor_id >> 8) & 0xFF, CAN_CMD_REFRESH, 0, 0, 0, 0, 0]
msg = can.Message(arbitration_id=CAN_PARAM_ID, data=data, is_extended_id=False)
self.canbus.send(msg)
return self._recv_motor_response(expected_recv_id=recv_id)
def _recv_motor_response(self, expected_recv_id: Optional[int] = None, timeout: float = 0.001) -> Optional[can.Message]:
"""
Receive a response from a motor.
Args:
expected_recv_id: If provided, only return messages from this CAN ID
timeout: Timeout in seconds (default: 1ms for high-speed operation)
Returns:
CAN message if received, None otherwise
"""
try:
start_time = time.time()
messages_seen = []
while time.time() - start_time < timeout:
msg = self.canbus.recv(timeout=0.0001) # 100us timeout for fast polling
if msg:
messages_seen.append(f"0x{msg.arbitration_id:02X}")
# If no filter specified, return any message
if expected_recv_id is None:
return msg
# Otherwise, only return if it matches the expected recv_id
if msg.arbitration_id == expected_recv_id:
return msg
else:
logger.debug(f"Ignoring message from CAN ID 0x{msg.arbitration_id:02X}, expected 0x{expected_recv_id:02X}")
# Only log warnings if we're in debug mode to reduce overhead
if logger.isEnabledFor(logging.DEBUG):
if messages_seen:
logger.debug(f"Received {len(messages_seen)} message(s) from IDs {set(messages_seen)}, but expected 0x{expected_recv_id:02X}")
else:
logger.debug(f"No CAN messages received (expected from 0x{expected_recv_id:02X})")
except Exception as e:
logger.debug(f"Failed to receive CAN message: {e}")
return None
def _recv_all_responses(self, expected_recv_ids: list[int], timeout: float = 0.002) -> dict[int, can.Message]:
"""
Efficiently receive responses from multiple motors at once.
Uses the OpenArms pattern: collect all available messages within timeout.
Args:
expected_recv_ids: List of CAN IDs we expect responses from
timeout: Total timeout in seconds (default: 2ms)
Returns:
Dictionary mapping recv_id to CAN message
"""
responses = {}
expected_set = set(expected_recv_ids)
start_time = time.time()
try:
while len(responses) < len(expected_recv_ids) and (time.time() - start_time) < timeout:
msg = self.canbus.recv(timeout=0.0002) # 200us poll timeout (increased from 100us for better reliability)
if msg and msg.arbitration_id in expected_set:
responses[msg.arbitration_id] = msg
if len(responses) == len(expected_recv_ids):
break # Got all responses, exit early
except Exception as e:
logger.debug(f"Error receiving responses: {e}")
return responses
def _mit_control(
self,
motor: NameOrID,
kp: float,
kd: float,
position_degrees: float,
velocity_deg_per_sec: float,
torque: float,
) -> None:
"""
Send MIT control command to a motor.
Args:
motor: Motor name or ID
kp: Position gain
kd: Velocity gain
position_degrees: Target position (degrees)
velocity_deg_per_sec: Target velocity (degrees/s)
torque: Target torque (N·m)
"""
motor_id = self._get_motor_id(motor)
motor_name = self._get_motor_name(motor)
motor_type = self._motor_types.get(motor_name, MotorType.DM4310)
# Convert degrees to radians for motor control
position_rad = np.radians(position_degrees)
velocity_rad_per_sec = np.radians(velocity_deg_per_sec)
# Get motor limits
pmax, vmax, tmax = MOTOR_LIMIT_PARAMS[motor_type]
# Encode parameters
kp_uint = self._float_to_uint(kp, 0, 500, 12)
kd_uint = self._float_to_uint(kd, 0, 5, 12)
q_uint = self._float_to_uint(position_rad, -pmax, pmax, 16)
dq_uint = self._float_to_uint(velocity_rad_per_sec, -vmax, vmax, 12)
tau_uint = self._float_to_uint(torque, -tmax, tmax, 12)
# Pack data
data = [0] * 8
data[0] = (q_uint >> 8) & 0xFF
data[1] = q_uint & 0xFF
data[2] = dq_uint >> 4
data[3] = ((dq_uint & 0xF) << 4) | ((kp_uint >> 8) & 0xF)
data[4] = kp_uint & 0xFF
data[5] = kd_uint >> 4
data[6] = ((kd_uint & 0xF) << 4) | ((tau_uint >> 8) & 0xF)
data[7] = tau_uint & 0xFF
msg = can.Message(arbitration_id=motor_id, data=data, is_extended_id=False)
self.canbus.send(msg)
recv_id = self._get_motor_recv_id(motor)
self._recv_motor_response(expected_recv_id=recv_id)
def _mit_control_batch(
self,
commands: Dict[NameOrID, Tuple[float, float, float, float, float]],
) -> None:
"""
Send MIT control commands to multiple motors in batch (optimized).
Sends all commands first, then collects responses. Much faster than sequential.
Args:
commands: Dict mapping motor name/ID to (kp, kd, position_deg, velocity_deg/s, torque)
Example: {'joint_1': (10.0, 0.5, 45.0, 0.0, 0.0), ...}
"""
if not commands:
return
expected_recv_ids = []
# Step 1: Send all MIT control commands (no waiting)
for motor, (kp, kd, position_degrees, velocity_deg_per_sec, torque) in commands.items():
motor_id = self._get_motor_id(motor)
motor_name = self._get_motor_name(motor)
motor_type = self._motor_types.get(motor_name, MotorType.DM4310)
# Convert degrees to radians
position_rad = np.radians(position_degrees)
velocity_rad_per_sec = np.radians(velocity_deg_per_sec)
# Get motor limits
pmax, vmax, tmax = MOTOR_LIMIT_PARAMS[motor_type]
# Encode parameters
kp_uint = self._float_to_uint(kp, 0, 500, 12)
kd_uint = self._float_to_uint(kd, 0, 5, 12)
q_uint = self._float_to_uint(position_rad, -pmax, pmax, 16)
dq_uint = self._float_to_uint(velocity_rad_per_sec, -vmax, vmax, 12)
tau_uint = self._float_to_uint(torque, -tmax, tmax, 12)
# Pack data
data = [0] * 8
data[0] = (q_uint >> 8) & 0xFF
data[1] = q_uint & 0xFF
data[2] = dq_uint >> 4
data[3] = ((dq_uint & 0xF) << 4) | ((kp_uint >> 8) & 0xF)
data[4] = kp_uint & 0xFF
data[5] = kd_uint >> 4
data[6] = ((kd_uint & 0xF) << 4) | ((tau_uint >> 8) & 0xF)
data[7] = tau_uint & 0xFF
# Send command
msg = can.Message(arbitration_id=motor_id, data=data, is_extended_id=False)
self.canbus.send(msg)
# Track expected response
recv_id = self._get_motor_recv_id(motor)
expected_recv_ids.append(recv_id)
# Step 2: Collect all responses at once
self._recv_all_responses(expected_recv_ids, timeout=0.002)
def _float_to_uint(self, x: float, x_min: float, x_max: float, bits: int) -> int:
"""Convert float to unsigned integer for CAN transmission."""
x = max(x_min, min(x_max, x)) # Clamp to range
span = x_max - x_min
data_norm = (x - x_min) / span
return int(data_norm * ((1 << bits) - 1))
def _uint_to_float(self, x: int, x_min: float, x_max: float, bits: int) -> float:
"""Convert unsigned integer from CAN to float."""
span = x_max - x_min
data_norm = float(x) / ((1 << bits) - 1)
return data_norm * span + x_min
def _decode_motor_state(self, data: bytes, motor_type: MotorType) -> Tuple[float, float, float, int, int]:
"""
Decode motor state from CAN data.
Returns:
Tuple of (position_degrees, velocity_deg_per_sec, torque, temp_mos, temp_rotor)
"""
if len(data) < 8:
raise ValueError("Invalid motor state data")
# Extract encoded values
q_uint = (data[1] << 8) | data[2]
dq_uint = (data[3] << 4) | (data[4] >> 4)
tau_uint = ((data[4] & 0x0F) << 8) | data[5]
t_mos = data[6]
t_rotor = data[7]
# Get motor limits
pmax, vmax, tmax = MOTOR_LIMIT_PARAMS[motor_type]
# Decode to physical values (radians)
position_rad = self._uint_to_float(q_uint, -pmax, pmax, 16)
velocity_rad_per_sec = self._uint_to_float(dq_uint, -vmax, vmax, 12)
torque = self._uint_to_float(tau_uint, -tmax, tmax, 12)
# Convert to degrees
position_degrees = np.degrees(position_rad)
velocity_deg_per_sec = np.degrees(velocity_rad_per_sec)
return position_degrees, velocity_deg_per_sec, torque, t_mos, t_rotor
def read(
self,
data_name: str,
motor: str,
*,
normalize: bool = True,
num_retry: int = 0,
) -> Value:
"""Read a value from a single motor. Positions are always in degrees."""
if not self.is_connected:
raise DeviceNotConnectedError(f"{self} is not connected.")
# Refresh motor to get latest state
msg = self._refresh_motor(motor)
if msg is None:
motor_id = self._get_motor_id(motor)
recv_id = self._get_motor_recv_id(motor)
raise ConnectionError(
f"No response from motor '{motor}' (send ID: 0x{motor_id:02X}, recv ID: 0x{recv_id:02X}). "
f"Check that: 1) Motor is powered (24V), 2) CAN wiring is correct, "
f"3) Motor IDs are configured correctly using Damiao Debugging Tools"
)
motor_type = self._motor_types.get(motor, MotorType.DM4310)
position_degrees, velocity_deg_per_sec, torque, t_mos, t_rotor = self._decode_motor_state(msg.data, motor_type)
# Return requested data (already in degrees for position/velocity)
if data_name == "Present_Position":
value = position_degrees
elif data_name == "Present_Velocity":
value = velocity_deg_per_sec
elif data_name == "Present_Torque":
value = torque
elif data_name == "Temperature_MOS":
value = t_mos
elif data_name == "Temperature_Rotor":
value = t_rotor
else:
raise ValueError(f"Unknown data_name: {data_name}")
# For Damiao, positions are always in degrees, no normalization needed
# We keep the normalize parameter for compatibility but don't use it
return value
def write(
self,
data_name: str,
motor: str,
value: Value,
*,
normalize: bool = True,
num_retry: int = 0,
) -> None:
"""Write a value to a single motor. Positions are always in degrees."""
if not self.is_connected:
raise DeviceNotConnectedError(f"{self} is not connected.")
# Value is expected to be in degrees for positions
if data_name == "Goal_Position":
# Use MIT control with position in degrees
self._mit_control(motor, 10.0, 0.5, value, 0, 0)
else:
raise ValueError(f"Writing {data_name} not supported in MIT mode")
def sync_read(
self,
data_name: str,
motors: str | list[str] | None = None,
*,
normalize: bool = True,
num_retry: int = 0,
) -> Dict[str, Value]:
"""
Read the same value from multiple motors simultaneously.
Uses batched operations: sends all refresh commands, then collects all responses.
This is MUCH faster than sequential reads (OpenArms pattern).
"""
motors = self._get_motors_list(motors)
result = {}
# Step 1: Send refresh commands to ALL motors first (no waiting)
for motor in motors:
motor_id = self._get_motor_id(motor)
data = [motor_id & 0xFF, (motor_id >> 8) & 0xFF, CAN_CMD_REFRESH, 0, 0, 0, 0, 0]
msg = can.Message(arbitration_id=CAN_PARAM_ID, data=data, is_extended_id=False)
self.canbus.send(msg)
# Step 2: Collect all responses at once (batch receive)
expected_recv_ids = [self._get_motor_recv_id(motor) for motor in motors]
responses = self._recv_all_responses(expected_recv_ids, timeout=0.01) # 10ms total timeout
# Step 3: Parse responses
for motor in motors:
try:
recv_id = self._get_motor_recv_id(motor)
msg = responses.get(recv_id)
if msg is None:
logger.warning(f"No response from motor '{motor}' (recv ID: 0x{recv_id:02X})")
result[motor] = 0.0
continue
motor_type = self._motor_types.get(motor, MotorType.DM4310)
position_degrees, velocity_deg_per_sec, torque, t_mos, t_rotor = self._decode_motor_state(msg.data, motor_type)
# Return requested data
if data_name == "Present_Position":
value = position_degrees
elif data_name == "Present_Velocity":
value = velocity_deg_per_sec
elif data_name == "Present_Torque":
value = torque
elif data_name == "Temperature_MOS":
value = t_mos
elif data_name == "Temperature_Rotor":
value = t_rotor
else:
raise ValueError(f"Unknown data_name: {data_name}")
result[motor] = value
except Exception as e:
logger.warning(f"Failed to read {data_name} from {motor}: {e}")
result[motor] = 0.0
return result
def sync_read_all_states(
self,
motors: str | list[str] | None = None,
*,
num_retry: int = 0,
) -> Dict[str, Dict[str, Value]]:
"""
Read ALL motor states (position, velocity, torque) from multiple motors in ONE refresh cycle.
This is 3x faster than calling sync_read() three times separately.
Returns:
Dictionary mapping motor names to state dicts with keys: 'position', 'velocity', 'torque'
Example: {'joint_1': {'position': 45.2, 'velocity': 1.3, 'torque': 0.5}, ...}
"""
motors = self._get_motors_list(motors)
result = {}
# Step 1: Send refresh commands to ALL motors first (with small delays to reduce bus congestion)
for motor in motors:
motor_id = self._get_motor_id(motor)
data = [motor_id & 0xFF, (motor_id >> 8) & 0xFF, CAN_CMD_REFRESH, 0, 0, 0, 0, 0]
msg = can.Message(arbitration_id=CAN_PARAM_ID, data=data, is_extended_id=False)
self.canbus.send(msg)
time.sleep(0.0001) # 100us delay between commands to reduce bus congestion
# Step 2: Collect all responses at once (batch receive)
expected_recv_ids = [self._get_motor_recv_id(motor) for motor in motors]
responses = self._recv_all_responses(expected_recv_ids, timeout=0.015) # 15ms timeout (increased for reliability)
# Step 3: Parse responses and extract ALL state values
for motor in motors:
try:
recv_id = self._get_motor_recv_id(motor)
msg = responses.get(recv_id)
if msg is None:
logger.warning(f"No response from motor '{motor}' (recv ID: 0x{recv_id:02X})")
result[motor] = {"position": 0.0, "velocity": 0.0, "torque": 0.0}
continue
motor_type = self._motor_types.get(motor, MotorType.DM4310)
position_degrees, velocity_deg_per_sec, torque, t_mos, t_rotor = self._decode_motor_state(msg.data, motor_type)
# Return all state values in one dict
result[motor] = {
"position": position_degrees,
"velocity": velocity_deg_per_sec,
"torque": torque,
"temp_mos": t_mos,
"temp_rotor": t_rotor,
}
except Exception as e:
logger.warning(f"Failed to read state from {motor}: {e}")
result[motor] = {"position": 0.0, "velocity": 0.0, "torque": 0.0}
return result
def sync_write(
self,
data_name: str,
values: Dict[str, Value],
*,
normalize: bool = True,
num_retry: int = 0,
) -> None:
"""
Write different values to multiple motors simultaneously. Positions are always in degrees.
Uses batched operations: sends all commands first, then collects responses (OpenArms pattern).
"""
if data_name == "Goal_Position":
# Step 1: Send all MIT control commands first (no waiting)
for motor, value_degrees in values.items():
motor_id = self._get_motor_id(motor)
motor_name = self._get_motor_name(motor)
motor_type = self._motor_types.get(motor_name, MotorType.DM4310)
# Convert degrees to radians
position_rad = np.radians(value_degrees)
# Default gains for position control
kp, kd = 10.0, 0.5
# Get motor limits and encode parameters
pmax, vmax, tmax = MOTOR_LIMIT_PARAMS[motor_type]
kp_uint = self._float_to_uint(kp, 0, 500, 12)
kd_uint = self._float_to_uint(kd, 0, 5, 12)
q_uint = self._float_to_uint(position_rad, -pmax, pmax, 16)
dq_uint = self._float_to_uint(0, -vmax, vmax, 12)
tau_uint = self._float_to_uint(0, -tmax, tmax, 12)
# Pack data
data = [0] * 8
data[0] = (q_uint >> 8) & 0xFF
data[1] = q_uint & 0xFF
data[2] = dq_uint >> 4
data[3] = ((dq_uint & 0xF) << 4) | ((kp_uint >> 8) & 0xF)
data[4] = kp_uint & 0xFF
data[5] = kd_uint >> 4
data[6] = ((kd_uint & 0xF) << 4) | ((tau_uint >> 8) & 0xF)
data[7] = tau_uint & 0xFF
msg = can.Message(arbitration_id=motor_id, data=data, is_extended_id=False)
self.canbus.send(msg)
time.sleep(0.0001) # 100us delay between commands to reduce bus congestion
# Step 2: Collect all responses at once
expected_recv_ids = [self._get_motor_recv_id(motor) for motor in values.keys()]
self._recv_all_responses(expected_recv_ids, timeout=0.015) # 15ms timeout (increased for reliability)
else:
# Fall back to individual writes for other data types
for motor, value in values.items():
self.write(data_name, motor, value, normalize=normalize, num_retry=num_retry)
def read_calibration(self) -> dict[str, MotorCalibration]:
"""Read calibration data from motors."""
# Damiao motors don't store calibration internally
# Return existing calibration or empty dict
return self.calibration if self.calibration else {}
def write_calibration(self, calibration_dict: dict[str, MotorCalibration], cache: bool = True) -> None:
"""Write calibration data to motors."""
# Damiao motors don't store calibration internally
# Just cache it in memory
if cache:
self.calibration = calibration_dict
def record_ranges_of_motion(
self, motors: NameOrID | list[NameOrID] | None = None, display_values: bool = True
) -> tuple[dict[NameOrID, Value], dict[NameOrID, Value]]:
"""
Interactively record the min/max values of each motor in degrees.
Move the joints by hand (with torque disabled) while the method streams live positions.
Press Enter to finish.
"""
if motors is None:
motors = list(self.motors.keys())
elif isinstance(motors, (str, int)):
motors = [motors]
# Disable torque for manual movement
self.disable_torque(motors)
time.sleep(0.1)
# Get initial positions (already in degrees)
start_positions = self.sync_read("Present_Position", motors, normalize=False)
mins = start_positions.copy()
maxes = start_positions.copy()
print("\nMove joints through their full range of motion. Press ENTER when done.")
user_pressed_enter = False
while not user_pressed_enter:
positions = self.sync_read("Present_Position", motors, normalize=False)
for motor in motors:
if motor in positions:
mins[motor] = min(positions[motor], mins.get(motor, positions[motor]))
maxes[motor] = max(positions[motor], maxes.get(motor, positions[motor]))
if display_values:
print("\n" + "=" * 50)
print(f"{'MOTOR':<20} | {'MIN (deg)':>12} | {'POS (deg)':>12} | {'MAX (deg)':>12}")
print("-" * 50)
for motor in motors:
if motor in positions:
print(f"{motor:<20} | {mins[motor]:>12.1f} | {positions[motor]:>12.1f} | {maxes[motor]:>12.1f}")
if enter_pressed():
user_pressed_enter = True
if display_values and not user_pressed_enter:
# Move cursor up to overwrite the previous output
move_cursor_up(len(motors) + 4)
time.sleep(0.05)
# Re-enable torque
self.enable_torque(motors)
# Validate ranges
for motor in motors:
if motor in mins and motor in maxes:
if abs(maxes[motor] - mins[motor]) < 5.0: # At least 5 degrees of range
raise ValueError(f"Motor {motor} has insufficient range of motion (< 5 degrees)")
return mins, maxes
def _get_motors_list(self, motors: str | list[str] | None) -> list[str]:
"""Convert motor specification to list of motor names."""
if motors is None:
return list(self.motors.keys())
elif isinstance(motors, str):
return [motors]
elif isinstance(motors, list):
return motors
else:
raise TypeError(f"Invalid motors type: {type(motors)}")
def _get_motor_id(self, motor: NameOrID) -> int:
"""Get CAN ID for a motor."""
if isinstance(motor, str):
if motor in self.motors:
return self.motors[motor].id
else:
raise ValueError(f"Unknown motor: {motor}")
else:
return motor
def _get_motor_name(self, motor: NameOrID) -> str:
"""Get motor name from name or ID."""
if isinstance(motor, str):
return motor
else:
for name, m in self.motors.items():
if m.id == motor:
return name
raise ValueError(f"Unknown motor ID: {motor}")
def _get_motor_recv_id(self, motor: NameOrID) -> Optional[int]:
"""Get motor recv_id from name or ID."""
motor_name = self._get_motor_name(motor)
motor_obj = self.motors.get(motor_name)
if motor_obj and hasattr(motor_obj, "recv_id"):
return motor_obj.recv_id
return None
@cached_property
def is_calibrated(self) -> bool:
"""Check if motors are calibrated."""
return bool(self.calibration)
src/lerobot/motors/damiao/tables.py
-209
View File
@@ -1,209 +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.
"""Configuration tables for Damiao motors."""
from enum import IntEnum
from typing import Dict, List, Tuple
# Motor type definitions
class MotorType(IntEnum):
DM3507 = 0
DM4310 = 1
DM4310_48V = 2
DM4340 = 3
DM4340_48V = 4
DM6006 = 5
DM8006 = 6
DM8009 = 7
DM10010L = 8
DM10010 = 9
DMH3510 = 10
DMH6215 = 11
DMG6220 = 12
# Control modes
class ControlMode(IntEnum):
MIT = 1
POS_VEL = 2
VEL = 3
TORQUE_POS = 4
# Motor variable IDs (RID)
class MotorVariable(IntEnum):
UV_VALUE = 0
KT_VALUE = 1
OT_VALUE = 2
OC_VALUE = 3
ACC = 4
DEC = 5
MAX_SPD = 6
MST_ID = 7
ESC_ID = 8
TIMEOUT = 9
CTRL_MODE = 10
DAMP = 11
INERTIA = 12
HW_VER = 13
SW_VER = 14
SN = 15
NPP = 16
RS = 17
LS = 18
FLUX = 19
GR = 20
PMAX = 21
VMAX = 22
TMAX = 23
I_BW = 24
KP_ASR = 25
KI_ASR = 26
KP_APR = 27
KI_APR = 28
OV_VALUE = 29
GREF = 30
DETA = 31
V_BW = 32
IQ_C1 = 33
VL_C1 = 34
CAN_BR = 35
SUB_VER = 36
U_OFF = 50
V_OFF = 51
K1 = 52
K2 = 53
M_OFF = 54
DIR = 55
P_M = 80
XOUT = 81
# Motor limit parameters [PMAX, VMAX, TMAX]
# PMAX: Maximum position (rad)
# VMAX: Maximum velocity (rad/s)
# TMAX: Maximum torque (N·m)
MOTOR_LIMIT_PARAMS = {
MotorType.DM3507: (12.5, 30, 10),
MotorType.DM4310: (12.5, 30, 10),
MotorType.DM4310_48V: (12.5, 50, 10),
MotorType.DM4340: (12.5, 8, 28),
MotorType.DM4340_48V: (12.5, 10, 28),
MotorType.DM6006: (12.5, 45, 20),
MotorType.DM8006: (12.5, 45, 40),
MotorType.DM8009: (12.5, 45, 54),
MotorType.DM10010L: (12.5, 25, 200),
MotorType.DM10010: (12.5, 20, 200),
MotorType.DMH3510: (12.5, 280, 1),
MotorType.DMH6215: (12.5, 45, 10),
MotorType.DMG6220: (12.5, 45, 10),
}
# Motor model names
MODEL_NAMES = {
MotorType.DM3507: "dm3507",
MotorType.DM4310: "dm4310",
MotorType.DM4310_48V: "dm4310_48v",
MotorType.DM4340: "dm4340",
MotorType.DM4340_48V: "dm4340_48v",
MotorType.DM6006: "dm6006",
MotorType.DM8006: "dm8006",
MotorType.DM8009: "dm8009",
MotorType.DM10010L: "dm10010l",
MotorType.DM10010: "dm10010",
MotorType.DMH3510: "dmh3510",
MotorType.DMH6215: "dmh6215",
MotorType.DMG6220: "dmg6220",
}
# Motor resolution table (encoder counts per revolution)
MODEL_RESOLUTION = {
"dm3507": 65536,
"dm4310": 65536,
"dm4310_48v": 65536,
"dm4340": 65536,
"dm4340_48v": 65536,
"dm6006": 65536,
"dm8006": 65536,
"dm8009": 65536,
"dm10010l": 65536,
"dm10010": 65536,
"dmh3510": 65536,
"dmh6215": 65536,
"dmg6220": 65536,
}
# CAN baudrates supported by Damiao motors
AVAILABLE_BAUDRATES = [
125000, # 0: 125 kbps
200000, # 1: 200 kbps
250000, # 2: 250 kbps
500000, # 3: 500 kbps
1000000, # 4: 1 mbps (default for OpenArms)
2000000, # 5: 2 mbps
2500000, # 6: 2.5 mbps
3200000, # 7: 3.2 mbps
4000000, # 8: 4 mbps
5000000, # 9: 5 mbps
]
DEFAULT_BAUDRATE = 1000000 # 1 Mbps is standard for OpenArms
# Default timeout in milliseconds
DEFAULT_TIMEOUT_MS = 1000
# Data that should be normalized
NORMALIZED_DATA = ["Present_Position", "Goal_Position"]
# OpenArms specific configurations
# Based on: https://docs.openarm.dev/software/setup/configure-test
# OpenArms has 7 DOF per arm (14 total for dual arm)
OPENARMS_ARM_MOTOR_IDS = {
"joint_1": {"send": 0x01, "recv": 0x11}, # J1 - Shoulder pan
"joint_2": {"send": 0x02, "recv": 0x12}, # J2 - Shoulder lift
"joint_3": {"send": 0x03, "recv": 0x13}, # J3 - Elbow flex
"joint_4": {"send": 0x04, "recv": 0x14}, # J4 - Wrist flex
"joint_5": {"send": 0x05, "recv": 0x15}, # J5 - Wrist roll
"joint_6": {"send": 0x06, "recv": 0x16}, # J6 - Wrist pitch
"joint_7": {"send": 0x07, "recv": 0x17}, # J7 - Wrist rotation
}
OPENARMS_GRIPPER_MOTOR_IDS = {
"gripper": {"send": 0x08, "recv": 0x18}, # J8 - Gripper
}
# Default motor types for OpenArms
OPENARMS_DEFAULT_MOTOR_TYPES = {
"joint_1": MotorType.DM8009, # Shoulder pan - high torque
"joint_2": MotorType.DM8009, # Shoulder lift - high torque
"joint_3": MotorType.DM4340, # Shoulder rotation
"joint_4": MotorType.DM4340, # Elbow flex
"joint_5": MotorType.DM4310, # Wrist roll
"joint_6": MotorType.DM4310, # Wrist pitch
"joint_7": MotorType.DM4310, # Wrist rotation
"gripper": MotorType.DM4310, # Gripper
}
# MIT control parameter ranges
MIT_KP_RANGE = (0.0, 500.0)
MIT_KD_RANGE = (0.0, 5.0)
# CAN frame command IDs
CAN_CMD_ENABLE = 0xFC
CAN_CMD_DISABLE = 0xFD
CAN_CMD_SET_ZERO = 0xFE
CAN_CMD_REFRESH = 0xCC
CAN_CMD_QUERY_PARAM = 0x33
CAN_CMD_WRITE_PARAM = 0x55
CAN_CMD_SAVE_PARAM = 0xAA
# CAN ID for parameter operations
CAN_PARAM_ID = 0x7FF
src/lerobot/motors/dynamixel/dynamixel.py
+2 -2
View File
@@ -24,7 +24,7 @@ from enum import Enum
from lerobot.motors.encoding_utils import decode_twos_complement, encode_twos_complement
from ..motors_bus import Motor, MotorCalibration, NameOrID, SerialMotorsBus, Value, get_address
from ..motors_bus import Motor, MotorCalibration, MotorsBus, NameOrID, Value, get_address
from .tables import (
AVAILABLE_BAUDRATES,
MODEL_BAUDRATE_TABLE,
@@ -100,7 +100,7 @@ def _split_into_byte_chunks(value: int, length: int) -> list[int]:
return data
class DynamixelMotorsBus(SerialMotorsBus):
class DynamixelMotorsBus(MotorsBus):
"""
The Dynamixel implementation for a MotorsBus. It relies on the python dynamixel sdk to communicate with
the motors. For more info, see the Dynamixel SDK Documentation:
src/lerobot/motors/feetech/feetech.py
+3 -3
View File
@@ -19,7 +19,7 @@ from pprint import pformat
from lerobot.motors.encoding_utils import decode_sign_magnitude, encode_sign_magnitude
from ..motors_bus import Motor, MotorCalibration, NameOrID, SerialMotorsBus, Value, get_address
from ..motors_bus import Motor, MotorCalibration, MotorsBus, NameOrID, Value, get_address
from .tables import (
FIRMWARE_MAJOR_VERSION,
FIRMWARE_MINOR_VERSION,
@@ -96,7 +96,7 @@ def patch_setPacketTimeout(self, packet_length): # noqa: N802
self.packet_timeout = (self.tx_time_per_byte * packet_length) + (self.tx_time_per_byte * 3.0) + 50
class FeetechMotorsBus(SerialMotorsBus):
class FeetechMotorsBus(MotorsBus):
"""
The FeetechMotorsBus class allows to efficiently read and write to the attached motors. It relies on the
python feetech sdk to communicate with the motors, which is itself based on the dynamixel sdk.
@@ -165,7 +165,7 @@ class FeetechMotorsBus(SerialMotorsBus):
def _handshake(self) -> None:
self._assert_motors_exist()
#self._assert_same_firmware()
self._assert_same_firmware()
def _find_single_motor(self, motor: str, initial_baudrate: int | None = None) -> tuple[int, int]:
if self.protocol_version == 0:
src/lerobot/motors/motors_bus.py
+4 -96
View File
@@ -19,8 +19,6 @@
# TODO(aliberts): Add block noqa when feature below is available
# https://github.com/astral-sh/ruff/issues/3711
from __future__ import annotations
import abc
import logging
from contextlib import contextmanager
@@ -43,92 +41,6 @@ Value: TypeAlias = int | float
logger = logging.getLogger(__name__)
class MotorsBusBase(abc.ABC):
"""
Base class for all motor bus implementations.
This is a minimal interface that all motor buses must implement, regardless of their
communication protocol (serial, CAN, etc.).
"""
def __init__(
self,
port: str,
motors: dict[str, Motor],
calibration: dict[str, MotorCalibration] | None = None,
):
self.port = port
self.motors = motors
self.calibration = calibration if calibration else {}
@abc.abstractmethod
def connect(self, handshake: bool = True) -> None:
"""Establish connection to the motors."""
pass
@abc.abstractmethod
def disconnect(self, disable_torque: bool = True) -> None:
"""Disconnect from the motors."""
pass
@property
@abc.abstractmethod
def is_connected(self) -> bool:
"""Check if connected to the motors."""
pass
@abc.abstractmethod
def read(self, data_name: str, motor: str, *, normalize: bool = True, num_retry: int = 0) -> Value:
"""Read a value from a single motor."""
pass
@abc.abstractmethod
def write(
self, data_name: str, motor: str, value: Value, *, normalize: bool = True, num_retry: int = 0
) -> None:
"""Write a value to a single motor."""
pass
@abc.abstractmethod
def sync_read(
self, data_name: str, motors: str | list[str] | None = None, *, normalize: bool = True
) -> dict[str, Value]:
"""Read a value from multiple motors."""
pass
@abc.abstractmethod
def sync_write(
self,
data_name: str,
values: Value | dict[str, Value],
motors: str | list[str] | None = None,
*,
normalize: bool = True,
) -> None:
"""Write values to multiple motors."""
pass
@abc.abstractmethod
def enable_torque(self, motors: str | list[str] | None = None, num_retry: int = 0) -> None:
"""Enable torque on selected motors."""
pass
@abc.abstractmethod
def disable_torque(self, motors: int | str | list[str] | None = None, num_retry: int = 0) -> None:
"""Disable torque on selected motors."""
pass
@abc.abstractmethod
def read_calibration(self) -> dict[str, MotorCalibration]:
"""Read calibration parameters from the motors."""
pass
@abc.abstractmethod
def write_calibration(self, calibration_dict: dict[str, MotorCalibration], cache: bool = True) -> None:
"""Write calibration parameters to the motors."""
pass
def get_ctrl_table(model_ctrl_table: dict[str, dict], model: str) -> dict[str, tuple[int, int]]:
ctrl_table = model_ctrl_table.get(model)
if ctrl_table is None:
@@ -291,15 +203,15 @@ class GroupSyncWrite(Protocol):
def txPacket(self): ...
class SerialMotorsBus(MotorsBusBase):
class MotorsBus(abc.ABC):
"""
A SerialMotorsBus allows to efficiently read and write to motors connected via serial communication.
A MotorsBus allows to efficiently read and write to the attached motors.
It represents several motors daisy-chained together and connected through a serial port.
There are currently two implementations of this class:
There are currently two implementations of this abstract class:
- DynamixelMotorsBus
- FeetechMotorsBus
This class is specifically for serial-based motor protocols (Dynamixel, Feetech, etc.).
Note: This class may evolve in the future should we add support for other types of bus.
A MotorsBus subclass instance requires a port (e.g. `FeetechMotorsBus(port="/dev/tty.usbmodem575E0031751"`)).
To find the port, you can run our utility script:
@@ -1300,7 +1212,3 @@ class SerialMotorsBus(MotorsBusBase):
for id_, value in ids_values.items():
data = self._serialize_data(value, length)
self.sync_writer.addParam(id_, data)
# Backward compatibility alias
MotorsBus = SerialMotorsBus

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