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admin/lerobot:main admin/lerobot:feat/smolvla-on-steerable admin/lerobot:docs/cheat-sheet admin/lerobot:feat/vla-jepa admin/lerobot:auto/update-uv-lock admin/lerobot:feat/codec-parameters admin/lerobot:feat/clean-can-bus admin/lerobot:feat/episodes-filtering admin/lerobot:pr/3545 admin/lerobot:feat/language-annotation-pipeline admin/lerobot:feat/language-columns admin/lerobot:fix/vlabench-ci-faster admin/lerobot:chore/colored-cli 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 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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
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admin/lerobot:feat/smolvla-on-steerable admin/lerobot:main admin/lerobot:docs/cheat-sheet admin/lerobot:feat/vla-jepa admin/lerobot:auto/update-uv-lock admin/lerobot:feat/codec-parameters admin/lerobot:feat/clean-can-bus admin/lerobot:feat/episodes-filtering admin/lerobot:pr/3545 admin/lerobot:feat/language-annotation-pipeline admin/lerobot:feat/language-columns admin/lerobot:fix/vlabench-ci-faster admin/lerobot:chore/colored-cli 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

1 Commits
feat/add_macos_ci .. mypy_support

Author SHA1 Message Date
AdilZouitine 8b4dcb1496 Enable mypy static type checking in pre-commit configuration and update mypy settings in pyproject.toml 2025-09-01 17:21:30 +02:00
364 changed files with 14894 additions and 44299 deletions
Expand all files Collapse all files
.github/ISSUE_TEMPLATE/bug-report.yml
+1 -1
View File
@@ -25,7 +25,7 @@ body:
id: system-info
attributes:
label: System Info
description: Please share your LeRobot configuration by running `lerobot-info` (if installed) or `python -m lerobot.scripts.display_sys_info` (if not installed) and pasting the output below.
description: If needed, you can share your lerobot configuration with us by running `python -m lerobot.scripts.display_sys_info` and copy-pasting its outputs below
render: Shell
placeholder: lerobot version, OS, python version, numpy version, torch version, and lerobot's configuration
validations:
.github/workflows/fast_tests.yml
+6 -19
View File
@@ -57,11 +57,7 @@ jobs:
# It runs everytime we commit to a PR or push to main
fast-pytest-tests:
name: Fast Pytest Tests
runs-on: ${{ matrix.os }}
strategy:
fail-fast: false
matrix:
os: [ubuntu-latest, macos-latest]
runs-on: ubuntu-latest
env:
MUJOCO_GL: egl
steps:
@@ -71,21 +67,12 @@ jobs:
lfs: true
# TODO(Steven): Evaluate the need of these dependencies
- name: Install dependencies
- name: Install apt dependencies
run: |
if [[ "${{ matrix.os }}" == 'ubuntu-latest' ]]; then
sudo apt-get update && sudo apt-get install -y build-essential \
git curl libglib2.0-0 libegl1-mesa-dev ffmpeg libusb-1.0-0-dev \
speech-dispatcher libgeos-dev portaudio19-dev
elif [[ "${{ matrix.os }}" == 'macos-latest' ]]; then
brew update && brew install git geos portaudio ffmpeg@7
# Add ffmpeg@7 paths for subsequent steps
echo "PATH=/opt/homebrew/opt/ffmpeg@7/bin:$PATH" >> $GITHUB_ENV
echo "LDFLAGS=-L/opt/homebrew/opt/ffmpeg@7/lib" >> $GITHUB_ENV
echo "CPPFLAGS=-I/opt/homebrew/opt/ffmpeg@7/include" >> $GITHUB_ENV
echo "PKG_CONFIG_PATH=/opt/homebrew/opt/ffmpeg@7/lib/pkgconfig" >> $GITHUB_ENV
echo "DYLD_LIBRARY_PATH=/opt/homebrew/opt/ffmpeg@7/lib:/opt/homebrew/lib:/usr/local/lib:$DYLD_LIBRARY_PATH" >> $GITHUB_ENV
fi
sudo apt-get update && sudo apt-get install -y build-essential git \
curl libglib2.0-0 libegl1-mesa-dev ffmpeg \
libusb-1.0-0-dev speech-dispatcher libgeos-dev portaudio19-dev
- name: Setup uv and Python
uses: astral-sh/setup-uv@v6 # zizmor: ignore[unpinned-uses]
with:
.github/workflows/full_tests.yml
+5 -14
View File
@@ -51,11 +51,7 @@ jobs:
# It runs everytime a PR is approved or a push to main
full-tests:
name: Full Tests
runs-on: ${{ matrix.os }}
strategy:
fail-fast: false
matrix:
os: [ubuntu-latest, macos-latest]
runs-on: ubuntu-latest
if: |
(github.event_name == 'pull_request_review' && github.event.review.state == 'approved') ||
github.event_name == 'push' ||
@@ -68,16 +64,11 @@ jobs:
lfs: true
persist-credentials: false
- name: Install dependencies
- name: Install apt dependencies
run: |
if [[ "${{ matrix.os }}" == 'ubuntu-latest' ]]; then
sudo apt-get update && sudo apt-get install -y build-essential \
git curl libglib2.0-0 libegl1-mesa-dev ffmpeg libusb-1.0-0-dev \
speech-dispatcher libgeos-dev portaudio19-dev
elif [[ "${{ matrix.os }}" == 'macos-latest' ]]; then
brew update && brew install git geos portaudio ffmpeg@7
echo "DYLD_LIBRARY_PATH=/opt/homebrew/opt/ffmpeg@7/lib:/opt/homebrew/lib:/usr/local/lib:$DYLD_LIBRARY_PATH" >> $GITHUB_ENV
fi
sudo apt-get update && sudo apt-get install -y build-essential \
git curl libglib2.0-0 libegl1-mesa-dev ffmpeg libusb-1.0-0-dev \
speech-dispatcher libgeos-dev portaudio19-dev
- name: Setup uv and Python
uses: astral-sh/setup-uv@v6 # zizmor: ignore[unpinned-uses]
.github/workflows/release.yml
+5 -14
View File
@@ -120,11 +120,7 @@ jobs:
test-release:
name: Test Release
needs: [build-and-publish]
runs-on: ${{ matrix.os }}
strategy:
fail-fast: false
matrix:
os: [ubuntu-latest, macos-latest]
runs-on: ubuntu-latest
permissions:
contents: read
env:
@@ -134,16 +130,11 @@ jobs:
with:
lfs: true
persist-credentials: false
- name: Install dependencies
- name: Install apt dependencies
run: |
if [[ "${{ matrix.os }}" == 'ubuntu-latest' ]]; then
sudo apt-get update && sudo apt-get install -y build-essential \
git curl libglib2.0-0 libegl1-mesa-dev ffmpeg libusb-1.0-0-dev \
speech-dispatcher libgeos-dev portaudio19-dev
elif [[ "${{ matrix.os }}" == 'macos-latest' ]]; then
brew update && brew install git geos portaudio ffmpeg@7
echo "DYLD_LIBRARY_PATH=/opt/homebrew/opt/ffmpeg@7/lib:/opt/homebrew/lib:/usr/local/lib:$DYLD_LIBRARY_PATH" >> $GITHUB_ENV
fi
sudo apt-get update && sudo apt-get install -y build-essential \
git curl libglib2.0-0 libegl1-mesa-dev ffmpeg libusb-1.0-0-dev \
speech-dispatcher libgeos-dev portaudio19-dev
- name: Setup uv and Python
uses: astral-sh/setup-uv@v6 # zizmor: ignore[unpinned-uses]
with:
.github/workflows/stale.yml
-68
View File
@@ -1,68 +0,0 @@
# Copyright 2025 The HuggingFace Inc. team. All rights reserved.
#
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
#
# http://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.
# This workflow handles closing stale issues and PRs.
name: Stale
on:
# Allows running this workflow manually from the Actions tab
workflow_dispatch:
# Runs at 02:00
schedule:
- cron: "0 2 * * *"
env:
CLOSE_ISSUE_MESSAGE: >
This issue was closed because it has been stalled for 14 days with no activity.
Feel free to reopen if is still relevant, or to ping a collaborator if you have any questions.
CLOSE_PR_MESSAGE: >
This PR was closed because it has been stalled for 14 days with no activity.
Feel free to reopen if is still relevant, or to ping a collaborator if you have any questions.
WARN_ISSUE_MESSAGE: >
This issue has been automatically marked as stale because it has not had
recent activity (6 months). It will be closed if no further activity occurs.
Thank you for your contributions.
WARN_PR_MESSAGE: >
This PR has been automatically marked as stale because it has not had
recent activity (6 months). It will be closed if no further activity occurs.
Thank you for your contributions.
jobs:
# This job runs the actions/stale action to close stale issues and PRs.
stale:
name: Close Stale Issues and PRs
runs-on: ubuntu-latest
permissions:
actions: write
contents: write # only for delete-branch option
issues: write
pull-requests: write
steps:
- uses: actions/stale@v10
with:
repo-token: ${{ secrets.GITHUB_TOKEN }}
stale-issue-label: stale
stale-pr-label: stale
exempt-issue-labels: never-stale
exempt-pr-labels: never-stale
days-before-issue-stale: 180 # TODO(Steven): Will modify this to 90 after initial cleanup
days-before-issue-close: 14
days-before-pr-stale: 180
days-before-pr-close: 14
delete-branch: true
close-issue-message: ${{ env.CLOSE_ISSUE_MESSAGE }}
close-pr-message: ${{ env.CLOSE_PR_MESSAGE }}
stale-issue-message: ${{ env.WARN_ISSUE_MESSAGE }}
stale-pr-message: ${{ env.WARN_PR_MESSAGE }}
operations-per-run: 500
.github/workflows/unbound_deps_tests.yml
-192
View File
@@ -1,192 +0,0 @@
# Copyright 2025 The HuggingFace Inc. team. All rights reserved.
#
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
#
# http://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.
# This workflow handles full testing with unboud dependencies versions.
name: Unbound Dependency Tests
on:
# Allows running this workflow manually from the Actions tab
workflow_dispatch:
# Run on the 1st and 15th of every month at 09:00 UTC
schedule:
- cron: '0 2 1,15 * *'
permissions:
contents: read
# Sets up the environment variables
env:
UV_VERSION: "0.8.0"
PYTHON_VERSION: "3.10"
DOCKER_IMAGE_NAME: huggingface/lerobot-gpu:unbound
# Ensures that only the latest action is built, canceling older runs.
concurrency:
group: ${{ github.workflow }}-${{ github.head_ref || github.run_id }}
cancel-in-progress: true
jobs:
# This job runs the E2E tests + pytest with all unbound extras
full-tests:
name: Full Unbound Tests
runs-on: ${{ matrix.os }}
strategy:
fail-fast: false
matrix:
os: [ubuntu-latest, macos-latest]
env:
MUJOCO_GL: egl
steps:
- uses: actions/checkout@v4
with:
lfs: true
persist-credentials: false
- name: Install dependencies
run: |
if [[ "${{ matrix.os }}" == 'ubuntu-latest' ]]; then
sudo apt-get update && sudo apt-get install -y build-essential \
git curl libglib2.0-0 libegl1-mesa-dev ffmpeg libusb-1.0-0-dev \
speech-dispatcher libgeos-dev portaudio19-dev
elif [[ "${{ matrix.os }}" == 'macos-latest' ]]; then
brew update && brew install git geos portaudio ffmpeg@7
echo "DYLD_LIBRARY_PATH=/opt/homebrew/opt/ffmpeg@7/lib:/opt/homebrew/lib:/usr/local/lib:$DYLD_LIBRARY_PATH" >> $GITHUB_ENV
fi
- name: Setup uv and Python
uses: astral-sh/setup-uv@v6 # zizmor: ignore[unpinned-uses]
with:
enable-cache: true
version: ${{ env.UV_VERSION }}
python-version: ${{ env.PYTHON_VERSION }}
- name: Unbound dependencies
run: |
sed -i 's/,[[:space:]]*<[0-9\.]*//g' pyproject.toml
echo "Dependencies unbound:" && cat pyproject.toml
- name: Install lerobot with all extras
run: uv sync --all-extras
- name: Run pytest (all extras)
run: uv run pytest tests -vv
- name: Run end-to-end tests
run: uv run make test-end-to-end
# This job builds a GPU enabled image for testing
build-and-push-docker:
name: Build and Push Docker
runs-on:
group: aws-general-8-plus
outputs:
image_tag: ${{ env.DOCKER_IMAGE_NAME }}
env:
GITHUB_REF: ${{ github.ref }}
steps:
- name: Install Git LFS
run: |
sudo apt-get update
sudo apt-get install git-lfs
git lfs install
- uses: actions/checkout@v4
with:
lfs: true
persist-credentials: false
- name: Set up Docker Buildx
uses: docker/setup-buildx-action@v3 # zizmor: ignore[unpinned-uses]
with:
cache-binary: false
- name: Login to Docker Hub
uses: docker/login-action@v3 # zizmor: ignore[unpinned-uses]
with:
username: ${{ secrets.DOCKERHUB_LEROBOT_USERNAME }}
password: ${{ secrets.DOCKERHUB_LEROBOT_PASSWORD }}
- name: Build and push Docker image
uses: docker/build-push-action@v6 # zizmor: ignore[unpinned-uses]
with:
context: .
file: ./docker/Dockerfile.internal
push: true
tags: ${{ env.DOCKER_IMAGE_NAME }}
build-args: |
UNBOUND_DEPS=true
# This job runs pytest with all unbound extras in a GPU enabled host
# It runs everytime a test image is created
gpu-tests:
name: GPU Unbound Tests
needs: [build-and-push-docker]
runs-on:
group: aws-g6-4xlarge-plus
env:
HF_HOME: /home/user_lerobot/.cache/huggingface
HF_LEROBOT_HOME: /home/user_lerobot/.cache/huggingface/lerobot
TORCH_HOME: /home/user_lerobot/.cache/torch
TRITON_CACHE_DIR: /home/user_lerobot/.cache/triton
container:
image: ${{ needs.build-and-push-docker.outputs.image_tag }} # zizmor: ignore[unpinned-images]
options: --gpus all --shm-size "16gb"
credentials:
username: ${{ secrets.DOCKERHUB_LEROBOT_USERNAME }}
password: ${{ secrets.DOCKERHUB_LEROBOT_PASSWORD }}
defaults:
run:
shell: bash
working-directory: /lerobot
steps:
- name: Run pytest on GPU
run: pytest tests -vv
- name: Run end-to-end tests
run: make test-end-to-end
# This job deletes the test image recently created
# It runs everytime after the gpu-tests have finished
delete-unbound-image:
name: Delete Unbound Image
needs: [gpu-tests, build-and-push-docker]
if: always() && needs.build-and-push-docker.result == 'success'
runs-on: ubuntu-latest
steps:
- name: Get Docker Hub Token and Delete Image
# zizmor: ignore[template-injection]
run: |
IMAGE_NAME=$(echo "${{ needs.build-and-push-docker.outputs.image_tag }}" | cut -d':' -f1)
IMAGE_TAG=$(echo "${{ needs.build-and-push-docker.outputs.image_tag }}" | cut -d':' -f2)
echo "Attempting to delete image: $IMAGE_NAME:$IMAGE_TAG"
TOKEN=$(curl -s -H "Content-Type: application/json" \
-X POST \
-d '{"username": "${{ secrets.DOCKERHUB_LEROBOT_USERNAME }}", "password": "${{ secrets.DOCKERHUB_LEROBOT_PASSWORD }}"}' \
https://hub.docker.com/v2/users/login/ | jq -r .token)
if [ "$TOKEN" == "null" ] || [ -z "$TOKEN" ]; then
echo "::error::Failed to get Docker Hub token."
exit 1
fi
HTTP_RESPONSE=$(curl -s -o /dev/null -w "%{http_code}" \
-H "Authorization: JWT ${TOKEN}" \
-X DELETE \
https://hub.docker.com/v2/repositories/${IMAGE_NAME}/tags/${IMAGE_TAG}/)
if [ "$HTTP_RESPONSE" -eq 204 ]; then
echo "Successfully deleted Docker image tag: $IMAGE_NAME:$IMAGE_TAG"
else
echo "::error::Failed to delete Docker image. HTTP status: $HTTP_RESPONSE"
exit 1
fi
.gitignore
-4
View File
@@ -173,7 +173,3 @@ outputs/
# Dev folders
.cache/*
*.stl
*.urdf
*.xml
*.part
.pre-commit-config.yaml
+1 -2
View File
@@ -90,8 +90,7 @@ repos:
rev: v1.16.0
hooks:
- id: mypy
args: [--config-file=pyproject.toml]
exclude: ^(examples|benchmarks|tests)/
args: [--python-version=3.10]
##### Docstring Checks #####
# - repo: https://github.com/akaihola/darglint2
CONTRIBUTING.md
+1
View File
@@ -72,6 +72,7 @@ post it.
Look at our implementations for [datasets](./src/lerobot/datasets/), [policies](./src/lerobot/policies/),
environments ([aloha](https://github.com/huggingface/gym-aloha),
[xarm](https://github.com/huggingface/gym-xarm),
[pusht](https://github.com/huggingface/gym-pusht))
and follow the same api design.
Makefile
+5 -5
View File
@@ -119,9 +119,10 @@ test-tdmpc-ete-train:
--policy.type=tdmpc \
--policy.device=$(DEVICE) \
--policy.push_to_hub=false \
--env.type=pusht \
--env.type=xarm \
--env.task=XarmLift-v0 \
--env.episode_length=5 \
--dataset.repo_id=lerobot/pusht_image \
--dataset.repo_id=lerobot/xarm_lift_medium \
--dataset.image_transforms.enable=true \
--dataset.episodes="[0]" \
--batch_size=2 \
@@ -139,10 +140,9 @@ test-tdmpc-ete-eval:
lerobot-eval \
--policy.path=tests/outputs/tdmpc/checkpoints/000002/pretrained_model \
--policy.device=$(DEVICE) \
--env.type=pusht \
--env.type=xarm \
--env.episode_length=5 \
--env.observation_height=96 \
--env.observation_width=96 \
--env.task=XarmLift-v0 \
--eval.n_episodes=1 \
--eval.batch_size=1
README.md
+54 -32
View File
@@ -197,12 +197,12 @@ wandb login
### Visualize datasets
Check out [example 1](https://github.com/huggingface/lerobot/blob/main/examples/dataset/load_lerobot_dataset.py) that illustrates how to use our dataset class which automatically downloads data from the Hugging Face hub.
Check out [example 1](https://github.com/huggingface/lerobot/blob/main/examples/1_load_lerobot_dataset.py) that illustrates how to use our dataset class which automatically downloads data from the Hugging Face hub.
You can also locally visualize episodes from a dataset on the hub by executing our script from the command line:
```bash
lerobot-dataset-viz \
python -m lerobot.scripts.visualize_dataset \
--repo-id lerobot/pusht \
--episode-index 0
```
@@ -210,7 +210,7 @@ lerobot-dataset-viz \
or from a dataset in a local folder with the `root` option and the `--local-files-only` (in the following case the dataset will be searched for in `./my_local_data_dir/lerobot/pusht`)
```bash
lerobot-dataset-viz \
python -m lerobot.scripts.visualize_dataset \
--repo-id lerobot/pusht \
--root ./my_local_data_dir \
--local-files-only 1 \
@@ -221,13 +221,13 @@ It will open `rerun.io` and display the camera streams, robot states and actions
https://github-production-user-asset-6210df.s3.amazonaws.com/4681518/328035972-fd46b787-b532-47e2-bb6f-fd536a55a7ed.mov?X-Amz-Algorithm=AWS4-HMAC-SHA256&X-Amz-Credential=AKIAVCODYLSA53PQK4ZA%2F20240505%2Fus-east-1%2Fs3%2Faws4_request&X-Amz-Date=20240505T172924Z&X-Amz-Expires=300&X-Amz-Signature=d680b26c532eeaf80740f08af3320d22ad0b8a4e4da1bcc4f33142c15b509eda&X-Amz-SignedHeaders=host&actor_id=24889239&key_id=0&repo_id=748713144
Our script can also visualize datasets stored on a distant server. See `lerobot-dataset-viz --help` for more instructions.
Our script can also visualize datasets stored on a distant server. See `python -m lerobot.scripts.visualize_dataset --help` for more instructions.
### The `LeRobotDataset` format
A dataset in `LeRobotDataset` format is very simple to use. It can be loaded from a repository on the Hugging Face hub or a local folder simply with e.g. `dataset = LeRobotDataset("lerobot/aloha_static_coffee")` and can be indexed into like any Hugging Face and PyTorch dataset. For instance `dataset[0]` will retrieve a single temporal frame from the dataset containing observation(s) and an action as PyTorch tensors ready to be fed to a model.
A specificity of `LeRobotDataset` is that, rather than retrieving a single frame by its index, we can retrieve several frames based on their temporal relationship with the indexed frame, by setting `delta_timestamps` to a list of relative times with respect to the indexed frame. For example, with `delta_timestamps = {"observation.image": [-1, -0.5, -0.2, 0]}` one can retrieve, for a given index, 4 frames: 3 "previous" frames 1 second, 0.5 seconds, and 0.2 seconds before the indexed frame, and the indexed frame itself (corresponding to the 0 entry). See example [1_load_lerobot_dataset.py](https://github.com/huggingface/lerobot/blob/main/examples/dataset/load_lerobot_dataset.py) for more details on `delta_timestamps`.
A specificity of `LeRobotDataset` is that, rather than retrieving a single frame by its index, we can retrieve several frames based on their temporal relationship with the indexed frame, by setting `delta_timestamps` to a list of relative times with respect to the indexed frame. For example, with `delta_timestamps = {"observation.image": [-1, -0.5, -0.2, 0]}` one can retrieve, for a given index, 4 frames: 3 "previous" frames 1 second, 0.5 seconds, and 0.2 seconds before the indexed frame, and the indexed frame itself (corresponding to the 0 entry). See example [1_load_lerobot_dataset.py](https://github.com/huggingface/lerobot/blob/main/examples/1_load_lerobot_dataset.py) for more details on `delta_timestamps`.
Under the hood, the `LeRobotDataset` format makes use of several ways to serialize data which can be useful to understand if you plan to work more closely with this format. We tried to make a flexible yet simple dataset format that would cover most type of features and specificities present in reinforcement learning and robotics, in simulation and in real-world, with a focus on cameras and robot states but easily extended to other types of sensory inputs as long as they can be represented by a tensor.
@@ -246,29 +246,19 @@ dataset attributes:
│ ├ timestamp (float32): timestamp in the episode
│ ├ next.done (bool): indicates the end of an episode ; True for the last frame in each episode
│ └ index (int64): general index in the whole dataset
meta: a LeRobotDatasetMetadata object containing:
│ ├ info: a dictionary of metadata on the dataset
│ ├ codebase_version (str): this is to keep track of the codebase version the dataset was created with
│ │ ├ fps (int): frame per second the dataset is recorded/synchronized to
│ ├ features (dict): all features contained in the dataset with their shapes and types
│ ├ total_episodes (int): total number of episodes in the dataset
│ │ ├ total_frames (int): total number of frames in the dataset
│ ├ robot_type (str): robot type used for recording
│ ├ data_path (str): formattable string for the parquet files
│ └ video_path (str): formattable string for the video files (if using videos)
episodes: a DataFrame containing episode metadata with columns:
│ │ ├ episode_index (int): index of the episode
│ │ ├ tasks (list): list of tasks for this episode
│ │ ├ length (int): number of frames in this episode
│ │ ├ dataset_from_index (int): start index of this episode in the dataset
│ │ └ dataset_to_index (int): end index of this episode in the dataset
│ ├ stats: a dictionary of statistics (max, mean, min, std) for each feature in the dataset, for instance
│ │ ├ observation.images.front_cam: {'max': tensor with same number of dimensions (e.g. `(c, 1, 1)` for images, `(c,)` for states), etc.}
│ │ └ ...
│ └ tasks: a DataFrame containing task information with task names as index and task_index as values
├ root (Path): local directory where the dataset is stored
├ image_transforms (Callable): optional image transformations to apply to visual modalities
└ delta_timestamps (dict): optional delta timestamps for temporal queries
episode_data_index: contains 2 tensors with the start and end indices of each episode
│ ├ from (1D int64 tensor): first frame index for each episode — shape (num episodes,) starts with 0
└ to: (1D int64 tensor): last frame index for each episode — shape (num episodes,)
├ stats: a dictionary of statistics (max, mean, min, std) for each feature in the dataset, for instance
├ observation.images.cam_high: {'max': tensor with same number of dimensions (e.g. `(c, 1, 1)` for images, `(c,)` for states), etc.}
...
├ info: a dictionary of metadata on the dataset
├ codebase_version (str): this is to keep track of the codebase version the dataset was created with
├ fps (float): frame per second the dataset is recorded/synchronized to
video (bool): indicates if frames are encoded in mp4 video files to save space or stored as png files
encoding (dict): if video, this documents the main options that were used with ffmpeg to encode the videos
├ videos_dir (Path): where the mp4 videos or png images are stored/accessed
└ camera_keys (list of string): the keys to access camera features in the item returned by the dataset (e.g. `["observation.images.cam_high", ...]`)
```
A `LeRobotDataset` is serialised using several widespread file formats for each of its parts, namely:
@@ -279,6 +269,42 @@ A `LeRobotDataset` is serialised using several widespread file formats for each
Dataset can be uploaded/downloaded from the HuggingFace hub seamlessly. To work on a local dataset, you can specify its location with the `root` argument if it's not in the default `~/.cache/huggingface/lerobot` location.
### Evaluate a pretrained policy
Check out [example 2](https://github.com/huggingface/lerobot/blob/main/examples/2_evaluate_pretrained_policy.py) that illustrates how to download a pretrained policy from Hugging Face hub, and run an evaluation on its corresponding environment.
We also provide a more capable script to parallelize the evaluation over multiple environments during the same rollout. Here is an example with a pretrained model hosted on [lerobot/diffusion_pusht](https://huggingface.co/lerobot/diffusion_pusht):
```bash
lerobot-eval \
--policy.path=lerobot/diffusion_pusht \
--env.type=pusht \
--eval.batch_size=10 \
--eval.n_episodes=10 \
--policy.use_amp=false \
--policy.device=cuda
```
Note: After training your own policy, you can re-evaluate the checkpoints with:
```bash
lerobot-eval --policy.path={OUTPUT_DIR}/checkpoints/last/pretrained_model
```
See `lerobot-eval --help` for more instructions.
### Train your own policy
Check out [example 3](https://github.com/huggingface/lerobot/blob/main/examples/3_train_policy.py) that illustrates how to train a model using our core library in python, and [example 4](https://github.com/huggingface/lerobot/blob/main/examples/4_train_policy_with_script.md) that shows how to use our training script from command line.
To use wandb for logging training and evaluation curves, make sure you've run `wandb login` as a one-time setup step. Then, when running the training command above, enable WandB in the configuration by adding `--wandb.enable=true`.
A link to the wandb logs for the run will also show up in yellow in your terminal. Here is an example of what they look like in your browser. Please also check [here](https://github.com/huggingface/lerobot/blob/main/examples/4_train_policy_with_script.md#typical-logs-and-metrics) for the explanation of some commonly used metrics in logs.
\<img src="https://raw.githubusercontent.com/huggingface/lerobot/main/media/wandb.png" alt="WandB logs example"\>
Note: For efficiency, during training every checkpoint is evaluated on a low number of episodes. You may use `--eval.n_episodes=500` to evaluate on more episodes than the default. Or, after training, you may want to re-evaluate your best checkpoints on more episodes or change the evaluation settings. See `lerobot-eval --help` for more instructions.
#### Reproduce state-of-the-art (SOTA)
We provide some pretrained policies on our [hub page](https://huggingface.co/lerobot) that can achieve state-of-the-art performances.
@@ -337,7 +363,3 @@ If you want, you can cite this work with:
## Star History
[![Star History Chart](https://api.star-history.com/svg?repos=huggingface/lerobot&type=Timeline)](https://star-history.com/#huggingface/lerobot&Timeline)
```
```
benchmarks/video/run_video_benchmark.py
+4 -7
View File
@@ -35,13 +35,12 @@ 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_torchvision,
encode_video_frames,
)
from lerobot.utils.constants import OBS_IMAGE
from lerobot.utils.benchmark import TimeBenchmark
BASE_ENCODING = OrderedDict(
[
@@ -109,8 +108,7 @@ def save_decoded_frames(
def save_first_episode(imgs_dir: Path, dataset: LeRobotDataset) -> None:
episode_index = 0
ep_num_images = dataset.meta.episodes["length"][episode_index]
ep_num_images = dataset.episode_data_index["to"][0].item()
if imgs_dir.exists() and len(list(imgs_dir.glob("frame_*.png"))) == ep_num_images:
return
@@ -118,7 +116,7 @@ def save_first_episode(imgs_dir: Path, dataset: LeRobotDataset) -> None:
hf_dataset = dataset.hf_dataset.with_format(None)
# We only save images from the first camera
img_keys = [key for key in hf_dataset.features if key.startswith(OBS_IMAGE)]
img_keys = [key for key in hf_dataset.features if key.startswith("observation.image")]
imgs_dataset = hf_dataset.select_columns(img_keys[0])
for i, item in enumerate(
@@ -267,8 +265,7 @@ def benchmark_encoding_decoding(
overwrite=True,
)
episode_index = 0
ep_num_images = dataset.meta.episodes["length"][episode_index]
ep_num_images = dataset.episode_data_index["to"][0].item()
width, height = tuple(dataset[0][dataset.meta.camera_keys[0]].shape[-2:])
num_pixels = width * height
video_size_bytes = video_path.stat().st_size
docker/Dockerfile.internal
-9
View File
@@ -39,7 +39,6 @@ RUN apt-get update && apt-get install -y --no-install-recommends \
software-properties-common build-essential git curl \
libglib2.0-0 libgl1-mesa-glx libegl1-mesa ffmpeg \
libusb-1.0-0-dev speech-dispatcher libgeos-dev portaudio19-dev \
cmake pkg-config ninja-build \
&& add-apt-repository -y ppa:deadsnakes/ppa \
&& apt-get update \
&& apt-get install -y --no-install-recommends \
@@ -75,14 +74,6 @@ RUN uv venv --python python${PYTHON_VERSION}
# Install Python dependencies for caching
COPY --chown=user_lerobot:user_lerobot pyproject.toml README.md MANIFEST.in ./
COPY --chown=user_lerobot:user_lerobot src/ src/
ARG UNBOUND_DEPS=false
RUN if [ "$UNBOUND_DEPS" = "true" ]; then \
sed -i 's/,[[:space:]]*<[0-9\.]*//g' pyproject.toml; \
echo "Dependencies unbound:" && cat pyproject.toml; \
fi
RUN uv pip install --no-cache ".[all]"
# Copy the rest of the application source code
docker/Dockerfile.user
-9
View File
@@ -31,7 +31,6 @@ ENV DEBIAN_FRONTEND=noninteractive \
RUN apt-get update && apt-get install -y --no-install-recommends \
build-essential git curl libglib2.0-0 libegl1-mesa-dev ffmpeg \
libusb-1.0-0-dev speech-dispatcher libgeos-dev portaudio19-dev \
cmake pkg-config ninja-build \
&& curl -LsSf https://astral.sh/uv/install.sh | sh \
&& mv /root/.local/bin/uv /usr/local/bin/uv \
&& useradd --create-home --shell /bin/bash user_lerobot \
@@ -61,14 +60,6 @@ RUN uv venv
# Install Python dependencies for caching
COPY --chown=user_lerobot:user_lerobot pyproject.toml README.md MANIFEST.in ./
COPY --chown=user_lerobot:user_lerobot src/ src/
ARG UNBOUND_DEPS=false
RUN if [ "$UNBOUND_DEPS" = "true" ]; then \
sed -i 's/,[[:space:]]*<[0-9\.]*//g' pyproject.toml; \
echo "Dependencies unbound:" && cat pyproject.toml; \
fi
RUN uv pip install --no-cache ".[all]"
# Copy the rest of the application code
docs/source/_toctree.yml
+5 -41
View File
@@ -7,6 +7,8 @@
- sections:
- local: il_robots
title: Imitation Learning for Robots
- local: il_sim
title: Imitation Learning in Sim
- local: cameras
title: Cameras
- local: integrate_hardware
@@ -19,42 +21,12 @@
title: Use Async Inference
title: "Tutorials"
- sections:
- local: lerobot-dataset-v3
title: Using LeRobotDataset
- local: porting_datasets_v3
title: Porting Large Datasets
- local: using_dataset_tools
title: Using the Dataset Tools
title: "Datasets"
- sections:
- local: act
title: ACT
- local: smolvla
title: SmolVLA
- local: pi0
title: π₀ (Pi0)
- local: pi05
title: π₀.₅ (Pi05)
title: Finetune SmolVLA
title: "Policies"
- sections:
- local: il_sim
title: Imitation Learning in Sim
- local: libero
title: Using Libero
- local: metaworld
title: Using MetaWorld
title: "Simulation"
- sections:
- local: introduction_processors
title: Introduction to Robot Processors
- local: debug_processor_pipeline
title: Debug your processor pipeline
- local: implement_your_own_processor
title: Implement your own processor
- local: processors_robots_teleop
title: Processors for Robots and Teleoperators
title: "Robot Processors"
- sections:
- local: hope_jr
title: Hope Jr
- local: so101
title: SO-101
- local: so100
@@ -63,15 +35,7 @@
title: Koch v1.1
- local: lekiwi
title: LeKiwi
- local: hope_jr
title: Hope Jr
- local: reachy2
title: Reachy 2
title: "Robots"
- sections:
- local: phone_teleop
title: Phone
title: "Teleoperators"
- sections:
- local: notebooks
title: Notebooks
docs/source/act.mdx
-92
View File
@@ -1,92 +0,0 @@
# ACT (Action Chunking with Transformers)
ACT is a **lightweight and efficient policy for imitation learning**, especially well-suited for fine-grained manipulation tasks. It's the **first model we recommend when you're starting out** with LeRobot due to its fast training time, low computational requirements, and strong performance.
<div class="video-container">
<iframe
width="100%"
height="415"
src="https://www.youtube.com/embed/ft73x0LfGpM"
title="LeRobot ACT Tutorial"
frameborder="0"
allow="accelerometer; autoplay; clipboard-write; encrypted-media; gyroscope; picture-in-picture"
allowfullscreen
></iframe>
</div>
_Watch this tutorial from the LeRobot team to learn how ACT works: [LeRobot ACT Tutorial](https://www.youtube.com/watch?v=ft73x0LfGpM)_
## Model Overview
Action Chunking with Transformers (ACT) was introduced in the paper [Learning Fine-Grained Bimanual Manipulation with Low-Cost Hardware](https://arxiv.org/abs/2304.13705) by Zhao et al. The policy was designed to enable precise, contact-rich manipulation tasks using affordable hardware and minimal demonstration data.
### Why ACT is Great for Beginners
ACT stands out as an excellent starting point for several reasons:
- **Fast Training**: Trains in a few hours on a single GPU
- **Lightweight**: Only ~80M parameters, making it efficient and easy to work with
- **Data Efficient**: Often achieves high success rates with just 50 demonstrations
### Architecture
ACT uses a transformer-based architecture with three main components:
1. **Vision Backbone**: ResNet-18 processes images from multiple camera viewpoints
2. **Transformer Encoder**: Synthesizes information from camera features, joint positions, and a learned latent variable
3. **Transformer Decoder**: Generates coherent action sequences using cross-attention
The policy takes as input:
- Multiple RGB images (e.g., from wrist cameras, front/top cameras)
- Current robot joint positions
- A latent style variable `z` (learned during training, set to zero during inference)
And outputs a chunk of `k` future action sequences.
## Installation Requirements
1. Install LeRobot by following our [Installation Guide](./installation).
2. ACT is included in the base LeRobot installation, so no additional dependencies are needed!
## Training ACT
ACT works seamlessly with the standard LeRobot training pipeline. Here's a complete example for training ACT on your dataset:
```bash
lerobot-train \
--dataset.repo_id=${HF_USER}/your_dataset \
--policy.type=act \
--output_dir=outputs/train/act_your_dataset \
--job_name=act_your_dataset \
--policy.device=cuda \
--wandb.enable=true \
--policy.repo_id=${HF_USER}/act_policy
```
### Training Tips
1. **Start with defaults**: ACT's default hyperparameters work well for most tasks
2. **Training duration**: Expect a few hours for 100k training steps on a single GPU
3. **Batch size**: Start with batch size 8 and adjust based on your GPU memory
### Train using Google Colab
If your local computer doesn't have a powerful GPU, you can utilize Google Colab to train your model by following the [ACT training notebook](./notebooks#training-act).
## Evaluating ACT
Once training is complete, you can evaluate your ACT policy using the `lerobot-record` command with your trained policy. This will run inference and record evaluation episodes:
```bash
lerobot-record \
--robot.type=so100_follower \
--robot.port=/dev/ttyACM0 \
--robot.id=my_robot \
--robot.cameras="{ front: {type: opencv, index_or_path: 0, width: 640, height: 480, fps: 30}}" \
--display_data=true \
--dataset.repo_id=${HF_USER}/eval_act_your_dataset \
--dataset.num_episodes=10 \
--dataset.single_task="Your task description" \
--policy.path=${HF_USER}/act_policy
```
docs/source/async.mdx
+13 -13
View File
@@ -31,15 +31,15 @@ Then, spin up a policy server (in one terminal, or in a separate machine) specif
You can spin up a policy server running:
```shell
python -m lerobot.async_inference.policy_server \
--host=127.0.0.1 \
--port=8080
python src/lerobot/scripts/server/policy_server.py \
--host=127.0.0.1 \
--port=8080 \
```
This will start a policy server listening on `127.0.0.1:8080` (`localhost`, port 8080). At this stage, the policy server is empty, as all information related to which policy to run and with which parameters are specified during the first handshake with the client. Spin up a client with:
```shell
python -m lerobot.async_inference.robot_client \
python src/lerobot/scripts/server/robot_client.py \
--server_address=127.0.0.1:8080 \ # SERVER: the host address and port of the policy server
--robot.type=so100_follower \ # ROBOT: your robot type
--robot.port=/dev/tty.usbmodem585A0076841 \ # ROBOT: your robot port
@@ -113,17 +113,17 @@ As such, spinning up a policy server is as easy as specifying the host address a
<hfoptions id="start_policy_server">
<hfoption id="Command">
```bash
python -m lerobot.async_inference.policy_server \
--host=127.0.0.1 \
--port=8080
python -m lerobot.scripts.server.policy_server \
--host="localhost" \
--port=8080
```
</hfoption>
<hfoption id="API example">
<!-- prettier-ignore-start -->
```python
from lerobot.async_inference.configs import PolicyServerConfig
from lerobot.async_inference.policy_server import serve
from lerobot.scripts.server.configs import PolicyServerConfig
from lerobot.scripts.server.policy_server import serve
config = PolicyServerConfig(
host="localhost",
@@ -148,7 +148,7 @@ The `RobotClient` streams observations to the `PolicyServer`, and receives actio
<hfoptions id="start_robot_client">
<hfoption id="Command">
```bash
python -m lerobot.async_inference.robot_client \
python src/lerobot/scripts/server/robot_client.py \
--server_address=127.0.0.1:8080 \ # SERVER: the host address and port of the policy server
--robot.type=so100_follower \ # ROBOT: your robot type
--robot.port=/dev/tty.usbmodem585A0076841 \ # ROBOT: your robot port
@@ -171,9 +171,9 @@ python -m lerobot.async_inference.robot_client \
import threading
from lerobot.robots.so100_follower import SO100FollowerConfig
from lerobot.cameras.opencv.configuration_opencv import OpenCVCameraConfig
from lerobot.async_inference.configs import RobotClientConfig
from lerobot.async_inference.robot_client import RobotClient
from lerobot.async_inference.helpers import visualize_action_queue_size
from lerobot.scripts.server.configs import RobotClientConfig
from lerobot.scripts.server.robot_client import RobotClient
from lerobot.scripts.server.helpers import visualize_action_queue_size
# 1. Create the robot instance
"""Check out the cameras available in your setup by running `python lerobot/find_cameras.py`"""
docs/source/backwardcomp.mdx
-56
View File
@@ -1,61 +1,5 @@
# Backward compatibility
## Policy Normalization Migration (PR #1452)
**Breaking Change**: LeRobot policies no longer have built-in normalization layers embedded in their weights. Normalization is now handled by external `PolicyProcessorPipeline` components.
### What changed?
| | Before PR #1452 | After PR #1452 |
| -------------------------- | ------------------------------------------------ | ------------------------------------------------------------ |
| **Normalization Location** | Embedded in model weights (`normalize_inputs.*`) | External `PolicyProcessorPipeline` components |
| **Model State Dict** | Contains normalization statistics | **Clean weights only** - no normalization parameters |
| **Usage** | `policy(batch)` handles everything | `preprocessor(batch)` → `policy(...)` → `postprocessor(...)` |
### Impact on existing models
- Models trained **before** PR #1452 have normalization embedded in their weights
- These models need migration to work with the new `PolicyProcessorPipeline` system
- The migration extracts normalization statistics and creates separate processor pipelines
### Migrating old models
Use the migration script to convert models with embedded normalization:
```shell
python src/lerobot/processor/migrate_policy_normalization.py \
--pretrained-path lerobot/act_aloha_sim_transfer_cube_human \
--push-to-hub \
--branch migrated
```
The script:
1. **Extracts** normalization statistics from model weights
2. **Creates** external preprocessor and postprocessor pipelines
3. **Removes** normalization layers from model weights
4. **Saves** clean model + processor pipelines
5. **Pushes** to Hub with automatic PR creation
### Using migrated models
```python
# New usage pattern (after migration)
from lerobot.policies.factory import make_policy, make_pre_post_processors
# Load model and processors separately
policy = make_policy(config, ds_meta=dataset.meta)
preprocessor, postprocessor = make_pre_post_processors(
policy_cfg=config,
dataset_stats=dataset.meta.stats
)
# Process data through pipeline
processed_batch = preprocessor(raw_batch)
action = policy.select_action(processed_batch)
final_action = postprocessor(action)
```
## Hardware API redesign
PR [#777](https://github.com/huggingface/lerobot/pull/777) improves the LeRobot calibration but is **not backward-compatible**. Below is a overview of what changed and how you can continue to work with datasets created before this pull request.
docs/source/debug_processor_pipeline.mdx
-299
View File
@@ -1,299 +0,0 @@
# Debug Your Processor Pipeline
Processor pipelines can be complex, especially when chaining multiple transformation steps.
Unlike simple function calls, pipelines lack natural observability, you can't easily see what happens
between each step or where things go wrong.
This guide provides debugging tools and techniques specifically designed to address these challenges
and help you understand data flow through your pipelines.
We'll explore three complementary debugging approaches: **hooks** for runtime monitoring, **step-through debugging** for detailed inspection, and **feature validation** for catching structural mismatches. Each serves a different purpose and together they provide complete visibility into your pipeline's behavior.
## Understanding Hooks
Hooks are functions that get called at specific points during pipeline execution.
They provide a way to inspect, monitor, or modify data without changing your pipeline code.
Think of them as "event listeners" for your pipeline.
### What is a Hook?
A hook is a callback function that gets automatically invoked at specific moments during pipeline execution.
The concept comes from event-driven programming, imagine you could "hook into" the pipeline's execution flow to observe or react to what's happening.
Think of hooks like inserting checkpoints into your pipeline. Every time the pipeline reaches one of these checkpoints, it pauses briefly to call your hook function, giving you a chance to inspect the current state, log information, and validate data.
A hook is simply a function that accepts two parameters:
- `step_idx: int` - The index of the current processing step (0, 1, 2, etc.)
- `transition: EnvTransition` - The data transition at that point in the pipeline
The beauty of hooks is their non-invasive nature: you can add monitoring, validation, or debugging logic without changing a single line of your pipeline code. The pipeline remains clean and focused on its core logic, while hooks handle the cross-cutting concerns like logging, monitoring, and debugging.
### Before vs After Hooks
The pipeline supports two types of hooks:
- **Before hooks** (`register_before_step_hook`) - Called before each step executes
- **After hooks** (`register_after_step_hook`) - Called after each step completes
```python
def before_hook(step_idx: int, transition: EnvTransition):
"""Called before step processes the transition."""
print(f"About to execute step {step_idx}")
# Useful for: logging, validation, setup
def after_hook(step_idx: int, transition: EnvTransition):
"""Called after step has processed the transition."""
print(f"Completed step {step_idx}")
# Useful for: monitoring results, cleanup, debugging
processor.register_before_step_hook(before_hook)
processor.register_after_step_hook(after_hook)
```
### Implementing a NaN Detection Hook
Here's a practical example of a hook that detects NaN values:
```python
def check_nans(step_idx: int, transition: EnvTransition):
"""Check for NaN values in observations."""
obs = transition.get(TransitionKey.OBSERVATION)
if obs:
for key, value in obs.items():
if isinstance(value, torch.Tensor) and torch.isnan(value).any():
print(f"NaN detected in {key} at step {step_idx}")
# Register the hook to run after each step
processor.register_after_step_hook(check_nans)
# Process your data - the hook will be called automatically
output = processor(input_data)
# Remove the hook when done debugging
processor.unregister_after_step_hook(check_nans)
```
### How Hooks Work Internally
Understanding the internal mechanism helps you use hooks more effectively. The pipeline maintains two separate lists: one for before-step hooks and another for after-step hooks. When you register a hook, it's simply appended to the appropriate list.
During execution, the pipeline follows a strict sequence: for each processing step, it first calls all before-hooks in registration order, then executes the actual step transformation, and finally calls all after-hooks in registration order. This creates a predictable, sandwich-like structure around each step.
The key insight is that hooks don't change the core pipeline logic—they're purely additive. The pipeline's `_forward` method orchestrates this dance between hooks and processing steps, ensuring that your debugging or monitoring code runs at exactly the right moments without interfering with the main data flow.
Here's a simplified view of how the pipeline executes hooks:
```python
class DataProcessorPipeline:
def __init__(self):
self.steps = [...]
self.before_step_hooks = [] # List of before hooks
self.after_step_hooks = [] # List of after hooks
def _forward(self, transition):
"""Internal method that processes the transition through all steps."""
for step_idx, processor_step in enumerate(self.steps):
# 1. Call all BEFORE hooks
for hook in self.before_step_hooks:
hook(step_idx, transition)
# 2. Execute the actual processing step
transition = processor_step(transition)
# 3. Call all AFTER hooks
for hook in self.after_step_hooks:
hook(step_idx, transition)
return transition
def register_before_step_hook(self, hook_fn):
self.before_step_hooks.append(hook_fn)
def register_after_step_hook(self, hook_fn):
self.after_step_hooks.append(hook_fn)
```
### Execution Flow
The execution flow looks like this:
```
Input → Before Hook → Step 0 → After Hook → Before Hook → Step 1 → After Hook → ... → Output
```
For example, with 3 steps and both hook types:
```python
def timing_before(step_idx, transition):
print(f"⏱️ Starting step {step_idx}")
def validation_after(step_idx, transition):
print(f"✅ Completed step {step_idx}")
processor.register_before_step_hook(timing_before)
processor.register_after_step_hook(validation_after)
# This will output:
# ⏱️ Starting step 0
# ✅ Completed step 0
# ⏱️ Starting step 1
# ✅ Completed step 1
# ⏱️ Starting step 2
# ✅ Completed step 2
```
### Multiple Hooks
You can register multiple hooks of the same type - they execute in the order registered:
```python
def log_shapes(step_idx: int, transition: EnvTransition):
obs = transition.get(TransitionKey.OBSERVATION)
if obs:
print(f"Step {step_idx} observation shapes:")
for key, value in obs.items():
if isinstance(value, torch.Tensor):
print(f" {key}: {value.shape}")
processor.register_after_step_hook(check_nans) # Executes first
processor.register_after_step_hook(log_shapes) # Executes second
# Both hooks will be called after each step in registration order
output = processor(input_data)
```
While hooks are excellent for monitoring specific issues (like NaN detection) or gathering metrics during normal pipeline execution, sometimes you need to dive deeper. When you want to understand exactly what happens at each step or debug complex transformation logic, step-through debugging provides the detailed inspection you need.
## Step-Through Debugging
Step-through debugging is like having a slow-motion replay for your pipeline. Instead of watching your data get transformed in one quick blur from input to output, you can pause and examine what happens after each individual step.
This approach is particularly valuable when you're trying to understand a complex pipeline, debug unexpected behavior, or verify that each transformation is working as expected. Unlike hooks, which are great for automated monitoring, step-through debugging gives you manual, interactive control over the inspection process.
The `step_through()` method is a generator that yields the transition state after each processing step, allowing you to inspect intermediate results. Think of it as creating a series of snapshots of your data as it flows through the pipeline—each snapshot shows you exactly what your data looks like after one more transformation has been applied.
### How Step-Through Works
The `step_through()` method fundamentally changes how the pipeline executes. Instead of running all steps in sequence and only returning the final result, it transforms the pipeline into an iterator that yields intermediate results.
Here's what happens internally: the method starts by converting your input data into the pipeline's internal transition format, then yields this initial state. Next, it applies the first processing step and yields the result. Then it applies the second step to that result and yields again, and so on. Each `yield` gives you a complete snapshot of the transition at that point.
This generator pattern is powerful because it's lazy—the pipeline only computes the next step when you ask for it. This means you can stop at any point, inspect the current state thoroughly, and decide whether to continue. You're not forced to run the entire pipeline just to debug one problematic step.
Instead of running the entire pipeline and only seeing the final result, `step_through()` pauses after each step and gives you the intermediate transition:
```python
# This creates a generator that yields intermediate states
for i, intermediate_result in enumerate(processor.step_through(input_data)):
print(f"=== After step {i} ===")
# Inspect the observation at this stage
obs = intermediate_result.get(TransitionKey.OBSERVATION)
if obs:
for key, value in obs.items():
if isinstance(value, torch.Tensor):
print(f"{key}: shape={value.shape}, dtype={value.dtype}")
```
### Interactive Debugging with Breakpoints
You can add breakpoints in the step-through loop to interactively debug:
```python
# Step through the pipeline with debugging
for i, intermediate in enumerate(processor.step_through(data)):
print(f"Step {i}: {processor.steps[i].__class__.__name__}")
# Set a breakpoint to inspect the current state
breakpoint() # Debugger will pause here
# You can now inspect 'intermediate' in the debugger:
# - Check tensor shapes and values
# - Verify expected transformations
# - Look for unexpected changes
```
During the debugger session, you can:
- Examine `intermediate[TransitionKey.OBSERVATION]` to see observation data
- Check `intermediate[TransitionKey.ACTION]` for action transformations
- Inspect any part of the transition to understand what each step does
Step-through debugging is perfect for understanding the _data_ transformations, but what about the _structure_ of that data? While hooks and step-through help you debug runtime behavior, you also need to ensure your pipeline produces data in the format expected by downstream components. This is where feature contract validation comes in.
## Validating Feature Contracts
Feature contracts define what data structure your pipeline expects as input and produces as output.
Validating these contracts helps catch mismatches early.
### Understanding Feature Contracts
Each processor step has a `transform_features()` method that describes how it changes the data structure:
```python
# Get the expected output features from your pipeline
initial_features = {
PipelineFeatureType.OBSERVATION: {
"observation.state": PolicyFeature(type=FeatureType.STATE, shape=(7,)),
"observation.image": PolicyFeature(type=FeatureType.IMAGE, shape=(3, 224, 224))
},
PipelineFeatureType.ACTION: {
"action": PolicyFeature(type=FeatureType.ACTION, shape=(4,))
}
}
# Check what your pipeline will output
output_features = processor.transform_features(initial_features)
print("Input features:")
for feature_type, features in initial_features.items():
print(f" {feature_type}:")
for key, feature in features.items():
print(f" {key}: {feature.type.value}, shape={feature.shape}")
print("\nOutput features:")
for feature_type, features in output_features.items():
print(f" {feature_type}:")
for key, feature in features.items():
print(f" {key}: {feature.type.value}, shape={feature.shape}")
```
### Verifying Expected Features
Check that your pipeline produces the features you expect:
```python
# Define what features you expect the pipeline to produce
expected_keys = ["observation.state", "observation.image", "action"]
print("Validating feature contract...")
for expected_key in expected_keys:
found = False
for feature_type, features in output_features.items():
if expected_key in features:
feature = features[expected_key]
print(f"✅ {expected_key}: {feature.type.value}, shape={feature.shape}")
found = True
break
if not found:
print(f"❌ Missing expected feature: {expected_key}")
```
This validation helps ensure your pipeline will work correctly with downstream components that expect specific data structures.
## Summary
Now that you understand the three debugging approaches, you can tackle any pipeline issue systematically:
1. **Hooks** - For runtime monitoring and validation without modifying pipeline code
2. **Step-through** - For inspecting intermediate states and understanding transformations
3. **Feature validation** - For ensuring data structure contracts are met
**When to use each approach:**
- Start with **step-through debugging** when you need to understand what your pipeline does or when something unexpected happens
- Add **hooks** for continuous monitoring during development and production to catch issues automatically
- Use **feature validation** before deployment to ensure your pipeline works with downstream components
These three tools work together to give you the complete observability that complex pipelines naturally lack. With hooks watching for issues, step-through helping you understand behavior, and feature validation ensuring compatibility, you'll be able to debug any pipeline confidently and efficiently.
docs/source/hilserl.mdx
+75 -397
View File
@@ -4,13 +4,7 @@ In this tutorial you will go through the full Human-in-the-Loop Sample-Efficient
HIL-SERL is a sample-efficient reinforcement learning algorithm that combines human demonstrations with online learning and human interventions. The approach starts from a small set of human demonstrations, uses them to train a reward classifier, and then employs an actor-learner architecture where humans can intervene during policy execution to guide exploration and correct unsafe behaviors. In this tutorial, you'll use a gamepad to provide interventions and control the robot during the learning process.
It combines three key ingredients:
1. **Offline demonstrations & reward classifier:** a handful of human-teleop episodes plus a vision-based success detector give the policy a shaped starting point.
2. **On-robot actor / learner loop with human interventions:** a distributed Soft Actor Critic (SAC) learner updates the policy while an actor explores on the physical robot; the human can jump in at any time to correct dangerous or unproductive behaviour.
3. **Safety & efficiency tools:** joint/end-effector (EE) bounds, crop region of interest (ROI) preprocessing and WandB monitoring keep the data useful and the hardware safe.
It combines three key ingredients: 1. **Offline demonstrations & reward classifier:** a handful of human-teleop episodes plus a vision-based success detector give the policy a shaped starting point. 2. **On-robot actor / learner loop with human interventions:** a distributed Soft Actor Critic (SAC) learner updates the policy while an actor explores on the physical robot; the human can jump in at any time to correct dangerous or unproductive behaviour. 3. **Safety & efficiency tools:** joint/end-effector (EE) bounds, crop region of interest (ROI) preprocessing and WandB monitoring keep the data useful and the hardware safe.
Together these elements let HIL-SERL reach near-perfect task success and faster cycle times than imitation-only baselines.
@@ -62,258 +56,49 @@ pip install -e ".[hilserl]"
### Understanding Configuration
The training process begins with proper configuration for the HILSerl environment. The main configuration class is `GymManipulatorConfig` in `lerobot/rl/gym_manipulator.py`, which contains nested `HILSerlRobotEnvConfig` and `DatasetConfig`. The configuration is organized into focused, nested sub-configs:
The training process begins with proper configuration for the HILSerl environment. The configuration class of interest is `HILSerlRobotEnvConfig` in `lerobot/envs/configs.py`. Which is defined as:
<!-- prettier-ignore-start -->
```python
class GymManipulatorConfig:
env: HILSerlRobotEnvConfig # Environment configuration (nested)
dataset: DatasetConfig # Dataset recording/replay configuration (nested)
mode: str | None = None # "record", "replay", or None (for training)
device: str = "cpu" # Compute device
class HILSerlRobotEnvConfig(EnvConfig):
robot: RobotConfig | None = None # Main robot agent (defined in `lerobot/robots`)
teleop: TeleoperatorConfig | None = None # Teleoperator agent, e.g., gamepad or leader arm
processor: HILSerlProcessorConfig # Processing pipeline configuration (nested)
name: str = "real_robot" # Environment name
task: str | None = None # Task identifier
teleop: TeleoperatorConfig | None = None # Teleoperator agent, e.g., gamepad or leader arm, (defined in `lerobot/teleoperators`)
wrapper: EnvTransformConfig | None = None # Environment wrapper settings; check `lerobot/scripts/server/gym_manipulator.py`
fps: int = 10 # Control frequency
# Nested processor configuration
class HILSerlProcessorConfig:
control_mode: str = "gamepad" # Control mode
observation: ObservationConfig | None = None # Observation processing settings
image_preprocessing: ImagePreprocessingConfig | None = None # Image crop/resize settings
gripper: GripperConfig | None = None # Gripper control and penalty settings
reset: ResetConfig | None = None # Environment reset and timing settings
inverse_kinematics: InverseKinematicsConfig | None = None # IK processing settings
reward_classifier: RewardClassifierConfig | None = None # Reward classifier settings
max_gripper_pos: float | None = 100.0 # Maximum gripper position
# Sub-configuration classes
class ObservationConfig:
add_joint_velocity_to_observation: bool = False # Add joint velocities to state
add_current_to_observation: bool = False # Add motor currents to state
display_cameras: bool = False # Display camera feeds during execution
class ImagePreprocessingConfig:
crop_params_dict: dict[str, tuple[int, int, int, int]] | None = None # Image cropping parameters
resize_size: tuple[int, int] | None = None # Target image size
class GripperConfig:
use_gripper: bool = True # Enable gripper control
gripper_penalty: float = 0.0 # Penalty for inappropriate gripper usage
class ResetConfig:
fixed_reset_joint_positions: Any | None = None # Joint positions for reset
reset_time_s: float = 5.0 # Time to wait during reset
control_time_s: float = 20.0 # Maximum episode duration
terminate_on_success: bool = True # Whether to terminate episodes on success detection
class InverseKinematicsConfig:
urdf_path: str | None = None # Path to robot URDF file
target_frame_name: str | None = None # End-effector frame name
end_effector_bounds: dict[str, list[float]] | None = None # EE workspace bounds
end_effector_step_sizes: dict[str, float] | None = None # EE step sizes per axis
class RewardClassifierConfig:
pretrained_path: str | None = None # Path to pretrained reward classifier
success_threshold: float = 0.5 # Success detection threshold
success_reward: float = 1.0 # Reward value for successful episodes
# Dataset configuration
class DatasetConfig:
repo_id: str # LeRobot dataset repository ID
task: str # Task identifier
root: str | None = None # Local dataset root directory
num_episodes_to_record: int = 5 # Number of episodes for recording
replay_episode: int | None = None # Episode index for replay
push_to_hub: bool = False # Whether to push datasets to Hub
name: str = "real_robot" # Environment name
mode: str = None # "record", "replay", or None (for training)
repo_id: str | None = None # LeRobot dataset repository ID
dataset_root: str | None = None # Local dataset root (optional)
task: str = "" # Task identifier
num_episodes: int = 10 # Number of episodes for recording
episode: int = 0 # episode index for replay
device: str = "cuda" # Compute device
push_to_hub: bool = True # Whether to push the recorded datasets to Hub
pretrained_policy_name_or_path: str | None = None # For policy loading
reward_classifier_pretrained_path: str | None = None # For reward model
number_of_steps_after_success: int = 0 # For reward classifier, collect more positive examples after a success to train a classifier
```
<!-- prettier-ignore-end -->
### Processor Pipeline Architecture
HIL-SERL uses a modular processor pipeline architecture that processes robot observations and actions through a series of composable steps. The pipeline is divided into two main components:
#### Environment Processor Pipeline
The environment processor (`env_processor`) handles incoming observations and environment state:
1. **VanillaObservationProcessorStep**: Converts raw robot observations into standardized format
2. **JointVelocityProcessorStep** (optional): Adds joint velocity information to observations
3. **MotorCurrentProcessorStep** (optional): Adds motor current readings to observations
4. **ForwardKinematicsJointsToEE** (optional): Computes end-effector pose from joint positions
5. **ImageCropResizeProcessorStep** (optional): Crops and resizes camera images
6. **TimeLimitProcessorStep** (optional): Enforces episode time limits
7. **GripperPenaltyProcessorStep** (optional): Applies penalties for inappropriate gripper usage
8. **RewardClassifierProcessorStep** (optional): Automated reward detection using vision models
9. **AddBatchDimensionProcessorStep**: Converts data to batch format for neural network processing
10. **DeviceProcessorStep**: Moves data to the specified compute device (CPU/GPU)
#### Action Processor Pipeline
The action processor (`action_processor`) handles outgoing actions and human interventions:
1. **AddTeleopActionAsComplimentaryDataStep**: Captures teleoperator actions for logging
2. **AddTeleopEventsAsInfoStep**: Records intervention events and episode control signals
3. **InterventionActionProcessorStep**: Handles human interventions and episode termination
4. **Inverse Kinematics Pipeline** (when enabled):
- **MapDeltaActionToRobotActionStep**: Converts delta actions to robot action format
- **EEReferenceAndDelta**: Computes end-effector reference and delta movements
- **EEBoundsAndSafety**: Enforces workspace safety bounds
- **InverseKinematicsEEToJoints**: Converts end-effector actions to joint targets
- **GripperVelocityToJoint**: Handles gripper control commands
#### Configuration Examples
**Basic Observation Processing**:
```json
{
"env": {
"processor": {
"observation": {
"add_joint_velocity_to_observation": true,
"add_current_to_observation": false,
"display_cameras": false
}
}
}
}
```
**Image Processing**:
```json
{
"env": {
"processor": {
"image_preprocessing": {
"crop_params_dict": {
"observation.images.front": [180, 250, 120, 150],
"observation.images.side": [180, 207, 180, 200]
},
"resize_size": [128, 128]
}
}
}
}
```
**Inverse Kinematics Setup**:
```json
{
"env": {
"processor": {
"inverse_kinematics": {
"urdf_path": "path/to/robot.urdf",
"target_frame_name": "end_effector",
"end_effector_bounds": {
"min": [0.16, -0.08, 0.03],
"max": [0.24, 0.2, 0.1]
},
"end_effector_step_sizes": {
"x": 0.02,
"y": 0.02,
"z": 0.02
}
}
}
}
}
```
### Advanced Observation Processing
The HIL-SERL framework supports additional observation processing features that can improve policy learning:
#### Joint Velocity Processing
Enable joint velocity estimation to provide the policy with motion information:
```json
{
"env": {
"processor": {
"observation": {
"add_joint_velocity_to_observation": true
}
}
}
}
```
This processor:
- Estimates joint velocities using finite differences between consecutive joint position readings
- Adds velocity information to the observation state vector
- Useful for policies that need motion awareness for dynamic tasks
#### Motor Current Processing
Monitor motor currents to detect contact forces and load conditions:
```json
{
"env": {
"processor": {
"observation": {
"add_current_to_observation": true
}
}
}
}
```
This processor:
- Reads motor current values from the robot's control system
- Adds current measurements to the observation state vector
- Helps detect contact events, object weights, and mechanical resistance
- Useful for contact-rich manipulation tasks
#### Combined Observation Processing
You can enable multiple observation processing features simultaneously:
```json
{
"env": {
"processor": {
"observation": {
"add_joint_velocity_to_observation": true,
"add_current_to_observation": true,
"display_cameras": false
}
}
}
}
```
**Note**: Enabling additional observation features increases the state space dimensionality, which may require adjusting your policy network architecture and potentially collecting more training data.
### Finding Robot Workspace Bounds
Before collecting demonstrations, you need to determine the appropriate operational bounds for your robot.
This helps simplify the problem of learning on the real robot in two ways: 1) by limiting the robot's operational space to a specific region that solves the task and avoids unnecessary or unsafe exploration, and 2) by allowing training in end-effector space rather than joint space. Empirically, learning in joint space for reinforcement learning in manipulation is often a harder problem - some tasks are nearly impossible to learn in joint space but become learnable when the action space is transformed to end-effector coordinates.
**Using lerobot-find-joint-limits**
**Using find_joint_limits.py**
This script helps you find the safe operational bounds for your robot's end-effector. Given that you have a follower and leader arm, you can use the script to find the bounds for the follower arm that will be applied during training.
Bounding the action space will reduce the redundant exploration of the agent and guarantees safety.
```bash
lerobot-find-joint-limits \
--robot.type=so100_follower \
--robot.port=/dev/tty.usbmodem58760431541 \
--robot.id=black \
--teleop.type=so100_leader \
--teleop.port=/dev/tty.usbmodem58760431551 \
--teleop.id=blue
python -m lerobot.scripts.find_joint_limits \
--robot.type=so100_follower \
--robot.port=/dev/tty.usbmodem58760431541 \
--robot.id=black \
--teleop.type=so100_leader \
--teleop.port=/dev/tty.usbmodem58760431551 \
--teleop.id=blue
```
**Workflow**
@@ -343,58 +128,24 @@ With the bounds defined, you can safely collect demonstrations for training. Tra
**Setting Up Record Mode**
Create a configuration file for recording demonstrations (or edit an existing one like [env_config.json](https://huggingface.co/datasets/lerobot/config_examples/resolve/main/rl/env_config.json)):
Create a configuration file for recording demonstrations (or edit an existing one like [env_config_so100.json](https://huggingface.co/datasets/aractingi/lerobot-example-config-files/blob/main/env_config_so100.json)):
1. Set `mode` to `"record"` at the root level
2. Specify a unique `repo_id` for your dataset in the `dataset` section (e.g., "username/task_name")
3. Set `num_episodes_to_record` in the `dataset` section to the number of demonstrations you want to collect
4. Set `env.processor.image_preprocessing.crop_params_dict` to `{}` initially (we'll determine crops later)
5. Configure `env.robot`, `env.teleop`, and other hardware settings in the `env` section
1. Set `mode` to `"record"`
2. Specify a unique `repo_id` for your dataset (e.g., "username/task_name")
3. Set `num_episodes` to the number of demonstrations you want to collect
4. Set `crop_params_dict` to `null` initially (we'll determine crops later)
5. Configure `robot`, `cameras`, and other hardware settings
Example configuration section:
```json
{
"env": {
"type": "gym_manipulator",
"name": "real_robot",
"fps": 10,
"processor": {
"control_mode": "gamepad",
"observation": {
"display_cameras": false
},
"image_preprocessing": {
"crop_params_dict": {},
"resize_size": [128, 128]
},
"gripper": {
"use_gripper": true,
"gripper_penalty": 0.0
},
"reset": {
"reset_time_s": 5.0,
"control_time_s": 20.0
}
},
"robot": {
// ... robot configuration ...
},
"teleop": {
// ... teleoperator configuration ...
}
},
"dataset": {
"repo_id": "username/pick_lift_cube",
"root": null,
"task": "pick_and_lift",
"num_episodes_to_record": 15,
"replay_episode": 0,
"push_to_hub": true
},
"mode": "record",
"device": "cpu"
}
"mode": "record",
"repo_id": "username/pick_lift_cube",
"dataset_root": null,
"task": "pick_and_lift",
"num_episodes": 15,
"episode": 0,
"push_to_hub": true
```
### Using a Teleoperation Device
@@ -440,20 +191,10 @@ The gamepad provides a very convenient way to control the robot and the episode
To setup the gamepad, you need to set the `control_mode` to `"gamepad"` and define the `teleop` section in the configuration file.
```json
{
"env": {
"teleop": {
"type": "gamepad",
"use_gripper": true
},
"processor": {
"control_mode": "gamepad",
"gripper": {
"type": "gamepad",
"use_gripper": true
}
}
}
}
},
```
<p align="center">
@@ -475,21 +216,11 @@ The SO101 leader arm has reduced gears that allows it to move and track the foll
To setup the SO101 leader, you need to set the `control_mode` to `"leader"` and define the `teleop` section in the configuration file.
```json
{
"env": {
"teleop": {
"type": "so101_leader",
"port": "/dev/tty.usbmodem585A0077921",
"use_degrees": true
"type": "so101_leader",
"port": "/dev/tty.usbmodem585A0077921", # check your port number
"use_degrees": true
},
"processor": {
"control_mode": "leader",
"gripper": {
"use_gripper": true
}
}
}
}
```
In order to annotate the success/failure of the episode, **you will need** to use a keyboard to press `s` for success, `esc` for failure.
@@ -515,12 +246,12 @@ During the online training, press `space` to take over the policy and `space` ag
Start the recording process, an example of the config file can be found [here](https://huggingface.co/datasets/aractingi/lerobot-example-config-files/blob/main/env_config_so100.json):
```bash
python -m lerobot.rl.gym_manipulator --config_path src/lerobot/configs/env_config_so100.json
python -m lerobot.scripts.rl.gym_manipulator --config_path src/lerobot/configs/env_config_so100.json
```
During recording:
1. The robot will reset to the initial position defined in the configuration file `env.processor.reset.fixed_reset_joint_positions`
1. The robot will reset to the initial position defined in the configuration file `fixed_reset_joint_positions`
2. Complete the task successfully
3. The episode ends with a reward of 1 when you press the "success" button
4. If the time limit is reached, or the fail button is pressed, the episode ends with a reward of 0
@@ -546,7 +277,7 @@ Note: If you already know the crop parameters, you can skip this step and just s
Use the `crop_dataset_roi.py` script to interactively select regions of interest in your camera images:
```bash
python -m lerobot.rl.crop_dataset_roi --repo-id username/pick_lift_cube
python -m lerobot.scripts.rl.crop_dataset_roi --repo-id username/pick_lift_cube
```
1. For each camera view, the script will display the first frame
@@ -579,19 +310,11 @@ observation.images.front: [180, 250, 120, 150]
Add these crop parameters to your training configuration:
```json
{
"env": {
"processor": {
"image_preprocessing": {
"crop_params_dict": {
"observation.images.side": [180, 207, 180, 200],
"observation.images.front": [180, 250, 120, 150]
},
"resize_size": [128, 128]
}
}
}
}
"crop_params_dict": {
"observation.images.side": [180, 207, 180, 200],
"observation.images.front": [180, 250, 120, 150]
},
"resize_size": [128, 128]
```
**Recommended image resolution**
@@ -615,57 +338,31 @@ Before training, you need to collect a dataset with labeled examples. The `recor
To collect a dataset, you need to modify some parameters in the environment configuration based on HILSerlRobotEnvConfig.
```bash
python -m lerobot.rl.gym_manipulator --config_path src/lerobot/configs/reward_classifier_train_config.json
python -m lerobot.scripts.rl.gym_manipulator --config_path src/lerobot/configs/reward_classifier_train_config.json
```
**Key Parameters for Data Collection**
- **mode**: set it to `"record"` to collect a dataset (at root level)
- **dataset.repo_id**: `"hf_username/dataset_name"`, name of the dataset and repo on the hub
- **dataset.num_episodes_to_record**: Number of episodes to record
- **env.processor.reset.terminate_on_success**: Whether to automatically terminate episodes when success is detected (default: `true`)
- **env.fps**: Number of frames per second to record
- **dataset.push_to_hub**: Whether to push the dataset to the hub
- **mode**: set it to `"record"` to collect a dataset
- **repo_id**: `"hf_username/dataset_name"`, name of the dataset and repo on the hub
- **num_episodes**: Number of episodes to record
- **number_of_steps_after_success**: Number of additional frames to record after a success (reward=1) is detected
- **fps**: Number of frames per second to record
- **push_to_hub**: Whether to push the dataset to the hub
The `env.processor.reset.terminate_on_success` parameter allows you to control episode termination behavior. When set to `false`, episodes will continue even after success is detected, allowing you to collect more positive examples with the reward=1 label. This is crucial for training reward classifiers as it provides more success state examples in your dataset. When set to `true` (default), episodes terminate immediately upon success detection.
**Important**: For reward classifier training, set `terminate_on_success: false` to collect sufficient positive examples. For regular HIL-SERL training, keep it as `true` to enable automatic episode termination when the task is completed successfully.
The `number_of_steps_after_success` parameter is crucial as it allows you to collect more positive examples. When a success is detected, the system will continue recording for the specified number of steps while maintaining the reward=1 label. Otherwise, there won't be enough states in the dataset labeled to 1 to train a good classifier.
Example configuration section for data collection:
```json
{
"env": {
"type": "gym_manipulator",
"name": "real_robot",
"fps": 10,
"processor": {
"reset": {
"reset_time_s": 5.0,
"control_time_s": 20.0,
"terminate_on_success": false
},
"gripper": {
"use_gripper": true
}
},
"robot": {
// ... robot configuration ...
},
"teleop": {
// ... teleoperator configuration ...
}
},
"dataset": {
"repo_id": "hf_username/dataset_name",
"dataset_root": "data/your_dataset",
"task": "reward_classifier_task",
"num_episodes_to_record": 20,
"replay_episode": null,
"push_to_hub": true
},
"mode": "record",
"device": "cpu"
"repo_id": "hf_username/dataset_name",
"dataset_root": "data/your_dataset",
"num_episodes": 20,
"push_to_hub": true,
"fps": 10,
"number_of_steps_after_success": 15
}
```
@@ -724,17 +421,9 @@ To use your trained reward classifier, configure the `HILSerlRobotEnvConfig` to
<!-- prettier-ignore-start -->
```python
config = GymManipulatorConfig(
env=HILSerlRobotEnvConfig(
processor=HILSerlProcessorConfig(
reward_classifier=RewardClassifierConfig(
pretrained_path="path_to_your_pretrained_trained_model"
)
),
# Other environment parameters
),
dataset=DatasetConfig(...),
mode=None # For training
env_config = HILSerlRobotEnvConfig(
reward_classifier_pretrained_path="path_to_your_pretrained_trained_model",
# Other environment parameters
)
```
<!-- prettier-ignore-end -->
@@ -743,25 +432,14 @@ or set the argument in the json config file.
```json
{
"env": {
"processor": {
"reward_classifier": {
"pretrained_path": "path_to_your_pretrained_model",
"success_threshold": 0.7,
"success_reward": 1.0
},
"reset": {
"terminate_on_success": true
}
}
}
"reward_classifier_pretrained_path": "path_to_your_pretrained_model"
}
```
Run `gym_manipulator.py` to test the model.
```bash
python -m lerobot.rl.gym_manipulator --config_path path/to/env_config.json
python -m lerobot.scripts.rl.gym_manipulator --config_path path/to/env_config.json
```
The reward classifier will automatically provide rewards based on the visual input from the robot's cameras.
@@ -769,12 +447,12 @@ The reward classifier will automatically provide rewards based on the visual inp
**Example Workflow for training the reward classifier**
1. **Create the configuration files**:
Create the necessary json configuration files for the reward classifier and the environment. Check the examples [here](https://huggingface.co/datasets/lerobot/config_examples/resolve/main/reward_classifier/config.json).
Create the necessary json configuration files for the reward classifier and the environment. Check the examples [here](https://huggingface.co/datasets/aractingi/lerobot-example-config-files/tree/main).
2. **Collect a dataset**:
```bash
python -m lerobot.rl.gym_manipulator --config_path src/lerobot/configs/env_config.json
python -m lerobot.scripts.rl.gym_manipulator --config_path src/lerobot/configs/env_config.json
```
3. **Train the classifier**:
@@ -785,7 +463,7 @@ The reward classifier will automatically provide rewards based on the visual inp
4. **Test the classifier**:
```bash
python -m lerobot.rl.gym_manipulator --config_path src/lerobot/configs/env_config.json
python -m lerobot.scripts.rl.gym_manipulator --config_path src/lerobot/configs/env_config.json
```
### Training with Actor-Learner
@@ -794,7 +472,7 @@ The LeRobot system uses a distributed actor-learner architecture for training. T
**Configuration Setup**
Create a training configuration file (example available [here](https://huggingface.co/datasets/lerobot/config_examples/resolve/main/rl/train_config.json)). The training config is based on the main `TrainRLServerPipelineConfig` class in `lerobot/configs/train.py`.
Create a training configuration file (example available [here](https://huggingface.co/datasets/aractingi/lerobot-example-config-files/blob/main/train_config_hilserl_so100.json)). The training config is based on the main `TrainRLServerPipelineConfig` class in `lerobot/configs/train.py`.
1. Configure the policy settings (`type="sac"`, `device`, etc.)
2. Set `dataset` to your cropped dataset
@@ -807,7 +485,7 @@ Create a training configuration file (example available [here](https://huggingfa
First, start the learner server process:
```bash
python -m lerobot.rl.learner --config_path src/lerobot/configs/train_config_hilserl_so100.json
python -m lerobot.scripts.rl.learner --config_path src/lerobot/configs/train_config_hilserl_so100.json
```
The learner:
@@ -822,7 +500,7 @@ The learner:
In a separate terminal, start the actor process with the same configuration:
```bash
python -m lerobot.rl.actor --config_path src/lerobot/configs/train_config_hilserl_so100.json
python -m lerobot.scripts.rl.actor --config_path src/lerobot/configs/train_config_hilserl_so100.json
```
The actor:
docs/source/hilserl_sim.mdx
+36 -62
View File
@@ -26,18 +26,15 @@ pip install -e ".[hilserl]"
## Configuration
To use `gym_hil` with LeRobot, you need to create a configuration file. An example is provided [here](https://huggingface.co/datasets/lerobot/config_examples/resolve/main/rl/gym_hil/env_config.json). Key configuration sections include:
To use `gym_hil` with LeRobot, you need to create a configuration file. An example is provided [here](https://huggingface.co/datasets/aractingi/lerobot-example-config-files/blob/main/gym_hil_env.json). Key configuration sections include:
### Environment Type and Task
```json
{
"env": {
"type": "gym_manipulator",
"name": "gym_hil",
"task": "PandaPickCubeGamepad-v0",
"fps": 10
},
"type": "hil",
"name": "franka_sim",
"task": "PandaPickCubeGamepad-v0",
"device": "cuda"
}
```
@@ -48,40 +45,28 @@ Available tasks:
- `PandaPickCubeGamepad-v0`: With gamepad control
- `PandaPickCubeKeyboard-v0`: With keyboard control
### Processor Configuration
### Gym Wrappers Configuration
```json
{
"env": {
"processor": {
"control_mode": "gamepad",
"gripper": {
"use_gripper": true,
"gripper_penalty": -0.02
},
"reset": {
"control_time_s": 15.0,
"fixed_reset_joint_positions": [
0.0, 0.195, 0.0, -2.43, 0.0, 2.62, 0.785
]
},
"inverse_kinematics": {
"end_effector_step_sizes": {
"x": 0.025,
"y": 0.025,
"z": 0.025
}
}
"wrapper": {
"gripper_penalty": -0.02,
"control_time_s": 15.0,
"use_gripper": true,
"fixed_reset_joint_positions": [0.0, 0.195, 0.0, -2.43, 0.0, 2.62, 0.785],
"end_effector_step_sizes": {
"x": 0.025,
"y": 0.025,
"z": 0.025
},
"control_mode": "gamepad"
}
}
}
```
Important parameters:
- `gripper.gripper_penalty`: Penalty for excessive gripper movement
- `gripper.use_gripper`: Whether to enable gripper control
- `inverse_kinematics.end_effector_step_sizes`: Size of the steps in the x,y,z axes of the end-effector
- `gripper_penalty`: Penalty for excessive gripper movement
- `use_gripper`: Whether to enable gripper control
- `end_effector_step_sizes`: Size of the steps in the x,y,z axes of the end-effector
- `control_mode`: Set to `"gamepad"` to use a gamepad controller
## Running with HIL RL of LeRobot
@@ -90,50 +75,39 @@ Important parameters:
To run the environment, set mode to null:
```bash
python -m lerobot.rl.gym_manipulator --config_path path/to/gym_hil_env.json
<!-- prettier-ignore-start -->
```python
python -m lerobot.scripts.rl.gym_manipulator --config_path path/to/gym_hil_env.json
```
<!-- prettier-ignore-end -->
### Recording a Dataset
To collect a dataset, set the mode to `record` whilst defining the repo_id and number of episodes to record:
```json
{
"env": {
"type": "gym_manipulator",
"name": "gym_hil",
"task": "PandaPickCubeGamepad-v0"
},
"dataset": {
"repo_id": "username/sim_dataset",
"root": null,
"task": "pick_cube",
"num_episodes_to_record": 10,
"replay_episode": null,
"push_to_hub": true
},
"mode": "record"
}
```
```bash
python -m lerobot.rl.gym_manipulator --config_path path/to/gym_hil_env.json
<!-- prettier-ignore-start -->
```python
python -m lerobot.scripts.rl.gym_manipulator --config_path path/to/gym_hil_env.json
```
<!-- prettier-ignore-end -->
### Training a Policy
To train a policy, checkout the configuration example available [here](https://huggingface.co/datasets/lerobot/config_examples/resolve/main/rl/gym_hil/train_config.json) and run the actor and learner servers:
To train a policy, checkout the configuration example available [here](https://huggingface.co/datasets/aractingi/lerobot-example-config-files/blob/main/train_gym_hil_env.json) and run the actor and learner servers:
```bash
python -m lerobot.rl.actor --config_path path/to/train_gym_hil_env.json
<!-- prettier-ignore-start -->
```python
python -m lerobot.scripts.rl.actor --config_path path/to/train_gym_hil_env.json
```
<!-- prettier-ignore-end -->
In a different terminal, run the learner server:
```bash
python -m lerobot.rl.learner --config_path path/to/train_gym_hil_env.json
<!-- prettier-ignore-start -->
```python
python -m lerobot.scripts.rl.learner --config_path path/to/train_gym_hil_env.json
```
<!-- prettier-ignore-end -->
The simulation environment provides a safe and repeatable way to develop and test your Human-In-the-Loop reinforcement learning components before deploying to real robots.
docs/source/il_robots.mdx
+7 -19
View File
@@ -200,7 +200,7 @@ from lerobot.teleoperators.so100_leader.config_so100_leader import SO100LeaderCo
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.utils.visualization_utils import _init_rerun
from lerobot.record import record_loop
NUM_EPISODES = 5
@@ -237,7 +237,7 @@ dataset = LeRobotDataset.create(
# Initialize the keyboard listener and rerun visualization
_, events = init_keyboard_listener()
init_rerun(session_name="recording")
_init_rerun(session_name="recording")
# Connect the robot and teleoperator
robot.connect()
@@ -513,21 +513,17 @@ from lerobot.cameras.opencv.configuration_opencv import OpenCVCameraConfig
from lerobot.datasets.lerobot_dataset import LeRobotDataset
from lerobot.datasets.utils import hw_to_dataset_features
from lerobot.policies.act.modeling_act import ACTPolicy
from lerobot.policies.factory import make_pre_post_processors
from lerobot.robots.so100_follower.config_so100_follower import SO100FollowerConfig
from lerobot.robots.so100_follower.so100_follower import SO100Follower
from lerobot.scripts.lerobot_record import record_loop
from lerobot.utils.control_utils import init_keyboard_listener
from lerobot.utils.utils import log_say
from lerobot.utils.visualization_utils import init_rerun
from lerobot.utils.visualization_utils import _init_rerun
from lerobot.record import record_loop
NUM_EPISODES = 5
FPS = 30
EPISODE_TIME_SEC = 60
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
camera_config = {"front": OpenCVCameraConfig(index_or_path=0, width=640, height=480, fps=FPS)}
@@ -539,7 +535,7 @@ robot_config = SO100FollowerConfig(
robot = SO100Follower(robot_config)
# Initialize the policy
policy = ACTPolicy.from_pretrained(HF_MODEL_ID)
policy = ACTPolicy.from_pretrained("<hf_username>/<my_policy_repo_id>")
# Configure the dataset features
action_features = hw_to_dataset_features(robot.action_features, "action")
@@ -548,7 +544,7 @@ dataset_features = {**action_features, **obs_features}
# Create the dataset
dataset = LeRobotDataset.create(
repo_id=HF_DATASET_ID,
repo_id="<hf_username>/eval_<dataset_repo_id>",
fps=FPS,
features=dataset_features,
robot_type=robot.name,
@@ -558,17 +554,11 @@ dataset = LeRobotDataset.create(
# Initialize the keyboard listener and rerun visualization
_, events = init_keyboard_listener()
init_rerun(session_name="recording")
_init_rerun(session_name="recording")
# Connect the robot
robot.connect()
preprocessor, postprocessor = make_pre_post_processors(
policy_cfg=policy,
pretrained_path=HF_MODEL_ID,
dataset_stats=dataset.meta.stats,
)
for episode_idx in range(NUM_EPISODES):
log_say(f"Running inference, recording eval episode {episode_idx + 1} of {NUM_EPISODES}")
@@ -578,8 +568,6 @@ for episode_idx in range(NUM_EPISODES):
events=events,
fps=FPS,
policy=policy,
preprocessor=preprocessor,
postprocessor=postprocessor,
dataset=dataset,
control_time_s=EPISODE_TIME_SEC,
single_task=TASK_DESCRIPTION,
docs/source/il_sim.mdx
+10 -58
View File
@@ -22,38 +22,13 @@ 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 use `gym_hil` with LeRobot, you need to use a configuration file. An example config file can be found [here](https://huggingface.co/datasets/aractingi/lerobot-example-config-files/blob/main/env_config_gym_hil_il.json).
To teleoperate and collect a dataset, we need to modify this config file. Here's an example configuration for imitation learning data collection:
To teleoperate and collect a dataset, we need to modify this config file and you should add your `repo_id` here: `"repo_id": "il_gym",` and `"num_episodes": 30,` and make sure you set `mode` to `record`, "mode": "record".
```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"
}
```
If you do not have a Nvidia GPU also change `"device": "cuda"` parameter in the config file (for example to `mps` for MacOS).
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"`
By default the config file assumes you use a controller. To use your keyboard please change the envoirment specified at `"task"` in the config file and set it to `"PandaPickCubeKeyboard-v0"`.
Then we can run this command to start:
@@ -61,14 +36,14 @@ Then we can run this command to start:
<hfoption id="Linux">
```bash
python -m lerobot.rl.gym_manipulator --config_path path/to/env_config_gym_hil_il.json
python -m lerobot.scripts.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
mjpython -m lerobot.scripts.rl.gym_manipulator --config_path path/to/env_config_gym_hil_il.json
```
</hfoption>
@@ -165,32 +140,9 @@ huggingface-cli upload ${HF_USER}/il_sim_test${CKPT} \
## 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).
To evaluate your policy we have to use the config file that can be found [here](https://huggingface.co/datasets/aractingi/lerobot-example-config-files/blob/main/eval_config_gym_hil.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`)
Make sure to replace the `repo_id` with the dataset you trained on, for example `pepijn223/il_sim_dataset` and replace the `pretrained_policy_name_or_path` with your model id, for example `pepijn223/il_sim_model`
Then you can run this command to visualize your trained policy
@@ -198,14 +150,14 @@ Then you can run this command to visualize your trained policy
<hfoption id="Linux">
```bash
python -m lerobot.rl.eval_policy --config_path=path/to/eval_config_gym_hil.json
python -m lerobot.scripts.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
mjpython -m lerobot.scripts.rl.eval_policy --config_path=path/to/eval_config_gym_hil.json
```
</hfoption>
docs/source/implement_your_own_processor.mdx
-273
View File
@@ -1,273 +0,0 @@
# Implement your own Robot Processor
In this tutorial, you'll learn how to implement your own Robot Processor.
It begins by exploring the need for a custom processor, then uses the `NormalizerProcessorStep` as the running example to explain how to implement, configure, and serialize a processor. Finally, it lists all helper processors that ship with LeRobot.
## Why would you need a custom processor?
In most cases, when reading raw data from sensors or when models output actions, you need to process this data to make it compatible with your target system. For example, a common need is normalizing data ranges to make them suitable for neural networks.
LeRobot's `NormalizerProcessorStep` handles this crucial task:
```python
# Input: raw joint positions in [0, 180] degrees
raw_action = torch.tensor([90.0, 45.0, 135.0])
# After processing: normalized to [-1, 1] range for model training
normalizer = NormalizerProcessorStep(features=features, norm_map=norm_map, stats=dataset_stats)
normalized_result = normalizer(transition)
# ...
```
Other common processing needs include:
- **Device placement**: Moving tensors between CPU/GPU and converting data types
- **Format conversion**: Transforming between different data structures
- **Batching**: Adding/removing batch dimensions for model compatibility
- **Safety constraints**: Applying limits to robot commands
```python
# Example pipeline combining multiple processors
pipeline = PolicyProcessorPipeline([
RenameObservationsProcessorStep(rename_map={}),
AddBatchDimensionProcessorStep(),
NormalizerProcessorStep(features=features, stats=stats),
DeviceProcessorStep(device="cuda"),
# ...
])
```
LeRobot provides a pipeline mechanism to implement sequences of processing steps for both input data and output actions, making it easy to compose these transformations in the right order for optimal performance.
## How to implement your own processor?
We'll use the `NormalizerProcessorStep` as our main example because it demonstrates essential processor patterns including state management, configuration serialization, and tensor handling that you'll commonly need.
Prepare the sequence of processing steps necessary for your problem. A processor step is a class that implements the following methods:
- `__call__`: implements the processing step for the input transition.
- `get_config`: gets the configuration of the processor step.
- `state_dict`: gets the state of the processor step.
- `load_state_dict`: loads the state of the processor step.
- `reset`: resets the state of the processor step.
- `feature_contract`: displays the modification to the feature space during the processor step.
### Implement the `__call__` method
The `__call__` method is the core of your processor step. It takes an `EnvTransition` and returns a modified `EnvTransition`. Here's how the `NormalizerProcessorStep` works:
```python
@dataclass
@ProcessorStepRegistry.register("normalizer_processor")
class NormalizerProcessorStep(ProcessorStep):
"""Normalize observations/actions using dataset statistics."""
features: dict[str, PolicyFeature]
norm_map: dict[FeatureType, NormalizationMode]
stats: dict[str, dict[str, Any]] | None = None
eps: float = 1e-8
_tensor_stats: dict = field(default_factory=dict, init=False, repr=False)
def __post_init__(self):
"""Convert stats to tensors for efficient computation."""
self.stats = self.stats or {}
self._tensor_stats = to_tensor(self.stats, device=self.device, dtype=torch.float32)
def __call__(self, transition: EnvTransition) -> EnvTransition:
new_transition = transition.copy()
# Normalize observations
# ...
# Normalize action
# ...
return new_transition
```
See the full implementation in `src/lerobot/processor/normalize_processor.py` for complete details.
**Key principles:**
- **Always use `transition.copy()`** to avoid side effects
- **Handle both observations and actions** consistently
- **Separate config from state**: `get_config()` returns JSON-serializable params, `state_dict()` returns tensors
- **Convert stats to tensors** in `__post_init__()` for efficient computation
### Configuration and State Management
Processors support serialization through three methods that separate configuration from tensor state. The `NormalizerProcessorStep` demonstrates this perfectly - it carries dataset statistics (tensors) in its state, and hyperparameters in its config:
```python
# Continuing the NormalizerProcessorStep example...
def get_config(self) -> dict[str, Any]:
"""JSON-serializable configuration (no tensors)."""
return {
"eps": self.eps,
"features": {k: {"type": v.type.value, "shape": v.shape} for k, v in self.features.items()},
"norm_map": {ft.value: nm.value for ft, nm in self.norm_map.items()},
# ...
}
def state_dict(self) -> dict[str, torch.Tensor]:
"""Tensor state only (e.g., dataset statistics)."""
flat: dict[str, torch.Tensor] = {}
for key, sub in self._tensor_stats.items():
for stat_name, tensor in sub.items():
flat[f"{key}.{stat_name}"] = tensor.cpu() # Always save to CPU
return flat
def load_state_dict(self, state: dict[str, torch.Tensor]) -> None:
"""Restore tensor state at runtime."""
self._tensor_stats.clear()
for flat_key, tensor in state.items():
key, stat_name = flat_key.rsplit(".", 1)
# Load to processor's configured device
self._tensor_stats.setdefault(key, {})[stat_name] = tensor.to(
dtype=torch.float32, device=self.device
)
# ...
```
**Usage:**
```python
# Save (e.g., inside a policy)
config = normalizer.get_config()
tensors = normalizer.state_dict()
# Restore (e.g., loading a pretrained policy)
new_normalizer = NormalizerProcessorStep(**config)
new_normalizer.load_state_dict(tensors)
# Now new_normalizer has the same stats and configuration
```
### Transform features
The `transform_features` method defines how your processor transforms feature names and shapes. This is crucial for policy configuration and debugging.
For `NormalizerProcessorStep`, features are typically preserved unchanged since normalization doesn't alter keys or shapes:
```python
def transform_features(self, features: dict[PipelineFeatureType, dict[str, PolicyFeature]]) -> dict[PipelineFeatureType, dict[str, PolicyFeature]]:
"""Normalization preserves all feature definitions."""
return features # No changes to feature structure
# ...
```
When your processor renames or reshapes data, implement this method to reflect the mapping for downstream components. For example, a simple rename processor:
```python
def transform_features(self, features: dict[str, PolicyFeature]) -> dict[str, PolicyFeature]:
# Simple renaming
if "pixels" in features:
features["observation.image"] = features.pop("pixels")
# Pattern-based renaming
for key in list(features.keys()):
if key.startswith("env_state."):
suffix = key[len("env_state."):]
features[f"observation.{suffix}"] = features.pop(key)
# ...
return features
```
**Key principles:**
- Use `features.pop(old_key)` to remove and get the old feature
- Use `features[new_key] = old_feature` to add the renamed feature
- Always return the modified features dictionary
- Document transformations clearly in the docstring
### Using overrides
You can override step parameters at load-time using `overrides`. This is handy for non-serializable objects or site-specific settings. It works both in policy factories and with `DataProcessorPipeline.from_pretrained(...)`.
**Foundational model adaptation**: This is particularly useful when working with foundational pretrained policies where you rarely have access to the original training statistics. You can inject your own dataset statistics to adapt the normalizer to your specific robot or environment data.
Example: during policy evaluation on the robot, override the device and rename map.
Use this to run a policy trained on CUDA on a CPU-only robot, or to remap camera keys when the robot uses different names than the dataset.
Direct usage with `from_pretrained`:
```python
from lerobot.processor import RobotProcessorPipeline
# Load a foundational policy trained on diverse robot data
# but adapt normalization to your specific robot/environment
new_stats = LeRobotDataset(repo_id="username/my-dataset").meta.stats
processor = RobotProcessorPipeline.from_pretrained(
"huggingface/foundational-robot-policy", # Pretrained foundation model
overrides={
"normalizer_processor": {"stats": new_stats}, # Inject your robot's statistics
"device_processor": {"device": "cuda:0"}, # registry name for registered steps
"rename_processor": {"rename_map": robot_key_map}, # Map your robot's observation keys
# ...
},
)
```
## Best Practices
Based on analysis of all LeRobot processor implementations, here are the key patterns and practices:
### 1. **Safe Data Handling**
Always create copies of input data to avoid unintended side effects. Use `transition.copy()` and `observation.copy()` rather than modifying data in-place. This prevents your processor from accidentally affecting other components in the pipeline.
Check for required data before processing and handle missing data gracefully. If your processor expects certain keys (like `"pixels"` for image processing), validate their presence first. For optional data, use safe access patterns like `transition.get()` and handle `None` values appropriately.
When data validation fails, provide clear, actionable error messages that help users understand what went wrong and how to fix it.
### 2. **Choose Appropriate Base Classes**
LeRobot provides specialized base classes that reduce boilerplate code and ensure consistency. Use `ObservationProcessorStep` when you only need to modify observations, `ActionProcessorStep` for action-only processing, and `RobotActionProcessorStep` specifically for dictionary-based robot actions.
Only inherit directly from `ProcessorStep` when you need full control over the entire transition or when processing multiple transition components simultaneously. The specialized base classes handle the transition management for you and provide type safety.
### 3. **Registration and Naming**
Register your processors with descriptive, namespaced names using `@ProcessorStepRegistry.register()`. Use organization prefixes like `"robotics_lab/safety_clipper"` or `"acme_corp/vision_enhancer"` to avoid naming conflicts. Avoid generic names like `"processor"` or `"step"` that could clash with other implementations.
Good registration makes your processors discoverable and enables clean serialization/deserialization when saving and loading pipelines.
### 4. **State Management Patterns**
Distinguish between configuration parameters (JSON-serializable values) and internal state (tensors, buffers). Use dataclass fields with `init=False, repr=False` for internal state that shouldn't appear in the constructor or string representation.
Implement the `reset()` method to clear internal state between episodes. This is crucial for stateful processors that accumulate data over time, like moving averages or temporal filters.
Remember that `get_config()` should only return JSON-serializable configuration, while `state_dict()` handles tensor state separately.
### 5. **Input Validation and Error Handling**
Validate input types and shapes before processing. Check tensor properties like `dtype` and dimensions to ensure compatibility with your algorithms. For robot actions, verify that required pose components or joint values are present and within expected ranges.
Use early returns for edge cases where no processing is needed. Provide clear, descriptive error messages that include the expected vs. actual data types or shapes. This makes debugging much easier for users.
### 6. **Device and Dtype Awareness**
Design your processors to automatically adapt to the device and dtype of input tensors. Internal tensors (like normalization statistics) should match the input tensor's device and dtype to ensure compatibility with multi-GPU training, mixed precision, and distributed setups.
Implement a `to()` method that moves your processor's internal state to the specified device. Check device/dtype compatibility at runtime and automatically migrate internal state when needed. This pattern enables seamless operation across different hardware configurations without manual intervention.
## Conclusion
You now have all the tools to implement custom processors in LeRobot! The key steps are:
1. **Define your processor** as a dataclass with the required methods (`__call__`, `get_config`, `state_dict`, `load_state_dict`, `reset`, `transform_features`)
2. **Register it** using `@ProcessorStepRegistry.register("name")` for discoverability
3. **Integrate it** into a `DataProcessorPipeline` with other processing steps
4. **Use base classes** like `ObservationProcessorStep` when possible to reduce boilerplate
5. **Implement device/dtype awareness** to support multi-GPU and mixed precision setups
The processor system is designed to be modular and composable, allowing you to build complex data processing pipelines from simple, focused components. Whether you're preprocessing sensor data for training or post-processing model outputs for robot execution, custom processors give you the flexibility to handle any data transformation your robotics application requires.
Key principles for robust processors:
- **Device/dtype adaptation**: Internal tensors should match input tensors
- **Clear error messages**: Help users understand what went wrong
- **Base class usage**: Leverage specialized base classes to reduce boilerplate
- **Feature contracts**: Declare data structure changes with `transform_features()`
Start simple, test thoroughly, and ensure your processors work seamlessly across different hardware configurations!
docs/source/installation.mdx
+1 -1
View File
@@ -91,7 +91,7 @@ LeRobot provides optional extras for specific functionalities. Multiple extras c
### Simulations
Install environment packages: `aloha` ([gym-aloha](https://github.com/huggingface/gym-aloha)), or `pusht` ([gym-pusht](https://github.com/huggingface/gym-pusht))
Install environment packages: `aloha` ([gym-aloha](https://github.com/huggingface/gym-aloha)), `xarm` ([gym-xarm](https://github.com/huggingface/gym-xarm)), or `pusht` ([gym-pusht](https://github.com/huggingface/gym-pusht))
Example:
```bash
docs/source/integrate_hardware.mdx
+2 -130
View File
@@ -8,7 +8,7 @@ To that end, we provide the [`Robot`](https://github.com/huggingface/lerobot/blo
- Your own robot which exposes a communication interface (e.g. serial, CAN, TCP)
- A way to read sensor data and send motor commands programmatically, e.g. manufacturer's SDK or API, or your own protocol implementation.
- LeRobot installed in your environment. Follow our [Installation Guide](./installation).
- LeRobot installed in your environment. Follow our [Installation Guide](./installation.mdx).
## Choose your motors
@@ -65,7 +65,7 @@ class MyCoolRobotConfig(RobotConfig):
```
<!-- prettier-ignore-end -->
[Cameras tutorial](./cameras) to understand how to detect and add your camera.
[Cameras tutorial](./cameras.mdx) to understand how to detect and add your camera.
Next, we'll create our actual robot class which inherits from `Robot`. This abstract class defines a contract you must follow for your robot to be usable with the rest of the LeRobot tools.
@@ -335,134 +335,6 @@ For implementing teleoperation devices, we also provide a [`Teleoperator`](https
The main differences are in the I/O functions: a teleoperator allows you to produce action via `get_action` and can receive feedback actions via `send_feedback`. Feedback could be anything controllable on the teleoperation device that could help the person controlling it understand the consequences of the actions sent. Think motion/force feedback on a leader arm, vibrations on a gamepad controller for example. To implement a teleoperator, you can follow this same tutorial and adapt it for these two methods.
## Using Your Own `LeRobot` Devices 🔌
You can easily extend `lerobot` with your own custom hardware—be it a camera, robot, or teleoperation device—by creating a separate, installable Python package. If you follow a few simple conventions, the `lerobot` command-line tools (like `lerobot-teleop` and `lerobot-record`) will **automatically discover and integrate your creations** without requiring any changes to the `lerobot` source code.
This guide outlines the conventions your plugin must follow.
### The 4 Core Conventions
To ensure your custom device is discoverable, you must adhere to the following four rules.
#### 1\. Create an Installable Package with a Specific Prefix
Your project must be a standard, installable Python package. Crucially, the name of your package (as defined in `pyproject.toml` or `setup.py`) must begin with one of these prefixes:
- `lerobot_robot_` for a robot.
- `lerobot_camera_` for a camera.
- `lerobot_teleoperator_` for a teleoperation device.
This prefix system is how `lerobot` automatically finds your plugin in the Python environment.
#### 2\. Follow the `SomethingConfig`/`Something` Naming Pattern
Your device's implementation class must be named after its configuration class, simply by removing the `Config` suffix.
- **Config Class:** `MyAwesomeTeleopConfig`
- **Device Class:** `MyAwesomeTeleop`
#### 3\. Place Your Files in a Predictable Structure
The device class (`MyAwesomeTeleop`) must be located in a predictable module relative to its configuration class (`MyAwesomeTeleopConfig`). `lerobot` will automatically search in these locations:
- In the **same module** as the config class.
- In a **submodule named after the device** (e.g., `my_awesome_teleop.py`).
The recommended and simplest structure is to place them in separate, clearly named files within the same directory.
#### 4\. Expose Classes in `__init__.py`
Your package's `__init__.py` file should import and expose both the configuration and the device classes, making them easily accessible.
### Putting It All Together: A Complete Example
Let's create a new teleoperator called `my_awesome_teleop`.
#### Directory Structure
Here is what the project folder should look like. The package name, `lerobot_teleoperator_my_awesome_teleop`, follows **Convention \#1**.
```
lerobot_teleoperator_my_awesome_teleop/
├── pyproject.toml # (or setup.py) lists lerobot as a dependency
└── lerobot_teleoperator_my_awesome_teleop/
├── __init__.py
├── config_my_awesome_teleop.py
└── my_awesome_teleop.py
```
#### File Contents
- **`config_my_awesome_teleop.py`**: Defines the configuration class. Note the `Config` suffix (**Convention \#2**).
```python
from dataclasses import dataclass
from lerobot.teleoperators.config import TeleoperatorConfig
@TeleoperatorConfig.register_subclass("my_awesome_teleop")
@dataclass
class MyAwesomeTeleopConfig(TeleoperatorConfig):
# Your configuration fields go here
port: str = "192.168.1.1"
```
- **`my_awesome_teleop.py`**: Implements the device. The class name `MyAwesomeTeleop` matches its config class name (**Convention \#2**). This file structure adheres to **Convention \#3**.
```python
from lerobot.teleoperators.teleoperator import Teleoperator
from .config_my_awesome_teleop import MyAwesomeTeleopConfig
class MyAwesomeTeleop(Teleoperator):
config_class = MyAwesomeTeleopConfig
name = "my_awesome_teleop"
def __init__(self, config: MyAwesomeTeleopConfig):
super().__init__(config)
self.config = config
# Your device logic (e.g., connect) goes here
```
- **`__init__.py`**: Exposes the key classes (**Convention \#4**).
```python
from .config_my_awesome_teleop import MyAwesomeTeleopConfig
from .my_awesome_teleop import MyAwesomeTeleop
```
### Installation and Usage
1. **Install your new plugin in your Python environment.** You can install your local plugin package using `pip`'s editable mode or from PyPi.
```bash
# Locally
# Navigate to your plugin's root directory and install it
cd lerobot_teleoperator_my_awesome_teleop
pip install -e .
# From PyPi
pip install lerobot_teleoperator_my_awesome_teleop
```
2. **Use it directly from the command line.** Now, you can use your custom device by referencing its type.
```bash
lerobot-teleoperate --teleop.type=my_awesome_teleop \
# other arguments
```
And that's it\! Your custom device is now fully integrated.
### Looking for an example ?
Check out these two packages from the community:
- https://github.com/SpesRobotics/lerobot-robot-xarm
- https://github.com/SpesRobotics/lerobot-teleoperator-teleop
## Wrapping Up
Once your robot class is complete, you can leverage the LeRobot ecosystem:
docs/source/introduction_processors.mdx
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# Introduction to Processors
In robotics, there's a fundamental mismatch between the data that robots and humans produce and what machine learning models expect.
Robots output raw sensor data like camera images and joint positions that need normalization, batching, and device placement before models can process them.
Language instructions from humans must be tokenized into numerical representations, and different robots use different coordinate systems that need standardization.
The challenge extends to model outputs as well.
Models might output end-effector positions while robots need joint-space commands, or teleoperators produce relative movements while robots expect absolute commands.
Model predictions are often normalized and need conversion back to real-world scales.
Cross-domain translation adds another layer of complexity.
Training data from one robot setup needs adaptation for deployment on different hardware, models trained with specific camera configurations must work with new arrangements, and datasets with different naming conventions need harmonization.
**That's where processors come in.** They serve as universal translators that bridge these gaps, ensuring seamless data flow from sensors to models to actuators.
Processors handle all the preprocessing and postprocessing steps needed to convert raw environment data into model-ready inputs and vice versa.
This means that your favorite policy can be used like this:
```python
import torch
from lerobot.datasets.lerobot_dataset import LeRobotDataset
from lerobot.policies.factory import make_pre_post_processors
from lerobot.policies.your_policy import YourPolicy
from lerobot.processor.pipeline import RobotProcessorPipeline, PolicyProcessorPipeline
dataset = LeRobotDataset("hf_user/dataset", episodes=[0])
sample = dataset[10]
model = YourPolicy.from_pretrained(
"hf_user/model",
)
model.eval()
model.to("cuda")
preprocessor, postprocessor = make_pre_post_processors(model.config, pretrained_path="hf_user/model", dataset_stats=dataset.meta.stats)
preprocessed_sample = preprocessor(sample)
action = model.select_action(preprocessed_sample)
postprocessed_action = postprocessor(action)
```
## What are Processors?
In robotics, data comes in many forms: images from cameras, joint positions from sensors, text instructions from users, and more. Each type of data requires specific transformations before a model can use it effectively. Models need this data to be:
- **Normalized**: Scaled to appropriate ranges for neural network processing
- **Batched**: Organized with proper dimensions for batch processing
- **Tokenized**: Text converted to numerical representations
- **Device-placed**: Moved to the right hardware (CPU/GPU)
- **Type-converted**: Cast to appropriate data types
Processors handle these transformations through composable, reusable steps that can be chained together into pipelines. Think of them as a modular assembly line where each station performs a specific transformation on your data.
## Core Concepts
### EnvTransition: The Universal Data Container
The `EnvTransition` is the fundamental data structure that flows through all processors.
It's a typed dictionary that represents a complete robot-environment interaction:
- **OBSERVATION**: All sensor data (images, states, proprioception)
- **ACTION**: The action to execute or that was executed
- **REWARD**: Reinforcement learning signal
- **DONE/TRUNCATED**: Episode boundary indicators
- **INFO**: Arbitrary metadata
- **COMPLEMENTARY_DATA**: Task descriptions, indices, padding flags, inter-step data
### ProcessorStep: The Building Block
A `ProcessorStep` is a single transformation unit that processes transitions. It's an abstract base class with two required methods:
```python
from lerobot.processor import ProcessorStep, EnvTransition
class MyProcessorStep(ProcessorStep):
"""Example processor step - inherit and implement abstract methods."""
def __call__(self, transition: EnvTransition) -> EnvTransition:
"""Transform the transition - REQUIRED abstract method."""
# Your processing logic here
return transition
def transform_features(self, features):
"""Declare how this step transforms feature shapes/types - REQUIRED abstract method."""
return features # Most processors return features unchanged
```
`__call__` is the core of your processor step. It takes an `EnvTransition` and returns a modified `EnvTransition`.
`transform_features` is used to declare how this step transforms feature shapes/types.
### DataProcessorPipeline: The Generic Orchestrator
The `DataProcessorPipeline[TInput, TOutput]` chains multiple `ProcessorStep` instances together:
```python
from lerobot.processor import RobotProcessorPipeline, PolicyProcessorPipeline
# For robot hardware (unbatched data)
robot_processor = RobotProcessorPipeline[RobotAction, RobotAction](
steps=[step1, step2, step3],
name="robot_pipeline"
)
# For model training/inference (batched data)
policy_processor = PolicyProcessorPipeline[dict[str, Any], dict[str, Any]](
steps=[step1, step2, step3],
name="policy_pipeline"
)
```
## RobotProcessorPipeline vs PolicyProcessorPipeline
The key distinction is in the data structures they handle:
| Aspect | RobotProcessorPipeline | PolicyProcessorPipeline |
| --------------- | -------------------------------------------- | ---------------------------------------- |
| **Input** | `dict[str, Any]` - Individual robot values | `dict[str, Any]` - Batched tensors |
| **Output** | `dict[str, Any]` - Individual robot commands | `torch.Tensor` - Policy predictions |
| **Use Case** | Real-time robot control | Model training/inference |
| **Data Format** | Unbatched, heterogeneous | Batched, homogeneous |
| **Examples** | `{"joint_1": 0.5}` | `{"observation.state": tensor([[0.5]])}` |
**Use `RobotProcessorPipeline`** for robot hardware interfaces:
```python
# Robot data structures: dict[str, Any] for observations and actions
robot_obs: dict[str, Any] = {
"joint_1": 0.5, # Individual joint values
"joint_2": -0.3,
"camera_0": image_array # Raw camera data
}
robot_action: dict[str, Any] = {
"joint_1": 0.2, # Target joint positions
"joint_2": 0.1,
"gripper": 0.8
}
```
**Use `PolicyProcessorPipeline`** for model training and batch processing:
```python
# Policy data structures: batch dicts and tensors
policy_batch: dict[str, Any] = {
"observation.state": torch.tensor([[0.5, -0.3]]), # Batched states
"observation.images.camera0": torch.tensor(...), # Batched images
"action": torch.tensor([[0.2, 0.1, 0.8]]) # Batched actions
}
policy_action: torch.Tensor = torch.tensor([[0.2, 0.1, 0.8]]) # Model output tensor
```
## Converter Functions
LeRobot provides converter functions to bridge different data formats in `lerobot.processor.converters`. These functions handle the crucial translations between robot hardware data structures, policy model formats, and the internal `EnvTransition` representation that flows through processor pipelines.
| Category | Function | Description |
| ------------------------------ | ----------------------------- | ------------------------------- |
| **Robot Hardware Converters** | `robot_action_to_transition` | Robot dict → EnvTransition |
| | `observation_to_transition` | Robot obs → EnvTransition |
| | `transition_to_robot_action` | EnvTransition → Robot dict |
| **Policy/Training Converters** | `batch_to_transition` | Batch dict → EnvTransition |
| | `transition_to_batch` | EnvTransition → Batch dict |
| | `policy_action_to_transition` | Policy tensor → EnvTransition |
| | `transition_to_policy_action` | EnvTransition → Policy tensor |
| **Utilities** | `create_transition` | Build transitions with defaults |
| | `identity_transition` | Pass-through converter |
The key insight is that **robot hardware converters** work with individual values and dictionaries, while **policy/training converters** work with batched tensors and model outputs. The converter functions automatically handle the structural differences, so your processor steps can focus on the core transformations without worrying about data format compatibility.
## Processor Examples
The following examples demonstrate real-world processor configurations for policy training and inference.
Here is an example processor for policy training and inference:
```python
# Training data preprocessing (optimized order for GPU performance)
training_preprocessor = PolicyProcessorPipeline[dict[str, Any], dict[str, Any]](
steps=[
RenameObservationsProcessorStep(rename_map={}), # Standardize keys
AddBatchDimensionProcessorStep(), # Add batch dims
TokenizerProcessorStep(tokenizer_name="...", ...), # Tokenize language
DeviceProcessorStep(device="cuda"), # Move to GPU first
NormalizerProcessorStep(features=..., stats=...), # Normalize on GPU
]
)
# Model output postprocessing
training_postprocessor = PolicyProcessorPipeline[torch.Tensor, torch.Tensor](
steps=[
DeviceProcessorStep(device="cpu"), # Move to CPU
UnnormalizerProcessorStep(features=..., stats=...), # Denormalize
]
to_transition=policy_action_to_transition,
to_output=transition_to_policy_action,
)
```
### An interaction between a robot and a policy with processors
The most common real-world scenario combines both pipeline types robot hardware generates observations that need policy processing, and policy outputs need robot-compatible postprocessing:
```python
# Real deployment: Robot sensors → Model → Robot commands
with torch.no_grad():
while not done:
raw_obs = robot.get_observation() # dict[str, Any]
# Add your robot observation to policy observation processor
policy_input = policy_preprocessor(raw_obs) # Batched dict
policy_output = policy.select_action(policy_input) # Policy tensor
policy_action = policy_postprocessor(policy_output)
# Add your robot action to policy action processor
robot.send_action(policy_action)
```
## Feature Contracts: Shape and Type Transformation
Processors don't just transform data - they can also **change the data structure itself**. The `transform_features()` method declares these changes, which is crucial for dataset recording and policy creation.
### Why Feature Contracts Matter
When building datasets or policies, LeRobot needs to know:
- **What data fields will exist** after processing
- **What shapes and types** each field will have
- **How to configure models** for the expected data structure
```python
# Example: A processor that adds velocity to observations
class VelocityProcessor(ObservationProcessorStep):
def observation(self, obs):
new_obs = obs.copy()
if "observation.state" in obs:
# concatenate computed velocity field to the state
new_obs["observation.state"] = self._compute_velocity(obs["observation.state"])
return new_obs
def transform_features(self, features):
"""Declare the new velocity field we're adding."""
state_feature = features[PipelineFeatureType.OBSERVATION].get("observation.state")
if state_feature:
double_shape = (state_feature.shape[0] * 2,) if state_feature.shape else (2,)
features[PipelineFeatureType.OBSERVATION]["observation.state"] = PolicyFeature(
type=FeatureType.STATE, shape=double_shape
)
return features
```
### Feature Specification Functions
`create_initial_features()` and `aggregate_pipeline_dataset_features()` solve a critical dataset creation problem: determining the exact final data structure before any data is processed.
Since processor pipelines can add new features (like velocity fields), change tensor shapes (like cropping images), or rename keys, datasets need to know the complete output specification upfront to allocate proper storage and define schemas.
These functions work together by starting with robot hardware specifications (`create_initial_features()`) then simulating the entire pipeline transformation (`aggregate_pipeline_dataset_features()`) to compute the final feature dictionary that gets passed to `LeRobotDataset.create()`, ensuring perfect alignment between what processors output and what datasets expect to store.
```python
from lerobot.datasets.pipeline_features import aggregate_pipeline_dataset_features
# Start with robot's raw features
initial_features = create_initial_features(
observation=robot.observation_features, # {"joint_1.pos": float, "camera_0": (480,640,3)}
action=robot.action_features # {"joint_1.pos": float, "gripper.pos": float}
)
# Apply processor pipeline to compute final features
final_features = aggregate_pipeline_dataset_features(
pipeline=my_processor_pipeline,
initial_features=initial_features,
use_videos=True
)
# Use for dataset creation
dataset = LeRobotDataset.create(
repo_id="my_dataset",
features=final_features, # Knows exactly what data to expect
...
)
```
## Common Processor Steps
LeRobot provides many registered processor steps. Here are the most commonly used core processors:
### Essential Processors
- **`normalizer_processor`**: Normalize observations/actions using dataset statistics (mean/std or min/max)
- **`device_processor`**: Move tensors to CPU/GPU with optional dtype conversion
- **`to_batch_processor`**: Add batch dimensions to transitions for model compatibility
- **`rename_observations_processor`**: Rename observation keys using mapping dictionaries
- **`tokenizer_processor`**: Tokenize natural language task descriptions into tokens and attention masks
### Next Steps
- **[Implement Your Own Processor](./implement_your_own_processor)** - Create custom processor steps
- **[Debug Your Pipeline](./debug_processor_pipeline)** - Troubleshoot and optimize pipelines
- **[Processors for Robots and Teleoperators](./processors_robots_teleop)** - Real-world integration patterns
## Summary
Processors solve the data translation problem in robotics by providing:
- **Modular transformations**: Composable, reusable processing steps
- **Type safety**: Generic pipelines with compile-time checking
- **Performance optimization**: GPU-accelerated operations
- **Robot/Policy distinction**: Separate pipelines for different data structures
- **Comprehensive ecosystem**: 30+ registered processors for common tasks
The key insight: `RobotProcessorPipeline` handles unbatched robot hardware data, while `PolicyProcessorPipeline` handles batched model data. Choose the right tool for your data structure!
docs/source/koch.mdx
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@@ -277,7 +277,7 @@ leader.disconnect()
</hfoption>
</hfoptions>
Congrats 🎉, your robot is all set to learn a task on its own. Start training it by following this tutorial: [Getting started with real-world robots](./il_robots)
Congrats 🎉, your robot is all set to learn a task on its own. Start training it by following this tutorial: [Getting started with real-world robots](./getting_started_real_world_robot)
> [!TIP]
> If you have any questions or need help, please reach out on [Discord](https://discord.com/invite/s3KuuzsPFb).
docs/source/lekiwi.mdx
+1 -1
View File
@@ -323,7 +323,7 @@ To replay an episode run the API example below, make sure to change `remote_ip`,
python examples/lekiwi/replay.py
```
Congrats 🎉, your robot is all set to learn a task on its own. Start training it by the training part of this tutorial: [Getting started with real-world robots](./il_robots)
Congrats 🎉, your robot is all set to learn a task on its own. Start training it by the training part of this tutorial: [Getting started with real-world robots](./getting_started_real_world_robot)
## Evaluate your policy
docs/source/lerobot-dataset-v3.mdx
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# LeRobotDataset v3.0
`LeRobotDataset v3.0` is a standardized format for robot learning data. It provides unified access to multi-modal time-series data, sensorimotor signals and multicamera video, as well as rich metadata for indexing, search, and visualization on the Hugging Face Hub.
This docs will guide you to:
- Understand the v3.0 design and directory layout
- Record a dataset and push it to the Hub
- Load datasets for training with `LeRobotDataset`
- Stream datasets without downloading using `StreamingLeRobotDataset`
- Apply image transforms for data augmentation during training
- Migrate existing `v2.1` datasets to `v3.0`
## Whats new in `v3`
- **File-based storage**: Many episodes per Parquet/MP4 file (v2 used one file per episode).
- **Relational metadata**: Episode boundaries and lookups are resolved through metadata, not filenames.
- **Hub-native streaming**: Consume datasets directly from the Hub with `StreamingLeRobotDataset`.
- **Lower file-system pressure**: Fewer, larger files ⇒ faster initialization and fewer issues at scale.
- **Unified organization**: Clean directory layout with consistent path templates across data and videos.
## Installation
`LeRobotDataset v3.0` will be included in `lerobot >= 0.4.0`.
Until that stable release, you can use the main branch by following the [build from source instructions](./installation#from-source).
## Record a dataset
Run the command below to record a dataset with the SO-101 and push to the Hub:
```bash
lerobot-record \
--robot.type=so101_follower \
--robot.port=/dev/tty.usbmodem585A0076841 \
--robot.id=my_awesome_follower_arm \
--robot.cameras="{ front: {type: opencv, index_or_path: 0, width: 1920, height: 1080, fps: 30}}" \
--teleop.type=so101_leader \
--teleop.port=/dev/tty.usbmodem58760431551 \
--teleop.id=my_awesome_leader_arm \
--display_data=true \
--dataset.repo_id=${HF_USER}/record-test \
--dataset.num_episodes=5 \
--dataset.single_task="Grab the black cube"
```
See the [recording guide](./il_robots#record-a-dataset) for more details.
## Format design
A core v3 principle is **decoupling storage from the user API**: data is stored efficiently (few large files), while the public API exposes intuitive episode-level access.
`v3` has three pillars:
1. **Tabular data**: Lowdimensional, highfrequency signals (states, actions, timestamps) stored in **Apache Parquet**. Access is memorymapped or streamed via the `datasets` stack.
2. **Visual data**: Camera frames concatenated and encoded into **MP4**. Frames from the same episode are grouped; videos are sharded per camera for practical sizes.
3. **Metadata**: JSON/Parquet records describing schema (feature names, dtypes, shapes), frame rates, normalization stats, and **episode segmentation** (start/end offsets into shared Parquet/MP4 files).
> To scale to millions of episodes, tabular rows and video frames from multiple episodes are **concatenated** into larger files. Episodespecific views are reconstructed **via metadata**, not file boundaries.
<div style="display:flex; justify-content:center; gap:12px; flex-wrap:wrap;">
<figure style="margin:0; text-align:center;">
<img
src="https://huggingface.co/datasets/huggingface/documentation-images/resolve/main/lerobotdataset-v3/asset1datasetv3.png"
alt="LeRobotDataset v3 diagram"
width="220"
/>
<figcaption style="font-size:0.9em; color:#666;">
From episodebased to filebased datasets
</figcaption>
</figure>
</div>
### Directory layout (simplified)
- **`meta/info.json`**: canonical schema (features, shapes/dtypes), FPS, codebase version, and **path templates** to locate data/video shards.
- **`meta/stats.json`**: global feature statistics (mean/std/min/max) used for normalization; exposed as `dataset.meta.stats`.
- **`meta/tasks.jsonl`**: naturallanguage task descriptions mapped to integer IDs for taskconditioned policies.
- **`meta/episodes/`**: perepisode records (lengths, tasks, offsets) stored as **chunked Parquet** for scalability.
- **`data/`**: framebyframe **Parquet** shards; each file typically contains **many episodes**.
- **`videos/`**: **MP4** shards per camera; each file typically contains **many episodes**.
## Load a dataset for training
`LeRobotDataset` returns Python dictionaries of PyTorch tensors and integrates with `torch.utils.data.DataLoader`. Here is a code example showing its use:
```python
import torch
from lerobot.datasets.lerobot_dataset import LeRobotDataset
repo_id = "yaak-ai/L2D-v3"
# 1) Load from the Hub (cached locally)
dataset = LeRobotDataset(repo_id)
# 2) Random access by index
sample = dataset[100]
print(sample)
# {
# 'observation.state': tensor([...]),
# 'action': tensor([...]),
# 'observation.images.front_left': tensor([C, H, W]),
# 'timestamp': tensor(1.234),
# ...
# }
# 3) Temporal windows via delta_timestamps (seconds relative to t)
delta_timestamps = {
"observation.images.front_left": [-0.2, -0.1, 0.0] # 0.2s and 0.1s before current frame
}
dataset = LeRobotDataset(repo_id, delta_timestamps=delta_timestamps)
# Accessing an index now returns a stack for the specified key(s)
sample = dataset[100]
print(sample["observation.images.front_left"].shape) # [T, C, H, W], where T=3
# 4) Wrap with a DataLoader for training
batch_size = 16
data_loader = torch.utils.data.DataLoader(dataset, batch_size=batch_size)
device = "cuda" if torch.cuda.is_available() else "cpu"
for batch in data_loader:
observations = batch["observation.state"].to(device)
actions = batch["action"].to(device)
images = batch["observation.images.front_left"].to(device)
# model.forward(batch)
```
## Stream a dataset (no downloads)
Use `StreamingLeRobotDataset` to iterate directly from the Hub without local copies. This allows to stream large datasets without the need to downloading them onto disk or loading them onto memory, and is a key feature of the new dataset format.
```python
from lerobot.datasets.streaming_dataset import StreamingLeRobotDataset
repo_id = "yaak-ai/L2D-v3"
dataset = StreamingLeRobotDataset(repo_id) # streams directly from the Hub
```
<div style="display:flex; justify-content:center; gap:12px; flex-wrap:wrap;">
<figure style="margin:0; text-align:center;">
<img
src="https://huggingface.co/datasets/huggingface/documentation-images/resolve/main/lerobotdataset-v3/streaming-lerobot.png"
alt="StreamingLeRobotDataset"
width="520"
/>
<figcaption style="font-size:0.9em; color:#666;">
Stream directly from the Hub for onthefly training.
</figcaption>
</figure>
</div>
## Image transforms
Image transforms are data augmentations applied to camera frames during training to improve model robustness and generalization. LeRobot supports various transforms including brightness, contrast, saturation, hue, and sharpness adjustments.
### Using transforms during dataset creation/recording
Currently, transforms are applied during **training time only**, not during recording. When you create or record a dataset, the raw images are stored without transforms. This allows you to experiment with different augmentations later without re-recording data.
### Adding transforms to existing datasets (API)
Use the `image_transforms` parameter when loading a dataset for training:
```python
from lerobot.datasets.lerobot_dataset import LeRobotDataset
from lerobot.datasets.transforms import ImageTransforms, ImageTransformsConfig, ImageTransformConfig
# Option 1: Use default transform configuration (disabled by default)
transforms_config = ImageTransformsConfig(
enable=True, # Enable transforms
max_num_transforms=3, # Apply up to 3 transforms per frame
random_order=False, # Apply in standard order
)
transforms = ImageTransforms(transforms_config)
dataset = LeRobotDataset(
repo_id="your-username/your-dataset",
image_transforms=transforms
)
# Option 2: Create custom transform configuration
custom_transforms_config = ImageTransformsConfig(
enable=True,
max_num_transforms=2,
random_order=True,
tfs={
"brightness": ImageTransformConfig(
weight=1.0,
type="ColorJitter",
kwargs={"brightness": (0.7, 1.3)} # Adjust brightness range
),
"contrast": ImageTransformConfig(
weight=2.0, # Higher weight = more likely to be selected
type="ColorJitter",
kwargs={"contrast": (0.8, 1.2)}
),
"sharpness": ImageTransformConfig(
weight=0.5, # Lower weight = less likely to be selected
type="SharpnessJitter",
kwargs={"sharpness": (0.3, 2.0)}
),
}
)
dataset = LeRobotDataset(
repo_id="your-username/your-dataset",
image_transforms=ImageTransforms(custom_transforms_config)
)
# Option 3: Use pure torchvision transforms
from torchvision.transforms import v2
torchvision_transforms = v2.Compose([
v2.ColorJitter(brightness=0.2, contrast=0.2, saturation=0.2, hue=0.1),
v2.GaussianBlur(kernel_size=3, sigma=(0.1, 2.0)),
])
dataset = LeRobotDataset(
repo_id="your-username/your-dataset",
image_transforms=torchvision_transforms
)
```
### Available transform types
LeRobot provides several transform types:
- **`ColorJitter`**: Adjusts brightness, contrast, saturation, and hue
- **`SharpnessJitter`**: Randomly adjusts image sharpness
- **`Identity`**: No transformation (useful for testing)
You can also use any `torchvision.transforms.v2` transform by passing it directly to the `image_transforms` parameter.
### Configuration options
- **`enable`**: Enable/disable transforms (default: `False`)
- **`max_num_transforms`**: Maximum number of transforms applied per frame (default: `3`)
- **`random_order`**: Apply transforms in random order vs. standard order (default: `False`)
- **`weight`**: Sampling probability for each transform (higher = more likely, if sum of weights is not 1, they will be normalized)
- **`kwargs`**: Transform-specific parameters (e.g., brightness range)
### Visualizing transforms
Use the visualization script to preview how transforms affect your data:
```bash
lerobot-imgtransform-viz \
--repo-id=your-username/your-dataset \
--output-dir=./transform_examples \
--n-examples=5
```
This saves example images showing the effect of each transform, helping you tune parameters.
### Best practices
- **Start conservative**: Begin with small ranges (e.g., brightness 0.9-1.1) and increase gradually
- **Test first**: Use the visualization script to ensure transforms look reasonable
- **Monitor training**: Strong augmentations can hurt performance if too aggressive
- **Match your domain**: If your robot operates in varying lighting, use brightness/contrast transforms
- **Combine wisely**: Using too many transforms simultaneously can make training unstable
## Migrate `v2.1` → `v3.0`
A converter aggregates perepisode files into larger shards and writes episode offsets/metadata. Convert your dataset using the instructions below.
```bash
# Pre-release build with v3 support:
pip install "https://github.com/huggingface/lerobot/archive/33cad37054c2b594ceba57463e8f11ee374fa93c.zip"
# Convert an existing v2.1 dataset hosted on the Hub:
python -m lerobot.datasets.v30.convert_dataset_v21_to_v30 --repo-id=<HF_USER/DATASET_ID>
```
**What it does**
- Aggregates parquet files: `episode-0000.parquet`, `episode-0001.parquet`, … → **`file-0000.parquet`**, …
- Aggregates mp4 files: `episode-0000.mp4`, `episode-0001.mp4`, … → **`file-0000.mp4`**, …
- Updates `meta/episodes/*` (chunked Parquet) with perepisode lengths, tasks, and byte/frame offsets.
## Common Issues
### Always call `finalize()` before pushing
When creating or recording datasets, you **must** call `dataset.finalize()` to properly close parquet writers. See the [PR #1903](https://github.com/huggingface/lerobot/pull/1903) for more details.
```python
from lerobot.datasets.lerobot_dataset import LeRobotDataset
# Create dataset and record episodes
dataset = LeRobotDataset.create(...)
for episode in range(num_episodes):
# Record frames
for frame in episode_data:
dataset.add_frame(frame)
dataset.save_episode()
# Call finalize() when done recording and before push_to_hub()
dataset.finalize() # Closes parquet writers, writes metadata footers
dataset.push_to_hub()
```
**Why is this necessary?**
Dataset v3.0 uses incremental parquet writing with buffered metadata for efficiency. The `finalize()` method:
- Flushes any buffered episode metadata to disk
- Closes parquet writers to write footer metadata, otherwise the parquet files will be corrupt
- Ensures the dataset is valid for loading
Without calling `finalize()`, your parquet files will be incomplete and the dataset won't load properly.
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# LIBERO
**LIBERO** is a benchmark designed to study **lifelong robot learning**. The idea is that robots wont just be pretrained once in a factory, theyll need to keep learning and adapting with their human users over time. This ongoing adaptation is called **lifelong learning in decision making (LLDM)**, and its a key step toward building robots that become truly personalized helpers.
- 📄 [LIBERO paper](https://arxiv.org/abs/2306.03310)
- 💻 [Original LIBERO repo](https://github.com/Lifelong-Robot-Learning/LIBERO)
To make progress on this challenge, LIBERO provides a set of standardized tasks that focus on **knowledge transfer**: how well a robot can apply what it has already learned to new situations. By evaluating on LIBERO, different algorithms can be compared fairly and researchers can build on each others work.
LIBERO includes **five task suites**:
- **LIBERO-Spatial (`libero_spatial`)** tasks that require reasoning about spatial relations.
- **LIBERO-Object (`libero_object`)** tasks centered on manipulating different objects.
- **LIBERO-Goal (`libero_goal`)** goal-conditioned tasks where the robot must adapt to changing targets.
- **LIBERO-90 (`libero_90`)** 90 short-horizon tasks from the LIBERO-100 collection.
- **LIBERO-Long (`libero_10`)** 10 long-horizon tasks from the LIBERO-100 collection.
Together, these suites cover **130 tasks**, ranging from simple object manipulations to complex multi-step scenarios. LIBERO is meant to grow over time, and to serve as a shared benchmark where the community can test and improve lifelong learning algorithms.
![An overview of the LIBERO benchmark](https://libero-project.github.io/assets/img/libero/fig1.png)
## Evaluating with LIBERO
At **LeRobot**, we ported [LIBERO](https://github.com/Lifelong-Robot-Learning/LIBERO) into our framework and used it mainly to **evaluate [SmolVLA](https://huggingface.co/docs/lerobot/en/smolvla)**, our lightweight Vision-Language-Action model.
LIBERO is now part of our **multi-eval supported simulation**, meaning you can benchmark your policies either on a **single suite of tasks** or across **multiple suites at once** with just a flag.
To Install LIBERO, after following LeRobot official instructions, just do:
`pip install -e ".[libero]"`
### Single-suite evaluation
Evaluate a policy on one LIBERO suite:
```bash
lerobot-eval \
--policy.path="your-policy-id" \
--env.type=libero \
--env.task=libero_object \
--eval.batch_size=2 \
--eval.n_episodes=3
```
- `--env.task` picks the suite (`libero_object`, `libero_spatial`, etc.).
- `--eval.batch_size` controls how many environments run in parallel.
- `--eval.n_episodes` sets how many episodes to run in total.
---
### Multi-suite evaluation
Benchmark a policy across multiple suites at once:
```bash
lerobot-eval \
--policy.path="your-policy-id" \
--env.type=libero \
--env.task=libero_object,libero_spatial \
--eval.batch_size=1 \
--eval.n_episodes=2
```
- Pass a comma-separated list to `--env.task` for multi-suite evaluation.
### Policy inputs and outputs
When using LIBERO through LeRobot, policies interact with the environment via **observations** and **actions**:
- **Observations**
- `observation.state` proprioceptive features (agent state).
- `observation.images.image` main camera view (`agentview_image`).
- `observation.images.image2` wrist camera view (`robot0_eye_in_hand_image`).
⚠️ **Note:** LeRobot enforces the `.images.*` prefix for any multi-modal visual features. Always ensure that your policy config `input_features` use the same naming keys, and that your dataset metadata keys follow this convention during evaluation.
If your data contains different keys, you must rename the observations to match what the policy expects, since naming keys are encoded inside the normalization statistics layer.
This will be fixed with the upcoming Pipeline PR.
- **Actions**
- Continuous control values in a `Box(-1, 1, shape=(7,))` space.
We also provide a notebook for quick testing:
Training with LIBERO
## Training with LIBERO
When training on LIBERO tasks, make sure your dataset parquet and metadata keys follow the LeRobot convention.
The environment expects:
- `observation.state` → 8-dim agent state
- `observation.images.image` → main camera (`agentview_image`)
- `observation.images.image2` → wrist camera (`robot0_eye_in_hand_image`)
⚠️ Cleaning the dataset upfront is **cleaner and more efficient** than remapping keys inside the code.
To avoid potential mismatches and key errors, we provide a **preprocessed LIBERO dataset** that is fully compatible with the current LeRobot codebase and requires no additional manipulation:
👉 [HuggingFaceVLA/libero](https://huggingface.co/datasets/HuggingFaceVLA/libero)
For reference, here is the **original dataset** published by Physical Intelligence:
👉 [physical-intelligence/libero](https://huggingface.co/datasets/physical-intelligence/libero)
---
### Example training command
```bash
lerobot-train \
--policy.type=smolvla \
--policy.repo_id=${HF_USER}/libero-test \
--policy.load_vlm_weights=true \
--dataset.repo_id=HuggingFaceVLA/libero \
--env.type=libero \
--env.task=libero_10 \
--output_dir=./outputs/ \
--steps=100000 \
--batch_size=4 \
--eval.batch_size=1 \
--eval.n_episodes=1 \
--eval_freq=1000 \
```
---
### Note on rendering
LeRobot uses MuJoCo for simulation. You need to set the rendering backend before training or evaluation:
- `export MUJOCO_GL=egl` → for headless servers (e.g. HPC, cloud)
## Reproducing π₀.₅ results
We reproduce the results of π₀.₅ on the LIBERO benchmark using the LeRobot implementation. We take the Physical Intelligence LIBERO base model (`pi05_libero`) and finetune for an additional 6k steps in bfloat16, with batch size of 256 on 8 H100 GPUs using the [HuggingFace LIBERO dataset](https://huggingface.co/datasets/HuggingFaceVLA/libero).
The finetuned model can be found here:
- **π₀.₅ LIBERO**: [lerobot/pi05_libero_finetuned](https://huggingface.co/lerobot/pi05_libero_finetuned)
We then evaluate the finetuned model using the LeRobot LIBERO implementation, by running the following command:
```bash
lerobot-eval \
--output_dir=/logs/ \
--env.type=libero \
--env.task=libero_spatial,libero_object,libero_goal,libero_10 \
--eval.batch_size=1 \
--eval.n_episodes=10 \
--policy.path=pi05_libero_finetuned \
--policy.n_action_steps=10 \
--output_dir=./eval_logs/ \
--env.max_parallel_tasks=1
```
**Note:** We set `n_action_steps=10`, similar to the original OpenPI implementation.
### Results
We obtain the following results on the LIBERO benchmark:
| Model | LIBERO Spatial | LIBERO Object | LIBERO Goal | LIBERO 10 | Average |
| -------- | -------------- | ------------- | ----------- | --------- | -------- |
| **π₀.₅** | 97.0 | 99.0 | 98.0 | 96.0 | **97.5** |
These results are consistent with the original [results](https://github.com/Physical-Intelligence/openpi/tree/main/examples/libero#results) reported by Physical Intelligence:
| Model | LIBERO Spatial | LIBERO Object | LIBERO Goal | LIBERO 10 | Average |
| -------- | -------------- | ------------- | ----------- | --------- | --------- |
| **π₀.₅** | 98.8 | 98.2 | 98.0 | 92.4 | **96.85** |
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# Meta-World
Meta-World is a well-designed, open-source simulation benchmark for multi-task and meta reinforcement learning in continuous-control robotic manipulation. It gives researchers a shared, realistic playground to test whether algorithms can _learn many different tasks_ and _generalize quickly to new ones_ — two central challenges for real-world robotics.
- 📄 [MetaWorld paper](https://arxiv.org/pdf/1910.10897)
- 💻 [Original MetaWorld repo](https://github.com/Farama-Foundation/Metaworld)
![MetaWorld MT10 demo](https://meta-world.github.io/figures/ml45.gif)
## Why Meta-World matters
- **Diverse, realistic tasks.** Meta-World bundles a large suite of simulated manipulation tasks (50 in the MT50 suite) using everyday objects and a common tabletop Sawyer arm. This diversity exposes algorithms to a wide variety of dynamics, contacts and goal specifications while keeping a consistent control and observation structure.
- **Focus on generalization and multi-task learning.** By evaluating across task distributions that share structure but differ in goals and objects, Meta-World reveals whether an agent truly learns transferable skills rather than overfitting to a narrow task.
- **Standardized evaluation protocol.** It provides clear evaluation modes and difficulty splits, so different methods can be compared fairly across easy, medium, hard and very-hard regimes.
- **Empirical insight.** Past evaluations on Meta-World show impressive progress on some fronts, but also highlight that current multi-task and meta-RL methods still struggle with large, diverse task sets. That gap points to important research directions.
## What it enables in LeRobot
In LeRobot, you can evaluate any policy or vision-language-action (VLA) model on Meta-World tasks and get a clear success-rate measure. The integration is designed to be straightforward:
- We provide a LeRobot-ready dataset for Meta-World (MT50) on the HF Hub: `https://huggingface.co/datasets/lerobot/metaworld_mt50`.
- This dataset is formatted for the MT50 evaluation that uses all 50 tasks (the most challenging multi-task setting).
- MT50 gives the policy a one-hot task vector and uses fixed object/goal positions for consistency.
- Task descriptions and the exact keys required for evaluation are available in the repo/dataset — use these to ensure your policy outputs the right success signals.
## Quick start, train a SmolVLA policy on Meta-World
Example command to train a SmolVLA policy on a subset of tasks:
```bash
lerobot-train \
--policy.type=smolvla \
--policy.repo_id=${HF_USER}/metaworld-test \
--policy.load_vlm_weights=true \
--dataset.repo_id=lerobot/metaworld_mt50 \
--env.type=metaworld \
--env.task=assembly-v3,dial-turn-v3,handle-press-side-v3 \
--output_dir=./outputs/ \
--steps=100000 \
--batch_size=4 \
--eval.batch_size=1 \
--eval.n_episodes=1 \
--eval_freq=1000
```
Notes:
- `--env.task` accepts explicit task lists (comma separated) or difficulty groups (e.g., `env.task="hard"`).
- Adjust `batch_size`, `steps`, and `eval_freq` to match your compute budget.
- **Gymnasium Assertion Error**: if you encounter an error like
`AssertionError: ['human', 'rgb_array', 'depth_array']` when running MetaWorld environments, this comes from a mismatch between MetaWorld and your Gymnasium version.
We recommend using:
```bash
pip install "gymnasium==1.1.0"
```
to ensure proper compatibility.
## Quick start — evaluate a trained policy
To evaluate a trained policy on the Meta-World medium difficulty split:
```bash
lerobot-eval \
--policy.path="your-policy-id" \
--env.type=metaworld \
--env.task=medium \
--eval.batch_size=1 \
--eval.n_episodes=2
```
This will run episodes and return per-task success rates using the standard Meta-World evaluation keys.
## Practical tips
- If you care about generalization, run on the full MT50 suite — its intentionally challenging and reveals strengths/weaknesses better than a few narrow tasks.
- Use the one-hot task conditioning for multi-task training (MT10 / MT50 conventions) so policies have explicit task context.
- Inspect the dataset task descriptions and the `info["is_success"]` keys when writing post-processing or logging so your success metrics line up with the benchmark.
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# Phone
Use your phone (iOS or Android) to control your robot.
**In this guide you'll learn:**
- How to connect an iOS/Android phone
- How phone pose is mapped to robot endeffector (EE) targets
- How to tweak safety limits, gripper control, and IK settings
To use phone to control your robot, install the relevant dependencies with:
```bash
pip install lerobot[phone]
```
## Get started
### Supported platforms
- iOS: Uses the HEBI Mobile I/O app (ARKit pose + buttons). Download the app first, open it and the examples will discover it on your network and stream the phone pose and inputs.
- Android: Uses the `teleop` package (WebXR). When you start the Python process, it prints a local URL. Open the link on your phone, tap Start, then use Move to stream pose.
Links:
- Android WebXR library: [`teleop` on PyPI](https://pypi.org/project/teleop/)
- iOS app: [HEBI Mobile I/O](https://docs.hebi.us/tools.html#mobile-io)
### Phone orientation and controls
- Orientation: hold the phone with the screen facing up and the top edge pointing in the same direction as the robot gripper. This ensures calibration aligns the phones frame with the robot frame so motion feels natural, see the image below for reference.
- Enable/disable:
- iOS: Hold `B1` to enable teleoperation, release to stop. The first press captures a reference pose.
- Android: Press and hold the `Move` button, release to stop. The first press captures a reference pose.
- Gripper control:
- iOS: Analog input `A3` controls the gripper as velocity input.
- Android: Buttons `A` and `B` act like increment/decrement (A opens, B closes). You can tune velocity in the `GripperVelocityToJoint` step.
<img src="https://huggingface.co/datasets/huggingface/documentation-images/resolve/main/lerobot/phone_teleop.webp" alt="Phone teleop orientation" title="Phone teleop orientation" width="40%">
### Step 1: Choose the platform
Modify the examples to use `PhoneOS.IOS` or `PhoneOS.ANDROID` in `PhoneConfig`. The API is identical across platforms, only the input source differs. All examples are under `examples/` and have `phone_so100_*.py` variants.
Teleoperation example:
```36:43:examples/phone_so100_teleop.py
from lerobot.teleoperators.phone.config_phone import PhoneConfig, PhoneOS
teleop_config = PhoneConfig(phone_os=PhoneOS.IOS) # or PhoneOS.ANDROID
teleop_device = Phone(teleop_config)
```
### Step 2: Connect and calibrate
When `Phone(teleop_config)` is created and `connect()` is called, calibration is prompted automatically. Hold the phone in the orientation described above, then:
- iOS: press and hold `B1` to capture the reference pose.
- Android: press `Move` button on the WebXR page to capture the reference pose.
Why calibrate? We capture the current pose so subsequent poses are expressed in a robot aligned frame. When you again press the button to enable control, the position is recaptured to avoid drift when your phone is repositioned while it was disabled.
### Step 3: Run an example
Run on of the examples scripts to teleoperate, record a dataset, replay a dataset or evaluate a policy.
All scripts assume you configured your robot (e.g., SO-100 follower) and set the correct serial port.
Additionally you need to **copy the urdf of the robot to the examples folder**. For the examples in this tutorial (Using SO100/SO101) it is highly recommended to use the urdf in the [SO-ARM100 repo](https://github.com/TheRobotStudio/SO-ARM100/blob/main/Simulation/SO101/so101_new_calib.urdf)
- Run this example to teleoperate:
```bash
python examples/phone_to_so100/teleoperate.py
```
After running the example:
- Android: after starting the script, open the printed local URL on your phone, tap Start, then press and hold Move.
- iOS: open HEBI Mobile I/O first; B1 enables motion. A3 controls the gripper.
Additionally you can customize mapping or safety limits by editing the processor steps shown in the examples. You can also remap inputs (e.g., use a different analog input) or adapt the pipeline to other robots (e.g., LeKiwi) by modifying the input and kinematics steps. More about this in the [Processors for Robots and Teleoperators](./processors_robots_teleop) guide.
- Run this example to record a dataset, which saves absolute end effector observations and actions:
```bash
python examples/phone_to_so100/record.py
```
- Run this example to replay recorded episodes:
```bash
python examples/phone_to_so100/replay.py
```
- Run this example to evaluate a pretrained policy:
```bash
python examples/phone_to_so100/evaluate.py
```
### Important pipeline steps and options
- Kinematics are used in multiple steps. We use [Placo](https://github.com/Rhoban/placo) which is a wrapper around Pinocchio for handling our kinematics. We construct the kinematics object by passing the robot's URDF and target frame. We set `target_frame_name` to the gripper frame.
```examples/phone_to_so100/teleoperate.py
kinematics_solver = RobotKinematics(
urdf_path="./SO101/so101_new_calib.urdf",
target_frame_name="gripper_frame_link",
joint_names=list(robot.bus.motors.keys()),
)
```
- The `MapPhoneActionToRobotAction` step converts the calibrated phone pose and inputs into target deltas and gripper commands, below is shown what the step outputs.
```src/lerobot/teleoperators/phone/phone_processor.py
action["enabled"] = enabled
action["target_x"] = -pos[1] if enabled else 0.0
action["target_y"] = pos[0] if enabled else 0.0
action["target_z"] = pos[2] if enabled else 0.0
action["target_wx"] = rotvec[1] if enabled else 0.0
action["target_wy"] = rotvec[0] if enabled else 0.0
action["target_wz"] = -rotvec[2] if enabled else 0.0
action["gripper_vel"] = gripper_vel # Still send gripper action when disabled
```
- The `EEReferenceAndDelta` step converts target deltas to an absolute desired EE pose, storing a reference on enable, the `end_effector_step_sizes` are the step sizes for the EE pose and can be modified to change the motion speed.
```examples/phone_to_so100/teleoperate.py
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,
),
```
- The `EEBoundsAndSafety` step clamps EE motion to a workspace and checks for large ee step jumps to ensure safety. The `end_effector_bounds` are the bounds for the EE pose and can be modified to change the workspace. The `max_ee_step_m` are the step limits for the EE pose and can be modified to change the safety limits.
```examples/phone_to_so100/teleoperate.py
EEBoundsAndSafety(
end_effector_bounds={"min": [-1.0, -1.0, -1.0], "max": [1.0, 1.0, 1.0]},
max_ee_step_m=0.10,
)
```
- The `GripperVelocityToJoint` step turns a velocitylike gripper input into absolute gripper position using the current measured state. The `speed_factor` is the factor by which the velocity is multiplied.
```examples/phone_to_so100/teleoperate.py
GripperVelocityToJoint(speed_factor=20.0)
```
#### Different IK initial guesses
We use different IK initial guesses in the kinematic steps. As initial guess either the current measured joints or the previous IK solution is used.
- Closed loop (used in record/eval): sets `initial_guess_current_joints=True` so IK starts from the measured joints each frame.
```examples/phone_to_so100/record.py
InverseKinematicsEEToJoints(
kinematics=kinematics_solver,
motor_names=list(robot.bus.motors.keys()),
initial_guess_current_joints=True, # closed loop
)
```
- Open loop (used in replay): sets `initial_guess_current_joints=False` so IK continues from the previous IK solution rather than the measured state. This preserves action stability when we replay without feedback.
```examples/phone_to_so100/replay.py
InverseKinematicsEEToJoints(
kinematics=kinematics_solver,
motor_names=list(robot.bus.motors.keys()),
initial_guess_current_joints=False, # open loop
)
```
### Pipeline steps explained
- MapPhoneActionToRobotAction: converts calibrated phone pose and inputs into target deltas and a gripper command. Motion is gated by an enable signal (B1 on iOS, Move on Android).
- EEReferenceAndDelta: latches a reference EE pose on enable and combines it with target deltas to produce an absolute desired EE pose each frame. When disabled, it keeps sending the last commanded pose.
- EEBoundsAndSafety: clamps the EE pose to a workspace and ratelimits jumps for safety. Also declares `action.ee.*` features.
- InverseKinematicsEEToJoints: turns an EE pose into joint positions with IK. `initial_guess_current_joints=True` is recommended for closedloop control; set `False` for openloop replay for stability.
- GripperVelocityToJoint: integrates a velocitylike gripper input into an absolute gripper position using the current measured state.
- ForwardKinematicsJointsToEE: computes `observation.state.ee.*` from observed joints for logging and training on EE state.
### Troubleshooting
- iOS not discovered: ensure HEBI Mobile I/O is open and your laptop/phone are on the same network.
- Android URL not reachable: check local you used `https` instead of `http`, use the exact IP printed by the script and allow your browser to enter and ignore the certificate issue.
- Motion feels inverted: adjust the sign flips in `MapPhoneActionToRobotAction` or swap axes to match your setup.
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# π₀ (Pi0)
π₀ is a **Vision-Language-Action model for general robot control**, from Physical Intelligence. The LeRobot implementation is adapted from their open source [OpenPI](https://github.com/Physical-Intelligence/openpi) repository.
## Model Overview
π₀ represents a breakthrough in robotics as the first general-purpose robot foundation model developed by [Physical Intelligence](https://www.physicalintelligence.company/blog/pi0). Unlike traditional robot programs that are narrow specialists programmed for repetitive motions, π₀ is designed to be a generalist policy that can understand visual inputs, interpret natural language instructions, and control a variety of different robots across diverse tasks.
### The Vision for Physical Intelligence
As described by Physical Intelligence, while AI has achieved remarkable success in digital domains, from chess-playing to drug discovery, human intelligence still dramatically outpaces AI in the physical world. To paraphrase Moravec's paradox, winning a game of chess represents an "easy" problem for AI, but folding a shirt or cleaning up a table requires solving some of the most difficult engineering problems ever conceived. π₀ represents a first step toward developing artificial physical intelligence that enables users to simply ask robots to perform any task they want, just like they can with large language models.
### Architecture and Approach
π₀ combines several key innovations:
- **Flow Matching**: Uses a novel method to augment pre-trained VLMs with continuous action outputs via flow matching (a variant of diffusion models)
- **Cross-Embodiment Training**: Trained on data from 8 distinct robot platforms including UR5e, Bimanual UR5e, Franka, Bimanual Trossen, Bimanual ARX, Mobile Trossen, and Mobile Fibocom
- **Internet-Scale Pre-training**: Inherits semantic knowledge from a pre-trained 3B parameter Vision-Language Model
- **High-Frequency Control**: Outputs motor commands at up to 50 Hz for real-time dexterous manipulation
## Installation Requirements
1. Install LeRobot by following our [Installation Guide](./installation).
2. Install Pi0 dependencies by running:
```bash
pip install -e ".[pi]"
```
## Training Data and Capabilities
π₀ is trained on the largest robot interaction dataset to date, combining three key data sources:
1. **Internet-Scale Pre-training**: Vision-language data from the web for semantic understanding
2. **Open X-Embodiment Dataset**: Open-source robot manipulation datasets
3. **Physical Intelligence Dataset**: Large and diverse dataset of dexterous tasks across 8 distinct robots
## Usage
To use π₀ in LeRobot, specify the policy type as:
```python
policy.type=pi0
```
## Training
For training π₀, you can use the standard LeRobot training script with the appropriate configuration:
```bash
python src/lerobot/scripts/lerobot_train.py \
--dataset.repo_id=your_dataset \
--policy.type=pi0 \
--output_dir=./outputs/pi0_training \
--job_name=pi0_training \
--policy.pretrained_path=lerobot/pi0_base \
--policy.repo_id=your_repo_id \
--policy.compile_model=true \
--policy.gradient_checkpointing=true \
--policy.dtype=bfloat16 \
--steps=3000 \
--policy.device=cuda \
--batch_size=32
```
### Key Training Parameters
- **`--policy.compile_model=true`**: Enables model compilation for faster training
- **`--policy.gradient_checkpointing=true`**: Reduces memory usage significantly during training
- **`--policy.dtype=bfloat16`**: Use mixed precision training for efficiency
- **`--batch_size=32`**: Batch size for training, adapt this based on your GPU memory
- **`--policy.pretrained_path=lerobot/pi0_base`**: The base π₀ model you want to finetune, options are:
- [lerobot/pi0_base](https://huggingface.co/lerobot/pi0_base)
- [lerobot/pi0_libero](https://huggingface.co/lerobot/pi0_libero) (specifically trained on the Libero dataset)
## License
This model follows the **Apache 2.0 License**, consistent with the original [OpenPI repository](https://github.com/Physical-Intelligence/openpi).
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# π₀.₅ (Pi05) Policy
π₀.₅ is a **Vision-Language-Action model with open-world generalization**, from Physical Intelligence. The LeRobot implementation is adapted from their open source [OpenPI](https://github.com/Physical-Intelligence/openpi) repository.
## Model Overview
π₀.₅ represents a significant evolution from π₀, developed by [Physical Intelligence](https://www.physicalintelligence.company/blog/pi05) to address a big challenge in robotics: **open-world generalization**. While robots can perform impressive tasks in controlled environments, π₀.₅ is designed to generalize to entirely new environments and situations that were never seen during training.
### The Generalization Challenge
As Physical Intelligence explains, the fundamental challenge isn't performing tasks of agility or dexterity, but generalization, the ability to correctly perform tasks in new settings with new objects. Consider a robot cleaning different homes: each home has different objects in different places. Generalization must occur at multiple levels:
- **Physical Level**: Understanding how to pick up a spoon (by the handle) or plate (by the edge), even with unseen objects in cluttered environments
- **Semantic Level**: Understanding task semantics, where to put clothes and shoes (laundry hamper, not on the bed), and what tools are appropriate for cleaning spills
- **Environmental Level**: Adapting to "messy" real-world environments like homes, grocery stores, offices, and hospitals
### Co-Training on Heterogeneous Data
The breakthrough innovation in π₀.₅ is **co-training on heterogeneous data sources**. The model learns from:
1. **Multimodal Web Data**: Image captioning, visual question answering, object detection
2. **Verbal Instructions**: Humans coaching robots through complex tasks step-by-step
3. **Subtask Commands**: High-level semantic behavior labels (e.g., "pick up the pillow" for an unmade bed)
4. **Cross-Embodiment Robot Data**: Data from various robot platforms with different capabilities
5. **Multi-Environment Data**: Static robots deployed across many different homes
6. **Mobile Manipulation Data**: ~400 hours of mobile robot demonstrations
This diverse training mixture creates a "curriculum" that enables generalization across physical, visual, and semantic levels simultaneously.
## Installation Requirements
1. Install LeRobot by following our [Installation Guide](./installation).
2. Install Pi0.5 dependencies by running:
```bash
pip install -e ".[pi]"
```
## Usage
To use π₀.₅ in your LeRobot configuration, specify the policy type as:
```python
policy.type=pi05
```
## Training
### Training Command Example
Here's a complete training command for finetuning the base π₀.₅ model on your own dataset:
```bash
python src/lerobot/scripts/lerobot_train.py\
--dataset.repo_id=your_dataset \
--policy.type=pi05 \
--output_dir=./outputs/pi05_training \
--job_name=pi05_training \
--policy.repo_id=your_repo_id \
--policy.pretrained_path=lerobot/pi05_base \
--policy.compile_model=true \
--policy.gradient_checkpointing=true \
--wandb.enable=true \
--policy.dtype=bfloat16 \
--steps=3000 \
--policy.device=cuda \
--batch_size=32
```
### Key Training Parameters
- **`--policy.compile_model=true`**: Enables model compilation for faster training
- **`--policy.gradient_checkpointing=true`**: Reduces memory usage significantly during training
- **`--policy.dtype=bfloat16`**: Use mixed precision training for efficiency
- **`--batch_size=32`**: Batch size for training, adapt this based on your GPU memory
- **`--policy.pretrained_path=lerobot/pi05_base`**: The base π₀.₅ model you want to finetune, options are:
- [lerobot/pi05_base](https://huggingface.co/lerobot/pi05_base)
- [lerobot/pi05_libero](https://huggingface.co/lerobot/pi05_libero) (specifically trained on the Libero dataset)
If your dataset is not converted with `quantiles`, you can convert it with the following command:
```bash
python src/lerobot/datasets/v30/augment_dataset_quantile_stats.py \
--repo-id=your_dataset \
```
Or train pi05 with this normalization mapping: `--policy.normalization_mapping='{"ACTION": "MEAN_STD", "STATE": "MEAN_STD", "VISUAL": "IDENTITY"}'`
## Performance Results
### Libero Benchmark Results
π₀.₅ has demonstrated strong performance on the Libero benchmark suite. To compare and test its LeRobot implementation, we finetuned the libero base model for an additional 6k steps on the Libero dataset and compared the results to the OpenPI reference results.
| Benchmark | LeRobot Implementation | OpenPI Reference |
| ------------------ | ---------------------- | ---------------- |
| **Libero Spatial** | 97.0% | 98.8% |
| **Libero Object** | 99.0% | 98.2% |
| **Libero Goal** | 98.0% | 98.0% |
| **Libero 10** | 96.0% | 92.4% |
| **Average** | 97.5% | 96.85% |
These results demonstrate π₀.₅'s strong generalization capabilities across diverse robotic manipulation tasks. To reproduce these results, you can follow the instructions in the [Libero](https://huggingface.co/docs/lerobot/libero) section.
## License
This model follows the **Apache 2.0 License**, consistent with the original [OpenPI repository](https://github.com/Physical-Intelligence/openpi).
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# Porting Large Datasets to LeRobot Dataset v3.0
This tutorial explains how to port large-scale robotic datasets to the LeRobot Dataset v3.0 format. We'll use the **DROID 1.0.1** dataset as our primary example, which demonstrates handling multi-terabyte datasets with thousands of shards across SLURM clusters.
## File Organization: v2.1 vs v3.0
Dataset v3.0 fundamentally changes how data is organized and stored:
**v2.1 Structure (Episode-based)**:
```
dataset/
├── data/chunk-000/episode_000000.parquet
├── data/chunk-000/episode_000001.parquet
├── videos/chunk-000/camera/episode_000000.mp4
└── meta/episodes.jsonl
```
**v3.0 Structure (File-based)**:
```
dataset/
├── data/chunk-000/file-000.parquet # Multiple episodes per file
├── videos/camera/chunk-000/file-000.mp4 # Consolidated video chunks
└── meta/episodes/chunk-000/file-000.parquet # Structured metadata
```
This transition from individual episode files to file-based chunks dramatically improves performance and reduces storage overhead.
## What's New in Dataset v3.0
Dataset v3.0 introduces significant improvements for handling large datasets:
### 🏗️ **Enhanced File Organization**
- **File-based structure**: Episodes are now grouped into chunked files rather than individual episode files
- **Configurable file sizes**: for data and video files
- **Improved storage efficiency**: Better compression and reduced overhead
### 📊 **Modern Metadata Management**
- **Parquet-based metadata**: Replaced JSON Lines with efficient parquet format
- **Structured episode access**: Direct pandas DataFrame access via `dataset.meta.episodes`
- **Per-episode statistics**: Enhanced statistics tracking at episode level
### 🚀 **Performance Enhancements**
- **Memory-mapped access**: Improved RAM usage through PyArrow memory mapping
- **Faster loading**: Significantly reduced dataset initialization time
- **Better scalability**: Designed for datasets with millions of episodes
## Prerequisites
Before porting large datasets, ensure you have:
- **LeRobot installed** with v3.0 support. Follow our [Installation Guide](./installation).
- **Sufficient storage**: Raw datasets can be very large (e.g., DROID requires 2TB)
- **Cluster access** (recommended for large datasets): SLURM or similar job scheduler
- **Dataset-specific dependencies**: For DROID, you'll need TensorFlow Dataset utilities
## Understanding the DROID Dataset
[DROID 1.0.1](https://droid-dataset.github.io/droid/the-droid-dataset) is an excellent example of a large-scale robotic dataset:
- **Size**: 1.7TB (RLDS format), 8.7TB (raw data)
- **Structure**: 2048 pre-defined TensorFlow dataset shards
- **Content**: 76,000+ robot manipulation trajectories from Franka Emika Panda robots
- **Scope**: Real-world manipulation tasks across multiple environments and objects
- **Format**: Originally in TensorFlow Records/RLDS format, requiring conversion to LeRobot format
- **Hosting**: Google Cloud Storage with public access via `gsutil`
The dataset contains diverse manipulation demonstrations with:
- Multiple camera views (wrist camera, exterior cameras)
- Natural language task descriptions
- Robot proprioceptive state and actions
- Success/failure annotations
### DROID Features Schema
```python
DROID_FEATURES = {
# Episode markers
"is_first": {"dtype": "bool", "shape": (1,)},
"is_last": {"dtype": "bool", "shape": (1,)},
"is_terminal": {"dtype": "bool", "shape": (1,)},
# Language instructions
"language_instruction": {"dtype": "string", "shape": (1,)},
"language_instruction_2": {"dtype": "string", "shape": (1,)},
"language_instruction_3": {"dtype": "string", "shape": (1,)},
# Robot state
"observation.state.gripper_position": {"dtype": "float32", "shape": (1,)},
"observation.state.cartesian_position": {"dtype": "float32", "shape": (6,)},
"observation.state.joint_position": {"dtype": "float32", "shape": (7,)},
# Camera observations
"observation.images.wrist_left": {"dtype": "image"},
"observation.images.exterior_1_left": {"dtype": "image"},
"observation.images.exterior_2_left": {"dtype": "image"},
# Actions
"action.gripper_position": {"dtype": "float32", "shape": (1,)},
"action.cartesian_position": {"dtype": "float32", "shape": (6,)},
"action.joint_position": {"dtype": "float32", "shape": (7,)},
# Standard LeRobot format
"observation.state": {"dtype": "float32", "shape": (8,)}, # joints + gripper
"action": {"dtype": "float32", "shape": (8,)}, # joints + gripper
}
```
## Approach 1: Single Computer Porting
### Step 1: Install Dependencies
For DROID specifically:
```bash
pip install tensorflow
pip install tensorflow_datasets
```
For other datasets, install the appropriate readers for your source format.
### Step 2: Download Raw Data
Download DROID from Google Cloud Storage using `gsutil`:
```bash
# Install Google Cloud SDK if not already installed
# https://cloud.google.com/sdk/docs/install
# Download the full RLDS dataset (1.7TB)
gsutil -m cp -r gs://gresearch/robotics/droid/1.0.1 /your/data/
# Or download just the 100-episode sample (2GB) for testing
gsutil -m cp -r gs://gresearch/robotics/droid_100 /your/data/
```
> [!WARNING]
> Large datasets require substantial time and storage:
>
> - **Full DROID (1.7TB)**: Several days to download depending on bandwidth
> - **Processing time**: 7+ days for local porting of full dataset
> - **Upload time**: 3+ days to push to Hugging Face Hub
> - **Local storage**: ~400GB for processed LeRobot format
### Step 3: Port the Dataset
```bash
python examples/port_datasets/port_droid.py \
--raw-dir /your/data/droid/1.0.1 \
--repo-id your_id/droid_1.0.1 \
--push-to-hub
```
### Development and Testing
For development, you can port a single shard:
```bash
python examples/port_datasets/port_droid.py \
--raw-dir /your/data/droid/1.0.1 \
--repo-id your_id/droid_1.0.1_test \
--num-shards 2048 \
--shard-index 0
```
This approach works for smaller datasets or testing, but large datasets require cluster computing.
## Approach 2: SLURM Cluster Porting (Recommended)
For large datasets like DROID, parallel processing across multiple nodes dramatically reduces processing time.
### Step 1: Install Cluster Dependencies
```bash
pip install datatrove # Hugging Face's distributed processing library
```
### Step 2: Configure Your SLURM Environment
Find your partition information:
```bash
sinfo --format="%R" # List available partitions
sinfo -N -p your_partition -h -o "%N cpus=%c mem=%m" # Check resources
```
Choose a **CPU partition** - no GPU needed for dataset porting.
### Step 3: Launch Parallel Porting Jobs
```bash
python examples/port_datasets/slurm_port_shards.py \
--raw-dir /your/data/droid/1.0.1 \
--repo-id your_id/droid_1.0.1 \
--logs-dir /your/logs \
--job-name port_droid \
--partition your_partition \
--workers 2048 \
--cpus-per-task 8 \
--mem-per-cpu 1950M
```
#### Parameter Guidelines
- **`--workers`**: Number of parallel jobs (max 2048 for DROID's shard count)
- **`--cpus-per-task`**: 8 CPUs recommended for frame encoding parallelization
- **`--mem-per-cpu`**: ~16GB total RAM (8×1950M) for loading raw frames
> [!TIP]
> Start with fewer workers (e.g., 100) to test your cluster configuration before launching thousands of jobs.
### Step 4: Monitor Progress
Check running jobs:
```bash
squeue -u $USER
```
Monitor overall progress:
```bash
jobs_status /your/logs
```
Inspect individual job logs:
```bash
less /your/logs/port_droid/slurm_jobs/JOB_ID_WORKER_ID.out
```
Debug failed jobs:
```bash
failed_logs /your/logs/port_droid
```
### Step 5: Aggregate Shards
Once all porting jobs complete:
```bash
python examples/port_datasets/slurm_aggregate_shards.py \
--repo-id your_id/droid_1.0.1 \
--logs-dir /your/logs \
--job-name aggr_droid \
--partition your_partition \
--workers 2048 \
--cpus-per-task 8 \
--mem-per-cpu 1950M
```
### Step 6: Upload to Hub
```bash
python examples/port_datasets/slurm_upload.py \
--repo-id your_id/droid_1.0.1 \
--logs-dir /your/logs \
--job-name upload_droid \
--partition your_partition \
--workers 50 \
--cpus-per-task 4 \
--mem-per-cpu 1950M
```
> [!NOTE]
> Upload uses fewer workers (50) since it's network-bound rather than compute-bound.
## Dataset v3.0 File Structure
Your completed dataset will have this modern structure:
```
dataset/
├── meta/
│ ├── episodes/
│ │ └── chunk-000/
│ │ └── file-000.parquet # Episode metadata
│ ├── tasks.parquet # Task definitions
│ ├── stats.json # Aggregated statistics
│ └── info.json # Dataset information
├── data/
│ └── chunk-000/
│ └── file-000.parquet # Consolidated episode data
└── videos/
└── camera_key/
└── chunk-000/
└── file-000.mp4 # Consolidated video files
```
This replaces the old episode-per-file structure with efficient, optimally-sized chunks.
## Migrating from Dataset v2.1
If you have existing datasets in v2.1 format, use the migration tool:
```bash
python src/lerobot/datasets/v30/convert_dataset_v21_to_v30.py \
--repo-id your_id/existing_dataset
```
This automatically:
- Converts file structure to v3.0 format
- Migrates metadata from JSON Lines to parquet
- Aggregates statistics and creates per-episode stats
- Updates version information
## Performance Benefits
Dataset v3.0 provides significant improvements for large datasets:
- **Faster loading**: 3-5x reduction in initialization time
- **Memory efficiency**: Better RAM usage through memory mapping
- **Scalable processing**: Handles millions of episodes efficiently
- **Storage optimization**: Reduced file count and improved compression
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# Processors for Robots and Teleoperators
This guide shows how to build and modify processing pipelines that connect teleoperators (e.g., phone) to robots and datasets. Pipelines standardize conversions between different action/observation spaces so you can swap teleops and robots without rewriting glue code.
We use the Phone to SO100 follower examples for concreteness, but the same patterns apply to other robots.
**What you'll learn**
- Absolute vs. relative EE control: What each means, tradeoffs, and how to choose for your task.
- Three-pipeline pattern: How to map teleop actions → dataset actions → robot commands, and robot observations → dataset observations.
- Adapters (`to_transition` / `to_output`): How these convert raw dicts to `EnvTransition` and back to reduce boilerplate.
- Dataset feature contracts: How steps declare features via `transform_features(...)`, and how to aggregate/merge them for recording.
- Choosing a representation: When to store joints, absolute EE poses, or relative EE deltas—and how that affects training.
- Pipeline customization guidance: How to swap robots/URDFs safely and tune bounds, step sizes, and options like IK initialization.
### Absolute vs relative EE control
The examples in this guide use absolute end effector (EE) poses because they are easy to reason about. In practice, relative EE deltas or joint position are often preferred as learning features.
With processors, you choose the learning features you want to use for your policy. This could be joints positions/velocities, absolute EE, or relative EE positions. You can also choose to store other features, such as joint torques, motor currents, etc.
## Three pipelines
We often compose three pipelines. Depending on your setup, some can be empty if action and observation spaces already match.
Each of these pipelines handle different conversions between different action and observation spaces. Below is a quick explanation of each pipeline.
1. Pipeline 1: Teleop action space → dataset action space (phone pose → EE targets)
2. Pipeline 2: Dataset action space → robot command space (EE targets → joints)
3. Pipeline 3: Robot observation space → dataset observation space (joints → EE pose)
Below is an example of the three pipelines that we use in the phone to SO-100 follower examples:
```69:90:examples/phone_so100_record.py
phone_to_robot_ee_pose_processor = RobotProcessorPipeline[RobotAction, RobotAction]( # teleop -> dataset action
steps=[
MapPhoneActionToRobotAction(platform=teleop_config.phone_os),
EEReferenceAndDelta(
kinematics=kinematics_solver, end_effector_step_sizes={"x": 0.5, "y": 0.5, "z": 0.5}, motor_names=list(robot.bus.motors.keys()),
),
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(),
],
to_transition=robot_action_to_transition,
to_output=transition_to_robot_action,
)
robot_ee_to_joints_processor = RobotProcessorPipeline[RobotAction, RobotAction]( # dataset action -> robot
steps=[
InverseKinematicsEEToJoints(
kinematics=kinematics_solver, motor_names=list(robot.bus.motors.keys()), initial_guess_current_joints=True,
),
],
to_transition=robot_action_to_transition,
to_output=transition_to_robot_action,
)
robot_joints_to_ee_pose = RobotProcessorPipeline[RobotObservation, RobotObservation]( # robot obs -> dataset obs
steps=[
ForwardKinematicsJointsToEE(kinematics=kinematics_solver, motor_names=list(robot.bus.motors.keys()))
],
to_transition=observation_to_transition,
to_output=transition_to_observation,
)
```
## Why to_transition / to_output
To convert from robot/teleoperator to pipeline and back, we use the `to_transition` and `to_output` pipeline adapters.
They standardize conversions to reduce boilerplate code, and form the bridge between the robot and teleoperators raw dictionaries and the pipelines `EnvTransition` format.
In the phone to SO-100 follower examples we use the following adapters:
- `robot_action_to_transition`: transforms the teleop action dict to a pipeline transition.
- `transition_to_robot_action`: transforms the pipeline transition to a robot action dict.
- `observation_to_transition`: transforms the robot observation dict to a pipeline transition.
- `transition_to_observation`: transforms the pipeline transition to a observation dict.
Checkout [src/lerobot/processor/converters.py](https://github.com/huggingface/lerobot/blob/main/src/lerobot/processor/converters.py) for more details.
## Dataset feature contracts
Dataset features are determined by the keys saved in the dataset. Each step can declare what features it modifies in a contract called `transform_features(...)`. Once you build a processor, the processor can then aggregate all of these features with `aggregate_pipeline_dataset_features()` and merge multiple feature dicts with `combine_feature_dicts(...)`.
Below is and example of how we declare features with the `transform_features` method in the phone to SO-100 follower examples:
```src/lerobot/robots/so100_follower/robot_kinematic_processor.py
def transform_features(
self, features: dict[PipelineFeatureType, dict[str, PolicyFeature]]
) -> dict[PipelineFeatureType, dict[str, PolicyFeature]]:
# We only use the ee pose in the dataset, so we don't need the joint positions
for n in self.motor_names:
features[PipelineFeatureType.ACTION].pop(f"{n}.pos", None)
# We specify the dataset features of this step that we want to be stored in the dataset
for k in ["x", "y", "z", "wx", "wy", "wz", "gripper_pos"]:
features[PipelineFeatureType.ACTION][f"ee.{k}"] = PolicyFeature(
type=FeatureType.STATE, shape=(1,)
)
return features
```
Here we declare what PolicyFeatures we modify in this step, so we know what features we can expect when we run the processor. These features can then be aggregated and used to create the dataset features.
Below is an example of how we aggregate and merge features in the phone to SO-100 record example:
```121:145:examples/phone_so100_record.py
features=combine_feature_dicts(
# Run the feature contract of the pipelines
# This tells you how the features would look like after the pipeline steps
aggregate_pipeline_dataset_features(
pipeline=phone_to_robot_ee_pose_processor,
initial_features=create_initial_features(action=phone.action_features), # <- Action features we can expect, these come from our teleop device (phone) and action processor
use_videos=True,
),
aggregate_pipeline_dataset_features(
pipeline=robot_joints_to_ee_pose,
initial_features=create_initial_features(observation=robot.observation_features), # <- Observation features we can expect, these come from our robot and observation processor
use_videos=True,
patterns=["observation.state.ee"], # <- Here you could optionally filter the features we want to store in the dataset, with a specific pattern
),
),
```
How it works:
- `aggregate_pipeline_dataset_features(...)`: applies `transform_features` across the pipeline and filters by patterns (images included when `use_videos=True`, and state features included when `patterns` is specified).
- `combine_feature_dicts(...)`: combine multiple feature dicts.
- Recording with `record_loop(...)` uses `build_dataset_frame(...)` to build frames consistent with `dataset.features` before we call `add_frame(...)` to add the frame to the dataset.
## Guidance when customizing robot pipelines
You can store any of the following features as your action/observation space:
- Joint positions
- Absolute EE poses
- Relative EE deltas
- Other features: joint velocity, torques, etc.
Pick what you want to use for your policy action and observation space and configure/modify the pipelines and steps accordingly.
### Different robots
- You can easily reuse pipelines, for example to use another robot with phone teleop, modify the examples and swap the robot `RobotKinematics` (URDF) and `motor_names` to use your own robot with Phone teleop. Additionally you should ensure `target_frame_name` points to your gripper/wrist.
### Safety first
- When changing pipelines, start with tight bounds, implement safety steps when working with real robots.
- Its advised to start with simulation first and then move to real robots.
Thats it! We hope this guide helps you get started with customizing your robot pipelines, If you run into any issues at any point, jump into our [Discord community](https://discord.com/invite/s3KuuzsPFb) for support.
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# Reachy 2
Reachy 2 is an open-source humanoid robot made by Pollen Robotics, specifically designed for the development of embodied AI and real-world applications.
Check out [Pollen Robotics website](https://www.pollen-robotics.com/reachy/), or access [Reachy 2 documentation](https://docs.pollen-robotics.com/) for more information on the platform!
## Teleoperate Reachy 2
Currently, there are two ways to teleoperate Reachy 2:
- Pollen Robotics VR teleoperation (not included in LeRobot).
- Robot-to-robot teleoperation (use one Reachy 2 to control another).
## Reachy 2 Simulation
**(Linux only)** You can run Reachy 2 in simulation (Gazebo or MuJoCo) using the provided [Docker image](https://hub.docker.com/r/pollenrobotics/reachy2_core).
1. Install [Docker Engine](https://docs.docker.com/engine/).
2. Run (for MuJoCo):
```
docker run --rm -it \
--name reachy \
--privileged \
--network host \
--ipc host \
--device-cgroup-rule='c 189:* rwm' \
--group-add audio \
-e ROS_DOMAIN_ID="$ROS_DOMAIN_ID" \
-e DISPLAY="$DISPLAY" \
-e RCUTILS_CONSOLE_OUTPUT_FORMAT="[{severity}]: {message}" \
-e REACHY2_CORE_SERVICE_FAKE="${REACHY2_CORE_SERVICE_FAKE:-true}" \
-v /dev:/dev \
-v "$HOME/.reachy_config":/home/reachy/.reachy_config_override \
-v "$HOME/.reachy.log":/home/reachy/.ros/log \
-v /usr/lib/x86_64-linux-gnu:/opt/host-libs \
--entrypoint /package/launch.sh \
pollenrobotics/reachy2_core:1.7.5.9_deploy \
start_rviz:=true start_sdk_server:=true mujoco:=true
```
> If MuJoCo runs slowly (low simulation frequency), append `-e LD_LIBRARY_PATH="/opt/host-libs:$LD_LIBRARY_PATH" \` to the previous command to improve performance:
>
> ```
> docker run --rm -it \
> --name reachy \
> --privileged \
> --network host \
> --ipc host \
> --device-cgroup-rule='c 189:* rwm' \
> --group-add audio \
> -e ROS_DOMAIN_ID="$ROS_DOMAIN_ID" \
> -e DISPLAY="$DISPLAY" \
> -e RCUTILS_CONSOLE_OUTPUT_FORMAT="[{severity}]: {message}" \
> -e REACHY2_CORE_SERVICE_FAKE="${REACHY2_CORE_SERVICE_FAKE:-true}" \
> -e LD_LIBRARY_PATH="/opt/host-libs:$LD_LIBRARY_PATH" \
> -v /dev:/dev \
> -v "$HOME/.reachy_config":/home/reachy/.reachy_config_override \
> -v "$HOME/.reachy.log":/home/reachy/.ros/log \
> -v /usr/lib/x86_64-linux-gnu:/opt/host-libs \
> --entrypoint /package/launch.sh \
> pollenrobotics/reachy2_core:1.7.5.9_deploy \
> start_rviz:=true start_sdk_server:=true mujoco:=true
> ```
## Setup
### Prerequisites
- On your robot, check the **service images** meet the minimum versions:
- **reachy2-core >= 1.7.5.2**
- **webrtc >= 2.0.1.1**
Then, if you want to use VR teleoperation:
- Install the [Reachy 2 teleoperation application](https://docs.pollen-robotics.com/teleoperation/teleoperation-introduction/discover-teleoperation/).
Use version **>=v1.2.0**
We recommend using two computers: one for teleoperation (Windows required) and another for recording with LeRobot.
### Install LeRobot
Follow the [installation instructions](https://github.com/huggingface/lerobot#installation) to install LeRobot.
Install LeRobot with Reachy 2 dependencies:
```bash
pip install -e ".[reachy2]"
```
### (Optional but recommended) Install pollen_data_acquisition_server
How you manage Reachy 2 recording sessions is up to you, but the **easiest** way is to use this server so you can control sessions directly from the VR teleoperation app.
> **Note:** Currently, only the VR teleoperation application works as a client for this server, so this step primarily targets teleoperation. Youre free to develop custom clients to manage sessions to your needs.
In your LeRobot environment, install the server from source:
```bash
git clone https://github.com/pollen-robotics/pollen_data_acquisition_server.git
cd pollen_data_acquisition_server
pip install -e .
```
Find the [pollen_data_acquisition_server documentation here](https://github.com/pollen-robotics/pollen_data_acquisition_server).
## Step 1: Recording
### Get Reachy 2 IP address
Before starting teleoperation and data recording, find the [robot's IP address](https://docs.pollen-robotics.com/getting-started/setup-reachy2/connect-reachy2/).
We strongly recommend connecting all devices (PC and robot) via **Ethernet**.
### Launch recording
There are two ways to manage recording sessions when using the Reachy 2 VR teleoperation application:
- **Using the data acquisition server (recommended for VR teleop)**: The VR app orchestrates sessions (via the server it tells LeRobot when to create datasets, start/stop episodes) while also controlling the robots motions.
- **Using LeRobots record script**: LeRobot owns session control and decides when to start/stop episodes. If you also use the VR teleop app, its only for motion control.
### Option 1: Using Pollen data acquisition server (recommended for VR teleop)
Make sure you have installed pollen_data_acquisition_server, as explained in the Setup section.
Launch the data acquisition server to be able to manage your session directly from the teleoperation application:
```bash
python -m pollen_data_acquisition_server.server
```
Then get into the teleoperation application and choose "Data acquisition session".
You can finally setup your session by following the screens displayed.
> Even without the VR app, you can use the `pollen_data_acquisition_server` with your own client implementation.
### Option 2: Using lerobot.record
Reachy 2 is fully supported by LeRobots recording features.
If you choose this option but still want to use the VR teleoperation application, select "Standard session" in the app.
**Example: start a recording without the mobile base:**
First add reachy2 and reachy2_teleoperator to the imports of the record script. Then you can use the following command:
```bash
python -m lerobot.record \
--robot.type=reachy2 \
--robot.ip_address=192.168.0.200 \
--robot.id=r2-0000 \
--robot.use_external_commands=true \
--robot.with_mobile_base=false \
--teleop.type=reachy2_teleoperator \
--teleop.ip_address=192.168.0.200 \
--teleop.with_mobile_base=false \
--dataset.repo_id=pollen_robotics/record_test \
--dataset.single_task="Reachy 2 recording test" \
--dataset.num_episodes=1 \
--dataset.episode_time_s=5 \
--dataset.fps=15 \
--dataset.push_to_hub=true \
--dataset.private=true \
--display_data=true
```
#### Specific Options
**Extended setup overview (all options included):**
```bash
python -m lerobot.record \
--robot.type=reachy2 \
--robot.ip_address=192.168.0.200 \
--robot.use_external_commands=true \
--robot.with_mobile_base=true \
--robot.with_l_arm=true \
--robot.with_r_arm=true \
--robot.with_neck=true \
--robot.with_antennas=true \
--robot.with_left_teleop_camera=true \
--robot.with_right_teleop_camera=true \
--robot.with_torso_camera=false \
--robot.disable_torque_on_disconnect=false \
--robot.max_relative_target=5.0 \
--teleop.type=reachy2_teleoperator \
--teleop.ip_address=192.168.0.200 \
--teleop.use_present_position=false \
--teleop.with_mobile_base=false \
--teleop.with_l_arm=true \
--teleop.with_r_arm=true \
--teleop.with_neck=true \
--teleop.with_antennas=true \
--dataset.repo_id=pollen_robotics/record_test \
--dataset.single_task="Reachy 2 recording test" \
--dataset.num_episodes=1 \
--dataset.episode_time_s=5 \
--dataset.fps=15 \
--dataset.push_to_hub=true \
--dataset.private=true \
--display_data=true
```
##### `--robot.use_external_commands`
Determine whether LeRobot robot.send_action() sends commands to the robot.
**Must** be set to false while using the VR teleoperation application, as the app already sends commands.
##### `--teleop.use_present_position`
Determine whether the teleoperator reads the goal or present position of the robot.
Must be set to true if a compliant Reachy 2 is used to control another one.
##### Use the relevant parts
From our initial tests, recording **all** joints when only some are moving can reduce model quality with certain policies.
To avoid this, you can exclude specific parts from recording and replay using:
````
--robot.with_<part>=false
```,
with `<part>` being one of : `mobile_base`, `l_arm`, `r_arm", `neck`, `antennas`.
It determine whether the corresponding part is recorded in the observations. True if not set.
By default, **all parts are recorded**.
The same per-part mechanism is available in `reachy2_teleoperator` as well.
````
--teleop.with\_<part>
```
with `<part>` being one of : `mobile_base`, `l_arm`, `r_arm", `neck`, `antennas`.
Determine whether the corresponding part is recorded in the actions. True if not set.
> **Important:** In a given session, the **enabled parts must match** on both the robot and the teleoperator.
For example, if the robot runs with `--robot.with_mobile_base=false`, the teleoperator must disable the same part `--teleoperator.with_mobile_base=false`.
##### Use the relevant cameras
You can do the same for **cameras**. By default, only the **teleoperation cameras** are recorded (both `left_teleop_camera` and `right_teleop_camera`). Enable or disable each camera with:
```
--robot.with_left_teleop_camera=<true|false>
--robot.with_right_teleop_camera=<true|false>
--robot.with_torso_camera=<true|false>
````
## Step 2: Replay
Make sure the robot is configured with the same parts as the dataset:
```bash
python -m lerobot.replay \
--robot.type=reachy2 \
--robot.ip_address=192.168.0.200 \
--robot.use_external_commands=false \
--robot.with_mobile_base=false \
--dataset.repo_id=pollen_robotics/record_test \
--dataset.episode=0
--display_data=true
````
## Step 3: Train
```bash
python -m lerobot.scripts.train \
--dataset.repo_id=pollen_robotics/record_test \
--policy.type=act \
--output_dir=outputs/train/reachy2_test \
--job_name=reachy2 \
--policy.device=mps \
--wandb.enable=true \
--policy.repo_id=pollen_robotics/record_test_policy
```
## Step 4: Evaluate
```bash
python -m lerobot.record \
--robot.type=reachy2 \
--robot.ip_address=192.168.0.200 \
--display_data=false \
--dataset.repo_id=pollen_robotics/eval_record_test \
--dataset.single_task="Evaluate reachy2 policy" \
--dataset.num_episodes=10 \
--policy.path=outputs/train/reachy2_test/checkpoints/last/pretrained_model
```
docs/source/smolvla.mdx
+3 -3
View File
@@ -1,4 +1,4 @@
# SmolVLA
# Finetune SmolVLA
SmolVLA is Hugging Faces lightweight foundation model for robotics. Designed for easy fine-tuning on LeRobot datasets, it helps accelerate your development!
@@ -29,7 +29,7 @@ SmolVLA is Hugging Faces lightweight foundation model for robotics. Designed
## Collect a dataset
SmolVLA is a base model, so fine-tuning on your own data is required for optimal performance in your setup.
We recommend recording ~50 episodes of your task as a starting point. Follow our guide to get started: [Recording a Dataset](./il_robots)
We recommend recording ~50 episodes of your task as a starting point. Follow our guide to get started: [Recording a Dataset](https://huggingface.co/docs/lerobot/getting_started_real_world_robot#record-a-dataset)
<Tip>
@@ -93,7 +93,7 @@ lerobot-train --help
## Evaluate the finetuned model and run it in real-time
Similarly for when recording an episode, it is recommended that you are logged in to the HuggingFace Hub. You can follow the corresponding steps: [Record a dataset](./il_robots).
Similarly for when recording an episode, it is recommended that you are logged in to the HuggingFace Hub. You can follow the corresponding steps: [Record a dataset](./getting_started_real_world_robot#record-a-dataset).
Once you are logged in, you can run inference in your setup by doing:
```bash
docs/source/so100.mdx
+1 -1
View File
@@ -634,7 +634,7 @@ leader.disconnect()
</hfoption>
</hfoptions>
Congrats 🎉, your robot is all set to learn a task on its own. Start training it by following this tutorial: [Getting started with real-world robots](./il_robots)
Congrats 🎉, your robot is all set to learn a task on its own. Start training it by following this tutorial: [Getting started with real-world robots](./getting_started_real_world_robot)
> [!TIP]
> If you have any questions or need help, please reach out on [Discord](https://discord.com/invite/s3KuuzsPFb).
docs/source/so101.mdx
+1 -1
View File
@@ -430,7 +430,7 @@ leader.disconnect()
</hfoption>
</hfoptions>
Congrats 🎉, your robot is all set to learn a task on its own. Start training it by following this tutorial: [Getting started with real-world robots](./il_robots)
Congrats 🎉, your robot is all set to learn a task on its own. Start training it by following this tutorial: [Getting started with real-world robots](./getting_started_real_world_robot)
> [!TIP]
> If you have any questions or need help, please reach out on [Discord](https://discord.com/invite/s3KuuzsPFb).
docs/source/using_dataset_tools.mdx
-102
View File
@@ -1,102 +0,0 @@
# Using Dataset Tools
This guide covers the dataset tools utilities available in LeRobot for modifying and editing existing datasets.
## Overview
LeRobot provides several utilities for manipulating datasets:
1. **Delete Episodes** - Remove specific episodes from a dataset
2. **Split Dataset** - Divide a dataset into multiple smaller 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
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, and remove features.
Run `lerobot-edit-dataset --help` for more information on the configuration of each operation.
### Usage Examples
#### Delete Episodes
Remove specific episodes from a dataset. This is useful for filtering out undesired data.
```bash
# Delete episodes 0, 2, and 5 (modifies original dataset)
lerobot-edit-dataset \
--repo_id lerobot/pusht \
--operation.type delete_episodes \
--operation.episode_indices "[0, 2, 5]"
# Delete episodes and save to a new dataset (preserves original dataset)
lerobot-edit-dataset \
--repo_id lerobot/pusht \
--new_repo_id lerobot/pusht_after_deletion \
--operation.type delete_episodes \
--operation.episode_indices "[0, 2, 5]"
```
#### Split Dataset
Divide a dataset into multiple subsets.
```bash
# Split by fractions (e.g. 80% train, 20% test, 20% val)
lerobot-edit-dataset \
--repo_id lerobot/pusht \
--operation.type split \
--operation.splits '{"train": 0.8, "test": 0.2, "val": 0.2}'
# Split by specific episode indices
lerobot-edit-dataset \
--repo_id lerobot/pusht \
--operation.type split \
--operation.splits '{"task1": [0, 1, 2, 3], "task2": [4, 5]}'
```
There are no constraints on the split names, they can be determined by the user. Resulting datasets are saved under the repo id with the split name appended, e.g. `lerobot/pusht_train`, `lerobot/pusht_task1`, `lerobot/pusht_task2`.
#### Merge Datasets
Combine multiple datasets into a single dataset.
```bash
# Merge train and validation splits back into one dataset
lerobot-edit-dataset \
--repo_id lerobot/pusht_merged \
--operation.type merge \
--operation.repo_ids "['lerobot/pusht_train', 'lerobot/pusht_val']"
```
#### Remove Features
Remove features from a dataset.
```bash
# Remove a camera feature
lerobot-edit-dataset \
--repo_id lerobot/pusht \
--operation.type remove_feature \
--operation.feature_names "['observation.images.top']"
```
### Push to 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 \
--repo_id lerobot/pusht \
--new_repo_id lerobot/pusht_after_deletion \
--operation.type delete_episodes \
--operation.episode_indices "[0, 2, 5]" \
--push_to_hub
```
There is also a tool for adding features to a dataset that is not yet covered in `lerobot-edit-dataset`.
examples/dataset/load_lerobot_dataset.py → examples/1_load_lerobot_dataset.py
+4 -4
View File
@@ -92,11 +92,11 @@ 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
# episodes, you can access the frame indices of any episode using the episode_data_index. 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]
from_idx = dataset.episode_data_index["from"][episode_index].item()
to_idx = dataset.episode_data_index["to"][episode_index].item()
# Then we grab all the image frames from the first camera:
camera_key = dataset.meta.camera_keys[0]
@@ -136,7 +136,7 @@ print(f"{dataset[0]['action'].shape=}\n") # (64, c)
# PyTorch datasets.
dataloader = torch.utils.data.DataLoader(
dataset,
num_workers=4,
num_workers=0,
batch_size=32,
shuffle=True,
)
examples/2_evaluate_pretrained_policy.py
+139
View File
@@ -0,0 +1,139 @@
# 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.
"""
This script demonstrates how to evaluate a pretrained policy from the HuggingFace Hub or from your local
training outputs directory. In the latter case, you might want to run examples/3_train_policy.py first.
It requires the installation of the 'gym_pusht' simulation environment. Install it by running:
```bash
pip install -e ".[pusht]"
```
"""
from pathlib import Path
import gym_pusht # noqa: F401
import gymnasium as gym
import imageio
import numpy
import torch
from lerobot.policies.diffusion.modeling_diffusion import DiffusionPolicy
# Create a directory to store the video of the evaluation
output_directory = Path("outputs/eval/example_pusht_diffusion")
output_directory.mkdir(parents=True, exist_ok=True)
# Select your device
device = "cuda"
# Provide the [hugging face repo id](https://huggingface.co/lerobot/diffusion_pusht):
pretrained_policy_path = "lerobot/diffusion_pusht"
# OR a path to a local outputs/train folder.
# pretrained_policy_path = Path("outputs/train/example_pusht_diffusion")
policy = DiffusionPolicy.from_pretrained(pretrained_policy_path)
# Initialize evaluation environment to render two observation types:
# an image of the scene and state/position of the agent. The environment
# also automatically stops running after 300 interactions/steps.
env = gym.make(
"gym_pusht/PushT-v0",
obs_type="pixels_agent_pos",
max_episode_steps=300,
)
# We can verify that the shapes of the features expected by the policy match the ones from the observations
# produced by the environment
print(policy.config.input_features)
print(env.observation_space)
# Similarly, we can check that the actions produced by the policy will match the actions expected by the
# environment
print(policy.config.output_features)
print(env.action_space)
# Reset the policy and environments to prepare for rollout
policy.reset()
numpy_observation, info = env.reset(seed=42)
# Prepare to collect every rewards and all the frames of the episode,
# from initial state to final state.
rewards = []
frames = []
# Render frame of the initial state
frames.append(env.render())
step = 0
done = False
while not done:
# Prepare observation for the policy running in Pytorch
state = torch.from_numpy(numpy_observation["agent_pos"])
image = torch.from_numpy(numpy_observation["pixels"])
# Convert to float32 with image from channel first in [0,255]
# to channel last in [0,1]
state = state.to(torch.float32)
image = image.to(torch.float32) / 255
image = image.permute(2, 0, 1)
# Send data tensors from CPU to GPU
state = state.to(device, non_blocking=True)
image = image.to(device, non_blocking=True)
# Add extra (empty) batch dimension, required to forward the policy
state = state.unsqueeze(0)
image = image.unsqueeze(0)
# Create the policy input dictionary
observation = {
"observation.state": state,
"observation.image": image,
}
# Predict the next action with respect to the current observation
with torch.inference_mode():
action = policy.select_action(observation)
# Prepare the action for the environment
numpy_action = action.squeeze(0).to("cpu").numpy()
# Step through the environment and receive a new observation
numpy_observation, reward, terminated, truncated, info = env.step(numpy_action)
print(f"{step=} {reward=} {terminated=}")
# Keep track of all the rewards and frames
rewards.append(reward)
frames.append(env.render())
# The rollout is considered done when the success state is reached (i.e. terminated is True),
# or the maximum number of iterations is reached (i.e. truncated is True)
done = terminated | truncated | done
step += 1
if terminated:
print("Success!")
else:
print("Failure!")
# Get the speed of environment (i.e. its number of frames per second).
fps = env.metadata["render_fps"]
# Encode all frames into a mp4 video.
video_path = output_directory / "rollout.mp4"
imageio.mimsave(str(video_path), numpy.stack(frames), fps=fps)
print(f"Video of the evaluation is available in '{video_path}'.")
examples/training/train_policy.py → examples/3_train_policy.py
+7 -7
View File
@@ -12,7 +12,11 @@
# See the License for the specific language governing permissions and
# limitations under the License.
"""This script demonstrates how to train Diffusion Policy on the PushT environment."""
"""This script demonstrates how to train Diffusion Policy on the PushT environment.
Once you have trained a model with this script, you can try to evaluate it on
examples/2_evaluate_pretrained_policy.py
"""
from pathlib import Path
@@ -23,7 +27,6 @@ from lerobot.datasets.lerobot_dataset import LeRobotDataset, LeRobotDatasetMetad
from lerobot.datasets.utils import dataset_to_policy_features
from lerobot.policies.diffusion.configuration_diffusion import DiffusionConfig
from lerobot.policies.diffusion.modeling_diffusion import DiffusionPolicy
from lerobot.policies.factory import make_pre_post_processors
def main():
@@ -53,10 +56,9 @@ def main():
cfg = DiffusionConfig(input_features=input_features, output_features=output_features)
# We can now instantiate our policy with this config and the dataset stats.
policy = DiffusionPolicy(cfg)
policy = DiffusionPolicy(cfg, dataset_stats=dataset_metadata.stats)
policy.train()
policy.to(device)
preprocessor, postprocessor = make_pre_post_processors(cfg, dataset_stats=dataset_metadata.stats)
# Another policy-dataset interaction is with the delta_timestamps. Each policy expects a given number frames
# which can differ for inputs, outputs and rewards (if there are some).
@@ -97,7 +99,7 @@ def main():
done = False
while not done:
for batch in dataloader:
batch = preprocessor(batch)
batch = {k: (v.to(device) if isinstance(v, torch.Tensor) else v) for k, v in batch.items()}
loss, _ = policy.forward(batch)
loss.backward()
optimizer.step()
@@ -112,8 +114,6 @@ def main():
# Save a policy checkpoint.
policy.save_pretrained(output_directory)
preprocessor.save_pretrained(output_directory)
postprocessor.save_pretrained(output_directory)
if __name__ == "__main__":
examples/4_train_policy_with_script.md
+311
View File
@@ -0,0 +1,311 @@
This tutorial will explain the training script, how to use it, and particularly how to configure everything needed for the training run.
> **Note:** The following assumes you're running these commands on a machine equipped with a cuda GPU. If you don't have one (or if you're using a Mac), you can add `--policy.device=cpu` (`--policy.device=mps` respectively). However, be advised that the code executes much slower on cpu.
## The training script
LeRobot offers a training script at [`lerobot/scripts/train.py`](../src/lerobot/scripts/train.py). At a high level it does the following:
- Initialize/load a configuration for the following steps using.
- Instantiates a dataset.
- (Optional) Instantiates a simulation environment corresponding to that dataset.
- Instantiates a policy.
- Runs a standard training loop with forward pass, backward pass, optimization step, and occasional logging, evaluation (of the policy on the environment), and checkpointing.
## Overview of the configuration system
In the training script, the main function `train` expects a `TrainPipelineConfig` object:
<!-- prettier-ignore-start -->
```python
# train.py
@parser.wrap()
def train(cfg: TrainPipelineConfig):
```
<!-- prettier-ignore-end -->
You can inspect the `TrainPipelineConfig` defined in [`lerobot/configs/train.py`](../src/lerobot/configs/train.py) (which is heavily commented and meant to be a reference to understand any option)
When running the script, inputs for the command line are parsed thanks to the `@parser.wrap()` decorator and an instance of this class is automatically generated. Under the hood, this is done with [Draccus](https://github.com/dlwh/draccus) which is a tool dedicated to this purpose. If you're familiar with Hydra, Draccus can similarly load configurations from config files (.json, .yaml) and also override their values through command line inputs. Unlike Hydra, these configurations are pre-defined in the code through dataclasses rather than being defined entirely in config files. This allows for more rigorous serialization/deserialization, typing, and to manipulate configuration as objects directly in the code and not as dictionaries or namespaces (which enables nice features in an IDE such as autocomplete, jump-to-def, etc.)
Let's have a look at a simplified example. Amongst other attributes, the training config has the following attributes:
<!-- prettier-ignore-start -->
```python
@dataclass
class TrainPipelineConfig:
dataset: DatasetConfig
env: envs.EnvConfig | None = None
policy: PreTrainedConfig | None = None
```
<!-- prettier-ignore-end -->
in which `DatasetConfig` for example is defined as such:
<!-- prettier-ignore-start -->
```python
@dataclass
class DatasetConfig:
repo_id: str
episodes: list[int] | None = None
video_backend: str = "pyav"
```
<!-- prettier-ignore-end -->
This creates a hierarchical relationship where, for example assuming we have a `cfg` instance of `TrainPipelineConfig`, we can access the `repo_id` value with `cfg.dataset.repo_id`.
From the command line, we can specify this value by using a very similar syntax `--dataset.repo_id=repo/id`.
By default, every field takes its default value specified in the dataclass. If a field doesn't have a default value, it needs to be specified either from the command line or from a config file which path is also given in the command line (more in this below). In the example above, the `dataset` field doesn't have a default value which means it must be specified.
## Specifying values from the CLI
Let's say that we want to train [Diffusion Policy](../src/lerobot/policies/diffusion) on the [pusht](https://huggingface.co/datasets/lerobot/pusht) dataset, using the [gym_pusht](https://github.com/huggingface/gym-pusht) environment for evaluation. The command to do so would look like this:
```bash
lerobot-train \
--dataset.repo_id=lerobot/pusht \
--policy.type=diffusion \
--env.type=pusht
```
Let's break this down:
- To specify the dataset, we just need to specify its `repo_id` on the hub which is the only required argument in the `DatasetConfig`. The rest of the fields have default values and in this case we are fine with those so we can just add the option `--dataset.repo_id=lerobot/pusht`.
- To specify the policy, we can just select diffusion policy using `--policy` appended with `.type`. Here, `.type` is a special argument which allows us to select config classes inheriting from `draccus.ChoiceRegistry` and that have been decorated with the `register_subclass()` method. To have a better explanation of this feature, have a look at this [Draccus demo](https://github.com/dlwh/draccus?tab=readme-ov-file#more-flexible-configuration-with-choice-types). In our code, we use this mechanism mainly to select policies, environments, robots, and some other components like optimizers. The policies available to select are located in [lerobot/policies](../src/lerobot/policies)
- Similarly, we select the environment with `--env.type=pusht`. The different environment configs are available in [`lerobot/envs/configs.py`](../src/lerobot/envs/configs.py)
Let's see another example. Let's say you've been training [ACT](../src/lerobot/policies/act) on [lerobot/aloha_sim_insertion_human](https://huggingface.co/datasets/lerobot/aloha_sim_insertion_human) using the [gym-aloha](https://github.com/huggingface/gym-aloha) environment for evaluation with:
```bash
lerobot-train \
--policy.type=act \
--dataset.repo_id=lerobot/aloha_sim_insertion_human \
--env.type=aloha \
--output_dir=outputs/train/act_aloha_insertion
```
> Notice we added `--output_dir` to explicitly tell where to write outputs from this run (checkpoints, training state, configs etc.). This is not mandatory and if you don't specify it, a default directory will be created from the current date and time, env.type and policy.type. This will typically look like `outputs/train/2025-01-24/16-10-05_aloha_act`.
We now want to train a different policy for aloha on another task. We'll change the dataset and use [lerobot/aloha_sim_transfer_cube_human](https://huggingface.co/datasets/lerobot/aloha_sim_transfer_cube_human) instead. Of course, we also need to change the task of the environment as well to match this other task.
Looking at the [`AlohaEnv`](../src/lerobot/envs/configs.py) config, the task is `"AlohaInsertion-v0"` by default, which corresponds to the task we trained on in the command above. The [gym-aloha](https://github.com/huggingface/gym-aloha?tab=readme-ov-file#description) environment also has the `AlohaTransferCube-v0` task which corresponds to this other task we want to train on. Putting this together, we can train this new policy on this different task using:
```bash
lerobot-train \
--policy.type=act \
--dataset.repo_id=lerobot/aloha_sim_transfer_cube_human \
--env.type=aloha \
--env.task=AlohaTransferCube-v0 \
--output_dir=outputs/train/act_aloha_transfer
```
## Loading from a config file
Now, let's assume that we want to reproduce the run just above. That run has produced a `train_config.json` file in its checkpoints, which serializes the `TrainPipelineConfig` instance it used:
```json
{
"dataset": {
"repo_id": "lerobot/aloha_sim_transfer_cube_human",
"episodes": null,
...
},
"env": {
"type": "aloha",
"task": "AlohaTransferCube-v0",
"fps": 50,
...
},
"policy": {
"type": "act",
"n_obs_steps": 1,
...
},
...
}
```
We can then simply load the config values from this file using:
```bash
lerobot-train \
--config_path=outputs/train/act_aloha_transfer/checkpoints/last/pretrained_model/ \
--output_dir=outputs/train/act_aloha_transfer_2
```
`--config_path` is also a special argument which allows to initialize the config from a local config file. It can point to a directory that contains `train_config.json` or to the config file itself directly.
Similarly to Hydra, we can still override some parameters in the CLI if we want to, e.g.:
```bash
lerobot-train \
--config_path=outputs/train/act_aloha_transfer/checkpoints/last/pretrained_model/ \
--output_dir=outputs/train/act_aloha_transfer_2
--policy.n_action_steps=80
```
> Note: While `--output_dir` is not required in general, in this case we need to specify it since it will otherwise take the value from the `train_config.json` (which is `outputs/train/act_aloha_transfer`). In order to prevent accidental deletion of previous run checkpoints, we raise an error if you're trying to write in an existing directory. This is not the case when resuming a run, which is what you'll learn next.
`--config_path` can also accept the repo_id of a repo on the hub that contains a `train_config.json` file, e.g. running:
```bash
lerobot-train --config_path=lerobot/diffusion_pusht
```
will start a training run with the same configuration used for training [lerobot/diffusion_pusht](https://huggingface.co/lerobot/diffusion_pusht)
## Resume training
Being able to resume a training run is important in case it crashed or aborted for any reason. We'll demonstrate how to do that here.
Let's reuse the command from the previous run and add a few more options:
```bash
lerobot-train \
--policy.type=act \
--dataset.repo_id=lerobot/aloha_sim_transfer_cube_human \
--env.type=aloha \
--env.task=AlohaTransferCube-v0 \
--log_freq=25 \
--save_freq=100 \
--output_dir=outputs/train/run_resumption
```
Here we've taken care to set up the log frequency and checkpointing frequency to low numbers so we can showcase resumption. You should be able to see some logging and have a first checkpoint within 1 minute (depending on hardware). Wait for the first checkpoint to happen, you should see a line that looks like this in your terminal:
```
INFO 2025-01-24 16:10:56 ts/train.py:263 Checkpoint policy after step 100
```
Now let's simulate a crash by killing the process (hit `ctrl`+`c`). We can then simply resume this run from the last checkpoint available with:
```bash
lerobot-train \
--config_path=outputs/train/run_resumption/checkpoints/last/pretrained_model/ \
--resume=true
```
You should see from the logging that your training picks up from where it left off.
Another reason for which you might want to resume a run is simply to extend training and add more training steps. The number of training steps is set by the option `--steps`, which is 100 000 by default.
You could double the number of steps of the previous run with:
```bash
lerobot-train \
--config_path=outputs/train/run_resumption/checkpoints/last/pretrained_model/ \
--resume=true \
--steps=200000
```
## Outputs of a run
In the output directory, there will be a folder called `checkpoints` with the following structure:
```bash
outputs/train/run_resumption/checkpoints
├── 000100 # checkpoint_dir for training step 100
│ ├── pretrained_model/
│ │ ├── config.json # policy config
│ │ ├── model.safetensors # policy weights
│ │ └── train_config.json # train config
│ └── training_state/
│ ├── optimizer_param_groups.json # optimizer param groups
│ ├── optimizer_state.safetensors # optimizer state
│ ├── rng_state.safetensors # rng states
│ ├── scheduler_state.json # scheduler state
│ └── training_step.json # training step
├── 000200
└── last -> 000200 # symlink to the last available checkpoint
```
## Fine-tuning a pre-trained policy
In addition to the features currently in Draccus, we've added a special `.path` argument for the policy, which allows to load a policy as you would with `PreTrainedPolicy.from_pretrained()`. In that case, `path` can be a local directory that contains a checkpoint or a repo_id pointing to a pretrained policy on the hub.
For example, we could fine-tune a [policy pre-trained on the aloha transfer task](https://huggingface.co/lerobot/act_aloha_sim_transfer_cube_human) on the aloha insertion task. We can achieve this with:
```bash
lerobot-train \
--policy.path=lerobot/act_aloha_sim_transfer_cube_human \
--dataset.repo_id=lerobot/aloha_sim_insertion_human \
--env.type=aloha \
--env.task=AlohaInsertion-v0
```
When doing so, keep in mind that the features of the fine-tuning dataset would have to match the input/output features of the pretrained policy.
## Typical logs and metrics
When you start the training process, you will first see your full configuration being printed in the terminal. You can check it to make sure that you configured your run correctly. The final configuration will also be saved with the checkpoint.
After that, you will see training log like this one:
```
INFO 2024-08-14 13:35:12 ts/train.py:192 step:0 smpl:64 ep:1 epch:0.00 loss:1.112 grdn:15.387 lr:2.0e-07 updt_s:1.738 data_s:4.774
```
or evaluation log:
```
INFO 2024-08-14 13:38:45 ts/train.py:226 step:100 smpl:6K ep:52 epch:0.25 ∑rwrd:20.693 success:0.0% eval_s:120.266
```
These logs will also be saved in wandb if `wandb.enable` is set to `true`. Here are the meaning of some abbreviations:
- `smpl`: number of samples seen during training.
- `ep`: number of episodes seen during training. An episode contains multiple samples in a complete manipulation task.
- `epch`: number of time all unique samples are seen (epoch).
- `grdn`: gradient norm.
- `∑rwrd`: compute the sum of rewards in every evaluation episode and then take an average of them.
- `success`: average success rate of eval episodes. Reward and success are usually different except for the sparsing reward setting, where reward=1 only when the task is completed successfully.
- `eval_s`: time to evaluate the policy in the environment, in second.
- `updt_s`: time to update the network parameters, in second.
- `data_s`: time to load a batch of data, in second.
Some metrics are useful for initial performance profiling. For example, if you find the current GPU utilization is low via the `nvidia-smi` command and `data_s` sometimes is too high, you may need to modify batch size or number of dataloading workers to accelerate dataloading. We also recommend [pytorch profiler](https://github.com/huggingface/lerobot?tab=readme-ov-file#improve-your-code-with-profiling) for detailed performance probing.
## In short
We'll summarize here the main use cases to remember from this tutorial.
#### Train a policy from scratch CLI
```bash
lerobot-train \
--policy.type=act \ # <- select 'act' policy
--env.type=pusht \ # <- select 'pusht' environment
--dataset.repo_id=lerobot/pusht # <- train on this dataset
```
#### Train a policy from scratch - config file + CLI
```bash
lerobot-train \
--config_path=path/to/pretrained_model \ # <- can also be a repo_id
--policy.n_action_steps=80 # <- you may still override values
```
#### Resume/continue a training run
```bash
lerobot-train \
--config_path=checkpoint/pretrained_model/ \
--resume=true \
--steps=200000 # <- you can change some training parameters
```
#### Fine-tuning
```bash
lerobot-train \
--policy.path=lerobot/act_aloha_sim_transfer_cube_human \ # <- can also be a local path to a checkpoint
--dataset.repo_id=lerobot/aloha_sim_insertion_human \
--env.type=aloha \
--env.task=AlohaInsertion-v0
```
---
Now that you know the basics of how to train a policy, you might want to know how to apply this knowledge to actual robots, or how to record your own datasets and train policies on your specific task?
If that's the case, head over to the next tutorial [`7_get_started_with_real_robot.md`](./7_get_started_with_real_robot.md).
Or in the meantime, happy training! 🤗
examples/backward_compatibility/replay.py
+3 -4
View File
@@ -44,7 +44,6 @@ from lerobot.robots import ( # noqa: F401
so100_follower,
so101_follower,
)
from lerobot.utils.constants import ACTION
from lerobot.utils.robot_utils import busy_wait
from lerobot.utils.utils import (
init_logging,
@@ -79,16 +78,16 @@ def replay(cfg: ReplayConfig):
robot = make_robot_from_config(cfg.robot)
dataset = LeRobotDataset(cfg.dataset.repo_id, root=cfg.dataset.root, episodes=[cfg.dataset.episode])
actions = dataset.hf_dataset.select_columns(ACTION)
actions = dataset.hf_dataset.select_columns("action")
robot.connect()
log_say("Replaying episode", cfg.play_sounds, blocking=True)
for idx in range(dataset.num_frames):
start_episode_t = time.perf_counter()
action_array = actions[idx][ACTION]
action_array = actions[idx]["action"]
action = {}
for i, name in enumerate(dataset.features[ACTION]["names"]):
for i, name in enumerate(dataset.features["action"]["names"]):
key = f"{name.removeprefix('main_')}.pos"
action[key] = action_array[i].item()
examples/dataset/use_dataset_image_transforms.py
-177
View File
@@ -1,177 +0,0 @@
#!/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.
"""
This example demonstrates how to use image transforms with LeRobot datasets for data augmentation during training.
Image transforms are applied to camera frames to improve model robustness and generalization. They are applied
at training time only, not during dataset recording, allowing you to experiment with different augmentations
without re-recording data.
"""
import torch
from torchvision.transforms import v2
from torchvision.transforms.functional import to_pil_image
from lerobot.datasets.lerobot_dataset import LeRobotDataset
from lerobot.datasets.transforms import ImageTransformConfig, ImageTransforms, ImageTransformsConfig
def save_image(tensor, filename):
"""Helper function to save a tensor as an image file."""
if tensor.dim() == 3: # [C, H, W]
if tensor.max() > 1.0:
tensor = tensor / 255.0
tensor = torch.clamp(tensor, 0.0, 1.0)
pil_image = to_pil_image(tensor)
pil_image.save(filename)
print(f"Saved: {filename}")
else:
print(f"Skipped {filename}: unexpected tensor shape {tensor.shape}")
def example_1_default_transforms():
"""Example 1: Use default transform configuration and save original vs transformed images"""
print("\n Example 1: Default Transform Configuration with Image Saving")
repo_id = "pepijn223/record_main_0" # Example dataset
try:
# Load dataset without transforms (original)
dataset_original = LeRobotDataset(repo_id=repo_id)
# Load dataset with transforms enabled
transforms_config = ImageTransformsConfig(
enable=True, # Enable transforms (disabled by default)
max_num_transforms=2, # Apply up to 2 transforms per frame
random_order=False, # Apply in standard order
)
dataset_with_transforms = LeRobotDataset(
repo_id=repo_id, image_transforms=ImageTransforms(transforms_config)
)
# Save original and transformed images for comparison
if len(dataset_original) > 0:
frame_idx = 0 # Use first frame
original_sample = dataset_original[frame_idx]
transformed_sample = dataset_with_transforms[frame_idx]
print(f"Saving comparison images (frame {frame_idx}):")
for cam_key in dataset_original.meta.camera_keys:
if cam_key in original_sample and cam_key in transformed_sample:
cam_name = cam_key.replace(".", "_").replace("/", "_")
# Save original and transformed images
save_image(original_sample[cam_key], f"{cam_name}_original.png")
save_image(transformed_sample[cam_key], f"{cam_name}_transformed.png")
except Exception as e:
print(f"Could not load dataset '{repo_id}': {e}")
def example_2_custom_transforms():
"""Example 2: Create custom transform configuration and save examples"""
print("\n Example 2: Custom Transform Configuration")
repo_id = "pepijn223/record_main_0" # Example dataset
try:
# Create custom transform configuration with strong effects
custom_transforms_config = ImageTransformsConfig(
enable=True,
max_num_transforms=2, # Apply up to 2 transforms per frame
random_order=True, # Apply transforms in random order
tfs={
"brightness": ImageTransformConfig(
weight=1.0,
type="ColorJitter",
kwargs={"brightness": (0.5, 1.5)}, # Strong brightness range
),
"contrast": ImageTransformConfig(
weight=1.0, # Higher weight = more likely to be selected
type="ColorJitter",
kwargs={"contrast": (0.6, 1.4)}, # Strong contrast
),
"sharpness": ImageTransformConfig(
weight=0.5, # Lower weight = less likely to be selected
type="SharpnessJitter",
kwargs={"sharpness": (0.2, 2.0)}, # Strong sharpness variation
),
},
)
dataset_with_custom_transforms = LeRobotDataset(
repo_id=repo_id, image_transforms=ImageTransforms(custom_transforms_config)
)
# Save examples with strong transforms
if len(dataset_with_custom_transforms) > 0:
sample = dataset_with_custom_transforms[0]
print("Saving custom transform examples:")
for cam_key in dataset_with_custom_transforms.meta.camera_keys:
if cam_key in sample:
cam_name = cam_key.replace(".", "_").replace("/", "_")
save_image(sample[cam_key], f"{cam_name}_custom_transforms.png")
except Exception as e:
print(f"Could not load dataset '{repo_id}': {e}")
def example_3_torchvision_transforms():
"""Example 3: Use pure torchvision transforms and save examples"""
print("\n Example 3: Pure Torchvision Transforms")
repo_id = "pepijn223/record_main_0" # Example dataset
try:
# Create torchvision transform pipeline
torchvision_transforms = v2.Compose(
[
v2.ColorJitter(brightness=0.3, contrast=0.3, saturation=0.3, hue=0.1),
v2.GaussianBlur(kernel_size=3, sigma=(0.1, 2.0)),
v2.RandomRotation(degrees=10), # Small rotation
]
)
dataset_with_torchvision = LeRobotDataset(repo_id=repo_id, image_transforms=torchvision_transforms)
# Save examples with torchvision transforms
if len(dataset_with_torchvision) > 0:
sample = dataset_with_torchvision[0]
print("Saving torchvision transform examples:")
for cam_key in dataset_with_torchvision.meta.camera_keys:
if cam_key in sample:
cam_name = cam_key.replace(".", "_").replace("/", "_")
save_image(sample[cam_key], f"{cam_name}_torchvision.png")
except Exception as e:
print(f"Could not load dataset '{repo_id}': {e}")
def main():
"""Run all examples"""
print("LeRobot Dataset Image Transforms Examples")
example_1_default_transforms()
example_2_custom_transforms()
example_3_torchvision_transforms()
if __name__ == "__main__":
main()
examples/dataset/use_dataset_tools.py
-124
View File
@@ -1,124 +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 script demonstrating dataset tools utilities.
This script shows how to:
1. Delete episodes from a dataset
2. Split a dataset into train/val sets
3. Add/remove features
4. Merge datasets
Usage:
python examples/dataset/use_dataset_tools.py
"""
import numpy as np
from lerobot.datasets.dataset_tools import (
add_features,
delete_episodes,
merge_datasets,
modify_features,
remove_feature,
split_dataset,
)
from lerobot.datasets.lerobot_dataset import LeRobotDataset
def main():
dataset = LeRobotDataset("lerobot/pusht")
print(f"Original dataset: {dataset.meta.total_episodes} episodes, {dataset.meta.total_frames} frames")
print(f"Features: {list(dataset.meta.features.keys())}")
print("\n1. Deleting episodes 0 and 2...")
filtered_dataset = delete_episodes(dataset, episode_indices=[0, 2], repo_id="lerobot/pusht_filtered")
print(f"Filtered dataset: {filtered_dataset.meta.total_episodes} episodes")
print("\n2. Splitting dataset into train/val...")
splits = split_dataset(
dataset,
splits={"train": 0.8, "val": 0.2},
)
print(f"Train split: {splits['train'].meta.total_episodes} episodes")
print(f"Val split: {splits['val'].meta.total_episodes} episodes")
print("\n3. Adding features...")
reward_values = np.random.randn(dataset.meta.total_frames).astype(np.float32)
def compute_success(row_dict, episode_index, frame_index):
episode_length = 10
return float(frame_index >= episode_length - 10)
dataset_with_features = add_features(
dataset,
features={
"reward": (
reward_values,
{"dtype": "float32", "shape": (1,), "names": None},
),
"success": (
compute_success,
{"dtype": "float32", "shape": (1,), "names": None},
),
},
repo_id="lerobot/pusht_with_features",
)
print(f"New features: {list(dataset_with_features.meta.features.keys())}")
print("\n4. Removing the success feature...")
dataset_cleaned = remove_feature(
dataset_with_features, feature_names="success", repo_id="lerobot/pusht_cleaned"
)
print(f"Features after removal: {list(dataset_cleaned.meta.features.keys())}")
print("\n5. Using modify_features to add and remove features simultaneously...")
dataset_modified = modify_features(
dataset_with_features,
add_features={
"discount": (
np.ones(dataset.meta.total_frames, dtype=np.float32) * 0.99,
{"dtype": "float32", "shape": (1,), "names": None},
),
},
remove_features="reward",
repo_id="lerobot/pusht_modified",
)
print(f"Modified features: {list(dataset_modified.meta.features.keys())}")
print("\n6. Merging train and val splits back together...")
merged = merge_datasets([splits["train"], splits["val"]], output_repo_id="lerobot/pusht_merged")
print(f"Merged dataset: {merged.meta.total_episodes} episodes")
print("\n7. Complex workflow example...")
if len(dataset.meta.camera_keys) > 1:
camera_to_remove = dataset.meta.camera_keys[0]
print(f"Removing camera: {camera_to_remove}")
dataset_no_cam = remove_feature(
dataset, feature_names=camera_to_remove, repo_id="pusht_no_first_camera"
)
print(f"Remaining cameras: {dataset_no_cam.meta.camera_keys}")
print("\nDone! Check ~/.cache/huggingface/lerobot/ for the created datasets.")
if __name__ == "__main__":
main()
examples/lekiwi/evaluate.py
+13 -61
View File
@@ -1,54 +1,31 @@
# !/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.
from lerobot.datasets.lerobot_dataset import LeRobotDataset
from lerobot.datasets.utils import hw_to_dataset_features
from lerobot.policies.act.modeling_act import ACTPolicy
from lerobot.policies.factory import make_pre_post_processors
from lerobot.processor import make_default_processors
from lerobot.record import record_loop
from lerobot.robots.lekiwi import LeKiwiClient, LeKiwiClientConfig
from lerobot.scripts.lerobot_record import record_loop
from lerobot.utils.constants import ACTION, OBS_STR
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.utils.visualization_utils import _init_rerun
NUM_EPISODES = 2
FPS = 30
EPISODE_TIME_SEC = 60
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
# Create the robot and teleoperator configurations
robot_config = LeKiwiClientConfig(remote_ip="172.18.134.136", id="lekiwi")
robot = LeKiwiClient(robot_config)
# Create policy
policy = ACTPolicy.from_pretrained(HF_MODEL_ID)
policy = ACTPolicy.from_pretrained("<hf_username>/<policy_repo_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)
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}
# Create the dataset
dataset = LeRobotDataset.create(
repo_id=HF_DATASET_ID,
repo_id="<hf_username>/<eval_dataset_repo_id>",
fps=FPS,
features=dataset_features,
robot_type=robot.name,
@@ -56,52 +33,33 @@ dataset = LeRobotDataset.create(
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
# 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()
_init_rerun(session_name="recording")
# 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
# Run the policy inference loop
record_loop(
robot=robot,
events=events,
fps=FPS,
policy=policy,
preprocessor=preprocessor, # Pass the pre and post policy processors
postprocessor=postprocessor,
dataset=dataset,
control_time_s=EPISODE_TIME_SEC,
single_task=TASK_DESCRIPTION,
display_data=True,
teleop_action_processor=teleop_action_processor,
robot_action_processor=robot_action_processor,
robot_observation_processor=robot_observation_processor,
)
# Reset the environment if not stopping or re-recording
# Logic for reset env
if not events["stop_recording"] and (
(recorded_episodes < NUM_EPISODES - 1) or events["rerecord_episode"]
):
@@ -113,9 +71,6 @@ while recorded_episodes < NUM_EPISODES and not events["stop_recording"]:
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"]:
@@ -125,14 +80,11 @@ while recorded_episodes < NUM_EPISODES and not events["stop_recording"]:
dataset.clear_episode_buffer()
continue
# Save episode
dataset.save_episode()
recorded_episodes += 1
# Clean up
log_say("Stop recording")
# Upload to hub and clean up
dataset.push_to_hub()
robot.disconnect()
listener.stop()
dataset.finalize()
dataset.push_to_hub()
examples/lekiwi/record.py
+14 -48
View File
@@ -1,60 +1,37 @@
# !/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.
from lerobot.datasets.lerobot_dataset import LeRobotDataset
from lerobot.datasets.utils import hw_to_dataset_features
from lerobot.processor import make_default_processors
from lerobot.record import record_loop
from lerobot.robots.lekiwi.config_lekiwi import LeKiwiClientConfig
from lerobot.robots.lekiwi.lekiwi_client import LeKiwiClient
from lerobot.scripts.lerobot_record import record_loop
from lerobot.teleoperators.keyboard import KeyboardTeleop, KeyboardTeleopConfig
from lerobot.teleoperators.so100_leader import SO100Leader, SO100LeaderConfig
from lerobot.utils.constants import ACTION, OBS_STR
from lerobot.utils.control_utils import init_keyboard_listener
from lerobot.utils.utils import log_say
from lerobot.utils.visualization_utils import init_rerun
from lerobot.utils.visualization_utils import _init_rerun
NUM_EPISODES = 2
NUM_EPISODES = 3
FPS = 30
EPISODE_TIME_SEC = 30
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()
# 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()
# 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)
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}
# Create the dataset
dataset = LeRobotDataset.create(
repo_id=HF_REPO_ID,
repo_id="<hf_username>/<dataset_repo_id>",
fps=FPS,
features=dataset_features,
robot_type=robot.name,
@@ -62,25 +39,23 @@ dataset = LeRobotDataset.create(
image_writer_threads=4,
)
# 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
_init_rerun(session_name="lekiwi_record")
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!")
raise ValueError("Robot, leader arm of keyboard 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
# Run the record loop
record_loop(
robot=robot,
events=events,
@@ -90,12 +65,9 @@ while recorded_episodes < NUM_EPISODES and not events["stop_recording"]:
control_time_s=EPISODE_TIME_SEC,
single_task=TASK_DESCRIPTION,
display_data=True,
teleop_action_processor=teleop_action_processor,
robot_action_processor=robot_action_processor,
robot_observation_processor=robot_observation_processor,
)
# Reset the environment if not stopping or re-recording
# Logic for reset env
if not events["stop_recording"] and (
(recorded_episodes < NUM_EPISODES - 1) or events["rerecord_episode"]
):
@@ -108,9 +80,6 @@ while recorded_episodes < NUM_EPISODES and not events["stop_recording"]:
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"]:
@@ -120,16 +89,13 @@ while recorded_episodes < NUM_EPISODES and not events["stop_recording"]:
dataset.clear_episode_buffer()
continue
# Save episode
dataset.save_episode()
recorded_episodes += 1
# Clean up
log_say("Stop recording")
# Upload to hub and clean up
dataset.push_to_hub()
robot.disconnect()
leader_arm.disconnect()
keyboard.disconnect()
listener.stop()
dataset.finalize()
dataset.push_to_hub()
examples/lekiwi/replay.py
+4 -32
View File
@@ -1,60 +1,32 @@
# !/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.
import time
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 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")
# 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)
actions = dataset.hf_dataset.select_columns("action")
# Connect to the robot
robot.connect()
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)):
for idx in range(dataset.num_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"])
name: float(actions[idx]["action"][i]) for i, name in enumerate(dataset.features["action"]["names"])
}
# Send action to robot
_ = robot.send_action(action)
robot.send_action(action)
busy_wait(max(1.0 / dataset.fps - (time.perf_counter() - t0), 0.0))
examples/lekiwi/teleoperate.py
+7 -32
View File
@@ -1,26 +1,10 @@
# !/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.
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 busy_wait
from lerobot.utils.visualization_utils import init_rerun, log_rerun_data
from lerobot.utils.visualization_utils import _init_rerun, log_rerun_data
FPS = 30
@@ -29,44 +13,35 @@ 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)
# 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(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!")
raise ValueError("Robot, leader arm of keyboard is not connected!")
print("Starting teleop loop...")
while True:
t0 = time.perf_counter()
# 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)
log_rerun_data(observation, {**arm_action, **base_action})
action = {**arm_action, **base_action} if len(base_action) > 0 else arm_action
# Send action to robot
_ = robot.send_action(action)
# Visualize
log_rerun_data(observation=observation, action=action)
robot.send_action(action)
busy_wait(max(1.0 / FPS - (time.perf_counter() - t0), 0.0))
examples/phone_to_so100/evaluate.py
-199
View File
@@ -1,199 +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.
from lerobot.cameras.opencv.configuration_opencv import OpenCVCameraConfig
from lerobot.configs.types import FeatureType, PolicyFeature
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.model.kinematics import RobotKinematics
from lerobot.policies.act.modeling_act import ACTPolicy
from lerobot.policies.factory import make_pre_post_processors
from lerobot.processor import (
RobotAction,
RobotObservation,
RobotProcessorPipeline,
make_default_teleop_action_processor,
)
from lerobot.processor.converters import (
observation_to_transition,
robot_action_observation_to_transition,
transition_to_observation,
transition_to_robot_action,
)
from lerobot.robots.so100_follower.config_so100_follower import SO100FollowerConfig
from lerobot.robots.so100_follower.robot_kinematic_processor import (
ForwardKinematicsJointsToEE,
InverseKinematicsEEToJoints,
)
from lerobot.robots.so100_follower.so100_follower import SO100Follower
from lerobot.scripts.lerobot_record import record_loop
from lerobot.utils.control_utils import init_keyboard_listener
from lerobot.utils.utils import log_say
from lerobot.utils.visualization_utils import init_rerun
NUM_EPISODES = 5
FPS = 30
EPISODE_TIME_SEC = 60
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,
)
robot = SO100Follower(robot_config)
# 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()),
)
# 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,
),
),
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,
)
# 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
# Save episode
dataset.save_episode()
episode_idx += 1
# Clean up
log_say("Stop recording")
robot.disconnect()
listener.stop()
dataset.finalize()
dataset.push_to_hub()
examples/phone_to_so100/record.py
-205
View File
@@ -1,205 +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.
from lerobot.cameras.opencv.configuration_opencv import OpenCVCameraConfig
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.model.kinematics import RobotKinematics
from lerobot.processor import RobotAction, RobotObservation, RobotProcessorPipeline
from lerobot.processor.converters import (
observation_to_transition,
robot_action_observation_to_transition,
transition_to_observation,
transition_to_robot_action,
)
from lerobot.robots.so100_follower.config_so100_follower import SO100FollowerConfig
from lerobot.robots.so100_follower.robot_kinematic_processor import (
EEBoundsAndSafety,
EEReferenceAndDelta,
ForwardKinematicsJointsToEE,
GripperVelocityToJoint,
InverseKinematicsEEToJoints,
)
from lerobot.robots.so100_follower.so100_follower import SO100Follower
from lerobot.scripts.lerobot_record import record_loop
from lerobot.teleoperators.phone.config_phone import PhoneConfig, PhoneOS
from lerobot.teleoperators.phone.phone_processor import MapPhoneActionToRobotAction
from lerobot.teleoperators.phone.teleop_phone import Phone
from lerobot.utils.control_utils import init_keyboard_listener
from lerobot.utils.utils import log_say
from lerobot.utils.visualization_utils import init_rerun
NUM_EPISODES = 2
FPS = 30
EPISODE_TIME_SEC = 60
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
# 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()),
)
# 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,
),
),
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,
)
# 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
# Save episode
dataset.save_episode()
episode_idx += 1
# Clean up
log_say("Stop recording")
robot.disconnect()
phone.disconnect()
listener.stop()
dataset.finalize()
dataset.push_to_hub()
examples/phone_to_so100/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.
import time
from lerobot.datasets.lerobot_dataset import LeRobotDataset
from lerobot.model.kinematics import RobotKinematics
from lerobot.processor import RobotAction, RobotObservation, RobotProcessorPipeline
from lerobot.processor.converters import (
robot_action_observation_to_transition,
transition_to_robot_action,
)
from lerobot.robots.so100_follower.config_so100_follower import SO100FollowerConfig
from lerobot.robots.so100_follower.robot_kinematic_processor import (
InverseKinematicsEEToJoints,
)
from lerobot.robots.so100_follower.so100_follower import SO100Follower
from lerobot.utils.constants import ACTION
from lerobot.utils.robot_utils import 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
)
# 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()),
)
# 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)
# Connect to the robot
robot.connect()
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()
# 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()
# Dataset EE -> robot joints
joint_action = robot_ee_to_joints_processor((ee_action, robot_obs))
# Send action to robot
_ = robot.send_action(joint_action)
busy_wait(1.0 / dataset.fps - (time.perf_counter() - t0))
# Clean up
robot.disconnect()
examples/phone_to_so100/teleoperate.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 specif
import time
from lerobot.model.kinematics import RobotKinematics
from lerobot.processor import RobotAction, RobotObservation, RobotProcessorPipeline
from lerobot.processor.converters import (
robot_action_observation_to_transition,
transition_to_robot_action,
)
from lerobot.robots.so100_follower.config_so100_follower import SO100FollowerConfig
from lerobot.robots.so100_follower.robot_kinematic_processor import (
EEBoundsAndSafety,
EEReferenceAndDelta,
GripperVelocityToJoint,
InverseKinematicsEEToJoints,
)
from lerobot.robots.so100_follower.so100_follower import SO100Follower
from lerobot.teleoperators.phone.config_phone import PhoneConfig, PhoneOS
from lerobot.teleoperators.phone.phone_processor import MapPhoneActionToRobotAction
from lerobot.teleoperators.phone.teleop_phone import Phone
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
# 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()),
)
# 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()
# 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!")
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 teleop action
phone_obs = teleop_device.get_action()
# 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)
# Visualize
log_rerun_data(observation=phone_obs, action=joint_action)
busy_wait(max(1.0 / FPS - (time.perf_counter() - t0), 0.0))
examples/port_datasets/display_error_files.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.
import argparse
import json
from pathlib import Path
def find_missing_workers(completions_dir, world_size):
"""Find workers that are not completed and returns their indices."""
full = list(range(world_size))
completed = []
for path in completions_dir.glob("*"):
if path.name in [".", ".."]:
continue
index = path.name.lstrip("0")
index = 0 if index == "" else int(index)
completed.append(index)
missing_workers = set(full) - set(completed)
return missing_workers
def find_output_files(slurm_dir, worker_indices):
"""Find output files associated to worker indices, and return tuples
of (worker index, output file path)
"""
out_files = []
for path in slurm_dir.glob("*.out"):
_, worker_id = path.name.replace(".out", "").split("_")
worker_id = int(worker_id)
if worker_id in worker_indices:
out_files.append((worker_id, path))
return out_files
def display_error_files(logs_dir, job_name):
executor_path = Path(logs_dir) / job_name / "executor.json"
completions_dir = Path(logs_dir) / job_name / "completions"
with open(executor_path) as f:
executor = json.load(f)
missing_workers = find_missing_workers(completions_dir, executor["world_size"])
for missing in sorted(missing_workers)[::-1]:
print(missing)
def main():
parser = argparse.ArgumentParser()
parser.add_argument(
"--logs-dir",
type=str,
help="Path to logs directory for `datatrove`.",
)
parser.add_argument(
"--job-name",
type=str,
default="port_droid",
help="Job name used in slurm, and name of the directory created inside the provided logs directory.",
)
args = parser.parse_args()
display_error_files(**vars(args))
if __name__ == "__main__":
main()
examples/port_datasets/port_droid.py
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@@ -1,432 +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.
import argparse
import logging
import time
from pathlib import Path
import numpy as np
import tensorflow_datasets as tfds
from lerobot.datasets.lerobot_dataset import LeRobotDataset, LeRobotDatasetMetadata
from lerobot.utils.utils import get_elapsed_time_in_days_hours_minutes_seconds
DROID_SHARDS = 2048
DROID_FPS = 15
DROID_ROBOT_TYPE = "Franka"
# Dataset schema slightly adapted from: https://droid-dataset.github.io/droid/the-droid-dataset.html#-dataset-schema
DROID_FEATURES = {
# true on first step of the episode
"is_first": {
"dtype": "bool",
"shape": (1,),
"names": None,
},
# true on last step of the episode
"is_last": {
"dtype": "bool",
"shape": (1,),
"names": None,
},
# true on last step of the episode if it is a terminal step, True for demos
"is_terminal": {
"dtype": "bool",
"shape": (1,),
"names": None,
},
# language_instruction is also stored as "task" to follow LeRobot standard
"language_instruction": {
"dtype": "string",
"shape": (1,),
"names": None,
},
"language_instruction_2": {
"dtype": "string",
"shape": (1,),
"names": None,
},
"language_instruction_3": {
"dtype": "string",
"shape": (1,),
"names": None,
},
"observation.state.gripper_position": {
"dtype": "float32",
"shape": (1,),
"names": {
"axes": ["gripper"],
},
},
"observation.state.cartesian_position": {
"dtype": "float32",
"shape": (6,),
"names": {
"axes": ["x", "y", "z", "roll", "pitch", "yaw"],
},
},
"observation.state.joint_position": {
"dtype": "float32",
"shape": (7,),
"names": {
"axes": ["joint_0", "joint_1", "joint_2", "joint_3", "joint_4", "joint_5", "joint_6"],
},
},
# Add this new feature to follow LeRobot standard of using joint position + gripper
"observation.state": {
"dtype": "float32",
"shape": (8,),
"names": {
"axes": ["joint_0", "joint_1", "joint_2", "joint_3", "joint_4", "joint_5", "joint_6", "gripper"],
},
},
# Initially called wrist_image_left
"observation.images.wrist_left": {
"dtype": "video",
"shape": (180, 320, 3),
"names": [
"height",
"width",
"channels",
],
},
# Initially called exterior_image_1_left
"observation.images.exterior_1_left": {
"dtype": "video",
"shape": (180, 320, 3),
"names": [
"height",
"width",
"channels",
],
},
# Initially called exterior_image_2_left
"observation.images.exterior_2_left": {
"dtype": "video",
"shape": (180, 320, 3),
"names": [
"height",
"width",
"channels",
],
},
"action.gripper_position": {
"dtype": "float32",
"shape": (1,),
"names": {
"axes": ["gripper"],
},
},
"action.gripper_velocity": {
"dtype": "float32",
"shape": (1,),
"names": {
"axes": ["gripper"],
},
},
"action.cartesian_position": {
"dtype": "float32",
"shape": (6,),
"names": {
"axes": ["x", "y", "z", "roll", "pitch", "yaw"],
},
},
"action.cartesian_velocity": {
"dtype": "float32",
"shape": (6,),
"names": {
"axes": ["x", "y", "z", "roll", "pitch", "yaw"],
},
},
"action.joint_position": {
"dtype": "float32",
"shape": (7,),
"names": {
"axes": ["joint_0", "joint_1", "joint_2", "joint_3", "joint_4", "joint_5", "joint_6"],
},
},
"action.joint_velocity": {
"dtype": "float32",
"shape": (7,),
"names": {
"axes": ["joint_0", "joint_1", "joint_2", "joint_3", "joint_4", "joint_5", "joint_6"],
},
},
# This feature was called "action" in RLDS dataset and consists of [6x joint velocities, 1x gripper position]
"action.original": {
"dtype": "float32",
"shape": (7,),
"names": {
"axes": ["x", "y", "z", "roll", "pitch", "yaw", "gripper"],
},
},
# Add this new feature to follow LeRobot standard of using joint position + gripper
"action": {
"dtype": "float32",
"shape": (8,),
"names": {
"axes": ["joint_0", "joint_1", "joint_2", "joint_3", "joint_4", "joint_5", "joint_6", "gripper"],
},
},
"discount": {
"dtype": "float32",
"shape": (1,),
"names": None,
},
"reward": {
"dtype": "float32",
"shape": (1,),
"names": None,
},
# Meta data that are the same for all frames in the episode
"task_category": {
"dtype": "string",
"shape": (1,),
"names": None,
},
"building": {
"dtype": "string",
"shape": (1,),
"names": None,
},
"collector_id": {
"dtype": "string",
"shape": (1,),
"names": None,
},
"date": {
"dtype": "string",
"shape": (1,),
"names": None,
},
"camera_extrinsics.wrist_left": {
"dtype": "float32",
"shape": (6,),
"names": {
"axes": ["x", "y", "z", "roll", "pitch", "yaw"],
},
},
"camera_extrinsics.exterior_1_left": {
"dtype": "float32",
"shape": (6,),
"names": {
"axes": ["x", "y", "z", "roll", "pitch", "yaw"],
},
},
"camera_extrinsics.exterior_2_left": {
"dtype": "float32",
"shape": (6,),
"names": {
"axes": ["x", "y", "z", "roll", "pitch", "yaw"],
},
},
"is_episode_successful": {
"dtype": "bool",
"shape": (1,),
"names": None,
},
}
def is_episode_successful(tf_episode_metadata):
# Adapted from: https://github.com/droid-dataset/droid_policy_learning/blob/dd1020eb20d981f90b5ff07dc80d80d5c0cb108b/robomimic/utils/rlds_utils.py#L8
return "/success/" in tf_episode_metadata["file_path"].numpy().decode()
def generate_lerobot_frames(tf_episode):
m = tf_episode["episode_metadata"]
frame_meta = {
"task_category": m["building"].numpy().decode(),
"building": m["building"].numpy().decode(),
"collector_id": m["collector_id"].numpy().decode(),
"date": m["date"].numpy().decode(),
"camera_extrinsics.wrist_left": m["extrinsics_wrist_cam"].numpy(),
"camera_extrinsics.exterior_1_left": m["extrinsics_exterior_cam_1"].numpy(),
"camera_extrinsics.exterior_2_left": m["extrinsics_exterior_cam_2"].numpy(),
"is_episode_successful": np.array([is_episode_successful(m)]),
}
for f in tf_episode["steps"]:
# Dataset schema slightly adapted from: https://droid-dataset.github.io/droid/the-droid-dataset.html#-dataset-schema
frame = {
"is_first": np.array([f["is_first"].numpy()]),
"is_last": np.array([f["is_last"].numpy()]),
"is_terminal": np.array([f["is_terminal"].numpy()]),
"language_instruction": f["language_instruction"].numpy().decode(),
"language_instruction_2": f["language_instruction_2"].numpy().decode(),
"language_instruction_3": f["language_instruction_3"].numpy().decode(),
"observation.state.gripper_position": f["observation"]["gripper_position"].numpy(),
"observation.state.cartesian_position": f["observation"]["cartesian_position"].numpy(),
"observation.state.joint_position": f["observation"]["joint_position"].numpy(),
"observation.images.wrist_left": f["observation"]["wrist_image_left"].numpy(),
"observation.images.exterior_1_left": f["observation"]["exterior_image_1_left"].numpy(),
"observation.images.exterior_2_left": f["observation"]["exterior_image_2_left"].numpy(),
"action.gripper_position": f["action_dict"]["gripper_position"].numpy(),
"action.gripper_velocity": f["action_dict"]["gripper_velocity"].numpy(),
"action.cartesian_position": f["action_dict"]["cartesian_position"].numpy(),
"action.cartesian_velocity": f["action_dict"]["cartesian_velocity"].numpy(),
"action.joint_position": f["action_dict"]["joint_position"].numpy(),
"action.joint_velocity": f["action_dict"]["joint_velocity"].numpy(),
"discount": np.array([f["discount"].numpy()]),
"reward": np.array([f["reward"].numpy()]),
"action.original": f["action"].numpy(),
}
# language_instruction is also stored as "task" to follow LeRobot standard
frame["task"] = frame["language_instruction"]
# Add this new feature to follow LeRobot standard of using joint position + gripper
frame["observation.state"] = np.concatenate(
[frame["observation.state.joint_position"], frame["observation.state.gripper_position"]]
)
frame["action"] = np.concatenate([frame["action.joint_position"], frame["action.gripper_position"]])
# Meta data that are the same for all frames in the episode
frame.update(frame_meta)
# Cast fp64 to fp32
for key in frame:
if isinstance(frame[key], np.ndarray) and frame[key].dtype == np.float64:
frame[key] = frame[key].astype(np.float32)
yield frame
def port_droid(
raw_dir: Path,
repo_id: str,
push_to_hub: bool = False,
num_shards: int | None = None,
shard_index: int | None = None,
):
dataset_name = raw_dir.parent.name
version = raw_dir.name
data_dir = raw_dir.parent.parent
builder = tfds.builder(f"{dataset_name}/{version}", data_dir=data_dir, version="")
if num_shards is not None:
tfds_num_shards = builder.info.splits["train"].num_shards
if tfds_num_shards != DROID_SHARDS:
raise ValueError(
f"Number of shards of Droid dataset is expected to be {DROID_SHARDS} but is {tfds_num_shards}."
)
if num_shards != tfds_num_shards:
raise ValueError(
f"We only shard over the fixed number of shards provided by tensorflow dataset ({tfds_num_shards}), but {num_shards} shards provided instead."
)
if shard_index >= tfds_num_shards:
raise ValueError(
f"Shard index is greater than the num of shards ({shard_index} >= {num_shards})."
)
raw_dataset = builder.as_dataset(split=f"train[{shard_index}shard]")
else:
raw_dataset = builder.as_dataset(split="train")
lerobot_dataset = LeRobotDataset.create(
repo_id=repo_id,
robot_type=DROID_ROBOT_TYPE,
fps=DROID_FPS,
features=DROID_FEATURES,
)
start_time = time.time()
num_episodes = raw_dataset.cardinality().numpy().item()
logging.info(f"Number of episodes {num_episodes}")
for episode_index, episode in enumerate(raw_dataset):
elapsed_time = time.time() - start_time
d, h, m, s = get_elapsed_time_in_days_hours_minutes_seconds(elapsed_time)
logging.info(
f"{episode_index} / {num_episodes} episodes processed (after {d} days, {h} hours, {m} minutes, {s:.3f} seconds)"
)
for frame in generate_lerobot_frames(episode):
lerobot_dataset.add_frame(frame)
lerobot_dataset.save_episode()
logging.info("Save_episode")
lerobot_dataset.finalize()
if push_to_hub:
lerobot_dataset.push_to_hub(
# Add openx tag, since it belongs to the openx collection of datasets
tags=["openx"],
private=False,
)
def validate_dataset(repo_id):
"""Sanity check that ensure meta data can be loaded and all files are present."""
meta = LeRobotDatasetMetadata(repo_id)
if meta.total_episodes == 0:
raise ValueError("Number of episodes is 0.")
for ep_idx in range(meta.total_episodes):
data_path = meta.root / meta.get_data_file_path(ep_idx)
if not data_path.exists():
raise ValueError(f"Parquet file is missing in: {data_path}")
for vid_key in meta.video_keys:
vid_path = meta.root / meta.get_video_file_path(ep_idx, vid_key)
if not vid_path.exists():
raise ValueError(f"Video file is missing in: {vid_path}")
def main():
parser = argparse.ArgumentParser()
parser.add_argument(
"--raw-dir",
type=Path,
required=True,
help="Directory containing input raw datasets (e.g. `path/to/dataset` or `path/to/dataset/version).",
)
parser.add_argument(
"--repo-id",
type=str,
help="Repositery identifier on Hugging Face: a community or a user name `/` the name of the dataset, required when push-to-hub is True",
)
parser.add_argument(
"--push-to-hub",
action="store_true",
help="Upload to hub.",
)
parser.add_argument(
"--num-shards",
type=int,
default=None,
help="Number of shards. Can be either None to load the full dataset, or 2048 to load one of the 2048 tensorflow dataset files.",
)
parser.add_argument(
"--shard-index",
type=int,
default=None,
help="Index of the shard. Can be either None to load the full dataset, or in [0,2047] to load one of the 2048 tensorflow dataset files.",
)
args = parser.parse_args()
port_droid(**vars(args))
if __name__ == "__main__":
main()
examples/port_datasets/slurm_aggregate_shards.py
-148
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@@ -1,148 +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.
import argparse
import logging
from pathlib import Path
from datatrove.executor import LocalPipelineExecutor
from datatrove.executor.slurm import SlurmPipelineExecutor
from datatrove.pipeline.base import PipelineStep
from port_datasets.droid_rlds.port_droid import DROID_SHARDS
from lerobot.datasets.aggregate import aggregate_datasets
from lerobot.utils.utils import init_logging
class AggregateDatasets(PipelineStep):
def __init__(
self,
repo_ids: list[str],
aggregated_repo_id: str,
):
super().__init__()
self.repo_ids = repo_ids
self.aggr_repo_id = aggregated_repo_id
def run(self, data=None, rank: int = 0, world_size: int = 1):
init_logging()
# Since aggregate_datasets already handles parallel processing internally,
# we only need one worker to run the entire aggregation
if rank == 0:
logging.info(f"Starting aggregation of {len(self.repo_ids)} datasets into {self.aggr_repo_id}")
aggregate_datasets(self.repo_ids, self.aggr_repo_id)
logging.info("Aggregation complete!")
else:
logging.info(f"Worker {rank} skipping - only worker 0 performs aggregation")
def make_aggregate_executor(
repo_ids, repo_id, job_name, logs_dir, workers, partition, cpus_per_task, mem_per_cpu, slurm=True
):
kwargs = {
"pipeline": [
AggregateDatasets(repo_ids, repo_id),
],
"logging_dir": str(logs_dir / job_name),
}
if slurm:
# For aggregation, we only need 1 task since aggregate_datasets handles everything
kwargs.update(
{
"job_name": job_name,
"tasks": 1, # Only need 1 task for aggregation
"workers": 1, # Only need 1 worker
"time": "08:00:00",
"partition": partition,
"cpus_per_task": cpus_per_task,
"sbatch_args": {"mem-per-cpu": mem_per_cpu},
}
)
executor = SlurmPipelineExecutor(**kwargs)
else:
kwargs.update(
{
"tasks": 1,
"workers": 1,
}
)
executor = LocalPipelineExecutor(**kwargs)
return executor
def main():
parser = argparse.ArgumentParser()
parser.add_argument(
"--repo-id",
type=str,
help="Repository identifier on Hugging Face: a community or a user name `/` the name of the dataset, required when push-to-hub is True.",
)
parser.add_argument(
"--logs-dir",
type=Path,
help="Path to logs directory for `datatrove`.",
)
parser.add_argument(
"--job-name",
type=str,
default="aggr_droid",
help="Job name used in slurm, and name of the directory created inside the provided logs directory.",
)
parser.add_argument(
"--slurm",
type=int,
default=1,
help="Launch over slurm. Use `--slurm 0` to launch sequentially (useful to debug).",
)
parser.add_argument(
"--workers",
type=int,
default=1, # Changed default to 1 since aggregation doesn't need multiple workers
help="Number of slurm workers. For aggregation, this should be 1.",
)
parser.add_argument(
"--partition",
type=str,
help="Slurm partition. Ideally a CPU partition. No need for GPU partition.",
)
parser.add_argument(
"--cpus-per-task",
type=int,
default=8,
help="Number of cpus that each slurm worker will use.",
)
parser.add_argument(
"--mem-per-cpu",
type=str,
default="1950M",
help="Memory per cpu that each worker will use.",
)
args = parser.parse_args()
kwargs = vars(args)
kwargs["slurm"] = kwargs.pop("slurm") == 1
repo_ids = [f"{args.repo_id}_world_{DROID_SHARDS}_rank_{rank}" for rank in range(DROID_SHARDS)]
aggregate_executor = make_aggregate_executor(repo_ids, **kwargs)
aggregate_executor.run()
if __name__ == "__main__":
main()
examples/port_datasets/slurm_port_shards.py
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@@ -1,162 +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.
import argparse
from pathlib import Path
from datatrove.executor import LocalPipelineExecutor
from datatrove.executor.slurm import SlurmPipelineExecutor
from datatrove.pipeline.base import PipelineStep
from port_datasets.droid_rlds.port_droid import DROID_SHARDS
class PortDroidShards(PipelineStep):
def __init__(
self,
raw_dir: Path | str,
repo_id: str = None,
):
super().__init__()
self.raw_dir = Path(raw_dir)
self.repo_id = repo_id
def run(self, data=None, rank: int = 0, world_size: int = 1):
from datasets.utils.tqdm import disable_progress_bars
from port_datasets.droid_rlds.port_droid import port_droid, validate_dataset
from lerobot.utils.utils import init_logging
init_logging()
disable_progress_bars()
shard_repo_id = f"{self.repo_id}_world_{world_size}_rank_{rank}"
try:
validate_dataset(shard_repo_id)
return
except Exception:
pass # nosec B110 - Dataset doesn't exist yet, continue with porting
port_droid(
self.raw_dir,
shard_repo_id,
push_to_hub=False,
num_shards=world_size,
shard_index=rank,
)
validate_dataset(shard_repo_id)
def make_port_executor(
raw_dir, repo_id, job_name, logs_dir, workers, partition, cpus_per_task, mem_per_cpu, slurm=True
):
kwargs = {
"pipeline": [
PortDroidShards(raw_dir, repo_id),
],
"logging_dir": str(logs_dir / job_name),
}
if slurm:
kwargs.update(
{
"job_name": job_name,
"tasks": DROID_SHARDS,
"workers": workers,
"time": "08:00:00",
"partition": partition,
"cpus_per_task": cpus_per_task,
"sbatch_args": {"mem-per-cpu": mem_per_cpu},
}
)
executor = SlurmPipelineExecutor(**kwargs)
else:
kwargs.update(
{
"tasks": 1,
"workers": 1,
}
)
executor = LocalPipelineExecutor(**kwargs)
return executor
def main():
parser = argparse.ArgumentParser()
parser.add_argument(
"--raw-dir",
type=Path,
required=True,
help="Directory containing input raw datasets (e.g. `path/to/dataset` or `path/to/dataset/version).",
)
parser.add_argument(
"--repo-id",
type=str,
help="Repositery identifier on Hugging Face: a community or a user name `/` the name of the dataset, required when push-to-hub is True.",
)
parser.add_argument(
"--logs-dir",
type=Path,
help="Path to logs directory for `datatrove`.",
)
parser.add_argument(
"--job-name",
type=str,
default="port_droid",
help="Job name used in slurm, and name of the directory created inside the provided logs directory.",
)
parser.add_argument(
"--slurm",
type=int,
default=1,
help="Launch over slurm. Use `--slurm 0` to launch sequentially (useful to debug).",
)
parser.add_argument(
"--workers",
type=int,
default=2048,
help="Number of slurm workers. It should be less than the maximum number of shards.",
)
parser.add_argument(
"--partition",
type=str,
help="Slurm partition. Ideally a CPU partition. No need for GPU partition.",
)
parser.add_argument(
"--cpus-per-task",
type=int,
default=8,
help="Number of cpus that each slurm worker will use.",
)
parser.add_argument(
"--mem-per-cpu",
type=str,
default="1950M",
help="Memory per cpu that each worker will use.",
)
args = parser.parse_args()
kwargs = vars(args)
kwargs["slurm"] = kwargs.pop("slurm") == 1
port_executor = make_port_executor(**kwargs)
port_executor.run()
if __name__ == "__main__":
main()
examples/port_datasets/slurm_upload.py
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@@ -1,281 +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.
import argparse
import logging
import os
from pathlib import Path
from datatrove.executor import LocalPipelineExecutor
from datatrove.executor.slurm import SlurmPipelineExecutor
from datatrove.pipeline.base import PipelineStep
from huggingface_hub import HfApi
from huggingface_hub.constants import REPOCARD_NAME
from port_datasets.droid_rlds.port_droid import DROID_SHARDS
from lerobot.datasets.lerobot_dataset import CODEBASE_VERSION, LeRobotDatasetMetadata
from lerobot.datasets.utils import create_lerobot_dataset_card
from lerobot.utils.utils import init_logging
class UploadDataset(PipelineStep):
def __init__(
self,
repo_id: str,
branch: str | None = None,
revision: str | None = None,
tags: list | None = None,
license: str | None = "apache-2.0",
private: bool = False,
distant_repo_id: str | None = None,
**card_kwargs,
):
super().__init__()
self.repo_id = repo_id
self.distant_repo_id = self.repo_id if distant_repo_id is None else distant_repo_id
self.branch = branch
self.tags = tags
self.license = license
self.private = private
self.card_kwargs = card_kwargs
self.revision = revision if revision else CODEBASE_VERSION
if os.environ.get("HF_HUB_ENABLE_HF_TRANSFER", "0") != "1":
logging.warning(
'HF_HUB_ENABLE_HF_TRANSFER is not set to "1". Install hf_transfer and set the env '
"variable for faster uploads:\npip install hf-transfer\nexport HF_HUB_ENABLE_HF_TRANSFER=1"
)
self.create_repo()
def create_repo(self):
logging.info(f"Loading meta data from {self.repo_id}...")
meta = LeRobotDatasetMetadata(self.repo_id)
logging.info(f"Creating repo {self.distant_repo_id}...")
hub_api = HfApi()
hub_api.create_repo(
repo_id=self.distant_repo_id,
private=self.private,
repo_type="dataset",
exist_ok=True,
)
if self.branch:
hub_api.create_branch(
repo_id=self.distant_repo_id,
branch=self.branch,
revision=self.revision,
repo_type="dataset",
exist_ok=True,
)
if not hub_api.file_exists(
self.distant_repo_id, REPOCARD_NAME, repo_type="dataset", revision=self.branch
):
card = create_lerobot_dataset_card(
tags=self.tags, dataset_info=meta.info, license=self.license, **self.card_kwargs
)
card.push_to_hub(repo_id=self.distant_repo_id, repo_type="dataset", revision=self.branch)
hub_api.create_tag(self.distant_repo_id, tag=CODEBASE_VERSION, repo_type="dataset")
def list_files_recursively(directory):
base_path = Path(directory)
return [str(file.relative_to(base_path)) for file in base_path.rglob("*") if file.is_file()]
logging.info(f"Listing all local files from {self.repo_id}...")
self.file_paths = list_files_recursively(meta.root)
self.file_paths = sorted(self.file_paths)
def create_chunks(self, lst, n):
from itertools import islice
it = iter(lst)
return [list(islice(it, size)) for size in [len(lst) // n + (i < len(lst) % n) for i in range(n)]]
def create_commits(self, additions):
import logging
import math
import random
import time
from huggingface_hub import create_commit
from huggingface_hub.utils import HfHubHTTPError
FILES_BETWEEN_COMMITS = 10 # noqa: N806
BASE_DELAY = 0.1 # noqa: N806
MAX_RETRIES = 12 # noqa: N806
# Split the files into smaller chunks for faster commit
# and avoiding "A commit has happened since" error
num_chunks = math.ceil(len(additions) / FILES_BETWEEN_COMMITS)
chunks = self.create_chunks(additions, num_chunks)
for chunk in chunks:
retries = 0
while True:
try:
create_commit(
self.distant_repo_id,
repo_type="dataset",
operations=chunk,
commit_message=f"DataTrove upload ({len(chunk)} files)",
revision=self.branch,
)
# TODO: every 100 chunks super_squach_commits()
logging.info("create_commit completed!")
break
except HfHubHTTPError as e:
if "A commit has happened since" in e.server_message:
if retries >= MAX_RETRIES:
logging.error(f"Failed to create commit after {MAX_RETRIES=}. Giving up.")
raise e
logging.info("Commit creation race condition issue. Waiting...")
time.sleep(BASE_DELAY * 2**retries + random.uniform(0, 2))
retries += 1
else:
raise e
def run(self, data=None, rank: int = 0, world_size: int = 1):
import logging
from datasets.utils.tqdm import disable_progress_bars
from huggingface_hub import CommitOperationAdd, preupload_lfs_files
from lerobot.datasets.lerobot_dataset import LeRobotDatasetMetadata
from lerobot.utils.utils import init_logging
init_logging()
disable_progress_bars()
chunks = self.create_chunks(self.file_paths, world_size)
file_paths = chunks[rank]
if len(file_paths) == 0:
raise ValueError(file_paths)
logging.info("Pre-uploading LFS files...")
for i, path in enumerate(file_paths):
logging.info(f"{i}: {path}")
meta = LeRobotDatasetMetadata(self.repo_id)
additions = [
CommitOperationAdd(path_in_repo=path, path_or_fileobj=meta.root / path) for path in file_paths
]
preupload_lfs_files(
repo_id=self.distant_repo_id, repo_type="dataset", additions=additions, revision=self.branch
)
logging.info("Creating commits...")
self.create_commits(additions)
logging.info("Done!")
def make_upload_executor(
repo_id, job_name, logs_dir, workers, partition, cpus_per_task, mem_per_cpu, slurm=True
):
kwargs = {
"pipeline": [
UploadDataset(repo_id),
],
"logging_dir": str(logs_dir / job_name),
}
if slurm:
kwargs.update(
{
"job_name": job_name,
"tasks": DROID_SHARDS,
"workers": workers,
"time": "08:00:00",
"partition": partition,
"cpus_per_task": cpus_per_task,
"sbatch_args": {"mem-per-cpu": mem_per_cpu},
}
)
executor = SlurmPipelineExecutor(**kwargs)
else:
kwargs.update(
{
"tasks": DROID_SHARDS,
"workers": 1,
}
)
executor = LocalPipelineExecutor(**kwargs)
return executor
def main():
parser = argparse.ArgumentParser()
parser.add_argument(
"--repo-id",
type=str,
help="Repositery identifier on Hugging Face: a community or a user name `/` the name of the dataset, required when push-to-hub is True.",
)
parser.add_argument(
"--logs-dir",
type=Path,
help="Path to logs directory for `datatrove`.",
)
parser.add_argument(
"--job-name",
type=str,
default="upload_droid",
help="Job name used in slurm, and name of the directory created inside the provided logs directory.",
)
parser.add_argument(
"--slurm",
type=int,
default=1,
help="Launch over slurm. Use `--slurm 0` to launch sequentially (useful to debug).",
)
parser.add_argument(
"--workers",
type=int,
default=50,
help="Number of slurm workers. It should be less than the maximum number of shards.",
)
parser.add_argument(
"--partition",
type=str,
help="Slurm partition. Ideally a CPU partition. No need for GPU partition.",
)
parser.add_argument(
"--cpus-per-task",
type=int,
default=8,
help="Number of cpus that each slurm worker will use.",
)
parser.add_argument(
"--mem-per-cpu",
type=str,
default="1950M",
help="Memory per cpu that each worker will use.",
)
init_logging()
args = parser.parse_args()
kwargs = vars(args)
kwargs["slurm"] = kwargs.pop("slurm") == 1
upload_executor = make_upload_executor(**kwargs)
upload_executor.run()
if __name__ == "__main__":
main()
examples/so100_to_so100_EE/evaluate.py
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@@ -1,200 +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.
from lerobot.cameras.opencv.configuration_opencv import OpenCVCameraConfig
from lerobot.configs.types import FeatureType, PolicyFeature
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.model.kinematics import RobotKinematics
from lerobot.policies.act.modeling_act import ACTPolicy
from lerobot.policies.factory import make_pre_post_processors
from lerobot.processor import (
RobotAction,
RobotObservation,
RobotProcessorPipeline,
make_default_teleop_action_processor,
)
from lerobot.processor.converters import (
observation_to_transition,
robot_action_observation_to_transition,
transition_to_observation,
transition_to_robot_action,
)
from lerobot.robots.so100_follower.config_so100_follower import SO100FollowerConfig
from lerobot.robots.so100_follower.robot_kinematic_processor import (
ForwardKinematicsJointsToEE,
InverseKinematicsEEToJoints,
)
from lerobot.robots.so100_follower.so100_follower import SO100Follower
from lerobot.scripts.lerobot_record import record_loop
from lerobot.utils.control_utils import init_keyboard_listener
from lerobot.utils.utils import log_say
from lerobot.utils.visualization_utils import init_rerun
NUM_EPISODES = 5
FPS = 30
EPISODE_TIME_SEC = 60
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,
)
robot = SO100Follower(robot_config)
# 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()),
)
# 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,
),
),
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,
)
# 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
# Save episode
dataset.save_episode()
episode_idx += 1
# Clean up
log_say("Stop recording")
robot.disconnect()
listener.stop()
dataset.finalize()
dataset.push_to_hub()
examples/so100_to_so100_EE/record.py
-204
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@@ -1,204 +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.
from lerobot.cameras.opencv.configuration_opencv import OpenCVCameraConfig
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.model.kinematics import RobotKinematics
from lerobot.processor import RobotAction, RobotObservation, RobotProcessorPipeline
from lerobot.processor.converters import (
observation_to_transition,
robot_action_observation_to_transition,
transition_to_observation,
transition_to_robot_action,
)
from lerobot.robots.so100_follower.config_so100_follower import SO100FollowerConfig
from lerobot.robots.so100_follower.robot_kinematic_processor import (
EEBoundsAndSafety,
ForwardKinematicsJointsToEE,
InverseKinematicsEEToJoints,
)
from lerobot.robots.so100_follower.so100_follower import SO100Follower
from lerobot.scripts.lerobot_record import record_loop
from lerobot.teleoperators.so100_leader.config_so100_leader import SO100LeaderConfig
from lerobot.teleoperators.so100_leader.so100_leader import SO100Leader
from lerobot.utils.control_utils import init_keyboard_listener
from lerobot.utils.utils import log_say
from lerobot.utils.visualization_utils import init_rerun
NUM_EPISODES = 2
FPS = 30
EPISODE_TIME_SEC = 60
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")
# 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
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,
),
),
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,
)
# 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
# Save episode
dataset.save_episode()
episode_idx += 1
# Clean up
log_say("Stop recording")
leader.disconnect()
follower.disconnect()
listener.stop()
dataset.finalize()
dataset.push_to_hub()
examples/so100_to_so100_EE/replay.py
-101
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@@ -1,101 +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.
import time
from lerobot.datasets.lerobot_dataset import LeRobotDataset
from lerobot.model.kinematics import RobotKinematics
from lerobot.processor import RobotAction, RobotObservation, RobotProcessorPipeline
from lerobot.processor.converters import (
robot_action_observation_to_transition,
transition_to_robot_action,
)
from lerobot.robots.so100_follower.config_so100_follower import SO100FollowerConfig
from lerobot.robots.so100_follower.robot_kinematic_processor import (
InverseKinematicsEEToJoints,
)
from lerobot.robots.so100_follower.so100_follower import SO100Follower
from lerobot.utils.constants import ACTION
from lerobot.utils.robot_utils import 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
)
# 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()),
)
# 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)
# Connect to the robot
robot.connect()
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()
# 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()
# Dataset EE -> robot joints
joint_action = robot_ee_to_joints_processor((ee_action, robot_obs))
# Send action to robot
_ = robot.send_action(joint_action)
busy_wait(1.0 / dataset.fps - (time.perf_counter() - t0))
# Clean up
robot.disconnect()
examples/so100_to_so100_EE/teleoperate.py
-121
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@@ -1,121 +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.
import time
from lerobot.model.kinematics import RobotKinematics
from lerobot.processor import RobotAction, RobotObservation, RobotProcessorPipeline
from lerobot.processor.converters import (
robot_action_observation_to_transition,
robot_action_to_transition,
transition_to_robot_action,
)
from lerobot.robots.so100_follower.config_so100_follower import SO100FollowerConfig
from lerobot.robots.so100_follower.robot_kinematic_processor import (
EEBoundsAndSafety,
ForwardKinematicsJointsToEE,
InverseKinematicsEEToJoints,
)
from lerobot.robots.so100_follower.so100_follower import SO100Follower
from lerobot.teleoperators.so100_leader.config_so100_leader import SO100LeaderConfig
from lerobot.teleoperators.so100_leader.so100_leader import SO100Leader
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")
# 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
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 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()
# Init rerun viewer
init_rerun(session_name="so100_so100_EE_teleop")
print("Starting teleop loop...")
while True:
t0 = time.perf_counter()
# Get robot observation
robot_obs = follower.get_observation()
# Get teleop observation
leader_joints_obs = leader.get_action()
# 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))
# Send action to robot
_ = follower.send_action(follower_joints_act)
# Visualize
log_rerun_data(observation=leader_ee_act, action=follower_joints_act)
busy_wait(max(1.0 / FPS - (time.perf_counter() - t0), 0.0))
examples/training/train_with_streaming.py
-108
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@@ -1,108 +0,0 @@
# Copyright 2025 The HuggingFace Inc. team. All rights reserved.
#
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
#
# http://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.
"""This script demonstrates how to train a Diffusion Policy on the PushT environment,
using a dataset processed in streaming mode."""
from pathlib import Path
import torch
from lerobot.configs.types import FeatureType
from lerobot.datasets.lerobot_dataset import LeRobotDatasetMetadata
from lerobot.datasets.streaming_dataset import StreamingLeRobotDataset
from lerobot.datasets.utils import dataset_to_policy_features
from lerobot.policies.act.configuration_act import ACTConfig
from lerobot.policies.act.modeling_act import ACTPolicy
from lerobot.policies.factory import make_pre_post_processors
from lerobot.utils.constants import ACTION
def main():
# Create a directory to store the training checkpoint.
output_directory = Path("outputs/train/example_streaming_dataset")
output_directory.mkdir(parents=True, exist_ok=True)
# Selects the "best" device available
device = (
torch.device("cuda")
if torch.cuda.is_available()
else torch.device("mps")
if torch.backends.mps.is_available()
else torch.device("cpu")
)
print(f"Using device: {device}")
training_steps = 10
log_freq = 1
dataset_id = "lerobot/droid_1.0.1" # 26M frames! Would require 4TB of disk space if installed locally (:
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}
# We can now instantiate our policy with this config and the dataset stats.
cfg = ACTConfig(input_features=input_features, output_features=output_features)
policy = ACTPolicy(cfg)
policy.train()
policy.to(device)
preprocessor, postprocessor = make_pre_post_processors(cfg, dataset_stats=dataset_metadata.stats)
# Delta timestamps are used to (1) augment frames used during training and (2) supervise the policy.
# Here, we use delta-timestamps to only provide ground truth actions for supervision
delta_timestamps = {
ACTION: [t / dataset_metadata.fps for t in range(cfg.n_action_steps)],
}
# Instantiating the training dataset in streaming mode allows to not consume up memory as the data is fetched
# iteratively rather than being load into memory all at once. Retrieved frames are shuffled across epochs
dataset = StreamingLeRobotDataset(dataset_id, delta_timestamps=delta_timestamps, tolerance_s=1e-3)
optimizer = torch.optim.Adam(policy.parameters(), lr=1e-4)
dataloader = torch.utils.data.DataLoader(
dataset,
num_workers=4,
batch_size=16,
pin_memory=device.type != "cpu",
drop_last=True,
prefetch_factor=2, # loads batches with multiprocessing while policy trains
)
# 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
# Save a policy checkpoint.
policy.save_pretrained(output_directory)
preprocessor.save_pretrained(output_directory)
postprocessor.save_pretrained(output_directory)
if __name__ == "__main__":
main()
pyproject.toml
+48 -138
View File
@@ -59,32 +59,32 @@ keywords = ["lerobot", "huggingface", "robotics", "machine learning", "artifici
dependencies = [
# Hugging Face dependencies
"datasets>=4.0.0,<4.2.0",
"diffusers>=0.27.2,<0.36.0",
"huggingface-hub[hf-transfer,cli]>=0.34.2,<0.36.0",
"datasets>=2.19.0,<=3.6.0", # TODO: Bumb dependency
"diffusers>=0.27.2",
"huggingface-hub[hf-transfer,cli]>=0.34.2",
# Core dependencies
"setuptools>=71.0.0,<81.0.0",
"cmake>=3.29.0.1,<4.2.0",
"einops>=0.8.0,<0.9.0",
"opencv-python-headless>=4.9.0,<4.13.0",
"av>=15.0.0,<16.0.0",
"jsonlines>=4.0.0,<5.0.0",
"packaging>=24.2,<26.0",
"pynput>=1.7.7,<1.9.0",
"pyserial>=3.5,<4.0",
"wandb>=0.20.0,<0.23.0",
"cmake>=3.29.0.1",
"einops>=0.8.0",
"opencv-python-headless>=4.9.0",
"av>=14.2.0",
"jsonlines>=4.0.0",
"packaging>=24.2",
"pynput>=1.7.7",
"pyserial>=3.5",
"wandb>=0.20.0",
"torch>=2.2.1,<2.8.0", # TODO: Bumb dependency
"torchcodec>=0.2.1,<0.6.0; sys_platform != 'win32' and (sys_platform != 'linux' or (platform_machine != 'aarch64' and platform_machine != 'arm64' and platform_machine != 'armv7l')) and (sys_platform != 'darwin' or platform_machine != 'x86_64')", # TODO: Bumb dependency
"torchvision>=0.21.0,<0.23.0", # TODO: Bumb dependency
"draccus==0.10.0", # TODO: Remove ==
"gymnasium>=1.0.0",
"gymnasium>=0.29.1,<1.0.0", # TODO: Bumb dependency
"rerun-sdk>=0.21.0,<0.23.0", # TODO: Bumb dependency
# Support dependencies
"deepdiff>=7.0.1,<9.0.0",
"flask>=3.0.3,<4.0.0",
"imageio[ffmpeg]>=2.34.0,<3.0.0",
"termcolor>=2.4.0,<4.0.0",
]
@@ -93,26 +93,24 @@ dependencies = [
[project.optional-dependencies]
# Common
pygame-dep = ["pygame>=2.5.1,<2.7.0"]
placo-dep = ["placo>=0.9.6,<0.10.0"]
transformers-dep = ["transformers>=4.53.0,<5.0.0"]
pygame-dep = ["pygame>=2.5.1"]
placo-dep = ["placo>=0.9.6"]
transformers-dep = ["transformers>=4.50.3,<4.52.0"] # TODO: Bumb dependency
grpcio-dep = ["grpcio==1.73.1", "protobuf==6.31.0"]
# Motors
feetech = ["feetech-servo-sdk>=1.0.0,<2.0.0"]
dynamixel = ["dynamixel-sdk>=3.7.31,<3.9.0"]
feetech = ["feetech-servo-sdk>=1.0.0"]
dynamixel = ["dynamixel-sdk>=3.7.31"]
# Robots
gamepad = ["lerobot[pygame-dep]", "hidapi>=0.14.0,<0.15.0"]
gamepad = ["lerobot[pygame-dep]", "hidapi>=0.14.0"]
hopejr = ["lerobot[feetech]", "lerobot[pygame-dep]"]
lekiwi = ["lerobot[feetech]", "pyzmq>=26.2.1,<28.0.0"]
reachy2 = ["reachy2_sdk>=1.0.14,<1.1.0"]
lekiwi = ["lerobot[feetech]", "pyzmq>=26.2.1"]
kinematics = ["lerobot[placo-dep]"]
intelrealsense = [
"pyrealsense2>=2.55.1.6486,<2.57.0 ; sys_platform != 'darwin'",
"pyrealsense2-macosx>=2.54,<2.55.0 ; sys_platform == 'darwin'",
"pyrealsense2>=2.55.1.6486 ; sys_platform != 'darwin'",
"pyrealsense2-macosx>=2.54 ; sys_platform == 'darwin'",
]
phone = ["hebi-py>=2.8.0,<2.12.0", "teleop>=0.1.0,<0.2.0"]
# stretch = [
# "hello-robot-stretch-body>=0.7.27 ; sys_platform == 'linux'",
# "pyrender @ git+https://github.com/mmatl/pyrender.git ; sys_platform == 'linux'",
@@ -120,23 +118,22 @@ phone = ["hebi-py>=2.8.0,<2.12.0", "teleop>=0.1.0,<0.2.0"]
# ] # TODO: Currently not supported
# Policies
pi = ["transformers @ git+https://github.com/huggingface/transformers.git@fix/lerobot_openpi"]
smolvla = ["lerobot[transformers-dep]", "num2words>=0.5.14,<0.6.0", "accelerate>=1.7.0,<2.0.0", "safetensors>=0.4.3,<1.0.0"]
hilserl = ["lerobot[transformers-dep]", "gym-hil>=0.1.11,<0.2.0", "lerobot[grpcio-dep]", "lerobot[placo-dep]"]
pi0 = ["lerobot[transformers-dep]"]
smolvla = ["lerobot[transformers-dep]", "num2words>=0.5.14", "accelerate>=1.7.0", "safetensors>=0.4.3"]
hilserl = ["lerobot[transformers-dep]", "gym-hil>=0.1.9", "lerobot[grpcio-dep]", "lerobot[placo-dep]"]
# Features
async = ["lerobot[grpcio-dep]", "matplotlib>=3.10.3,<4.0.0"]
async = ["lerobot[grpcio-dep]", "matplotlib>=3.10.3"]
# Development
dev = ["pre-commit>=3.7.0,<5.0.0", "debugpy>=1.8.1,<1.9.0", "lerobot[grpcio-dep]", "grpcio-tools==1.73.1"]
test = ["pytest>=8.1.0,<9.0.0", "pytest-timeout>=2.4.0,<3.0.0", "pytest-cov>=5.0.0,<8.0.0", "mock-serial>=0.0.1,<0.1.0 ; sys_platform != 'win32'"]
video_benchmark = ["scikit-image>=0.23.2,<0.26.0", "pandas>=2.2.2,<2.4.0"]
dev = ["pre-commit>=3.7.0", "debugpy>=1.8.1", "lerobot[grpcio-dep]", "grpcio-tools==1.73.1"]
test = ["pytest>=8.1.0", "pytest-timeout>=2.4.0", "pytest-cov>=5.0.0", "mock-serial>=0.0.1 ; sys_platform != 'win32'"]
video_benchmark = ["scikit-image>=0.23.2", "pandas>=2.2.2"]
# Simulation
aloha = ["gym-aloha>=0.1.2,<0.2.0"]
pusht = ["gym-pusht>=0.1.5,<0.2.0", "pymunk>=6.6.0,<7.0.0"] # TODO: Fix pymunk version in gym-pusht instead
libero = ["lerobot[transformers-dep]", "libero @ git+https://github.com/huggingface/lerobot-libero.git@main#egg=libero"]
metaworld = ["metaworld>=3.0.0"]
aloha = ["gym-aloha>=0.1.1"]
pusht = ["gym-pusht>=0.1.5", "pymunk>=6.6.0,<7.0.0"] # TODO: Fix pymunk version in gym-pusht instead
xarm = ["gym-xarm>=0.1.1"]
# All
all = [
@@ -144,10 +141,9 @@ all = [
"lerobot[gamepad]",
"lerobot[hopejr]",
"lerobot[lekiwi]",
"lerobot[reachy2]",
"lerobot[kinematics]",
"lerobot[intelrealsense]",
"lerobot[pi]",
"lerobot[pi0]",
"lerobot[smolvla]",
"lerobot[hilserl]",
"lerobot[async]",
@@ -156,26 +152,19 @@ all = [
"lerobot[video_benchmark]",
"lerobot[aloha]",
"lerobot[pusht]",
"lerobot[phone]",
"lerobot[libero]",
"lerobot[metaworld]",
"lerobot[xarm]"
]
[project.scripts]
lerobot-calibrate="lerobot.scripts.lerobot_calibrate:main"
lerobot-find-cameras="lerobot.scripts.lerobot_find_cameras:main"
lerobot-find-port="lerobot.scripts.lerobot_find_port:main"
lerobot-record="lerobot.scripts.lerobot_record:main"
lerobot-replay="lerobot.scripts.lerobot_replay:main"
lerobot-setup-motors="lerobot.scripts.lerobot_setup_motors:main"
lerobot-teleoperate="lerobot.scripts.lerobot_teleoperate:main"
lerobot-eval="lerobot.scripts.lerobot_eval:main"
lerobot-train="lerobot.scripts.lerobot_train:main"
lerobot-dataset-viz="lerobot.scripts.lerobot_dataset_viz:main"
lerobot-info="lerobot.scripts.lerobot_info:main"
lerobot-find-joint-limits="lerobot.scripts.lerobot_find_joint_limits:main"
lerobot-imgtransform-viz="lerobot.scripts.lerobot_imgtransform_viz:main"
lerobot-edit-dataset="lerobot.scripts.lerobot_edit_dataset:main"
lerobot-calibrate="lerobot.calibrate:main"
lerobot-find-cameras="lerobot.find_cameras:main"
lerobot-find-port="lerobot.find_port:main"
lerobot-record="lerobot.record:main"
lerobot-replay="lerobot.replay:main"
lerobot-setup-motors="lerobot.setup_motors:main"
lerobot-teleoperate="lerobot.teleoperate:main"
lerobot-eval="lerobot.scripts.eval:main"
lerobot-train="lerobot.scripts.train:main"
# ---------------- Tool Configurations ----------------
[tool.setuptools.packages.find]
@@ -202,7 +191,7 @@ exclude = ["tests/artifacts/**/*.safetensors", "*_pb2.py", "*_pb2_grpc.py"]
# N: pep8-naming
# TODO: Uncomment rules when ready to use
select = [
"E", "W", "F", "I", "B", "C4", "T20", "N", "UP", "SIM" #, "A", "S", "D", "RUF"
"E", "W", "F", "I", "B", "C4", "T20", "N" # "SIM", "A", "S", "D", "RUF", "UP"
]
ignore = [
"E501", # Line too long
@@ -268,87 +257,8 @@ default.extend-ignore-identifiers-re = [
# color = true
# paths = ["src/lerobot"]
# TODO: Enable mypy gradually module by module across multiple PRs
# Uncomment [tool.mypy] first, then uncomment individual module overrides as they get proper type annotations
[tool.mypy]
python_version = "3.10"
ignore_missing_imports = true
follow_imports = "skip"
# warn_return_any = true
# warn_unused_configs = true
# strict = true
# disallow_untyped_defs = true
# disallow_incomplete_defs = true
# check_untyped_defs = true
[[tool.mypy.overrides]]
module = "lerobot.*"
ignore_errors = true
[[tool.mypy.overrides]]
module = "lerobot.envs.*"
# Enable type checking only for the envs module
ignore_errors = false
# [[tool.mypy.overrides]]
# module = "lerobot.utils.*"
# ignore_errors = false
# [[tool.mypy.overrides]]
# module = "lerobot.configs.*"
# ignore_errors = false
# [[tool.mypy.overrides]]
# module = "lerobot.optim.*"
# ignore_errors = false
# [[tool.mypy.overrides]]
# module = "lerobot.model.*"
# ignore_errors = false
# [[tool.mypy.overrides]]
# module = "lerobot.processor.*"
# ignore_errors = false
# [[tool.mypy.overrides]]
# module = "lerobot.datasets.*"
# ignore_errors = false
# [[tool.mypy.overrides]]
# module = "lerobot.cameras.*"
# ignore_errors = false
# [[tool.mypy.overrides]]
# module = "lerobot.motors.*"
# ignore_errors = false
# [[tool.mypy.overrides]]
# module = "lerobot.robots.*"
# ignore_errors = false
# [[tool.mypy.overrides]]
# module = "lerobot.teleoperators.*"
# ignore_errors = false
# [[tool.mypy.overrides]]
# module = "lerobot.policies.*"
# ignore_errors = false
# [[tool.mypy.overrides]]
# module = "lerobot.rl.*"
# ignore_errors = false
# [[tool.mypy.overrides]]
# module = "lerobot.async_inference.*"
# ignore_errors = false
# [[tool.mypy.overrides]]
# module = "lerobot.transport.*"
# ignore_errors = false
# [[tool.mypy.overrides]]
# module = "lerobot.scripts.*"
# ignore_errors = false
warn_return_any = true
warn_unused_configs = true
ignore_missing_imports = false
src/lerobot/__init__.py
+12
View File
@@ -57,6 +57,7 @@ available_tasks_per_env = {
"AlohaTransferCube-v0",
],
"pusht": ["PushT-v0"],
"xarm": ["XarmLift-v0"],
}
available_envs = list(available_tasks_per_env.keys())
@@ -74,6 +75,16 @@ available_datasets_per_env = {
# TODO(alexander-soare): Add "lerobot/pusht_keypoints". Right now we can't because this is too tightly
# coupled with tests.
"pusht": ["lerobot/pusht", "lerobot/pusht_image"],
"xarm": [
"lerobot/xarm_lift_medium",
"lerobot/xarm_lift_medium_replay",
"lerobot/xarm_push_medium",
"lerobot/xarm_push_medium_replay",
"lerobot/xarm_lift_medium_image",
"lerobot/xarm_lift_medium_replay_image",
"lerobot/xarm_push_medium_image",
"lerobot/xarm_push_medium_replay_image",
],
}
available_real_world_datasets = [
@@ -184,6 +195,7 @@ available_motors = [
available_policies_per_env = {
"aloha": ["act"],
"pusht": ["diffusion", "vqbet"],
"xarm": ["tdmpc"],
"koch_real": ["act_koch_real"],
"aloha_real": ["act_aloha_real"],
}
src/lerobot/scripts/lerobot_calibrate.py → src/lerobot/calibrate.py
-2
View File
@@ -52,7 +52,6 @@ from lerobot.teleoperators import ( # noqa: F401
so100_leader,
so101_leader,
)
from lerobot.utils.import_utils import register_third_party_devices
from lerobot.utils.utils import init_logging
@@ -84,7 +83,6 @@ def calibrate(cfg: CalibrateConfig):
def main():
register_third_party_devices()
calibrate()
src/lerobot/cameras/opencv/camera_opencv.py
+1 -1
View File
@@ -31,7 +31,7 @@ if platform.system() == "Windows" and "OPENCV_VIDEOIO_MSMF_ENABLE_HW_TRANSFORMS"
import cv2
import numpy as np
from lerobot.utils.errors import DeviceAlreadyConnectedError, DeviceNotConnectedError
from lerobot.errors import DeviceAlreadyConnectedError, DeviceNotConnectedError
from ..camera import Camera
from ..utils import get_cv2_backend, get_cv2_rotation
src/lerobot/cameras/reachy2_camera/__init__.py
-16
View File
@@ -1,16 +0,0 @@
# 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 .configuration_reachy2_camera import Reachy2CameraConfig
from .reachy2_camera import Reachy2Camera
src/lerobot/cameras/reachy2_camera/configuration_reachy2_camera.py
-78
View File
@@ -1,78 +0,0 @@
# 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
@CameraConfig.register_subclass("reachy2_camera")
@dataclass
class Reachy2CameraConfig(CameraConfig):
"""Configuration class for Reachy 2 camera devices.
This class provides configuration options for Reachy 2 cameras,
supporting both the teleop and depth cameras. It includes settings
for resolution, frame rate, color mode, and the selection of the cameras.
Example configurations:
```python
# Basic configurations
Reachy2CameraConfig(
name="teleop",
image_type="left",
ip_address="192.168.0.200", # IP address of the robot
fps=15,
width=640,
height=480,
color_mode=ColorMode.RGB,
) # Left teleop camera, 640x480 @ 15FPS
```
Attributes:
name: Name of the camera device. Can be "teleop" or "depth".
image_type: Type of image stream. For "teleop" camera, can be "left" or "right".
For "depth" camera, can be "rgb" or "depth". (depth is not supported yet)
fps: Requested frames per second for the color stream.
width: Requested frame width in pixels for the color stream.
height: Requested frame height in pixels for the color stream.
color_mode: Color mode for image output (RGB or BGR). Defaults to RGB.
ip_address: IP address of the robot. Defaults to "localhost".
port: Port number for the camera server. Defaults to 50065.
Note:
- Only 3-channel color output (RGB/BGR) is currently supported.
"""
name: str
image_type: str
color_mode: ColorMode = ColorMode.RGB
ip_address: str | None = "localhost"
port: int = 50065
# use_depth: bool = False
def __post_init__(self):
if self.name not in ["teleop", "depth"]:
raise ValueError(f"`name` is expected to be 'teleop' or 'depth', but {self.name} is provided.")
if (self.name == "teleop" and self.image_type not in ["left", "right"]) or (
self.name == "depth" and self.image_type not in ["rgb", "depth"]
):
raise ValueError(
f"`image_type` is expected to be 'left' or 'right' for teleop camera, and 'rgb' or 'depth' for depth camera, but {self.image_type} is provided."
)
if self.color_mode not in ["rgb", "bgr"]:
raise ValueError(
f"`color_mode` is expected to be 'rgb' or 'bgr', but {self.color_mode} is provided."
)
src/lerobot/cameras/reachy2_camera/reachy2_camera.py
-288
View File
@@ -1,288 +0,0 @@
# 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 Reachy2Camera class for capturing frames from Reachy 2 cameras using Reachy 2's CameraManager.
"""
import logging
import os
import platform
import time
from threading import Event, Lock, Thread
from typing import Any
# Fix MSMF hardware transform compatibility for Windows before importing cv2
if platform.system() == "Windows" and "OPENCV_VIDEOIO_MSMF_ENABLE_HW_TRANSFORMS" not in os.environ:
os.environ["OPENCV_VIDEOIO_MSMF_ENABLE_HW_TRANSFORMS"] = "0"
import cv2
import numpy as np
from reachy2_sdk.media.camera import CameraView
from reachy2_sdk.media.camera_manager import CameraManager
from lerobot.utils.errors import DeviceNotConnectedError
from ..camera import Camera
from .configuration_reachy2_camera import ColorMode, Reachy2CameraConfig
logger = logging.getLogger(__name__)
class Reachy2Camera(Camera):
"""
Manages Reachy 2 camera using Reachy 2 CameraManager.
This class provides a high-level interface to connect to, configure, and read
frames from Reachy 2 cameras. It supports both synchronous and asynchronous
frame reading.
An Reachy2Camera instance requires a camera name (e.g., "teleop") and an image
type (e.g., "left") to be specified in the configuration.
The camera's default settings (FPS, resolution, color mode) are used unless
overridden in the configuration.
"""
def __init__(self, config: Reachy2CameraConfig):
"""
Initializes the Reachy2Camera instance.
Args:
config: The configuration settings for the camera.
"""
super().__init__(config)
self.config = config
self.fps = config.fps
self.color_mode = config.color_mode
self.cam_manager: CameraManager | None = None
self.thread: Thread | None = None
self.stop_event: Event | None = None
self.frame_lock: Lock = Lock()
self.latest_frame: np.ndarray | None = None
self.new_frame_event: Event = Event()
def __str__(self) -> str:
return f"{self.__class__.__name__}({self.config.name}, {self.config.image_type})"
@property
def is_connected(self) -> bool:
"""Checks if the camera is currently connected and opened."""
if self.config.name == "teleop":
return self.cam_manager._grpc_connected and self.cam_manager.teleop if self.cam_manager else False
elif self.config.name == "depth":
return self.cam_manager._grpc_connected and self.cam_manager.depth if self.cam_manager else False
else:
raise ValueError(f"Invalid camera name '{self.config.name}'. Expected 'teleop' or 'depth'.")
def connect(self, warmup: bool = True):
"""
Connects to the Reachy2 CameraManager as specified in the configuration.
"""
self.cam_manager = CameraManager(host=self.config.ip_address, port=self.config.port)
self.cam_manager.initialize_cameras()
logger.info(f"{self} connected.")
@staticmethod
def find_cameras(ip_address: str = "localhost", port: int = 50065) -> list[dict[str, Any]]:
"""
Detects available Reachy 2 cameras.
Returns:
List[Dict[str, Any]]: A list of dictionaries,
where each dictionary contains 'name', 'stereo',
and the default profile properties (width, height, fps).
"""
initialized_cameras = []
camera_manager = CameraManager(host=ip_address, port=port)
for camera in [camera_manager.teleop, camera_manager.depth]:
if camera is None:
continue
height, width, _, _, _, _, _ = camera.get_parameters()
camera_info = {
"name": camera._cam_info.name,
"stereo": camera._cam_info.stereo,
"default_profile": {
"width": width,
"height": height,
"fps": 30,
},
}
initialized_cameras.append(camera_info)
camera_manager.disconnect()
return initialized_cameras
def read(self, color_mode: ColorMode | None = None) -> np.ndarray:
"""
Reads a single frame synchronously from the camera.
This is a blocking call.
Args:
color_mode (Optional[ColorMode]): If specified, overrides the default
color mode (`self.color_mode`) for this read operation (e.g.,
request RGB even if default is BGR).
Returns:
np.ndarray: The captured frame as a NumPy array in the format
(height, width, channels), using the specified or default
color mode and applying any configured rotation.
"""
if not self.is_connected:
raise DeviceNotConnectedError(f"{self} is not connected.")
start_time = time.perf_counter()
frame = None
if self.cam_manager is None:
raise DeviceNotConnectedError(f"{self} is not connected.")
else:
if self.config.name == "teleop" and hasattr(self.cam_manager, "teleop"):
if self.config.image_type == "left":
frame = self.cam_manager.teleop.get_frame(CameraView.LEFT, size=(640, 480))[0]
elif self.config.image_type == "right":
frame = self.cam_manager.teleop.get_frame(CameraView.RIGHT, size=(640, 480))[0]
elif self.config.name == "depth" and hasattr(self.cam_manager, "depth"):
if self.config.image_type == "depth":
frame = self.cam_manager.depth.get_depth_frame()[0]
elif self.config.image_type == "rgb":
frame = self.cam_manager.depth.get_frame(size=(640, 480))[0]
if frame is None:
return np.empty((0, 0, 3), dtype=np.uint8)
if self.config.color_mode == "rgb":
frame = cv2.cvtColor(frame, cv2.COLOR_BGR2RGB)
read_duration_ms = (time.perf_counter() - start_time) * 1e3
logger.debug(f"{self} read took: {read_duration_ms:.1f}ms")
return frame
def _read_loop(self):
"""
Internal loop run by the background thread for asynchronous reading.
On each iteration:
1. Reads a color frame
2. Stores result in latest_frame (thread-safe)
3. Sets new_frame_event to notify listeners
Stops on DeviceNotConnectedError, logs other errors and continues.
"""
while not self.stop_event.is_set():
try:
color_image = self.read()
with self.frame_lock:
self.latest_frame = color_image
self.new_frame_event.set()
except DeviceNotConnectedError:
break
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 = 200) -> np.ndarray:
"""
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 the camera hardware directly,
but may wait up to timeout_ms for the background thread to provide a frame.
Args:
timeout_ms (float): Maximum time in milliseconds to wait for a frame
to become available. Defaults to 200ms (0.2 seconds).
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 camera {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):
"""
Stops the background read thread (if running).
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.cam_manager is not None:
self.cam_manager.disconnect()
logger.info(f"{self} disconnected.")
src/lerobot/cameras/realsense/camera_realsense.py
+1 -1
View File
@@ -29,7 +29,7 @@ try:
except Exception as e:
logging.info(f"Could not import realsense: {e}")
from lerobot.utils.errors import DeviceAlreadyConnectedError, DeviceNotConnectedError
from lerobot.errors import DeviceAlreadyConnectedError, DeviceNotConnectedError
from ..camera import Camera
from ..configs import ColorMode
src/lerobot/cameras/utils.py
+6 -15
View File
@@ -15,19 +15,19 @@
# limitations under the License.
import platform
from typing import cast
from lerobot.utils.import_utils import make_device_from_device_class
from pathlib import Path
from typing import TypeAlias
from .camera import Camera
from .configs import CameraConfig, Cv2Rotation
IndexOrPath: TypeAlias = int | Path
def make_cameras_from_configs(camera_configs: dict[str, CameraConfig]) -> dict[str, Camera]:
cameras: dict[str, Camera] = {}
cameras = {}
for key, cfg in camera_configs.items():
# TODO(Steven): Consider just using the make_device_from_device_class for all types
if cfg.type == "opencv":
from .opencv import OpenCVCamera
@@ -37,17 +37,8 @@ def make_cameras_from_configs(camera_configs: dict[str, CameraConfig]) -> dict[s
from .realsense.camera_realsense import RealSenseCamera
cameras[key] = RealSenseCamera(cfg)
elif cfg.type == "reachy2_camera":
from .reachy2_camera.reachy2_camera import Reachy2Camera
cameras[key] = Reachy2Camera(cfg)
else:
try:
cameras[key] = cast(Camera, make_device_from_device_class(cfg))
except Exception as e:
raise ValueError(f"Error creating camera {key} with config {cfg}: {e}") from e
raise ValueError(f"The motor type '{cfg.type}' is not valid.")
return cameras
src/lerobot/configs/default.py
+3 -1
View File
@@ -16,6 +16,9 @@
from dataclasses import dataclass, field
from lerobot import (
policies, # noqa: F401
)
from lerobot.datasets.transforms import ImageTransformsConfig
from lerobot.datasets.video_utils import get_safe_default_codec
@@ -34,7 +37,6 @@ class DatasetConfig:
revision: str | None = None
use_imagenet_stats: bool = True
video_backend: str = field(default_factory=get_safe_default_codec)
streaming: bool = False
@dataclass
src/lerobot/configs/policies.py
+9 -9
View File
@@ -26,10 +26,10 @@ from huggingface_hub import hf_hub_download
from huggingface_hub.constants import CONFIG_NAME
from huggingface_hub.errors import HfHubHTTPError
from lerobot.configs.types import FeatureType, PolicyFeature
from lerobot.configs.types import FeatureType, NormalizationMode, PolicyFeature
from lerobot.constants import ACTION, OBS_STATE
from lerobot.optim.optimizers import OptimizerConfig
from lerobot.optim.schedulers import LRSchedulerConfig
from lerobot.utils.constants import ACTION, OBS_STATE
from lerobot.utils.hub import HubMixin
from lerobot.utils.utils import auto_select_torch_device, is_amp_available, is_torch_device_available
@@ -53,6 +53,7 @@ class PreTrainedConfig(draccus.ChoiceRegistry, HubMixin, abc.ABC):
"""
n_obs_steps: int = 1
normalization_mapping: dict[str, NormalizationMode] = field(default_factory=dict)
input_features: dict[str, PolicyFeature] = field(default_factory=dict)
output_features: dict[str, PolicyFeature] = field(default_factory=dict)
@@ -71,11 +72,9 @@ class PreTrainedConfig(draccus.ChoiceRegistry, HubMixin, abc.ABC):
tags: list[str] | None = None
# Add tags to your policy on the hub.
license: str | None = None
# Either the repo ID of a model hosted on the Hub or a path to a directory containing weights
# saved using `Policy.save_pretrained`. If not provided, the policy is initialized from scratch.
pretrained_path: str | None = None
def __post_init__(self):
self.pretrained_path = None
if not self.device or not is_torch_device_available(self.device):
auto_device = auto_select_torch_device()
logging.warning(f"Device '{self.device}' is not available. Switching to '{auto_device}'.")
@@ -198,10 +197,11 @@ class PreTrainedConfig(draccus.ChoiceRegistry, HubMixin, abc.ABC):
config = json.load(f)
config.pop("type")
with tempfile.NamedTemporaryFile("w+", delete=False, suffix=".json") as f:
with tempfile.NamedTemporaryFile("w+") as f:
json.dump(config, f)
config_file = f.name
f.flush()
cli_overrides = policy_kwargs.pop("cli_overrides", [])
with draccus.config_type("json"):
return draccus.parse(orig_config.__class__, config_file, args=cli_overrides)
cli_overrides = policy_kwargs.pop("cli_overrides", [])
with draccus.config_type("json"):
return draccus.parse(orig_config.__class__, config_file, args=cli_overrides)
src/lerobot/configs/types.py
+5 -8
View File
@@ -15,6 +15,7 @@
# https://stackoverflow.com/questions/24481852/serialising-an-enum-member-to-json
from dataclasses import dataclass
from enum import Enum
from typing import Any, Protocol
class FeatureType(str, Enum):
@@ -23,20 +24,16 @@ class FeatureType(str, Enum):
ENV = "ENV"
ACTION = "ACTION"
REWARD = "REWARD"
LANGUAGE = "LANGUAGE"
class PipelineFeatureType(str, Enum):
ACTION = "ACTION"
OBSERVATION = "OBSERVATION"
class NormalizationMode(str, Enum):
MIN_MAX = "MIN_MAX"
MEAN_STD = "MEAN_STD"
IDENTITY = "IDENTITY"
QUANTILES = "QUANTILES"
QUANTILE10 = "QUANTILE10"
class DictLike(Protocol):
def __getitem__(self, key: Any) -> Any: ...
@dataclass
src/lerobot/utils/constants.py → src/lerobot/constants.py
+5 -23
View File
@@ -17,22 +17,15 @@ from pathlib import Path
from huggingface_hub.constants import HF_HOME
OBS_STR = "observation"
OBS_PREFIX = OBS_STR + "."
OBS_ENV_STATE = OBS_STR + ".environment_state"
OBS_STATE = OBS_STR + ".state"
OBS_IMAGE = OBS_STR + ".image"
OBS_IMAGES = OBS_IMAGE + "s"
OBS_LANGUAGE = OBS_STR + ".language"
OBS_LANGUAGE_TOKENS = OBS_LANGUAGE + ".tokens"
OBS_LANGUAGE_ATTENTION_MASK = OBS_LANGUAGE + ".attention_mask"
OBS_ENV_STATE = "observation.environment_state"
OBS_STATE = "observation.state"
OBS_IMAGE = "observation.image"
OBS_IMAGES = "observation.images"
ACTION = "action"
REWARD = "next.reward"
TRUNCATED = "next.truncated"
DONE = "next.done"
ROBOTS = "robots"
ROBOT_TYPE = "robot_type"
TELEOPERATORS = "teleoperators"
# files & directories
@@ -46,9 +39,6 @@ OPTIMIZER_STATE = "optimizer_state.safetensors"
OPTIMIZER_PARAM_GROUPS = "optimizer_param_groups.json"
SCHEDULER_STATE = "scheduler_state.json"
POLICY_PREPROCESSOR_DEFAULT_NAME = "policy_preprocessor"
POLICY_POSTPROCESSOR_DEFAULT_NAME = "policy_postprocessor"
if "LEROBOT_HOME" in os.environ:
raise ValueError(
f"You have a 'LEROBOT_HOME' environment variable set to '{os.getenv('LEROBOT_HOME')}'.\n"
@@ -62,11 +52,3 @@ HF_LEROBOT_HOME = Path(os.getenv("HF_LEROBOT_HOME", default_cache_path)).expandu
# calibration dir
default_calibration_path = HF_LEROBOT_HOME / "calibration"
HF_LEROBOT_CALIBRATION = Path(os.getenv("HF_LEROBOT_CALIBRATION", default_calibration_path)).expanduser()
# streaming datasets
LOOKBACK_BACKTRACKTABLE = 100
LOOKAHEAD_BACKTRACKTABLE = 100
# openpi
OPENPI_ATTENTION_MASK_VALUE = -2.3819763e38 # TODO(pepijn): Modify this when extending support to fp8 models
src/lerobot/datasets/aggregate.py
-531
View File
@@ -1,531 +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.
import logging
import shutil
from pathlib import Path
import pandas as pd
import tqdm
from lerobot.datasets.compute_stats import aggregate_stats
from lerobot.datasets.lerobot_dataset import LeRobotDatasetMetadata
from lerobot.datasets.utils import (
DEFAULT_CHUNK_SIZE,
DEFAULT_DATA_FILE_SIZE_IN_MB,
DEFAULT_DATA_PATH,
DEFAULT_EPISODES_PATH,
DEFAULT_VIDEO_FILE_SIZE_IN_MB,
DEFAULT_VIDEO_PATH,
get_file_size_in_mb,
get_parquet_file_size_in_mb,
to_parquet_with_hf_images,
update_chunk_file_indices,
write_info,
write_stats,
write_tasks,
)
from lerobot.datasets.video_utils import concatenate_video_files, get_video_duration_in_s
def validate_all_metadata(all_metadata: list[LeRobotDatasetMetadata]):
"""Validates that all dataset metadata have consistent properties.
Ensures all datasets have the same fps, robot_type, and features to guarantee
compatibility when aggregating them into a single dataset.
Args:
all_metadata: List of LeRobotDatasetMetadata objects to validate.
Returns:
tuple: A tuple containing (fps, robot_type, features) from the first metadata.
Raises:
ValueError: If any metadata has different fps, robot_type, or features
than the first metadata in the list.
"""
fps = all_metadata[0].fps
robot_type = all_metadata[0].robot_type
features = all_metadata[0].features
for meta in tqdm.tqdm(all_metadata, desc="Validate all meta data"):
if fps != meta.fps:
raise ValueError(f"Same fps is expected, but got fps={meta.fps} instead of {fps}.")
if robot_type != meta.robot_type:
raise ValueError(
f"Same robot_type is expected, but got robot_type={meta.robot_type} instead of {robot_type}."
)
if features != meta.features:
raise ValueError(
f"Same features is expected, but got features={meta.features} instead of {features}."
)
return fps, robot_type, features
def update_data_df(df, src_meta, dst_meta):
"""Updates a data DataFrame with new indices and task mappings for aggregation.
Adjusts episode indices, frame indices, and task indices to account for
previously aggregated data in the destination dataset.
Args:
df: DataFrame containing the data to be updated.
src_meta: Source dataset metadata.
dst_meta: Destination dataset metadata.
Returns:
pd.DataFrame: Updated DataFrame with adjusted indices.
"""
df["episode_index"] = df["episode_index"] + dst_meta.info["total_episodes"]
df["index"] = df["index"] + dst_meta.info["total_frames"]
src_task_names = src_meta.tasks.index.take(df["task_index"].to_numpy())
df["task_index"] = dst_meta.tasks.loc[src_task_names, "task_index"].to_numpy()
return df
def update_meta_data(
df,
dst_meta,
meta_idx,
data_idx,
videos_idx,
):
"""Updates metadata DataFrame with new chunk, file, and timestamp indices.
Adjusts all indices and timestamps to account for previously aggregated
data and videos in the destination dataset.
Args:
df: DataFrame containing the metadata to be updated.
dst_meta: Destination dataset metadata.
meta_idx: Dictionary containing current metadata chunk and file indices.
data_idx: Dictionary containing current data chunk and file indices.
videos_idx: Dictionary containing current video indices and timestamps.
Returns:
pd.DataFrame: Updated DataFrame with adjusted indices and timestamps.
"""
df["meta/episodes/chunk_index"] = df["meta/episodes/chunk_index"] + meta_idx["chunk"]
df["meta/episodes/file_index"] = df["meta/episodes/file_index"] + meta_idx["file"]
df["data/chunk_index"] = df["data/chunk_index"] + data_idx["chunk"]
df["data/file_index"] = df["data/file_index"] + data_idx["file"]
for key, video_idx in videos_idx.items():
# Store original video file indices before updating
orig_chunk_col = f"videos/{key}/chunk_index"
orig_file_col = f"videos/{key}/file_index"
df["_orig_chunk"] = df[orig_chunk_col].copy()
df["_orig_file"] = df[orig_file_col].copy()
# 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", {})
if src_to_offset:
# Apply offset based on original source file
for idx in df.index:
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[f"videos/{key}/from_timestamp"] = (
df[f"videos/{key}/from_timestamp"] + video_idx["latest_duration"]
)
df[f"videos/{key}/to_timestamp"] = df[f"videos/{key}/to_timestamp"] + video_idx["latest_duration"]
# Clean up temporary columns
df = df.drop(columns=["_orig_chunk", "_orig_file"])
df["dataset_from_index"] = df["dataset_from_index"] + dst_meta.info["total_frames"]
df["dataset_to_index"] = df["dataset_to_index"] + dst_meta.info["total_frames"]
df["episode_index"] = df["episode_index"] + dst_meta.info["total_episodes"]
return df
def aggregate_datasets(
repo_ids: list[str],
aggr_repo_id: str,
roots: list[Path] | None = None,
aggr_root: Path | None = None,
data_files_size_in_mb: float | None = None,
video_files_size_in_mb: float | None = None,
chunk_size: int | None = None,
):
"""Aggregates multiple LeRobot datasets into a single unified dataset.
This is the main function that orchestrates the aggregation process by:
1. Loading and validating all source dataset metadata
2. Creating a new destination dataset with unified tasks
3. Aggregating videos, data, and metadata from all source datasets
4. Finalizing the aggregated dataset with proper statistics
Args:
repo_ids: List of repository IDs for the datasets to aggregate.
aggr_repo_id: Repository ID for the aggregated output dataset.
roots: Optional list of root paths for the source datasets.
aggr_root: Optional root path for the aggregated dataset.
data_files_size_in_mb: Maximum size for data files in MB (defaults to DEFAULT_DATA_FILE_SIZE_IN_MB)
video_files_size_in_mb: Maximum size for video files in MB (defaults to DEFAULT_VIDEO_FILE_SIZE_IN_MB)
chunk_size: Maximum number of files per chunk (defaults to DEFAULT_CHUNK_SIZE)
"""
logging.info("Start aggregate_datasets")
if data_files_size_in_mb is None:
data_files_size_in_mb = DEFAULT_DATA_FILE_SIZE_IN_MB
if video_files_size_in_mb is None:
video_files_size_in_mb = DEFAULT_VIDEO_FILE_SIZE_IN_MB
if chunk_size is None:
chunk_size = DEFAULT_CHUNK_SIZE
all_metadata = (
[LeRobotDatasetMetadata(repo_id) for repo_id in repo_ids]
if roots is None
else [
LeRobotDatasetMetadata(repo_id, root=root) for repo_id, root in zip(repo_ids, roots, strict=False)
]
)
fps, robot_type, features = validate_all_metadata(all_metadata)
video_keys = [key for key in features if features[key]["dtype"] == "video"]
dst_meta = LeRobotDatasetMetadata.create(
repo_id=aggr_repo_id,
fps=fps,
robot_type=robot_type,
features=features,
root=aggr_root,
use_videos=len(video_keys) > 0,
chunks_size=chunk_size,
data_files_size_in_mb=data_files_size_in_mb,
video_files_size_in_mb=video_files_size_in_mb,
)
logging.info("Find all tasks")
unique_tasks = pd.concat([m.tasks for m in all_metadata]).index.unique()
dst_meta.tasks = pd.DataFrame({"task_index": range(len(unique_tasks))}, index=unique_tasks)
meta_idx = {"chunk": 0, "file": 0}
data_idx = {"chunk": 0, "file": 0}
videos_idx = {
key: {"chunk": 0, "file": 0, "latest_duration": 0, "episode_duration": 0} for key in video_keys
}
dst_meta.episodes = {}
for src_meta in tqdm.tqdm(all_metadata, desc="Copy data and videos"):
videos_idx = aggregate_videos(src_meta, dst_meta, videos_idx, video_files_size_in_mb, chunk_size)
data_idx = aggregate_data(src_meta, dst_meta, data_idx, data_files_size_in_mb, chunk_size)
meta_idx = aggregate_metadata(src_meta, dst_meta, meta_idx, data_idx, videos_idx)
dst_meta.info["total_episodes"] += src_meta.total_episodes
dst_meta.info["total_frames"] += src_meta.total_frames
finalize_aggregation(dst_meta, all_metadata)
logging.info("Aggregation complete.")
def aggregate_videos(src_meta, dst_meta, videos_idx, video_files_size_in_mb, chunk_size):
"""Aggregates video chunks from a source dataset into the destination dataset.
Handles video file concatenation and rotation based on file size limits.
Creates new video files when size limits are exceeded.
Args:
src_meta: Source dataset metadata.
dst_meta: Destination dataset metadata.
videos_idx: Dictionary tracking video chunk and file indices.
video_files_size_in_mb: Maximum size for video files in MB (defaults to DEFAULT_VIDEO_FILE_SIZE_IN_MB)
chunk_size: Maximum number of files per chunk (defaults to DEFAULT_CHUNK_SIZE)
Returns:
dict: Updated videos_idx with current chunk and file indices.
"""
for key in videos_idx:
videos_idx[key]["episode_duration"] = 0
# Track offset for each source (chunk, file) pair
videos_idx[key]["src_to_offset"] = {}
for key, video_idx in videos_idx.items():
unique_chunk_file_pairs = {
(chunk, file)
for chunk, file in zip(
src_meta.episodes[f"videos/{key}/chunk_index"],
src_meta.episodes[f"videos/{key}/file_index"],
strict=False,
)
}
unique_chunk_file_pairs = sorted(unique_chunk_file_pairs)
chunk_idx = video_idx["chunk"]
file_idx = video_idx["file"]
current_offset = video_idx["latest_duration"]
for src_chunk_idx, src_file_idx in unique_chunk_file_pairs:
src_path = src_meta.root / DEFAULT_VIDEO_PATH.format(
video_key=key,
chunk_index=src_chunk_idx,
file_index=src_file_idx,
)
dst_path = dst_meta.root / DEFAULT_VIDEO_PATH.format(
video_key=key,
chunk_index=chunk_idx,
file_index=file_idx,
)
src_duration = get_video_duration_in_s(src_path)
if not dst_path.exists():
# 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))
videos_idx[key]["episode_duration"] += src_duration
current_offset += src_duration
continue
# Check file sizes before appending
src_size = get_file_size_in_mb(src_path)
dst_size = get_file_size_in_mb(dst_path)
if dst_size + src_size >= video_files_size_in_mb:
# 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
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,
file_index=file_idx,
)
dst_path.parent.mkdir(parents=True, exist_ok=True)
shutil.copy(str(src_path), str(dst_path))
# Reset offset for next file
current_offset = src_duration
else:
# 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,
)
current_offset += src_duration
videos_idx[key]["episode_duration"] += src_duration
videos_idx[key]["chunk"] = chunk_idx
videos_idx[key]["file"] = file_idx
return videos_idx
def aggregate_data(src_meta, dst_meta, data_idx, data_files_size_in_mb, chunk_size):
"""Aggregates data chunks from a source dataset into the destination dataset.
Reads source data files, updates indices to match the aggregated dataset,
and writes them to the destination with proper file rotation.
Args:
src_meta: Source dataset metadata.
dst_meta: Destination dataset metadata.
data_idx: Dictionary tracking data chunk and file indices.
Returns:
dict: Updated data_idx with current chunk and file indices.
"""
unique_chunk_file_ids = {
(c, f)
for c, f in zip(
src_meta.episodes["data/chunk_index"], src_meta.episodes["data/file_index"], strict=False
)
}
unique_chunk_file_ids = sorted(unique_chunk_file_ids)
for src_chunk_idx, src_file_idx in unique_chunk_file_ids:
src_path = src_meta.root / DEFAULT_DATA_PATH.format(
chunk_index=src_chunk_idx, file_index=src_file_idx
)
df = pd.read_parquet(src_path)
df = update_data_df(df, src_meta, dst_meta)
data_idx = append_or_create_parquet_file(
df,
src_path,
data_idx,
data_files_size_in_mb,
chunk_size,
DEFAULT_DATA_PATH,
contains_images=len(dst_meta.image_keys) > 0,
aggr_root=dst_meta.root,
)
return data_idx
def aggregate_metadata(src_meta, dst_meta, meta_idx, data_idx, videos_idx):
"""Aggregates metadata from a source dataset into the destination dataset.
Reads source metadata files, updates all indices and timestamps,
and writes them to the destination with proper file rotation.
Args:
src_meta: Source dataset metadata.
dst_meta: Destination dataset metadata.
meta_idx: Dictionary tracking metadata chunk and file indices.
data_idx: Dictionary tracking data chunk and file indices.
videos_idx: Dictionary tracking video indices and timestamps.
Returns:
dict: Updated meta_idx with current chunk and file indices.
"""
chunk_file_ids = {
(c, f)
for c, f in zip(
src_meta.episodes["meta/episodes/chunk_index"],
src_meta.episodes["meta/episodes/file_index"],
strict=False,
)
}
chunk_file_ids = sorted(chunk_file_ids)
for chunk_idx, file_idx in chunk_file_ids:
src_path = src_meta.root / DEFAULT_EPISODES_PATH.format(chunk_index=chunk_idx, file_index=file_idx)
df = pd.read_parquet(src_path)
df = update_meta_data(
df,
dst_meta,
meta_idx,
data_idx,
videos_idx,
)
meta_idx = append_or_create_parquet_file(
df,
src_path,
meta_idx,
DEFAULT_DATA_FILE_SIZE_IN_MB,
DEFAULT_CHUNK_SIZE,
DEFAULT_EPISODES_PATH,
contains_images=False,
aggr_root=dst_meta.root,
)
# Increment latest_duration by the total duration added from this source dataset
for k in videos_idx:
videos_idx[k]["latest_duration"] += videos_idx[k]["episode_duration"]
return meta_idx
def append_or_create_parquet_file(
df: pd.DataFrame,
src_path: Path,
idx: dict[str, int],
max_mb: float,
chunk_size: int,
default_path: str,
contains_images: bool = False,
aggr_root: Path = None,
):
"""Appends data to an existing parquet file or creates a new one based on size constraints.
Manages file rotation when size limits are exceeded to prevent individual files
from becoming too large. Handles both regular parquet files and those containing images.
Args:
df: DataFrame to write to the parquet file.
src_path: Path to the source file (used for size estimation).
idx: Dictionary containing current 'chunk' and 'file' indices.
max_mb: Maximum allowed file size in MB before rotation.
chunk_size: Maximum number of files per chunk before incrementing chunk index.
default_path: Format string for generating file paths.
contains_images: Whether the data contains images requiring special handling.
aggr_root: Root path for the aggregated dataset.
Returns:
dict: Updated index dictionary with current chunk and file indices.
"""
dst_path = aggr_root / default_path.format(chunk_index=idx["chunk"], file_index=idx["file"])
if not dst_path.exists():
dst_path.parent.mkdir(parents=True, exist_ok=True)
if contains_images:
to_parquet_with_hf_images(df, dst_path)
else:
df.to_parquet(dst_path)
return idx
src_size = get_parquet_file_size_in_mb(src_path)
dst_size = get_parquet_file_size_in_mb(dst_path)
if dst_size + src_size >= max_mb:
idx["chunk"], idx["file"] = update_chunk_file_indices(idx["chunk"], idx["file"], chunk_size)
new_path = aggr_root / default_path.format(chunk_index=idx["chunk"], file_index=idx["file"])
new_path.parent.mkdir(parents=True, exist_ok=True)
final_df = df
target_path = new_path
else:
existing_df = pd.read_parquet(dst_path)
final_df = pd.concat([existing_df, df], ignore_index=True)
target_path = dst_path
if contains_images:
to_parquet_with_hf_images(final_df, target_path)
else:
final_df.to_parquet(target_path)
return idx
def finalize_aggregation(aggr_meta, all_metadata):
"""Finalizes the dataset aggregation by writing summary files and statistics.
Writes the tasks file, info file with total counts and splits, and
aggregated statistics from all source datasets.
Args:
aggr_meta: Aggregated dataset metadata.
all_metadata: List of all source dataset metadata objects.
"""
logging.info("write tasks")
write_tasks(aggr_meta.tasks, aggr_meta.root)
logging.info("write info")
aggr_meta.info.update(
{
"total_tasks": len(aggr_meta.tasks),
"total_episodes": sum(m.total_episodes for m in all_metadata),
"total_frames": sum(m.total_frames for m in all_metadata),
"splits": {"train": f"0:{sum(m.total_episodes for m in all_metadata)}"},
}
)
write_info(aggr_meta.info, aggr_meta.root)
logging.info("write stats")
aggr_meta.stats = aggregate_stats([m.stats for m in all_metadata])
write_stats(aggr_meta.stats, aggr_meta.root)
src/lerobot/datasets/backward_compatibility.py
+24 -12
View File
@@ -14,17 +14,34 @@
import packaging.version
V30_MESSAGE = """
V2_MESSAGE = """
The dataset you requested ({repo_id}) is in {version} format.
We introduced a new format since v3.0 which is not backward compatible with v2.1.
Please, update your dataset to the new format using this command:
We introduced a new format since v2.0 which is not backward compatible with v1.x.
Please, use our conversion script. Modify the following command with your own task description:
```
python -m lerobot.datasets.v30.convert_dataset_v21_to_v30 --repo-id={repo_id}
python -m lerobot.datasets.v2.convert_dataset_v1_to_v2 \\
--repo-id {repo_id} \\
--single-task "TASK DESCRIPTION." # <---- /!\\ Replace TASK DESCRIPTION /!\\
```
If you already have a converted version uploaded to the hub, then this error might be because of
an older version in your local cache. Consider deleting the cached version and retrying.
A few examples to replace TASK DESCRIPTION: "Pick up the blue cube and place it into the bin.", "Insert the
peg into the socket.", "Slide open the ziploc bag.", "Take the elevator to the 1st floor.", "Open the top
cabinet, store the pot inside it then close the cabinet.", "Push the T-shaped block onto the T-shaped
target.", "Grab the spray paint on the shelf and place it in the bin on top of the robot dog.", "Fold the
sweatshirt.", ...
If you encounter a problem, contact LeRobot maintainers on [Discord](https://discord.com/invite/s3KuuzsPFb)
or open an [issue on GitHub](https://github.com/huggingface/lerobot/issues/new/choose).
"""
V21_MESSAGE = """
The dataset you requested ({repo_id}) is in {version} format.
While current version of LeRobot is backward-compatible with it, the version of your dataset still uses global
stats instead of per-episode stats. Update your dataset stats to the new format using this command:
```
python -m lerobot.datasets.v21.convert_dataset_v20_to_v21 --repo-id={repo_id}
```
If you encounter a problem, contact LeRobot maintainers on [Discord](https://discord.com/invite/s3KuuzsPFb)
or open an [issue on GitHub](https://github.com/huggingface/lerobot/issues/new/choose).
@@ -41,12 +58,7 @@ class CompatibilityError(Exception): ...
class BackwardCompatibilityError(CompatibilityError):
def __init__(self, repo_id: str, version: packaging.version.Version):
if version.major == 2 and version.minor == 1:
message = V30_MESSAGE.format(repo_id=repo_id, version=version)
else:
raise NotImplementedError(
"Contact the maintainer on [Discord](https://discord.com/invite/s3KuuzsPFb)."
)
message = V2_MESSAGE.format(repo_id=repo_id, version=version)
super().__init__(message)
src/lerobot/datasets/compute_stats.py
+31 -481
View File
@@ -17,179 +17,6 @@ import numpy as np
from lerobot.datasets.utils import load_image_as_numpy
DEFAULT_QUANTILES = [0.01, 0.10, 0.50, 0.90, 0.99]
class RunningQuantileStats:
"""
Maintains running statistics for batches of vectors, including mean,
standard deviation, min, max, and approximate quantiles.
Statistics are computed per feature dimension and updated incrementally
as new batches are observed. Quantiles are estimated using histograms,
which adapt dynamically if the observed data range expands.
"""
def __init__(self, quantile_list: list[float] | None = None, num_quantile_bins: int = 5000):
self._count = 0
self._mean = None
self._mean_of_squares = None
self._min = None
self._max = None
self._histograms = None
self._bin_edges = None
self._num_quantile_bins = num_quantile_bins
self._quantile_list = quantile_list
if self._quantile_list is None:
self._quantile_list = DEFAULT_QUANTILES
self._quantile_keys = [f"q{int(q * 100):02d}" for q in self._quantile_list]
def update(self, batch: np.ndarray) -> None:
"""Update the running statistics with a batch of vectors.
Args:
batch: An array where all dimensions except the last are batch dimensions.
"""
batch = batch.reshape(-1, batch.shape[-1])
num_elements, vector_length = batch.shape
if self._count == 0:
self._mean = np.mean(batch, axis=0)
self._mean_of_squares = np.mean(batch**2, axis=0)
self._min = np.min(batch, axis=0)
self._max = np.max(batch, axis=0)
self._histograms = [np.zeros(self._num_quantile_bins) for _ in range(vector_length)]
self._bin_edges = [
np.linspace(self._min[i] - 1e-10, self._max[i] + 1e-10, self._num_quantile_bins + 1)
for i in range(vector_length)
]
else:
if vector_length != self._mean.size:
raise ValueError("The length of new vectors does not match the initialized vector length.")
new_max = np.max(batch, axis=0)
new_min = np.min(batch, axis=0)
max_changed = np.any(new_max > self._max)
min_changed = np.any(new_min < self._min)
self._max = np.maximum(self._max, new_max)
self._min = np.minimum(self._min, new_min)
if max_changed or min_changed:
self._adjust_histograms()
self._count += num_elements
batch_mean = np.mean(batch, axis=0)
batch_mean_of_squares = np.mean(batch**2, axis=0)
# Update running mean and mean of squares
self._mean += (batch_mean - self._mean) * (num_elements / self._count)
self._mean_of_squares += (batch_mean_of_squares - self._mean_of_squares) * (
num_elements / self._count
)
self._update_histograms(batch)
def get_statistics(self) -> dict[str, np.ndarray]:
"""Compute and return the statistics of the vectors processed so far.
Args:
quantiles: List of quantiles to compute (e.g., [0.01, 0.10, 0.50, 0.90, 0.99]). If None, no quantiles computed.
Returns:
Dictionary containing the computed statistics.
"""
if self._count < 2:
raise ValueError("Cannot compute statistics for less than 2 vectors.")
variance = self._mean_of_squares - self._mean**2
stddev = np.sqrt(np.maximum(0, variance))
stats = {
"min": self._min.copy(),
"max": self._max.copy(),
"mean": self._mean.copy(),
"std": stddev,
"count": np.array([self._count]),
}
quantile_results = self._compute_quantiles()
for i, q in enumerate(self._quantile_keys):
stats[q] = quantile_results[i]
return stats
def _adjust_histograms(self):
"""Adjust histograms when min or max changes."""
for i in range(len(self._histograms)):
old_edges = self._bin_edges[i]
old_hist = self._histograms[i]
# Create new edges with small padding to ensure range coverage
padding = (self._max[i] - self._min[i]) * 1e-10
new_edges = np.linspace(
self._min[i] - padding, self._max[i] + padding, self._num_quantile_bins + 1
)
# Redistribute existing histogram counts to new bins
# We need to map each old bin center to the new bins
old_centers = (old_edges[:-1] + old_edges[1:]) / 2
new_hist = np.zeros(self._num_quantile_bins)
for old_center, count in zip(old_centers, old_hist, strict=False):
if count > 0:
# Find which new bin this old center belongs to
bin_idx = np.searchsorted(new_edges, old_center) - 1
bin_idx = max(0, min(bin_idx, self._num_quantile_bins - 1))
new_hist[bin_idx] += count
self._histograms[i] = new_hist
self._bin_edges[i] = new_edges
def _update_histograms(self, batch: np.ndarray) -> None:
"""Update histograms with new vectors."""
for i in range(batch.shape[1]):
hist, _ = np.histogram(batch[:, i], bins=self._bin_edges[i])
self._histograms[i] += hist
def _compute_quantiles(self) -> list[np.ndarray]:
"""Compute quantiles based on histograms."""
results = []
for q in self._quantile_list:
target_count = q * self._count
q_values = []
for hist, edges in zip(self._histograms, self._bin_edges, strict=True):
q_value = self._compute_single_quantile(hist, edges, target_count)
q_values.append(q_value)
results.append(np.array(q_values))
return results
def _compute_single_quantile(self, hist: np.ndarray, edges: np.ndarray, target_count: float) -> float:
"""Compute a single quantile value from histogram and bin edges."""
cumsum = np.cumsum(hist)
idx = np.searchsorted(cumsum, target_count)
if idx == 0:
return edges[0]
if idx >= len(cumsum):
return edges[-1]
# If not edge case, interpolate within the bin
count_before = cumsum[idx - 1]
count_in_bin = cumsum[idx] - count_before
# If no samples in this bin, use the bin edge
if count_in_bin == 0:
return edges[idx]
# Linear interpolation within the bin
fraction = (target_count - count_before) / count_in_bin
return edges[idx] + fraction * (edges[idx + 1] - edges[idx])
def estimate_num_samples(
dataset_len: int, min_num_samples: int = 100, max_num_samples: int = 10_000, power: float = 0.75
@@ -245,282 +72,33 @@ def sample_images(image_paths: list[str]) -> np.ndarray:
return images
def _reshape_stats_by_axis(
stats: dict[str, np.ndarray],
axis: int | tuple[int, ...] | None,
keepdims: bool,
original_shape: tuple[int, ...],
) -> dict[str, np.ndarray]:
"""Reshape all statistics to match NumPy's output conventions.
Applies consistent reshaping to all statistics (except 'count') based on the
axis and keepdims parameters. This ensures statistics have the correct shape
for broadcasting with the original data.
Args:
stats: Dictionary of computed statistics
axis: Axis or axes along which statistics were computed
keepdims: Whether to keep reduced dimensions as size-1 dimensions
original_shape: Shape of the original array
Returns:
Dictionary with reshaped statistics
Note:
The 'count' statistic is never reshaped as it represents metadata
rather than per-feature statistics.
"""
if axis == (1,) and not keepdims:
return stats
result = {}
for key, value in stats.items():
if key == "count":
result[key] = value
else:
result[key] = _reshape_single_stat(value, axis, keepdims, original_shape)
return result
def _reshape_for_image_stats(value: np.ndarray, keepdims: bool) -> np.ndarray:
"""Reshape statistics for image data (axis=(0,2,3))."""
if keepdims and value.ndim == 1:
return value.reshape(1, -1, 1, 1)
return value
def _reshape_for_vector_stats(
value: np.ndarray, keepdims: bool, original_shape: tuple[int, ...]
) -> np.ndarray:
"""Reshape statistics for vector data (axis=0 or axis=(0,))."""
if not keepdims:
return value
if len(original_shape) == 1 and value.ndim > 0:
return value.reshape(1)
elif len(original_shape) >= 2 and value.ndim == 1:
return value.reshape(1, -1)
return value
def _reshape_for_feature_stats(value: np.ndarray, keepdims: bool) -> np.ndarray:
"""Reshape statistics for feature-wise computation (axis=(1,))."""
if not keepdims:
return value
if value.ndim == 0:
return value.reshape(1, 1)
elif value.ndim == 1:
return value.reshape(-1, 1)
return value
def _reshape_for_global_stats(
value: np.ndarray, keepdims: bool, original_shape: tuple[int, ...]
) -> np.ndarray | float:
"""Reshape statistics for global reduction (axis=None)."""
if keepdims:
target_shape = tuple(1 for _ in original_shape)
return value.reshape(target_shape)
# Keep at least 1-D arrays to satisfy validator
return np.atleast_1d(value)
def _reshape_single_stat(
value: np.ndarray, axis: int | tuple[int, ...] | None, keepdims: bool, original_shape: tuple[int, ...]
) -> np.ndarray | float:
"""Apply appropriate reshaping to a single statistic array.
This function transforms statistic arrays to match expected output shapes
based on the axis configuration and keepdims parameter.
Args:
value: The statistic array to reshape
axis: Axis or axes that were reduced during computation
keepdims: Whether to maintain reduced dimensions as size-1 dimensions
original_shape: Shape of the original data before reduction
Returns:
Reshaped array following NumPy broadcasting conventions
"""
if axis == (0, 2, 3):
return _reshape_for_image_stats(value, keepdims)
if axis in [0, (0,)]:
return _reshape_for_vector_stats(value, keepdims, original_shape)
if axis == (1,):
return _reshape_for_feature_stats(value, keepdims)
if axis is None:
return _reshape_for_global_stats(value, keepdims, original_shape)
return value
def _prepare_array_for_stats(array: np.ndarray, axis: int | tuple[int, ...] | None) -> tuple[np.ndarray, int]:
"""Prepare array for statistics computation by reshaping according to axis.
Args:
array: Input data array
axis: Axis or axes along which to compute statistics
Returns:
Tuple of (reshaped_array, sample_count)
"""
if axis == (0, 2, 3): # Image data
batch_size, channels, height, width = array.shape
reshaped = array.transpose(0, 2, 3, 1).reshape(-1, channels)
return reshaped, batch_size
if axis == 0 or axis == (0,): # Vector data
reshaped = array
if array.ndim == 1:
reshaped = array.reshape(-1, 1)
return reshaped, array.shape[0]
if axis == (1,): # Feature-wise statistics
return array.T, array.shape[1]
if axis is None: # Global statistics
reshaped = array.reshape(-1, 1)
# For backward compatibility, count represents the first dimension size
return reshaped, array.shape[0] if array.ndim > 0 else 1
raise ValueError(f"Unsupported axis configuration: {axis}")
def _compute_basic_stats(
array: np.ndarray, sample_count: int, quantile_list: list[float] | None = None
) -> dict[str, np.ndarray]:
"""Compute basic statistics for arrays with insufficient samples for quantiles.
Args:
array: Reshaped array ready for statistics computation
sample_count: Number of samples represented in the data
Returns:
Dictionary with basic statistics and quantiles set to mean values
"""
if quantile_list is None:
quantile_list = DEFAULT_QUANTILES
quantile_list_keys = [f"q{int(q * 100):02d}" for q in quantile_list]
stats = {
"min": np.min(array, axis=0),
"max": np.max(array, axis=0),
"mean": np.mean(array, axis=0),
"std": np.std(array, axis=0),
"count": np.array([sample_count]),
def get_feature_stats(array: np.ndarray, axis: tuple, keepdims: bool) -> dict[str, np.ndarray]:
return {
"min": np.min(array, axis=axis, keepdims=keepdims),
"max": np.max(array, axis=axis, keepdims=keepdims),
"mean": np.mean(array, axis=axis, keepdims=keepdims),
"std": np.std(array, axis=axis, keepdims=keepdims),
"count": np.array([len(array)]),
}
for q in quantile_list_keys:
stats[q] = stats["mean"].copy()
return stats
def get_feature_stats(
array: np.ndarray,
axis: int | tuple[int, ...] | None,
keepdims: bool,
quantile_list: list[float] | None = None,
) -> dict[str, np.ndarray]:
"""Compute comprehensive statistics for array features along specified axes.
This function calculates min, max, mean, std, and quantiles (1%, 10%, 50%, 90%, 99%)
for the input array along the specified axes. It handles different data layouts:
- Image data: axis=(0,2,3) computes per-channel statistics
- Vector data: axis=0 computes per-feature statistics
- Feature-wise: axis=1 computes statistics across features
- Global: axis=None computes statistics over entire array
Args:
array: Input data array with shape appropriate for the specified axis
axis: Axis or axes along which to compute statistics
- (0, 2, 3): For image data (batch, channels, height, width)
- 0 or (0,): For vector/tabular data (samples, features)
- (1,): For computing across features
- None: For global statistics over entire array
keepdims: If True, reduced axes are kept as dimensions with size 1
Returns:
Dictionary containing:
- 'min': Minimum values
- 'max': Maximum values
- 'mean': Mean values
- 'std': Standard deviation
- 'count': Number of samples (always shape (1,))
- 'q01', 'q10', 'q50', 'q90', 'q99': Quantile values
"""
if quantile_list is None:
quantile_list = DEFAULT_QUANTILES
original_shape = array.shape
reshaped, sample_count = _prepare_array_for_stats(array, axis)
if reshaped.shape[0] < 2:
stats = _compute_basic_stats(reshaped, sample_count, quantile_list)
else:
running_stats = RunningQuantileStats()
running_stats.update(reshaped)
stats = running_stats.get_statistics()
stats["count"] = np.array([sample_count])
stats = _reshape_stats_by_axis(stats, axis, keepdims, original_shape)
return stats
def compute_episode_stats(
episode_data: dict[str, list[str] | np.ndarray],
features: dict,
quantile_list: list[float] | None = None,
) -> dict:
"""Compute comprehensive statistics for all features in an episode.
Processes different data types appropriately:
- Images/videos: Samples from paths, computes per-channel stats, normalizes to [0,1]
- Numerical arrays: Computes per-feature statistics
- Strings: Skipped (no statistics computed)
Args:
episode_data: Dictionary mapping feature names to data
- For images/videos: list of file paths
- For numerical data: numpy arrays
features: Dictionary describing each feature's dtype and shape
Returns:
Dictionary mapping feature names to their statistics dictionaries.
Each statistics dictionary contains min, max, mean, std, count, and quantiles.
Note:
Image statistics are normalized to [0,1] range and have shape (3,1,1) for
per-channel values when dtype is 'image' or 'video'.
"""
if quantile_list is None:
quantile_list = DEFAULT_QUANTILES
def compute_episode_stats(episode_data: dict[str, list[str] | np.ndarray], features: dict) -> dict:
ep_stats = {}
for key, data in episode_data.items():
if features[key]["dtype"] == "string":
continue
if features[key]["dtype"] in ["image", "video"]:
ep_ft_array = sample_images(data)
axes_to_reduce = (0, 2, 3)
continue # HACK: we should receive np.arrays of strings
elif features[key]["dtype"] in ["image", "video"]:
ep_ft_array = sample_images(data) # data is a list of image paths
axes_to_reduce = (0, 2, 3) # keep channel dim
keepdims = True
else:
ep_ft_array = data
axes_to_reduce = 0
keepdims = data.ndim == 1
ep_ft_array = data # data is already a np.ndarray
axes_to_reduce = 0 # compute stats over the first axis
keepdims = data.ndim == 1 # keep as np.array
ep_stats[key] = get_feature_stats(
ep_ft_array, axis=axes_to_reduce, keepdims=keepdims, quantile_list=quantile_list
)
ep_stats[key] = get_feature_stats(ep_ft_array, axis=axes_to_reduce, keepdims=keepdims)
# finally, we normalize and remove batch dim for images
if features[key]["dtype"] in ["image", "video"]:
ep_stats[key] = {
k: v if k == "count" else np.squeeze(v / 255.0, axis=0) for k, v in ep_stats[key].items()
@@ -529,37 +107,20 @@ def compute_episode_stats(
return ep_stats
def _validate_stat_value(value: np.ndarray, key: str, feature_key: str) -> None:
"""Validate a single statistic value."""
if not isinstance(value, np.ndarray):
raise ValueError(
f"Stats must be composed of numpy array, but key '{key}' of feature '{feature_key}' "
f"is of type '{type(value)}' instead."
)
if value.ndim == 0:
raise ValueError("Number of dimensions must be at least 1, and is 0 instead.")
if key == "count" and value.shape != (1,):
raise ValueError(f"Shape of 'count' must be (1), but is {value.shape} instead.")
if "image" in feature_key and key != "count" and value.shape != (3, 1, 1):
raise ValueError(f"Shape of quantile '{key}' must be (3,1,1), but is {value.shape} instead.")
def _assert_type_and_shape(stats_list: list[dict[str, dict]]):
"""Validate that all statistics have correct types and shapes.
Args:
stats_list: List of statistics dictionaries to validate
Raises:
ValueError: If any statistic has incorrect type or shape
"""
for stats in stats_list:
for feature_key, feature_stats in stats.items():
for stat_key, stat_value in feature_stats.items():
_validate_stat_value(stat_value, stat_key, feature_key)
for i in range(len(stats_list)):
for fkey in stats_list[i]:
for k, v in stats_list[i][fkey].items():
if not isinstance(v, np.ndarray):
raise ValueError(
f"Stats must be composed of numpy array, but key '{k}' of feature '{fkey}' is of type '{type(v)}' instead."
)
if v.ndim == 0:
raise ValueError("Number of dimensions must be at least 1, and is 0 instead.")
if k == "count" and v.shape != (1,):
raise ValueError(f"Shape of 'count' must be (1), but is {v.shape} instead.")
if "image" in fkey and k != "count" and v.shape != (3, 1, 1):
raise ValueError(f"Shape of '{k}' must be (3,1,1), but is {v.shape} instead.")
def aggregate_feature_stats(stats_ft_list: list[dict[str, dict]]) -> dict[str, dict[str, np.ndarray]]:
@@ -582,7 +143,7 @@ def aggregate_feature_stats(stats_ft_list: list[dict[str, dict]]) -> dict[str, d
weighted_variances = (variances + delta_means**2) * counts
total_variance = weighted_variances.sum(axis=0) / total_count
aggregated = {
return {
"min": np.min(np.stack([s["min"] for s in stats_ft_list]), axis=0),
"max": np.max(np.stack([s["max"] for s in stats_ft_list]), axis=0),
"mean": total_mean,
@@ -590,17 +151,6 @@ def aggregate_feature_stats(stats_ft_list: list[dict[str, dict]]) -> dict[str, d
"count": total_count,
}
if stats_ft_list:
quantile_keys = [k for k in stats_ft_list[0] if k.startswith("q") and k[1:].isdigit()]
for q_key in quantile_keys:
if all(q_key in s for s in stats_ft_list):
quantile_values = np.stack([s[q_key] for s in stats_ft_list])
weighted_quantiles = quantile_values * counts
aggregated[q_key] = weighted_quantiles.sum(axis=0) / total_count
return aggregated
def aggregate_stats(stats_list: list[dict[str, dict]]) -> dict[str, dict[str, np.ndarray]]:
"""Aggregate stats from multiple compute_stats outputs into a single set of stats.
src/lerobot/datasets/dataset_tools.py
-1089
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File diff suppressed because it is too large Load Diff
src/lerobot/datasets/factory.py
+12 -25
View File
@@ -25,9 +25,7 @@ from lerobot.datasets.lerobot_dataset import (
LeRobotDatasetMetadata,
MultiLeRobotDataset,
)
from lerobot.datasets.streaming_dataset import StreamingLeRobotDataset
from lerobot.datasets.transforms import ImageTransforms
from lerobot.utils.constants import ACTION, OBS_PREFIX, REWARD
IMAGENET_STATS = {
"mean": [[[0.485]], [[0.456]], [[0.406]]], # (c,1,1)
@@ -55,11 +53,11 @@ def resolve_delta_timestamps(
"""
delta_timestamps = {}
for key in ds_meta.features:
if key == REWARD and cfg.reward_delta_indices is not None:
if key == "next.reward" and cfg.reward_delta_indices is not None:
delta_timestamps[key] = [i / ds_meta.fps for i in cfg.reward_delta_indices]
if key == ACTION and cfg.action_delta_indices is not None:
if key == "action" and cfg.action_delta_indices is not None:
delta_timestamps[key] = [i / ds_meta.fps for i in cfg.action_delta_indices]
if key.startswith(OBS_PREFIX) and cfg.observation_delta_indices is not None:
if key.startswith("observation.") and cfg.observation_delta_indices is not None:
delta_timestamps[key] = [i / ds_meta.fps for i in cfg.observation_delta_indices]
if len(delta_timestamps) == 0:
@@ -89,26 +87,15 @@ def make_dataset(cfg: TrainPipelineConfig) -> LeRobotDataset | MultiLeRobotDatas
cfg.dataset.repo_id, root=cfg.dataset.root, revision=cfg.dataset.revision
)
delta_timestamps = resolve_delta_timestamps(cfg.policy, ds_meta)
if not cfg.dataset.streaming:
dataset = LeRobotDataset(
cfg.dataset.repo_id,
root=cfg.dataset.root,
episodes=cfg.dataset.episodes,
delta_timestamps=delta_timestamps,
image_transforms=image_transforms,
revision=cfg.dataset.revision,
video_backend=cfg.dataset.video_backend,
)
else:
dataset = StreamingLeRobotDataset(
cfg.dataset.repo_id,
root=cfg.dataset.root,
episodes=cfg.dataset.episodes,
delta_timestamps=delta_timestamps,
image_transforms=image_transforms,
revision=cfg.dataset.revision,
max_num_shards=cfg.num_workers,
)
dataset = LeRobotDataset(
cfg.dataset.repo_id,
root=cfg.dataset.root,
episodes=cfg.dataset.episodes,
delta_timestamps=delta_timestamps,
image_transforms=image_transforms,
revision=cfg.dataset.revision,
video_backend=cfg.dataset.video_backend,
)
else:
raise NotImplementedError("The MultiLeRobotDataset isn't supported for now.")
dataset = MultiLeRobotDataset(
src/lerobot/datasets/image_writer.py
+2 -25
View File
@@ -68,30 +68,7 @@ def image_array_to_pil_image(image_array: np.ndarray, range_check: bool = True)
return PIL.Image.fromarray(image_array)
def write_image(image: np.ndarray | PIL.Image.Image, fpath: Path, compress_level: int = 1):
"""
Saves a NumPy array or PIL Image to a file.
This function handles both NumPy arrays and PIL Image objects, converting
the former to a PIL Image before saving. It includes error handling for
the save operation.
Args:
image (np.ndarray | PIL.Image.Image): The image data to save.
fpath (Path): The destination file path for the image.
compress_level (int, optional): The compression level for the saved
image, as used by PIL.Image.save(). Defaults to 1.
Refer to: https://github.com/huggingface/lerobot/pull/2135
for more details on the default value rationale.
Raises:
TypeError: If the input 'image' is not a NumPy array or a
PIL.Image.Image object.
Side Effects:
Prints an error message to the console if the image writing process
fails for any reason.
"""
def write_image(image: np.ndarray | PIL.Image.Image, fpath: Path):
try:
if isinstance(image, np.ndarray):
img = image_array_to_pil_image(image)
@@ -99,7 +76,7 @@ def write_image(image: np.ndarray | PIL.Image.Image, fpath: Path, compress_level
img = image
else:
raise TypeError(f"Unsupported image type: {type(image)}")
img.save(fpath, compress_level=compress_level)
img.save(fpath)
except Exception as e:
print(f"Error writing image {fpath}: {e}")
src/lerobot/datasets/lerobot_dataset.py
+249 -672
View File
File diff suppressed because it is too large Load Diff
src/lerobot/datasets/online_buffer.py
+5 -3
View File
@@ -337,11 +337,13 @@ def compute_sampler_weights(
if len(offline_dataset) > 0:
offline_data_mask_indices = []
for start_index, end_index in zip(
offline_dataset.meta.episodes["dataset_from_index"],
offline_dataset.meta.episodes["dataset_to_index"],
offline_dataset.episode_data_index["from"],
offline_dataset.episode_data_index["to"],
strict=True,
):
offline_data_mask_indices.extend(range(start_index, end_index - offline_drop_n_last_frames))
offline_data_mask_indices.extend(
range(start_index.item(), end_index.item() - offline_drop_n_last_frames)
)
offline_data_mask = torch.zeros(len(offline_dataset), dtype=torch.bool)
offline_data_mask[torch.tensor(offline_data_mask_indices)] = True
weights.append(
src/lerobot/datasets/pipeline_features.py
-139
View File
@@ -1,139 +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.
import re
from collections.abc import Sequence
from typing import Any
from lerobot.configs.types import PipelineFeatureType
from lerobot.datasets.utils import hw_to_dataset_features
from lerobot.processor import DataProcessorPipeline
from lerobot.utils.constants import ACTION, OBS_IMAGES, OBS_STATE, OBS_STR
def create_initial_features(
action: dict[str, Any] | None = None, observation: dict[str, Any] | None = None
) -> dict[PipelineFeatureType, dict[str, Any]]:
"""
Creates the initial features dict for the dataset from action and observation specs.
Args:
action: A dictionary of action feature names to their types/shapes.
observation: A dictionary of observation feature names to their types/shapes.
Returns:
The initial features dictionary structured by PipelineFeatureType.
"""
features = {PipelineFeatureType.ACTION: {}, PipelineFeatureType.OBSERVATION: {}}
if action:
features[PipelineFeatureType.ACTION] = action
if observation:
features[PipelineFeatureType.OBSERVATION] = observation
return features
# Helper to filter state/action keys based on regex patterns.
def should_keep(key: str, patterns: tuple[str]) -> bool:
if patterns is None:
return True
return any(re.search(pat, key) for pat in patterns)
def strip_prefix(key: str, prefixes_to_strip: tuple[str]) -> str:
for prefix in prefixes_to_strip:
if key.startswith(prefix):
return key[len(prefix) :]
return key
# Define prefixes to strip from feature keys for clean names.
# Handles both fully qualified (e.g., "action.state") and short (e.g., "state") forms.
PREFIXES_TO_STRIP = tuple(
f"{token}." for const in (ACTION, OBS_STATE, OBS_IMAGES) for token in (const, const.split(".")[-1])
)
def aggregate_pipeline_dataset_features(
pipeline: DataProcessorPipeline,
initial_features: dict[PipelineFeatureType, dict[str, Any]],
*,
use_videos: bool = True,
patterns: Sequence[str] | None = None,
) -> dict[str, dict]:
"""
Aggregates and filters pipeline features to create a dataset-ready features dictionary.
This function transforms initial features using the pipeline, categorizes them as action or observations
(image or state), filters them based on `use_videos` and `patterns`, and finally
formats them for use with a Hugging Face LeRobot Dataset.
Args:
pipeline: The DataProcessorPipeline to apply.
initial_features: A dictionary of raw feature specs for actions and observations.
use_videos: If False, image features are excluded.
patterns: A sequence of regex patterns to filter action and state features.
Image features are not affected by this filter.
Returns:
A dictionary of features formatted for a Hugging Face LeRobot Dataset.
"""
all_features = pipeline.transform_features(initial_features)
# Intermediate storage for categorized and filtered features.
processed_features: dict[str, dict[str, Any]] = {
ACTION: {},
OBS_STR: {},
}
images_token = OBS_IMAGES.split(".")[-1]
# Iterate through all features transformed by the pipeline.
for ptype, feats in all_features.items():
if ptype not in [PipelineFeatureType.ACTION, PipelineFeatureType.OBSERVATION]:
continue
for key, value in feats.items():
# 1. Categorize the feature.
is_action = ptype == PipelineFeatureType.ACTION
# Observations are classified as images if their key matches image-related tokens or if the shape of the feature is 3.
# All other observations are treated as state.
is_image = not is_action and (
(isinstance(value, tuple) and len(value) == 3)
or (
key.startswith(f"{OBS_IMAGES}.")
or key.startswith(f"{images_token}.")
or f".{images_token}." in key
)
)
# 2. Apply filtering rules.
if is_image and not use_videos:
continue
if not is_image and not should_keep(key, patterns):
continue
# 3. Add the feature to the appropriate group with a clean name.
name = strip_prefix(key, PREFIXES_TO_STRIP)
if is_action:
processed_features[ACTION][name] = value
else:
processed_features[OBS_STR][name] = value
# Convert the processed features into the final dataset format.
dataset_features = {}
if processed_features[ACTION]:
dataset_features.update(hw_to_dataset_features(processed_features[ACTION], ACTION, use_videos))
if processed_features[OBS_STR]:
dataset_features.update(hw_to_dataset_features(processed_features[OBS_STR], OBS_STR, use_videos))
return dataset_features
src/lerobot/datasets/push_dataset_to_hub/utils.py
+57
View File
@@ -13,10 +13,67 @@
# 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 inspect
from concurrent.futures import ThreadPoolExecutor
from pathlib import Path
import datasets
import numpy
import PIL
import torch
from lerobot.datasets.video_utils import encode_video_frames
def concatenate_episodes(ep_dicts):
data_dict = {}
keys = ep_dicts[0].keys()
for key in keys:
if torch.is_tensor(ep_dicts[0][key][0]):
data_dict[key] = torch.cat([ep_dict[key] for ep_dict in ep_dicts])
else:
if key not in data_dict:
data_dict[key] = []
for ep_dict in ep_dicts:
for x in ep_dict[key]:
data_dict[key].append(x)
total_frames = data_dict["frame_index"].shape[0]
data_dict["index"] = torch.arange(0, total_frames, 1)
return data_dict
def save_images_concurrently(imgs_array: numpy.array, out_dir: Path, max_workers: int = 4):
out_dir = Path(out_dir)
out_dir.mkdir(parents=True, exist_ok=True)
def save_image(img_array, i, out_dir):
img = PIL.Image.fromarray(img_array)
img.save(str(out_dir / f"frame_{i:06d}.png"), quality=100)
num_images = len(imgs_array)
with ThreadPoolExecutor(max_workers=max_workers) as executor:
[executor.submit(save_image, imgs_array[i], i, out_dir) for i in range(num_images)]
def get_default_encoding() -> dict:
"""Returns the default ffmpeg encoding parameters used by `encode_video_frames`."""
signature = inspect.signature(encode_video_frames)
return {
k: v.default
for k, v in signature.parameters.items()
if v.default is not inspect.Parameter.empty and k in ["vcodec", "pix_fmt", "g", "crf"]
}
def check_repo_id(repo_id: str) -> None:
if len(repo_id.split("/")) != 2:
raise ValueError(
f"""`repo_id` is expected to contain a community or user id `/` the name of the dataset
(e.g. 'lerobot/pusht'), but contains '{repo_id}'."""
)
# TODO(aliberts): remove
def calculate_episode_data_index(hf_dataset: datasets.Dataset) -> dict[str, torch.Tensor]:
src/lerobot/datasets/sampler.py
+6 -6
View File
@@ -21,8 +21,7 @@ import torch
class EpisodeAwareSampler:
def __init__(
self,
dataset_from_indices: list[int],
dataset_to_indices: list[int],
episode_data_index: dict,
episode_indices_to_use: list | None = None,
drop_n_first_frames: int = 0,
drop_n_last_frames: int = 0,
@@ -31,8 +30,7 @@ class EpisodeAwareSampler:
"""Sampler that optionally incorporates episode boundary information.
Args:
dataset_from_indices: List of indices containing the start of each episode in the dataset.
dataset_to_indices: List of indices containing the end of each episode in the dataset.
episode_data_index: Dictionary with keys 'from' and 'to' containing the start and end indices of each episode.
episode_indices_to_use: List of episode indices to use. If None, all episodes are used.
Assumes that episodes are indexed from 0 to N-1.
drop_n_first_frames: Number of frames to drop from the start of each episode.
@@ -41,10 +39,12 @@ class EpisodeAwareSampler:
"""
indices = []
for episode_idx, (start_index, end_index) in enumerate(
zip(dataset_from_indices, dataset_to_indices, strict=True)
zip(episode_data_index["from"], episode_data_index["to"], strict=True)
):
if episode_indices_to_use is None or episode_idx in episode_indices_to_use:
indices.extend(range(start_index + drop_n_first_frames, end_index - drop_n_last_frames))
indices.extend(
range(start_index.item() + drop_n_first_frames, end_index.item() - drop_n_last_frames)
)
self.indices = indices
self.shuffle = shuffle
src/lerobot/datasets/streaming_dataset.py
-533
View File
@@ -1,533 +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.
from collections.abc import Callable, Generator, Iterator
from pathlib import Path
import datasets
import numpy as np
import torch
from datasets import load_dataset
from lerobot.datasets.lerobot_dataset import CODEBASE_VERSION, LeRobotDatasetMetadata
from lerobot.datasets.utils import (
Backtrackable,
LookAheadError,
LookBackError,
check_version_compatibility,
find_float_index,
get_delta_indices,
is_float_in_list,
item_to_torch,
safe_shard,
)
from lerobot.datasets.video_utils import (
VideoDecoderCache,
decode_video_frames_torchcodec,
)
from lerobot.utils.constants import HF_LEROBOT_HOME, LOOKAHEAD_BACKTRACKTABLE, LOOKBACK_BACKTRACKTABLE
class StreamingLeRobotDataset(torch.utils.data.IterableDataset):
"""LeRobotDataset with streaming capabilities.
This class extends LeRobotDataset to add streaming functionality, allowing data to be streamed
rather than loaded entirely into memory. This is especially useful for large datasets that may
not fit in memory or when you want to quickly explore a dataset without downloading it completely.
The key innovation is using a Backtrackable iterator that maintains a bounded buffer of recent
items, allowing us to access previous frames for delta timestamps without loading the entire
dataset into memory.
Example:
Basic usage:
```python
from lerobot.common.datasets.streaming_dataset import StreamingLeRobotDataset
# Create a streaming dataset with delta timestamps
delta_timestamps = {
"observation.image": [-1.0, -0.5, 0.0], # 1 sec ago, 0.5 sec ago, current
"action": [0.0, 0.1, 0.2], # current, 0.1 sec future, 0.2 sec future
}
dataset = StreamingLeRobotDataset(
repo_id="your-dataset-repo-id",
delta_timestamps=delta_timestamps,
streaming=True,
buffer_size=1000,
)
# Iterate over the dataset
for i, item in enumerate(dataset):
print(f"Sample {i}: Episode {item['episode_index']} Frame {item['frame_index']}")
# item will contain stacked frames according to delta_timestamps
if i >= 10:
break
```
"""
def __init__(
self,
repo_id: str,
root: str | Path | None = None,
episodes: list[int] | None = None,
image_transforms: Callable | None = None,
delta_timestamps: dict[list[float]] | None = None,
tolerance_s: float = 1e-4,
revision: str | None = None,
force_cache_sync: bool = False,
streaming: bool = True,
buffer_size: int = 1000,
max_num_shards: int = 16,
seed: int = 42,
rng: np.random.Generator | None = None,
shuffle: bool = True,
):
"""Initialize a StreamingLeRobotDataset.
Args:
repo_id (str): This is the repo id that will be used to fetch the dataset.
root (Path | None, optional): Local directory to use for downloading/writing files.
episodes (list[int] | None, optional): If specified, this will only load episodes specified by
their episode_index in this list.
image_transforms (Callable | None, optional): Transform to apply to image data.
tolerance_s (float, optional): Tolerance in seconds for timestamp matching.
revision (str, optional): Git revision id (branch name, tag, or commit hash).
force_cache_sync (bool, optional): Flag to sync and refresh local files first.
streaming (bool, optional): Whether to stream the dataset or load it all. Defaults to True.
buffer_size (int, optional): Buffer size for shuffling when streaming. Defaults to 1000.
max_num_shards (int, optional): Number of shards to re-shard the input dataset into. Defaults to 16.
seed (int, optional): Reproducibility random seed.
rng (np.random.Generator | None, optional): Random number generator.
shuffle (bool, optional): Whether to shuffle the dataset across exhaustions. Defaults to True.
"""
super().__init__()
self.repo_id = repo_id
self.root = Path(root) if root else HF_LEROBOT_HOME / repo_id
self.streaming_from_local = root is not None
self.image_transforms = image_transforms
self.episodes = episodes
self.tolerance_s = tolerance_s
self.revision = revision if revision else CODEBASE_VERSION
self.seed = seed
self.rng = rng if rng is not None else np.random.default_rng(seed)
self.shuffle = shuffle
self.streaming = streaming
self.buffer_size = buffer_size
# We cache the video decoders to avoid re-initializing them at each frame (avoiding a ~10x slowdown)
self.video_decoder_cache = None
self.root.mkdir(exist_ok=True, parents=True)
# Load metadata
self.meta = LeRobotDatasetMetadata(
self.repo_id, self.root, self.revision, force_cache_sync=force_cache_sync
)
# Check version
check_version_compatibility(self.repo_id, self.meta._version, CODEBASE_VERSION)
self.delta_timestamps = None
self.delta_indices = None
if delta_timestamps is not None:
self._validate_delta_timestamp_keys(delta_timestamps) # raises ValueError if invalid
self.delta_timestamps = delta_timestamps
self.delta_indices = get_delta_indices(self.delta_timestamps, self.fps)
self.hf_dataset: datasets.IterableDataset = load_dataset(
self.repo_id if not self.streaming_from_local else str(self.root),
split="train",
streaming=self.streaming,
data_files="data/*/*.parquet",
revision=self.revision,
)
self.num_shards = min(self.hf_dataset.num_shards, max_num_shards)
@property
def num_frames(self):
return self.meta.total_frames
@property
def num_episodes(self):
return self.meta.total_episodes
@property
def fps(self):
return self.meta.fps
@staticmethod
def _iter_random_indices(
rng: np.random.Generator, buffer_size: int, random_batch_size=100
) -> Iterator[int]:
while True:
yield from (int(i) for i in rng.integers(0, buffer_size, size=random_batch_size))
@staticmethod
def _infinite_generator_over_elements(rng: np.random.Generator, elements: list[int]) -> Iterator[int]:
while True:
yield rng.choice(elements)
# TODO(fracapuano): Implement multi-threaded prefetching to accelerate data loading.
# The current sequential iteration is a bottleneck. A producer-consumer pattern
# could be used with a ThreadPoolExecutor to run `make_frame` (especially video decoding)
# in parallel, feeding a queue from which this iterator will yield processed items.
def __iter__(self) -> Iterator[dict[str, torch.Tensor]]:
if self.video_decoder_cache is None:
self.video_decoder_cache = VideoDecoderCache()
# keep the same seed across exhaustions if shuffle is False, otherwise shuffle data across exhaustions
rng = np.random.default_rng(self.seed) if not self.shuffle else self.rng
buffer_indices_generator = self._iter_random_indices(rng, self.buffer_size)
idx_to_backtrack_dataset = {
idx: self._make_backtrackable_dataset(safe_shard(self.hf_dataset, idx, self.num_shards))
for idx in range(self.num_shards)
}
# This buffer is populated while iterating on the dataset's shards
# the logic is to add 2 levels of randomness:
# (1) sample one shard at random from the ones available, and
# (2) sample one frame from the shard sampled at (1)
frames_buffer = []
while available_shards := list(idx_to_backtrack_dataset.keys()):
shard_key = next(self._infinite_generator_over_elements(rng, available_shards))
backtrack_dataset = idx_to_backtrack_dataset[shard_key] # selects which shard to iterate on
try:
for frame in self.make_frame(backtrack_dataset):
if len(frames_buffer) == self.buffer_size:
i = next(buffer_indices_generator) # samples a element from the buffer
yield frames_buffer[i]
frames_buffer[i] = frame
else:
frames_buffer.append(frame)
break # random shard sampled, switch shard
except (
RuntimeError,
StopIteration,
): # NOTE: StopIteration inside a generator throws a RuntimeError since python 3.7
del idx_to_backtrack_dataset[shard_key] # Remove exhausted shard, onto another shard
# Once shards are all exhausted, shuffle the buffer and yield the remaining frames
rng.shuffle(frames_buffer)
yield from frames_buffer
def _get_window_steps(
self, delta_timestamps: dict[str, list[float]] | None = None, dynamic_bounds: bool = False
) -> tuple[int, int]:
if delta_timestamps is None:
return 1, 1
if not dynamic_bounds:
# Fix the windows
lookback = LOOKBACK_BACKTRACKTABLE
lookahead = LOOKAHEAD_BACKTRACKTABLE
else:
# Dynamically adjust the windows based on the given delta_timesteps
all_timestamps = sum(delta_timestamps.values(), [])
lookback = min(all_timestamps) * self.fps
lookahead = max(all_timestamps) * self.fps
# When lookback is >=0 it means no negative timesteps have been provided
lookback = 0 if lookback >= 0 else (lookback * -1)
return lookback, lookahead
def _make_backtrackable_dataset(self, dataset: datasets.IterableDataset) -> Backtrackable:
lookback, lookahead = self._get_window_steps(self.delta_timestamps)
return Backtrackable(dataset, history=lookback, lookahead=lookahead)
def _make_timestamps_from_indices(
self, start_ts: float, indices: dict[str, list[int]] | None = None
) -> dict[str, list[float]]:
if indices is not None:
return {
key: (
start_ts + torch.tensor(indices[key]) / self.fps
).tolist() # NOTE: why not delta_timestamps directly?
for key in self.delta_timestamps
}
else:
return dict.fromkeys(self.meta.video_keys, [start_ts])
def _make_padding_camera_frame(self, camera_key: str):
"""Variable-shape padding frame for given camera keys, given in (H, W, C)"""
return torch.zeros(self.meta.info["features"][camera_key]["shape"]).permute(-1, 0, 1)
def _get_video_frame_padding_mask(
self,
video_frames: dict[str, torch.Tensor],
query_timestamps: dict[str, list[float]],
original_timestamps: dict[str, list[float]],
) -> dict[str, torch.BoolTensor]:
padding_mask = {}
for video_key, timestamps in original_timestamps.items():
if video_key not in video_frames:
continue # only padding on video keys that are available
frames = []
mask = []
padding_frame = self._make_padding_camera_frame(video_key)
for ts in timestamps:
if is_float_in_list(ts, query_timestamps[video_key]):
idx = find_float_index(ts, query_timestamps[video_key])
frames.append(video_frames[video_key][idx, :])
mask.append(False)
else:
frames.append(padding_frame)
mask.append(True)
padding_mask[f"{video_key}_is_pad"] = torch.BoolTensor(mask)
return padding_mask
def make_frame(self, dataset_iterator: Backtrackable) -> Generator:
"""Makes a frame starting from a dataset iterator"""
item = next(dataset_iterator)
item = item_to_torch(item)
updates = [] # list of "updates" to apply to the item retrieved from hf_dataset (w/o camera features)
# Get episode index from the item
ep_idx = item["episode_index"]
# "timestamp" restarts from 0 for each episode, whereas we need a global timestep within the single .mp4 file (given by index/fps)
current_ts = item["index"] / self.fps
episode_boundaries_ts = {
key: (
self.meta.episodes[ep_idx][f"videos/{key}/from_timestamp"],
self.meta.episodes[ep_idx][f"videos/{key}/to_timestamp"],
)
for key in self.meta.video_keys
}
# Apply delta querying logic if necessary
if self.delta_indices is not None:
query_result, padding = self._get_delta_frames(dataset_iterator, item)
updates.append(query_result)
updates.append(padding)
# Load video frames, when needed
if len(self.meta.video_keys) > 0:
original_timestamps = self._make_timestamps_from_indices(current_ts, self.delta_indices)
# Some timestamps might not result available considering the episode's boundaries
query_timestamps = self._get_query_timestamps(
current_ts, self.delta_indices, episode_boundaries_ts
)
video_frames = self._query_videos(query_timestamps, ep_idx)
if self.image_transforms is not None:
image_keys = self.meta.camera_keys
for cam in image_keys:
video_frames[cam] = self.image_transforms(video_frames[cam])
updates.append(video_frames)
if self.delta_indices is not None:
# We always return the same number of frames. Unavailable frames are padded.
padding_mask = self._get_video_frame_padding_mask(
video_frames, query_timestamps, original_timestamps
)
updates.append(padding_mask)
result = item.copy()
for update in updates:
result.update(update)
result["task"] = self.meta.tasks.iloc[item["task_index"]].name
yield result
def _get_query_timestamps(
self,
current_ts: float,
query_indices: dict[str, list[int]] | None = None,
episode_boundaries_ts: dict[str, tuple[float, float]] | None = None,
) -> dict[str, list[float]]:
query_timestamps = {}
keys_to_timestamps = self._make_timestamps_from_indices(current_ts, query_indices)
for key in self.meta.video_keys:
if query_indices is not None and key in query_indices:
timestamps = keys_to_timestamps[key]
# Clamp out timesteps outside of episode boundaries
query_timestamps[key] = torch.clamp(
torch.tensor(timestamps), *episode_boundaries_ts[key]
).tolist()
else:
query_timestamps[key] = [current_ts]
return query_timestamps
def _query_videos(self, query_timestamps: dict[str, list[float]], ep_idx: int) -> dict:
"""Note: When using data workers (e.g. DataLoader with num_workers>0), do not call this function
in the main process (e.g. by using a second Dataloader with num_workers=0). It will result in a
Segmentation Fault. This probably happens because a memory reference to the video loader is created in
the main process and a subprocess fails to access it.
"""
item = {}
for video_key, query_ts in query_timestamps.items():
root = self.meta.url_root if self.streaming and not self.streaming_from_local else self.root
video_path = f"{root}/{self.meta.get_video_file_path(ep_idx, video_key)}"
frames = decode_video_frames_torchcodec(
video_path, query_ts, self.tolerance_s, decoder_cache=self.video_decoder_cache
)
item[video_key] = frames.squeeze(0) if len(query_ts) == 1 else frames
return item
def _get_delta_frames(self, dataset_iterator: Backtrackable, current_item: dict):
# TODO(fracapuano): Modularize this function, refactor the code
"""Get frames with delta offsets using the backtrackable iterator.
Args:
current_item (dict): Current item from the iterator.
ep_idx (int): Episode index.
Returns:
tuple: (query_result, padding) - frames at delta offsets and padding info.
"""
current_episode_idx = current_item["episode_index"]
# Prepare results
query_result = {}
padding = {}
for key, delta_indices in self.delta_indices.items():
if key in self.meta.video_keys:
continue # visual frames are decoded separately
target_frames = []
is_pad = []
# Create a results dictionary to store frames in processing order, then reconstruct original order for stacking
delta_results = {}
# Separate and sort deltas by difficulty (easier operations first)
negative_deltas = sorted([d for d in delta_indices if d < 0], reverse=True) # [-1, -2, -3, ...]
positive_deltas = sorted([d for d in delta_indices if d > 0]) # [1, 2, 3, ...]
zero_deltas = [d for d in delta_indices if d == 0]
# Process zero deltas (current frame)
for delta in zero_deltas:
delta_results[delta] = (
current_item[key],
False,
)
# Process negative deltas in order of increasing difficulty
lookback_failed = False
last_successful_frame = current_item[key]
for delta in negative_deltas:
if lookback_failed:
delta_results[delta] = (last_successful_frame, True)
continue
try:
steps_back = abs(delta)
if dataset_iterator.can_peek_back(steps_back):
past_item = dataset_iterator.peek_back(steps_back)
past_item = item_to_torch(past_item)
if past_item["episode_index"] == current_episode_idx:
delta_results[delta] = (past_item[key], False)
last_successful_frame = past_item[key]
else:
raise LookBackError("Retrieved frame is from different episode!")
else:
raise LookBackError("Cannot go back further than the history buffer!")
except LookBackError:
delta_results[delta] = (last_successful_frame, True)
lookback_failed = True # All subsequent negative deltas will also fail
# Process positive deltas in order of increasing difficulty
lookahead_failed = False
last_successful_frame = current_item[key]
for delta in positive_deltas:
if lookahead_failed:
delta_results[delta] = (last_successful_frame, True)
continue
try:
if dataset_iterator.can_peek_ahead(delta):
future_item = dataset_iterator.peek_ahead(delta)
future_item = item_to_torch(future_item)
if future_item["episode_index"] == current_episode_idx:
delta_results[delta] = (future_item[key], False)
last_successful_frame = future_item[key]
else:
raise LookAheadError("Retrieved frame is from different episode!")
else:
raise LookAheadError("Cannot go ahead further than the lookahead buffer!")
except LookAheadError:
delta_results[delta] = (last_successful_frame, True)
lookahead_failed = True # All subsequent positive deltas will also fail
# Reconstruct original order for stacking
for delta in delta_indices:
frame, is_padded = delta_results[delta]
# add batch dimension for stacking
target_frames.append(frame) # frame.unsqueeze(0))
is_pad.append(is_padded)
# Stack frames and add to results
if target_frames:
query_result[key] = torch.stack(target_frames)
padding[f"{key}_is_pad"] = torch.BoolTensor(is_pad)
return query_result, padding
def _validate_delta_timestamp_keys(self, delta_timestamps: dict[list[float]]) -> None:
"""
Validate that all keys in delta_timestamps correspond to actual features in the dataset.
Raises:
ValueError: If any delta timestamp key doesn't correspond to a dataset feature.
"""
if delta_timestamps is None:
return
# Get all available feature keys from the dataset metadata
available_features = set(self.meta.features.keys())
# Get all keys from delta_timestamps
delta_keys = set(delta_timestamps.keys())
# Find any keys that don't correspond to features
invalid_keys = delta_keys - available_features
if invalid_keys:
raise ValueError(
f"The following delta_timestamp keys do not correspond to dataset features: {invalid_keys}. "
f"Available features are: {sorted(available_features)}"
)
src/lerobot/datasets/transforms.py
+1 -1
View File
@@ -120,7 +120,7 @@ class SharpnessJitter(Transform):
self.sharpness = self._check_input(sharpness)
def _check_input(self, sharpness):
if isinstance(sharpness, (int | float)):
if isinstance(sharpness, (int, float)):
if sharpness < 0:
raise ValueError("If sharpness is a single number, it must be non negative.")
sharpness = [1.0 - sharpness, 1.0 + sharpness]
src/lerobot/datasets/utils.py
+285 -798
View File
File diff suppressed because it is too large Load Diff
src/lerobot/datasets/v2/batch_convert_dataset_v1_to_v2.py
+884
View File
@@ -0,0 +1,884 @@
#!/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.
"""
This script is for internal use to convert all datasets under the 'lerobot' hub user account to v2.
Note: Since the original Aloha datasets don't use shadow motors, you need to comment those out in
lerobot/configs/robot/aloha.yaml before running this script.
"""
import traceback
from pathlib import Path
from textwrap import dedent
from lerobot import available_datasets
from lerobot.datasets.v2.convert_dataset_v1_to_v2 import convert_dataset
from lerobot.robots.aloha.configuration_aloha import AlohaRobotConfig
LOCAL_DIR = Path("data/")
# spellchecker:off
ALOHA_MOBILE_INFO = {
"robot_config": AlohaRobotConfig(),
"license": "mit",
"url": "https://mobile-aloha.github.io/",
"paper": "https://huggingface.co/papers/2401.02117",
"citation_bibtex": dedent(r"""
@inproceedings{fu2024mobile,
author = {Fu, Zipeng and Zhao, Tony Z. and Finn, Chelsea},
title = {Mobile ALOHA: Learning Bimanual Mobile Manipulation with Low-Cost Whole-Body Teleoperation},
booktitle = {arXiv},
year = {2024},
}""").lstrip(),
}
ALOHA_STATIC_INFO = {
"robot_config": AlohaRobotConfig(),
"license": "mit",
"url": "https://tonyzhaozh.github.io/aloha/",
"paper": "https://huggingface.co/papers/2304.13705",
"citation_bibtex": dedent(r"""
@article{Zhao2023LearningFB,
title={Learning Fine-Grained Bimanual Manipulation with Low-Cost Hardware},
author={Tony Zhao and Vikash Kumar and Sergey Levine and Chelsea Finn},
journal={RSS},
year={2023},
volume={abs/2304.13705},
url={https://huggingface.co/papers/2304.13705}
}""").lstrip(),
}
PUSHT_INFO = {
"license": "mit",
"url": "https://diffusion-policy.cs.columbia.edu/",
"paper": "https://huggingface.co/papers/2303.04137",
"citation_bibtex": dedent(r"""
@article{chi2024diffusionpolicy,
author = {Cheng Chi and Zhenjia Xu and Siyuan Feng and Eric Cousineau and Yilun Du and Benjamin Burchfiel and Russ Tedrake and Shuran Song},
title ={Diffusion Policy: Visuomotor Policy Learning via Action Diffusion},
journal = {The International Journal of Robotics Research},
year = {2024},
}""").lstrip(),
}
XARM_INFO = {
"license": "mit",
"url": "https://www.nicklashansen.com/td-mpc/",
"paper": "https://huggingface.co/papers/2203.04955",
"citation_bibtex": dedent(r"""
@inproceedings{Hansen2022tdmpc,
title={Temporal Difference Learning for Model Predictive Control},
author={Nicklas Hansen and Xiaolong Wang and Hao Su},
booktitle={ICML},
year={2022}
}
"""),
}
UNITREEH_INFO = {
"license": "apache-2.0",
}
DATASETS = {
"aloha_mobile_cabinet": {
"single_task": "Open the top cabinet, store the pot inside it then close the cabinet.",
**ALOHA_MOBILE_INFO,
},
"aloha_mobile_chair": {
"single_task": "Push the chairs in front of the desk to place them against it.",
**ALOHA_MOBILE_INFO,
},
"aloha_mobile_elevator": {
"single_task": "Take the elevator to the 1st floor.",
**ALOHA_MOBILE_INFO,
},
"aloha_mobile_shrimp": {
"single_task": "Sauté the raw shrimp on both sides, then serve it in the bowl.",
**ALOHA_MOBILE_INFO,
},
"aloha_mobile_wash_pan": {
"single_task": "Pick up the pan, rinse it in the sink and then place it in the drying rack.",
**ALOHA_MOBILE_INFO,
},
"aloha_mobile_wipe_wine": {
"single_task": "Pick up the wet cloth on the faucet and use it to clean the spilled wine on the table and underneath the glass.",
**ALOHA_MOBILE_INFO,
},
"aloha_static_battery": {
"single_task": "Place the battery into the slot of the remote controller.",
**ALOHA_STATIC_INFO,
},
"aloha_static_candy": {"single_task": "Pick up the candy and unwrap it.", **ALOHA_STATIC_INFO},
"aloha_static_coffee": {
"single_task": "Place the coffee capsule inside the capsule container, then place the cup onto the center of the cup tray, then push the 'Hot Water' and 'Travel Mug' buttons.",
**ALOHA_STATIC_INFO,
},
"aloha_static_coffee_new": {
"single_task": "Place the coffee capsule inside the capsule container, then place the cup onto the center of the cup tray.",
**ALOHA_STATIC_INFO,
},
"aloha_static_cups_open": {
"single_task": "Pick up the plastic cup and open its lid.",
**ALOHA_STATIC_INFO,
},
"aloha_static_fork_pick_up": {
"single_task": "Pick up the fork and place it on the plate.",
**ALOHA_STATIC_INFO,
},
"aloha_static_pingpong_test": {
"single_task": "Transfer one of the two balls in the right glass into the left glass, then transfer it back to the right glass.",
**ALOHA_STATIC_INFO,
},
"aloha_static_pro_pencil": {
"single_task": "Pick up the pencil with the right arm, hand it over to the left arm then place it back onto the table.",
**ALOHA_STATIC_INFO,
},
"aloha_static_screw_driver": {
"single_task": "Pick up the screwdriver with the right arm, hand it over to the left arm then place it into the cup.",
**ALOHA_STATIC_INFO,
},
"aloha_static_tape": {
"single_task": "Cut a small piece of tape from the tape dispenser then place it on the cardboard box's edge.",
**ALOHA_STATIC_INFO,
},
"aloha_static_thread_velcro": {
"single_task": "Pick up the velcro cable tie with the left arm, then insert the end of the velcro tie into the other end's loop with the right arm.",
**ALOHA_STATIC_INFO,
},
"aloha_static_towel": {
"single_task": "Pick up a piece of paper towel and place it on the spilled liquid.",
**ALOHA_STATIC_INFO,
},
"aloha_static_vinh_cup": {
"single_task": "Pick up the plastic cup with the right arm, then pop its lid open with the left arm.",
**ALOHA_STATIC_INFO,
},
"aloha_static_vinh_cup_left": {
"single_task": "Pick up the plastic cup with the left arm, then pop its lid open with the right arm.",
**ALOHA_STATIC_INFO,
},
"aloha_static_ziploc_slide": {"single_task": "Slide open the ziploc bag.", **ALOHA_STATIC_INFO},
"aloha_sim_insertion_scripted": {"single_task": "Insert the peg into the socket.", **ALOHA_STATIC_INFO},
"aloha_sim_insertion_scripted_image": {
"single_task": "Insert the peg into the socket.",
**ALOHA_STATIC_INFO,
},
"aloha_sim_insertion_human": {"single_task": "Insert the peg into the socket.", **ALOHA_STATIC_INFO},
"aloha_sim_insertion_human_image": {
"single_task": "Insert the peg into the socket.",
**ALOHA_STATIC_INFO,
},
"aloha_sim_transfer_cube_scripted": {
"single_task": "Pick up the cube with the right arm and transfer it to the left arm.",
**ALOHA_STATIC_INFO,
},
"aloha_sim_transfer_cube_scripted_image": {
"single_task": "Pick up the cube with the right arm and transfer it to the left arm.",
**ALOHA_STATIC_INFO,
},
"aloha_sim_transfer_cube_human": {
"single_task": "Pick up the cube with the right arm and transfer it to the left arm.",
**ALOHA_STATIC_INFO,
},
"aloha_sim_transfer_cube_human_image": {
"single_task": "Pick up the cube with the right arm and transfer it to the left arm.",
**ALOHA_STATIC_INFO,
},
"pusht": {"single_task": "Push the T-shaped block onto the T-shaped target.", **PUSHT_INFO},
"pusht_image": {"single_task": "Push the T-shaped block onto the T-shaped target.", **PUSHT_INFO},
"unitreeh1_fold_clothes": {"single_task": "Fold the sweatshirt.", **UNITREEH_INFO},
"unitreeh1_rearrange_objects": {"single_task": "Put the object into the bin.", **UNITREEH_INFO},
"unitreeh1_two_robot_greeting": {
"single_task": "Greet the other robot with a high five.",
**UNITREEH_INFO,
},
"unitreeh1_warehouse": {
"single_task": "Grab the spray paint on the shelf and place it in the bin on top of the robot dog.",
**UNITREEH_INFO,
},
"xarm_lift_medium": {"single_task": "Pick up the cube and lift it.", **XARM_INFO},
"xarm_lift_medium_image": {"single_task": "Pick up the cube and lift it.", **XARM_INFO},
"xarm_lift_medium_replay": {"single_task": "Pick up the cube and lift it.", **XARM_INFO},
"xarm_lift_medium_replay_image": {"single_task": "Pick up the cube and lift it.", **XARM_INFO},
"xarm_push_medium": {"single_task": "Push the cube onto the target.", **XARM_INFO},
"xarm_push_medium_image": {"single_task": "Push the cube onto the target.", **XARM_INFO},
"xarm_push_medium_replay": {"single_task": "Push the cube onto the target.", **XARM_INFO},
"xarm_push_medium_replay_image": {"single_task": "Push the cube onto the target.", **XARM_INFO},
"umi_cup_in_the_wild": {
"single_task": "Put the cup on the plate.",
"license": "apache-2.0",
},
"asu_table_top": {
"tasks_col": "language_instruction",
"license": "mit",
"paper": "https://link.springer.com/article/10.1007/s10514-023-10129-1",
"citation_bibtex": dedent(r"""
@inproceedings{zhou2023modularity,
title={Modularity through Attention: Efficient Training and Transfer of Language-Conditioned Policies for Robot Manipulation},
author={Zhou, Yifan and Sonawani, Shubham and Phielipp, Mariano and Stepputtis, Simon and Amor, Heni},
booktitle={Conference on Robot Learning},
pages={1684--1695},
year={2023},
organization={PMLR}
}
@article{zhou2023learning,
title={Learning modular language-conditioned robot policies through attention},
author={Zhou, Yifan and Sonawani, Shubham and Phielipp, Mariano and Ben Amor, Heni and Stepputtis, Simon},
journal={Autonomous Robots},
pages={1--21},
year={2023},
publisher={Springer}
}""").lstrip(),
},
"austin_buds_dataset": {
"tasks_col": "language_instruction",
"license": "mit",
"url": "https://ut-austin-rpl.github.io/BUDS-website/",
"paper": "https://huggingface.co/papers/2109.13841",
"citation_bibtex": dedent(r"""
@article{zhu2022bottom,
title={Bottom-Up Skill Discovery From Unsegmented Demonstrations for Long-Horizon Robot Manipulation},
author={Zhu, Yifeng and Stone, Peter and Zhu, Yuke},
journal={IEEE Robotics and Automation Letters},
volume={7},
number={2},
pages={4126--4133},
year={2022},
publisher={IEEE}
}""").lstrip(),
},
"austin_sailor_dataset": {
"tasks_col": "language_instruction",
"license": "mit",
"url": "https://ut-austin-rpl.github.io/sailor/",
"paper": "https://huggingface.co/papers/2210.11435",
"citation_bibtex": dedent(r"""
@inproceedings{nasiriany2022sailor,
title={Learning and Retrieval from Prior Data for Skill-based Imitation Learning},
author={Soroush Nasiriany and Tian Gao and Ajay Mandlekar and Yuke Zhu},
booktitle={Conference on Robot Learning (CoRL)},
year={2022}
}""").lstrip(),
},
"austin_sirius_dataset": {
"tasks_col": "language_instruction",
"license": "mit",
"url": "https://ut-austin-rpl.github.io/sirius/",
"paper": "https://huggingface.co/papers/2211.08416",
"citation_bibtex": dedent(r"""
@inproceedings{liu2022robot,
title = {Robot Learning on the Job: Human-in-the-Loop Autonomy and Learning During Deployment},
author = {Huihan Liu and Soroush Nasiriany and Lance Zhang and Zhiyao Bao and Yuke Zhu},
booktitle = {Robotics: Science and Systems (RSS)},
year = {2023}
}""").lstrip(),
},
"berkeley_autolab_ur5": {
"tasks_col": "language_instruction",
"license": "cc-by-4.0",
"url": "https://sites.google.com/view/berkeley-ur5/home",
"citation_bibtex": dedent(r"""
@misc{BerkeleyUR5Website,
title = {Berkeley {UR5} Demonstration Dataset},
author = {Lawrence Yunliang Chen and Simeon Adebola and Ken Goldberg},
howpublished = {https://sites.google.com/view/berkeley-ur5/home},
}""").lstrip(),
},
"berkeley_cable_routing": {
"tasks_col": "language_instruction",
"license": "cc-by-4.0",
"url": "https://sites.google.com/view/cablerouting/home",
"paper": "https://huggingface.co/papers/2307.08927",
"citation_bibtex": dedent(r"""
@article{luo2023multistage,
author = {Jianlan Luo and Charles Xu and Xinyang Geng and Gilbert Feng and Kuan Fang and Liam Tan and Stefan Schaal and Sergey Levine},
title = {Multi-Stage Cable Routing through Hierarchical Imitation Learning},
journal = {arXiv pre-print},
year = {2023},
url = {https://huggingface.co/papers/2307.08927},
}""").lstrip(),
},
"berkeley_fanuc_manipulation": {
"tasks_col": "language_instruction",
"license": "mit",
"url": "https://sites.google.com/berkeley.edu/fanuc-manipulation",
"citation_bibtex": dedent(r"""
@article{fanuc_manipulation2023,
title={Fanuc Manipulation: A Dataset for Learning-based Manipulation with FANUC Mate 200iD Robot},
author={Zhu, Xinghao and Tian, Ran and Xu, Chenfeng and Ding, Mingyu and Zhan, Wei and Tomizuka, Masayoshi},
year={2023},
}""").lstrip(),
},
"berkeley_gnm_cory_hall": {
"tasks_col": "language_instruction",
"license": "mit",
"paper": "https://huggingface.co/papers/1709.10489",
"citation_bibtex": dedent(r"""
@inproceedings{kahn2018self,
title={Self-supervised deep reinforcement learning with generalized computation graphs for robot navigation},
author={Kahn, Gregory and Villaflor, Adam and Ding, Bosen and Abbeel, Pieter and Levine, Sergey},
booktitle={2018 IEEE international conference on robotics and automation (ICRA)},
pages={5129--5136},
year={2018},
organization={IEEE}
}""").lstrip(),
},
"berkeley_gnm_recon": {
"tasks_col": "language_instruction",
"license": "mit",
"url": "https://sites.google.com/view/recon-robot",
"paper": "https://huggingface.co/papers/2104.05859",
"citation_bibtex": dedent(r"""
@inproceedings{shah2021rapid,
title={Rapid Exploration for Open-World Navigation with Latent Goal Models},
author={Dhruv Shah and Benjamin Eysenbach and Nicholas Rhinehart and Sergey Levine},
booktitle={5th Annual Conference on Robot Learning },
year={2021},
url={https://openreview.net/forum?id=d_SWJhyKfVw}
}""").lstrip(),
},
"berkeley_gnm_sac_son": {
"tasks_col": "language_instruction",
"license": "mit",
"url": "https://sites.google.com/view/SACSoN-review",
"paper": "https://huggingface.co/papers/2306.01874",
"citation_bibtex": dedent(r"""
@article{hirose2023sacson,
title={SACSoN: Scalable Autonomous Data Collection for Social Navigation},
author={Hirose, Noriaki and Shah, Dhruv and Sridhar, Ajay and Levine, Sergey},
journal={arXiv preprint arXiv:2306.01874},
year={2023}
}""").lstrip(),
},
"berkeley_mvp": {
"tasks_col": "language_instruction",
"license": "mit",
"paper": "https://huggingface.co/papers/2203.06173",
"citation_bibtex": dedent(r"""
@InProceedings{Radosavovic2022,
title = {Real-World Robot Learning with Masked Visual Pre-training},
author = {Ilija Radosavovic and Tete Xiao and Stephen James and Pieter Abbeel and Jitendra Malik and Trevor Darrell},
booktitle = {CoRL},
year = {2022}
}""").lstrip(),
},
"berkeley_rpt": {
"tasks_col": "language_instruction",
"license": "mit",
"paper": "https://huggingface.co/papers/2306.10007",
"citation_bibtex": dedent(r"""
@article{Radosavovic2023,
title={Robot Learning with Sensorimotor Pre-training},
author={Ilija Radosavovic and Baifeng Shi and Letian Fu and Ken Goldberg and Trevor Darrell and Jitendra Malik},
year={2023},
journal={arXiv:2306.10007}
}""").lstrip(),
},
"cmu_franka_exploration_dataset": {
"tasks_col": "language_instruction",
"license": "mit",
"url": "https://human-world-model.github.io/",
"paper": "https://huggingface.co/papers/2308.10901",
"citation_bibtex": dedent(r"""
@inproceedings{mendonca2023structured,
title={Structured World Models from Human Videos},
author={Mendonca, Russell and Bahl, Shikhar and Pathak, Deepak},
journal={RSS},
year={2023}
}""").lstrip(),
},
"cmu_play_fusion": {
"tasks_col": "language_instruction",
"license": "mit",
"url": "https://play-fusion.github.io/",
"paper": "https://huggingface.co/papers/2312.04549",
"citation_bibtex": dedent(r"""
@inproceedings{chen2023playfusion,
title={PlayFusion: Skill Acquisition via Diffusion from Language-Annotated Play},
author={Chen, Lili and Bahl, Shikhar and Pathak, Deepak},
booktitle={CoRL},
year={2023}
}""").lstrip(),
},
"cmu_stretch": {
"tasks_col": "language_instruction",
"license": "mit",
"url": "https://robo-affordances.github.io/",
"paper": "https://huggingface.co/papers/2304.08488",
"citation_bibtex": dedent(r"""
@inproceedings{bahl2023affordances,
title={Affordances from Human Videos as a Versatile Representation for Robotics},
author={Bahl, Shikhar and Mendonca, Russell and Chen, Lili and Jain, Unnat and Pathak, Deepak},
booktitle={CVPR},
year={2023}
}
@article{mendonca2023structured,
title={Structured World Models from Human Videos},
author={Mendonca, Russell and Bahl, Shikhar and Pathak, Deepak},
journal={CoRL},
year={2023}
}""").lstrip(),
},
"columbia_cairlab_pusht_real": {
"tasks_col": "language_instruction",
"license": "mit",
"url": "https://diffusion-policy.cs.columbia.edu/",
"paper": "https://huggingface.co/papers/2303.04137",
"citation_bibtex": dedent(r"""
@inproceedings{chi2023diffusionpolicy,
title={Diffusion Policy: Visuomotor Policy Learning via Action Diffusion},
author={Chi, Cheng and Feng, Siyuan and Du, Yilun and Xu, Zhenjia and Cousineau, Eric and Burchfiel, Benjamin and Song, Shuran},
booktitle={Proceedings of Robotics: Science and Systems (RSS)},
year={2023}
}""").lstrip(),
},
"conq_hose_manipulation": {
"tasks_col": "language_instruction",
"license": "mit",
"url": "https://sites.google.com/view/conq-hose-manipulation-dataset/home",
"citation_bibtex": dedent(r"""
@misc{ConqHoseManipData,
author={Peter Mitrano and Dmitry Berenson},
title={Conq Hose Manipulation Dataset, v1.15.0},
year={2024},
howpublished={https://sites.google.com/view/conq-hose-manipulation-dataset}
}""").lstrip(),
},
"dlr_edan_shared_control": {
"tasks_col": "language_instruction",
"license": "mit",
"paper": "https://ieeexplore.ieee.org/document/9341156",
"citation_bibtex": dedent(r"""
@inproceedings{vogel_edan_2020,
title = {EDAN - an EMG-Controlled Daily Assistant to Help People with Physical Disabilities},
language = {en},
booktitle = {2020 {IEEE}/{RSJ} {International} {Conference} on {Intelligent} {Robots} and {Systems} ({IROS})},
author = {Vogel, Jörn and Hagengruber, Annette and Iskandar, Maged and Quere, Gabriel and Leipscher, Ulrike and Bustamante, Samuel and Dietrich, Alexander and Hoeppner, Hannes and Leidner, Daniel and Albu-Schäffer, Alin},
year = {2020}
}
@inproceedings{quere_shared_2020,
address = {Paris, France},
title = {Shared {Control} {Templates} for {Assistive} {Robotics}},
language = {en},
booktitle = {2020 {IEEE} {International} {Conference} on {Robotics} and {Automation} ({ICRA})},
author = {Quere, Gabriel and Hagengruber, Annette and Iskandar, Maged and Bustamante, Samuel and Leidner, Daniel and Stulp, Freek and Vogel, Joern},
year = {2020},
pages = {7},
}""").lstrip(),
},
"dlr_sara_grid_clamp": {
"tasks_col": "language_instruction",
"license": "mit",
"paper": "https://www.researchsquare.com/article/rs-3289569/v1",
"citation_bibtex": dedent(r"""
@article{padalkar2023guided,
title={A guided reinforcement learning approach using shared control templates for learning manipulation skills in the real world},
author={Padalkar, Abhishek and Quere, Gabriel and Raffin, Antonin and Silv{\'e}rio, Jo{\~a}o and Stulp, Freek},
journal={Research square preprint rs-3289569/v1},
year={2023}
}""").lstrip(),
},
"dlr_sara_pour": {
"tasks_col": "language_instruction",
"license": "mit",
"paper": "https://elib.dlr.de/193739/1/padalkar2023rlsct.pdf",
"citation_bibtex": dedent(r"""
@inproceedings{padalkar2023guiding,
title={Guiding Reinforcement Learning with Shared Control Templates},
author={Padalkar, Abhishek and Quere, Gabriel and Steinmetz, Franz and Raffin, Antonin and Nieuwenhuisen, Matthias and Silv{\'e}rio, Jo{\~a}o and Stulp, Freek},
booktitle={40th IEEE International Conference on Robotics and Automation, ICRA 2023},
year={2023},
organization={IEEE}
}""").lstrip(),
},
"droid_100": {
"tasks_col": "language_instruction",
"license": "mit",
"url": "https://droid-dataset.github.io/",
"paper": "https://huggingface.co/papers/2403.12945",
"citation_bibtex": dedent(r"""
@article{khazatsky2024droid,
title = {DROID: A Large-Scale In-The-Wild Robot Manipulation Dataset},
author = {Alexander Khazatsky and Karl Pertsch and Suraj Nair and Ashwin Balakrishna and Sudeep Dasari and Siddharth Karamcheti and Soroush Nasiriany and Mohan Kumar Srirama and Lawrence Yunliang Chen and Kirsty Ellis and Peter David Fagan and Joey Hejna and Masha Itkina and Marion Lepert and Yecheng Jason Ma and Patrick Tree Miller and Jimmy Wu and Suneel Belkhale and Shivin Dass and Huy Ha and Arhan Jain and Abraham Lee and Youngwoon Lee and Marius Memmel and Sungjae Park and Ilija Radosavovic and Kaiyuan Wang and Albert Zhan and Kevin Black and Cheng Chi and Kyle Beltran Hatch and Shan Lin and Jingpei Lu and Jean Mercat and Abdul Rehman and Pannag R Sanketi and Archit Sharma and Cody Simpson and Quan Vuong and Homer Rich Walke and Blake Wulfe and Ted Xiao and Jonathan Heewon Yang and Arefeh Yavary and Tony Z. Zhao and Christopher Agia and Rohan Baijal and Mateo Guaman Castro and Daphne Chen and Qiuyu Chen and Trinity Chung and Jaimyn Drake and Ethan Paul Foster and Jensen Gao and David Antonio Herrera and Minho Heo and Kyle Hsu and Jiaheng Hu and Donovon Jackson and Charlotte Le and Yunshuang Li and Kevin Lin and Roy Lin and Zehan Ma and Abhiram Maddukuri and Suvir Mirchandani and Daniel Morton and Tony Nguyen and Abigail O'Neill and Rosario Scalise and Derick Seale and Victor Son and Stephen Tian and Emi Tran and Andrew E. Wang and Yilin Wu and Annie Xie and Jingyun Yang and Patrick Yin and Yunchu Zhang and Osbert Bastani and Glen Berseth and Jeannette Bohg and Ken Goldberg and Abhinav Gupta and Abhishek Gupta and Dinesh Jayaraman and Joseph J Lim and Jitendra Malik and Roberto Martín-Martín and Subramanian Ramamoorthy and Dorsa Sadigh and Shuran Song and Jiajun Wu and Michael C. Yip and Yuke Zhu and Thomas Kollar and Sergey Levine and Chelsea Finn},
year = {2024},
}""").lstrip(),
},
"fmb": {
"tasks_col": "language_instruction",
"license": "cc-by-4.0",
"url": "https://functional-manipulation-benchmark.github.io/",
"paper": "https://huggingface.co/papers/2401.08553",
"citation_bibtex": dedent(r"""
@article{luo2024fmb,
title={FMB: a Functional Manipulation Benchmark for Generalizable Robotic Learning},
author={Luo, Jianlan and Xu, Charles and Liu, Fangchen and Tan, Liam and Lin, Zipeng and Wu, Jeffrey and Abbeel, Pieter and Levine, Sergey},
journal={arXiv preprint arXiv:2401.08553},
year={2024}
}""").lstrip(),
},
"iamlab_cmu_pickup_insert": {
"tasks_col": "language_instruction",
"license": "mit",
"url": "https://openreview.net/forum?id=WuBv9-IGDUA",
"paper": "https://huggingface.co/papers/2401.14502",
"citation_bibtex": dedent(r"""
@inproceedings{saxena2023multiresolution,
title={Multi-Resolution Sensing for Real-Time Control with Vision-Language Models},
author={Saumya Saxena and Mohit Sharma and Oliver Kroemer},
booktitle={7th Annual Conference on Robot Learning},
year={2023},
url={https://openreview.net/forum?id=WuBv9-IGDUA}
}""").lstrip(),
},
"imperialcollege_sawyer_wrist_cam": {
"tasks_col": "language_instruction",
"license": "mit",
},
"jaco_play": {
"tasks_col": "language_instruction",
"license": "cc-by-4.0",
"url": "https://github.com/clvrai/clvr_jaco_play_dataset",
"citation_bibtex": dedent(r"""
@software{dass2023jacoplay,
author = {Dass, Shivin and Yapeter, Jullian and Zhang, Jesse and Zhang, Jiahui
and Pertsch, Karl and Nikolaidis, Stefanos and Lim, Joseph J.},
title = {CLVR Jaco Play Dataset},
url = {https://github.com/clvrai/clvr_jaco_play_dataset},
version = {1.0.0},
year = {2023}
}""").lstrip(),
},
"kaist_nonprehensile": {
"tasks_col": "language_instruction",
"license": "cc-by-4.0",
"url": "https://github.com/JaeHyung-Kim/rlds_dataset_builder",
"citation_bibtex": dedent(r"""
@article{kimpre,
title={Pre-and post-contact policy decomposition for non-prehensile manipulation with zero-shot sim-to-real transfer},
author={Kim, Minchan and Han, Junhyek and Kim, Jaehyung and Kim, Beomjoon},
booktitle={2023 IEEE/RSJ International Conference on Intelligent Robots and Systems (IROS)},
year={2023},
organization={IEEE}
}""").lstrip(),
},
"nyu_door_opening_surprising_effectiveness": {
"tasks_col": "language_instruction",
"license": "mit",
"url": "https://jyopari.github.io/VINN/",
"paper": "https://huggingface.co/papers/2112.01511",
"citation_bibtex": dedent(r"""
@misc{pari2021surprising,
title={The Surprising Effectiveness of Representation Learning for Visual Imitation},
author={Jyothish Pari and Nur Muhammad Shafiullah and Sridhar Pandian Arunachalam and Lerrel Pinto},
year={2021},
eprint={2112.01511},
archivePrefix={arXiv},
primaryClass={cs.RO}
}""").lstrip(),
},
"nyu_franka_play_dataset": {
"tasks_col": "language_instruction",
"license": "mit",
"url": "https://play-to-policy.github.io/",
"paper": "https://huggingface.co/papers/2210.10047",
"citation_bibtex": dedent(r"""
@article{cui2022play,
title = {From Play to Policy: Conditional Behavior Generation from Uncurated Robot Data},
author = {Cui, Zichen Jeff and Wang, Yibin and Shafiullah, Nur Muhammad Mahi and Pinto, Lerrel},
journal = {arXiv preprint arXiv:2210.10047},
year = {2022}
}""").lstrip(),
},
"nyu_rot_dataset": {
"tasks_col": "language_instruction",
"license": "mit",
"url": "https://rot-robot.github.io/",
"paper": "https://huggingface.co/papers/2206.15469",
"citation_bibtex": dedent(r"""
@inproceedings{haldar2023watch,
title={Watch and match: Supercharging imitation with regularized optimal transport},
author={Haldar, Siddhant and Mathur, Vaibhav and Yarats, Denis and Pinto, Lerrel},
booktitle={Conference on Robot Learning},
pages={32--43},
year={2023},
organization={PMLR}
}""").lstrip(),
},
"roboturk": {
"tasks_col": "language_instruction",
"license": "mit",
"url": "https://roboturk.stanford.edu/dataset_real.html",
"paper": "PAPER",
"citation_bibtex": dedent(r"""
@inproceedings{mandlekar2019scaling,
title={Scaling robot supervision to hundreds of hours with roboturk: Robotic manipulation dataset through human reasoning and dexterity},
author={Mandlekar, Ajay and Booher, Jonathan and Spero, Max and Tung, Albert and Gupta, Anchit and Zhu, Yuke and Garg, Animesh and Savarese, Silvio and Fei-Fei, Li},
booktitle={2019 IEEE/RSJ International Conference on Intelligent Robots and Systems (IROS)},
pages={1048--1055},
year={2019},
organization={IEEE}
}""").lstrip(),
},
"stanford_hydra_dataset": {
"tasks_col": "language_instruction",
"license": "mit",
"url": "https://sites.google.com/view/hydra-il-2023",
"paper": "https://huggingface.co/papers/2306.17237",
"citation_bibtex": dedent(r"""
@article{belkhale2023hydra,
title={HYDRA: Hybrid Robot Actions for Imitation Learning},
author={Belkhale, Suneel and Cui, Yuchen and Sadigh, Dorsa},
journal={arxiv},
year={2023}
}""").lstrip(),
},
"stanford_kuka_multimodal_dataset": {
"tasks_col": "language_instruction",
"license": "mit",
"url": "https://sites.google.com/view/visionandtouch",
"paper": "https://huggingface.co/papers/1810.10191",
"citation_bibtex": dedent(r"""
@inproceedings{lee2019icra,
title={Making sense of vision and touch: Self-supervised learning of multimodal representations for contact-rich tasks},
author={Lee, Michelle A and Zhu, Yuke and Srinivasan, Krishnan and Shah, Parth and Savarese, Silvio and Fei-Fei, Li and Garg, Animesh and Bohg, Jeannette},
booktitle={2019 IEEE International Conference on Robotics and Automation (ICRA)},
year={2019},
url={https://huggingface.co/papers/1810.10191}
}""").lstrip(),
},
"stanford_robocook": {
"tasks_col": "language_instruction",
"license": "mit",
"url": "https://hshi74.github.io/robocook/",
"paper": "https://huggingface.co/papers/2306.14447",
"citation_bibtex": dedent(r"""
@article{shi2023robocook,
title={RoboCook: Long-Horizon Elasto-Plastic Object Manipulation with Diverse Tools},
author={Shi, Haochen and Xu, Huazhe and Clarke, Samuel and Li, Yunzhu and Wu, Jiajun},
journal={arXiv preprint arXiv:2306.14447},
year={2023}
}""").lstrip(),
},
"taco_play": {
"tasks_col": "language_instruction",
"license": "cc-by-4.0",
"url": "https://www.kaggle.com/datasets/oiermees/taco-robot",
"paper": "https://huggingface.co/papers/2209.08959, https://huggingface.co/papers/2210.01911",
"citation_bibtex": dedent(r"""
@inproceedings{rosete2022tacorl,
author = {Erick Rosete-Beas and Oier Mees and Gabriel Kalweit and Joschka Boedecker and Wolfram Burgard},
title = {Latent Plans for Task Agnostic Offline Reinforcement Learning},
journal = {Proceedings of the 6th Conference on Robot Learning (CoRL)},
year = {2022}
}
@inproceedings{mees23hulc2,
title={Grounding Language with Visual Affordances over Unstructured Data},
author={Oier Mees and Jessica Borja-Diaz and Wolfram Burgard},
booktitle = {Proceedings of the IEEE International Conference on Robotics and Automation (ICRA)},
year={2023},
address = {London, UK}
}""").lstrip(),
},
"tokyo_u_lsmo": {
"tasks_col": "language_instruction",
"license": "mit",
"url": "URL",
"paper": "https://huggingface.co/papers/2107.05842",
"citation_bibtex": dedent(r"""
@Article{Osa22,
author = {Takayuki Osa},
journal = {The International Journal of Robotics Research},
title = {Motion Planning by Learning the Solution Manifold in Trajectory Optimization},
year = {2022},
number = {3},
pages = {291--311},
volume = {41},
}""").lstrip(),
},
"toto": {
"tasks_col": "language_instruction",
"license": "mit",
"url": "https://toto-benchmark.org/",
"paper": "https://huggingface.co/papers/2306.00942",
"citation_bibtex": dedent(r"""
@inproceedings{zhou2023train,
author={Zhou, Gaoyue and Dean, Victoria and Srirama, Mohan Kumar and Rajeswaran, Aravind and Pari, Jyothish and Hatch, Kyle and Jain, Aryan and Yu, Tianhe and Abbeel, Pieter and Pinto, Lerrel and Finn, Chelsea and Gupta, Abhinav},
booktitle={2023 IEEE International Conference on Robotics and Automation (ICRA)},
title={Train Offline, Test Online: A Real Robot Learning Benchmark},
year={2023},
}""").lstrip(),
},
"ucsd_kitchen_dataset": {
"tasks_col": "language_instruction",
"license": "mit",
"citation_bibtex": dedent(r"""
@ARTICLE{ucsd_kitchens,
author = {Ge Yan, Kris Wu, and Xiaolong Wang},
title = {{ucsd kitchens Dataset}},
year = {2023},
month = {August}
}""").lstrip(),
},
"ucsd_pick_and_place_dataset": {
"tasks_col": "language_instruction",
"license": "mit",
"url": "https://owmcorl.github.io/#",
"paper": "https://huggingface.co/papers/2310.16029",
"citation_bibtex": dedent(r"""
@preprint{Feng2023Finetuning,
title={Finetuning Offline World Models in the Real World},
author={Yunhai Feng, Nicklas Hansen, Ziyan Xiong, Chandramouli Rajagopalan, Xiaolong Wang},
year={2023}
}""").lstrip(),
},
"uiuc_d3field": {
"tasks_col": "language_instruction",
"license": "mit",
"url": "https://robopil.github.io/d3fields/",
"paper": "https://huggingface.co/papers/2309.16118",
"citation_bibtex": dedent(r"""
@article{wang2023d3field,
title={D^3Field: Dynamic 3D Descriptor Fields for Generalizable Robotic Manipulation},
author={Wang, Yixuan and Li, Zhuoran and Zhang, Mingtong and Driggs-Campbell, Katherine and Wu, Jiajun and Fei-Fei, Li and Li, Yunzhu},
journal={arXiv preprint arXiv:},
year={2023},
}""").lstrip(),
},
"usc_cloth_sim": {
"tasks_col": "language_instruction",
"license": "mit",
"url": "https://uscresl.github.io/dmfd/",
"paper": "https://huggingface.co/papers/2207.10148",
"citation_bibtex": dedent(r"""
@article{salhotra2022dmfd,
author={Salhotra, Gautam and Liu, I-Chun Arthur and Dominguez-Kuhne, Marcus and Sukhatme, Gaurav S.},
journal={IEEE Robotics and Automation Letters},
title={Learning Deformable Object Manipulation From Expert Demonstrations},
year={2022},
volume={7},
number={4},
pages={8775-8782},
doi={10.1109/LRA.2022.3187843}
}""").lstrip(),
},
"utaustin_mutex": {
"tasks_col": "language_instruction",
"license": "mit",
"url": "https://ut-austin-rpl.github.io/MUTEX/",
"paper": "https://huggingface.co/papers/2309.14320",
"citation_bibtex": dedent(r"""
@inproceedings{shah2023mutex,
title={{MUTEX}: Learning Unified Policies from Multimodal Task Specifications},
author={Rutav Shah and Roberto Mart{\'\i}n-Mart{\'\i}n and Yuke Zhu},
booktitle={7th Annual Conference on Robot Learning},
year={2023},
url={https://openreview.net/forum?id=PwqiqaaEzJ}
}""").lstrip(),
},
"utokyo_pr2_opening_fridge": {
"tasks_col": "language_instruction",
"license": "mit",
"citation_bibtex": dedent(r"""
@misc{oh2023pr2utokyodatasets,
author={Jihoon Oh and Naoaki Kanazawa and Kento Kawaharazuka},
title={X-Embodiment U-Tokyo PR2 Datasets},
year={2023},
url={https://github.com/ojh6404/rlds_dataset_builder},
}""").lstrip(),
},
"utokyo_pr2_tabletop_manipulation": {
"tasks_col": "language_instruction",
"license": "mit",
"citation_bibtex": dedent(r"""
@misc{oh2023pr2utokyodatasets,
author={Jihoon Oh and Naoaki Kanazawa and Kento Kawaharazuka},
title={X-Embodiment U-Tokyo PR2 Datasets},
year={2023},
url={https://github.com/ojh6404/rlds_dataset_builder},
}""").lstrip(),
},
"utokyo_saytap": {
"tasks_col": "language_instruction",
"license": "mit",
"url": "https://saytap.github.io/",
"paper": "https://huggingface.co/papers/2306.07580",
"citation_bibtex": dedent(r"""
@article{saytap2023,
author = {Yujin Tang and Wenhao Yu and Jie Tan and Heiga Zen and Aleksandra Faust and
Tatsuya Harada},
title = {SayTap: Language to Quadrupedal Locomotion},
eprint = {arXiv:2306.07580},
url = {https://saytap.github.io},
note = {https://saytap.github.io},
year = {2023}
}""").lstrip(),
},
"utokyo_xarm_bimanual": {
"tasks_col": "language_instruction",
"license": "cc-by-4.0",
"citation_bibtex": dedent(r"""
@misc{matsushima2023weblab,
title={Weblab xArm Dataset},
author={Tatsuya Matsushima and Hiroki Furuta and Yusuke Iwasawa and Yutaka Matsuo},
year={2023},
}""").lstrip(),
},
"utokyo_xarm_pick_and_place": {
"tasks_col": "language_instruction",
"license": "cc-by-4.0",
"citation_bibtex": dedent(r"""
@misc{matsushima2023weblab,
title={Weblab xArm Dataset},
author={Tatsuya Matsushima and Hiroki Furuta and Yusuke Iwasawa and Yutaka Matsuo},
year={2023},
}""").lstrip(),
},
"viola": {
"tasks_col": "language_instruction",
"license": "mit",
"url": "https://ut-austin-rpl.github.io/VIOLA/",
"paper": "https://huggingface.co/papers/2210.11339",
"citation_bibtex": dedent(r"""
@article{zhu2022viola,
title={VIOLA: Imitation Learning for Vision-Based Manipulation with Object Proposal Priors},
author={Zhu, Yifeng and Joshi, Abhishek and Stone, Peter and Zhu, Yuke},
journal={6th Annual Conference on Robot Learning (CoRL)},
year={2022}
}""").lstrip(),
},
}
# spellchecker:on
def batch_convert():
status = {}
logfile = LOCAL_DIR / "conversion_log.txt"
assert set(DATASETS) == {id_.split("/")[1] for id_ in available_datasets}
for num, (name, kwargs) in enumerate(DATASETS.items()):
repo_id = f"lerobot/{name}"
print(f"\nConverting {repo_id} ({num}/{len(DATASETS)})")
print("---------------------------------------------------------")
try:
convert_dataset(repo_id, LOCAL_DIR, **kwargs)
status = f"{repo_id}: success."
with open(logfile, "a") as file:
file.write(status + "\n")
except Exception:
status = f"{repo_id}: failed\n {traceback.format_exc()}"
with open(logfile, "a") as file:
file.write(status + "\n")
continue
if __name__ == "__main__":
batch_convert()
src/lerobot/datasets/v2/convert_dataset_v1_to_v2.py
+687
View File
@@ -0,0 +1,687 @@
#!/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.
"""
This script will help you convert any LeRobot dataset already pushed to the hub from codebase version 1.6 to
2.0. You will be required to provide the 'tasks', which is a short but accurate description in plain English
for each of the task performed in the dataset. This will allow to easily train models with task-conditioning.
We support 3 different scenarios for these tasks (see instructions below):
1. Single task dataset: all episodes of your dataset have the same single task.
2. Single task episodes: the episodes of your dataset each contain a single task but they can differ from
one episode to the next.
3. Multi task episodes: episodes of your dataset may each contain several different tasks.
Can you can also provide a robot config .yaml file (not mandatory) to this script via the option
'--robot-config' so that it writes information about the robot (robot type, motors names) this dataset was
recorded with. For now, only Aloha/Koch type robots are supported with this option.
# 1. Single task dataset
If your dataset contains a single task, you can simply provide it directly via the CLI with the
'--single-task' option.
Examples:
```bash
python -m lerobot.datasets.v2.convert_dataset_v1_to_v2 \
--repo-id lerobot/aloha_sim_insertion_human_image \
--single-task "Insert the peg into the socket." \
--robot-config lerobot/configs/robot/aloha.yaml \
--local-dir data
```
```bash
python -m lerobot.datasets.v2.convert_dataset_v1_to_v2 \
--repo-id aliberts/koch_tutorial \
--single-task "Pick the Lego block and drop it in the box on the right." \
--robot-config lerobot/configs/robot/koch.yaml \
--local-dir data
```
# 2. Single task episodes
If your dataset is a multi-task dataset, you have two options to provide the tasks to this script:
- If your dataset already contains a language instruction column in its parquet file, you can simply provide
this column's name with the '--tasks-col' arg.
Example:
```bash
python -m lerobot.datasets.v2.convert_dataset_v1_to_v2 \
--repo-id lerobot/stanford_kuka_multimodal_dataset \
--tasks-col "language_instruction" \
--local-dir data
```
- If your dataset doesn't contain a language instruction, you should provide the path to a .json file with the
'--tasks-path' arg. This file should have the following structure where keys correspond to each
episode_index in the dataset, and values are the language instruction for that episode.
Example:
```json
{
"0": "Do something",
"1": "Do something else",
"2": "Do something",
"3": "Go there",
...
}
```
# 3. Multi task episodes
If you have multiple tasks per episodes, your dataset should contain a language instruction column in its
parquet file, and you must provide this column's name with the '--tasks-col' arg.
Example:
```bash
python -m lerobot.datasets.v2.convert_dataset_v1_to_v2 \
--repo-id lerobot/stanford_kuka_multimodal_dataset \
--tasks-col "language_instruction" \
--local-dir data
```
"""
import argparse
import contextlib
import filecmp
import json
import logging
import math
import shutil
import subprocess
import tempfile
from pathlib import Path
import datasets
import pyarrow.compute as pc
import pyarrow.parquet as pq
import torch
from datasets import Dataset
from huggingface_hub import HfApi
from huggingface_hub.errors import EntryNotFoundError, HfHubHTTPError
from safetensors.torch import load_file
from lerobot.datasets.utils import (
DEFAULT_CHUNK_SIZE,
DEFAULT_PARQUET_PATH,
DEFAULT_VIDEO_PATH,
EPISODES_PATH,
INFO_PATH,
STATS_PATH,
TASKS_PATH,
create_branch,
create_lerobot_dataset_card,
flatten_dict,
get_safe_version,
load_json,
unflatten_dict,
write_json,
write_jsonlines,
)
from lerobot.datasets.video_utils import (
VideoFrame, # noqa: F401
get_image_pixel_channels,
get_video_info,
)
from lerobot.robots import RobotConfig
V16 = "v1.6"
V20 = "v2.0"
GITATTRIBUTES_REF = "aliberts/gitattributes_reference"
V1_VIDEO_FILE = "{video_key}_episode_{episode_index:06d}.mp4"
V1_INFO_PATH = "meta_data/info.json"
V1_STATS_PATH = "meta_data/stats.safetensors"
def parse_robot_config(robot_cfg: RobotConfig) -> tuple[str, dict]:
if robot_cfg.type in ["aloha", "koch"]:
state_names = [
f"{arm}_{motor}" if len(robot_cfg.follower_arms) > 1 else motor
for arm in robot_cfg.follower_arms
for motor in robot_cfg.follower_arms[arm].motors
]
action_names = [
# f"{arm}_{motor}" for arm in ["left", "right"] for motor in robot_cfg["leader_arms"][arm]["motors"]
f"{arm}_{motor}" if len(robot_cfg.leader_arms) > 1 else motor
for arm in robot_cfg.leader_arms
for motor in robot_cfg.leader_arms[arm].motors
]
# elif robot_cfg["robot_type"] == "stretch3": TODO
else:
raise NotImplementedError(
"Please provide robot_config={'robot_type': ..., 'names': ...} directly to convert_dataset()."
)
return {
"robot_type": robot_cfg.type,
"names": {
"observation.state": state_names,
"observation.effort": state_names,
"action": action_names,
},
}
def convert_stats_to_json(v1_dir: Path, v2_dir: Path) -> None:
safetensor_path = v1_dir / V1_STATS_PATH
stats = load_file(safetensor_path)
serialized_stats = {key: value.tolist() for key, value in stats.items()}
serialized_stats = unflatten_dict(serialized_stats)
json_path = v2_dir / STATS_PATH
json_path.parent.mkdir(exist_ok=True, parents=True)
with open(json_path, "w") as f:
json.dump(serialized_stats, f, indent=4)
# Sanity check
with open(json_path) as f:
stats_json = json.load(f)
stats_json = flatten_dict(stats_json)
stats_json = {key: torch.tensor(value) for key, value in stats_json.items()}
for key in stats:
torch.testing.assert_close(stats_json[key], stats[key])
def get_features_from_hf_dataset(
dataset: Dataset, robot_config: RobotConfig | None = None
) -> dict[str, list]:
robot_config = parse_robot_config(robot_config)
features = {}
for key, ft in dataset.features.items():
if isinstance(ft, datasets.Value):
dtype = ft.dtype
shape = (1,)
names = None
if isinstance(ft, datasets.Sequence):
assert isinstance(ft.feature, datasets.Value)
dtype = ft.feature.dtype
shape = (ft.length,)
motor_names = (
robot_config["names"][key] if robot_config else [f"motor_{i}" for i in range(ft.length)]
)
assert len(motor_names) == shape[0]
names = {"motors": motor_names}
elif isinstance(ft, datasets.Image):
dtype = "image"
image = dataset[0][key] # Assuming first row
channels = get_image_pixel_channels(image)
shape = (image.height, image.width, channels)
names = ["height", "width", "channels"]
elif ft._type == "VideoFrame":
dtype = "video"
shape = None # Add shape later
names = ["height", "width", "channels"]
features[key] = {
"dtype": dtype,
"shape": shape,
"names": names,
}
return features
def add_task_index_by_episodes(dataset: Dataset, tasks_by_episodes: dict) -> tuple[Dataset, list[str]]:
df = dataset.to_pandas()
tasks = list(set(tasks_by_episodes.values()))
tasks_to_task_index = {task: task_idx for task_idx, task in enumerate(tasks)}
episodes_to_task_index = {ep_idx: tasks_to_task_index[task] for ep_idx, task in tasks_by_episodes.items()}
df["task_index"] = df["episode_index"].map(episodes_to_task_index).astype(int)
features = dataset.features
features["task_index"] = datasets.Value(dtype="int64")
dataset = Dataset.from_pandas(df, features=features, split="train")
return dataset, tasks
def add_task_index_from_tasks_col(
dataset: Dataset, tasks_col: str
) -> tuple[Dataset, dict[str, list[str]], list[str]]:
df = dataset.to_pandas()
# HACK: This is to clean some of the instructions in our version of Open X datasets
prefix_to_clean = "tf.Tensor(b'"
suffix_to_clean = "', shape=(), dtype=string)"
df[tasks_col] = df[tasks_col].str.removeprefix(prefix_to_clean).str.removesuffix(suffix_to_clean)
# Create task_index col
tasks_by_episode = df.groupby("episode_index")[tasks_col].unique().apply(lambda x: x.tolist()).to_dict()
tasks = df[tasks_col].unique().tolist()
tasks_to_task_index = {task: idx for idx, task in enumerate(tasks)}
df["task_index"] = df[tasks_col].map(tasks_to_task_index).astype(int)
# Build the dataset back from df
features = dataset.features
features["task_index"] = datasets.Value(dtype="int64")
dataset = Dataset.from_pandas(df, features=features, split="train")
dataset = dataset.remove_columns(tasks_col)
return dataset, tasks, tasks_by_episode
def split_parquet_by_episodes(
dataset: Dataset,
total_episodes: int,
total_chunks: int,
output_dir: Path,
) -> list:
table = dataset.data.table
episode_lengths = []
for ep_chunk in range(total_chunks):
ep_chunk_start = DEFAULT_CHUNK_SIZE * ep_chunk
ep_chunk_end = min(DEFAULT_CHUNK_SIZE * (ep_chunk + 1), total_episodes)
chunk_dir = "/".join(DEFAULT_PARQUET_PATH.split("/")[:-1]).format(episode_chunk=ep_chunk)
(output_dir / chunk_dir).mkdir(parents=True, exist_ok=True)
for ep_idx in range(ep_chunk_start, ep_chunk_end):
ep_table = table.filter(pc.equal(table["episode_index"], ep_idx))
episode_lengths.insert(ep_idx, len(ep_table))
output_file = output_dir / DEFAULT_PARQUET_PATH.format(
episode_chunk=ep_chunk, episode_index=ep_idx
)
pq.write_table(ep_table, output_file)
return episode_lengths
def move_videos(
repo_id: str,
video_keys: list[str],
total_episodes: int,
total_chunks: int,
work_dir: Path,
clean_gittatributes: Path,
branch: str = "main",
) -> None:
"""
HACK: Since HfApi() doesn't provide a way to move files directly in a repo, this function will run git
commands to fetch git lfs video files references to move them into subdirectories without having to
actually download them.
"""
_lfs_clone(repo_id, work_dir, branch)
videos_moved = False
video_files = [str(f.relative_to(work_dir)) for f in work_dir.glob("videos*/*.mp4")]
if len(video_files) == 0:
video_files = [str(f.relative_to(work_dir)) for f in work_dir.glob("videos*/*/*/*.mp4")]
videos_moved = True # Videos have already been moved
assert len(video_files) == total_episodes * len(video_keys)
lfs_untracked_videos = _get_lfs_untracked_videos(work_dir, video_files)
current_gittatributes = work_dir / ".gitattributes"
if not filecmp.cmp(current_gittatributes, clean_gittatributes, shallow=False):
fix_gitattributes(work_dir, current_gittatributes, clean_gittatributes)
if lfs_untracked_videos:
fix_lfs_video_files_tracking(work_dir, video_files)
if videos_moved:
return
video_dirs = sorted(work_dir.glob("videos*/"))
for ep_chunk in range(total_chunks):
ep_chunk_start = DEFAULT_CHUNK_SIZE * ep_chunk
ep_chunk_end = min(DEFAULT_CHUNK_SIZE * (ep_chunk + 1), total_episodes)
for vid_key in video_keys:
chunk_dir = "/".join(DEFAULT_VIDEO_PATH.split("/")[:-1]).format(
episode_chunk=ep_chunk, video_key=vid_key
)
(work_dir / chunk_dir).mkdir(parents=True, exist_ok=True)
for ep_idx in range(ep_chunk_start, ep_chunk_end):
target_path = DEFAULT_VIDEO_PATH.format(
episode_chunk=ep_chunk, video_key=vid_key, episode_index=ep_idx
)
video_file = V1_VIDEO_FILE.format(video_key=vid_key, episode_index=ep_idx)
if len(video_dirs) == 1:
video_path = video_dirs[0] / video_file
else:
for dir in video_dirs:
if (dir / video_file).is_file():
video_path = dir / video_file
break
video_path.rename(work_dir / target_path)
commit_message = "Move video files into chunk subdirectories"
subprocess.run(["git", "add", "."], cwd=work_dir, check=True)
subprocess.run(["git", "commit", "-m", commit_message], cwd=work_dir, check=True)
subprocess.run(["git", "push"], cwd=work_dir, check=True)
def fix_lfs_video_files_tracking(work_dir: Path, lfs_untracked_videos: list[str]) -> None:
"""
HACK: This function fixes the tracking by git lfs which was not properly set on some repos. In that case,
there's no other option than to download the actual files and reupload them with lfs tracking.
"""
for i in range(0, len(lfs_untracked_videos), 100):
files = lfs_untracked_videos[i : i + 100]
try:
subprocess.run(["git", "rm", "--cached", *files], cwd=work_dir, capture_output=True, check=True)
except subprocess.CalledProcessError as e:
print("git rm --cached ERROR:")
print(e.stderr)
subprocess.run(["git", "add", *files], cwd=work_dir, check=True)
commit_message = "Track video files with git lfs"
subprocess.run(["git", "commit", "-m", commit_message], cwd=work_dir, check=True)
subprocess.run(["git", "push"], cwd=work_dir, check=True)
def fix_gitattributes(work_dir: Path, current_gittatributes: Path, clean_gittatributes: Path) -> None:
shutil.copyfile(clean_gittatributes, current_gittatributes)
subprocess.run(["git", "add", ".gitattributes"], cwd=work_dir, check=True)
subprocess.run(["git", "commit", "-m", "Fix .gitattributes"], cwd=work_dir, check=True)
subprocess.run(["git", "push"], cwd=work_dir, check=True)
def _lfs_clone(repo_id: str, work_dir: Path, branch: str) -> None:
subprocess.run(["git", "lfs", "install"], cwd=work_dir, check=True)
repo_url = f"https://huggingface.co/datasets/{repo_id}"
env = {"GIT_LFS_SKIP_SMUDGE": "1"} # Prevent downloading LFS files
subprocess.run(
["git", "clone", "--branch", branch, "--single-branch", "--depth", "1", repo_url, str(work_dir)],
check=True,
env=env,
)
def _get_lfs_untracked_videos(work_dir: Path, video_files: list[str]) -> list[str]:
lfs_tracked_files = subprocess.run(
["git", "lfs", "ls-files", "-n"], cwd=work_dir, capture_output=True, text=True, check=True
)
lfs_tracked_files = set(lfs_tracked_files.stdout.splitlines())
return [f for f in video_files if f not in lfs_tracked_files]
def get_videos_info(repo_id: str, local_dir: Path, video_keys: list[str], branch: str) -> dict:
# Assumes first episode
video_files = [
DEFAULT_VIDEO_PATH.format(episode_chunk=0, video_key=vid_key, episode_index=0)
for vid_key in video_keys
]
hub_api = HfApi()
hub_api.snapshot_download(
repo_id=repo_id, repo_type="dataset", local_dir=local_dir, revision=branch, allow_patterns=video_files
)
videos_info_dict = {}
for vid_key, vid_path in zip(video_keys, video_files, strict=True):
videos_info_dict[vid_key] = get_video_info(local_dir / vid_path)
return videos_info_dict
def convert_dataset(
repo_id: str,
local_dir: Path,
single_task: str | None = None,
tasks_path: Path | None = None,
tasks_col: Path | None = None,
robot_config: RobotConfig | None = None,
test_branch: str | None = None,
**card_kwargs,
):
v1 = get_safe_version(repo_id, V16)
v1x_dir = local_dir / V16 / repo_id
v20_dir = local_dir / V20 / repo_id
v1x_dir.mkdir(parents=True, exist_ok=True)
v20_dir.mkdir(parents=True, exist_ok=True)
hub_api = HfApi()
hub_api.snapshot_download(
repo_id=repo_id, repo_type="dataset", revision=v1, local_dir=v1x_dir, ignore_patterns="videos*/"
)
branch = "main"
if test_branch:
branch = test_branch
create_branch(repo_id=repo_id, branch=test_branch, repo_type="dataset")
metadata_v1 = load_json(v1x_dir / V1_INFO_PATH)
dataset = datasets.load_dataset("parquet", data_dir=v1x_dir / "data", split="train")
features = get_features_from_hf_dataset(dataset, robot_config)
video_keys = [key for key, ft in features.items() if ft["dtype"] == "video"]
if single_task and "language_instruction" in dataset.column_names:
logging.warning(
"'single_task' provided but 'language_instruction' tasks_col found. Using 'language_instruction'.",
)
single_task = None
tasks_col = "language_instruction"
# Episodes & chunks
episode_indices = sorted(dataset.unique("episode_index"))
total_episodes = len(episode_indices)
assert episode_indices == list(range(total_episodes))
total_videos = total_episodes * len(video_keys)
total_chunks = total_episodes // DEFAULT_CHUNK_SIZE
if total_episodes % DEFAULT_CHUNK_SIZE != 0:
total_chunks += 1
# Tasks
if single_task:
tasks_by_episodes = dict.fromkeys(episode_indices, single_task)
dataset, tasks = add_task_index_by_episodes(dataset, tasks_by_episodes)
tasks_by_episodes = {ep_idx: [task] for ep_idx, task in tasks_by_episodes.items()}
elif tasks_path:
tasks_by_episodes = load_json(tasks_path)
tasks_by_episodes = {int(ep_idx): task for ep_idx, task in tasks_by_episodes.items()}
dataset, tasks = add_task_index_by_episodes(dataset, tasks_by_episodes)
tasks_by_episodes = {ep_idx: [task] for ep_idx, task in tasks_by_episodes.items()}
elif tasks_col:
dataset, tasks, tasks_by_episodes = add_task_index_from_tasks_col(dataset, tasks_col)
else:
raise ValueError
assert set(tasks) == {task for ep_tasks in tasks_by_episodes.values() for task in ep_tasks}
tasks = [{"task_index": task_idx, "task": task} for task_idx, task in enumerate(tasks)]
write_jsonlines(tasks, v20_dir / TASKS_PATH)
features["task_index"] = {
"dtype": "int64",
"shape": (1,),
"names": None,
}
# Videos
if video_keys:
assert metadata_v1.get("video", False)
dataset = dataset.remove_columns(video_keys)
clean_gitattr = Path(
hub_api.hf_hub_download(
repo_id=GITATTRIBUTES_REF, repo_type="dataset", local_dir=local_dir, filename=".gitattributes"
)
).absolute()
with tempfile.TemporaryDirectory() as tmp_video_dir:
move_videos(
repo_id, video_keys, total_episodes, total_chunks, Path(tmp_video_dir), clean_gitattr, branch
)
videos_info = get_videos_info(repo_id, v1x_dir, video_keys=video_keys, branch=branch)
for key in video_keys:
features[key]["shape"] = (
videos_info[key].pop("video.height"),
videos_info[key].pop("video.width"),
videos_info[key].pop("video.channels"),
)
features[key]["video_info"] = videos_info[key]
assert math.isclose(videos_info[key]["video.fps"], metadata_v1["fps"], rel_tol=1e-3)
if "encoding" in metadata_v1:
assert videos_info[key]["video.pix_fmt"] == metadata_v1["encoding"]["pix_fmt"]
else:
assert metadata_v1.get("video", 0) == 0
videos_info = None
# Split data into 1 parquet file by episode
episode_lengths = split_parquet_by_episodes(dataset, total_episodes, total_chunks, v20_dir)
if robot_config is not None:
robot_type = robot_config.type
repo_tags = [robot_type]
else:
robot_type = "unknown"
repo_tags = None
# Episodes
episodes = [
{"episode_index": ep_idx, "tasks": tasks_by_episodes[ep_idx], "length": episode_lengths[ep_idx]}
for ep_idx in episode_indices
]
write_jsonlines(episodes, v20_dir / EPISODES_PATH)
# Assemble metadata v2.0
metadata_v2_0 = {
"codebase_version": V20,
"robot_type": robot_type,
"total_episodes": total_episodes,
"total_frames": len(dataset),
"total_tasks": len(tasks),
"total_videos": total_videos,
"total_chunks": total_chunks,
"chunks_size": DEFAULT_CHUNK_SIZE,
"fps": metadata_v1["fps"],
"splits": {"train": f"0:{total_episodes}"},
"data_path": DEFAULT_PARQUET_PATH,
"video_path": DEFAULT_VIDEO_PATH if video_keys else None,
"features": features,
}
write_json(metadata_v2_0, v20_dir / INFO_PATH)
convert_stats_to_json(v1x_dir, v20_dir)
card = create_lerobot_dataset_card(tags=repo_tags, dataset_info=metadata_v2_0, **card_kwargs)
with contextlib.suppress(EntryNotFoundError, HfHubHTTPError):
hub_api.delete_folder(repo_id=repo_id, path_in_repo="data", repo_type="dataset", revision=branch)
with contextlib.suppress(EntryNotFoundError, HfHubHTTPError):
hub_api.delete_folder(repo_id=repo_id, path_in_repo="meta_data", repo_type="dataset", revision=branch)
with contextlib.suppress(EntryNotFoundError, HfHubHTTPError):
hub_api.delete_folder(repo_id=repo_id, path_in_repo="meta", repo_type="dataset", revision=branch)
hub_api.upload_folder(
repo_id=repo_id,
path_in_repo="data",
folder_path=v20_dir / "data",
repo_type="dataset",
revision=branch,
)
hub_api.upload_folder(
repo_id=repo_id,
path_in_repo="meta",
folder_path=v20_dir / "meta",
repo_type="dataset",
revision=branch,
)
card.push_to_hub(repo_id=repo_id, repo_type="dataset", revision=branch)
if not test_branch:
create_branch(repo_id=repo_id, branch=V20, repo_type="dataset")
def make_robot_config(robot_type: str, **kwargs) -> RobotConfig:
if robot_type == "aloha":
raise NotImplementedError # TODO
elif robot_type == "koch_follower":
from lerobot.robots.koch_follower import KochFollowerConfig
return KochFollowerConfig(**kwargs)
elif robot_type == "so100_follower":
from lerobot.robots.so100_follower import SO100FollowerConfig
return SO100FollowerConfig(**kwargs)
elif robot_type == "stretch":
from lerobot.robots.stretch3 import Stretch3RobotConfig
return Stretch3RobotConfig(**kwargs)
elif robot_type == "lekiwi":
from lerobot.robots.lekiwi import LeKiwiConfig
return LeKiwiConfig(**kwargs)
else:
raise ValueError(f"Robot type '{robot_type}' is not available.")
def main():
parser = argparse.ArgumentParser()
task_args = parser.add_mutually_exclusive_group(required=True)
parser.add_argument(
"--repo-id",
type=str,
required=True,
help="Repository identifier on Hugging Face: a community or a user name `/` the name of the dataset (e.g. `lerobot/pusht`, `cadene/aloha_sim_insertion_human`).",
)
task_args.add_argument(
"--single-task",
type=str,
help="A short but accurate description of the single task performed in the dataset.",
)
task_args.add_argument(
"--tasks-col",
type=str,
help="The name of the column containing language instructions",
)
task_args.add_argument(
"--tasks-path",
type=Path,
help="The path to a .json file containing one language instruction for each episode_index",
)
parser.add_argument(
"--robot",
type=str,
default=None,
help="Robot config used for the dataset during conversion (e.g. 'koch', 'aloha', 'so100', etc.)",
)
parser.add_argument(
"--local-dir",
type=Path,
default=None,
help="Local directory to store the dataset during conversion. Defaults to /tmp/lerobot_dataset_v2",
)
parser.add_argument(
"--license",
type=str,
default="apache-2.0",
help="Repo license. Must be one of https://huggingface.co/docs/hub/repositories-licenses. Defaults to mit.",
)
parser.add_argument(
"--test-branch",
type=str,
default=None,
help="Repo branch to test your conversion first (e.g. 'v2.0.test')",
)
args = parser.parse_args()
if not args.local_dir:
args.local_dir = Path("/tmp/lerobot_dataset_v2")
if args.robot is not None:
robot_config = make_robot_config(args.robot)
del args.robot
convert_dataset(**vars(args), robot_config=robot_config)
if __name__ == "__main__":
main()
src/lerobot/datasets/v21/_remove_language_instruction.py
+87
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@@ -0,0 +1,87 @@
# 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 logging
import traceback
from pathlib import Path
from datasets import get_dataset_config_info
from huggingface_hub import HfApi
from lerobot import available_datasets
from lerobot.datasets.lerobot_dataset import LeRobotDatasetMetadata
from lerobot.datasets.utils import INFO_PATH, write_info
from lerobot.datasets.v21.convert_dataset_v20_to_v21 import V20, SuppressWarnings
LOCAL_DIR = Path("data/")
hub_api = HfApi()
def fix_dataset(repo_id: str) -> str:
if not hub_api.revision_exists(repo_id, V20, repo_type="dataset"):
return f"{repo_id}: skipped (not in {V20})."
dataset_info = get_dataset_config_info(repo_id, "default")
with SuppressWarnings():
lerobot_metadata = LeRobotDatasetMetadata(repo_id, revision=V20, force_cache_sync=True)
meta_features = {key for key, ft in lerobot_metadata.features.items() if ft["dtype"] != "video"}
parquet_features = set(dataset_info.features)
diff_parquet_meta = parquet_features - meta_features
diff_meta_parquet = meta_features - parquet_features
if diff_parquet_meta:
raise ValueError(f"In parquet not in info.json: {parquet_features - meta_features}")
if not diff_meta_parquet:
return f"{repo_id}: skipped (no diff)"
if diff_meta_parquet:
logging.warning(f"In info.json not in parquet: {meta_features - parquet_features}")
assert diff_meta_parquet == {"language_instruction"}
lerobot_metadata.features.pop("language_instruction")
write_info(lerobot_metadata.info, lerobot_metadata.root)
commit_info = hub_api.upload_file(
path_or_fileobj=lerobot_metadata.root / INFO_PATH,
path_in_repo=INFO_PATH,
repo_id=repo_id,
repo_type="dataset",
revision=V20,
commit_message="Remove 'language_instruction'",
create_pr=True,
)
return f"{repo_id}: success - PR: {commit_info.pr_url}"
def batch_fix():
status = {}
LOCAL_DIR.mkdir(parents=True, exist_ok=True)
logfile = LOCAL_DIR / "fix_features_v20.txt"
for num, repo_id in enumerate(available_datasets):
print(f"\nConverting {repo_id} ({num}/{len(available_datasets)})")
print("---------------------------------------------------------")
try:
status = fix_dataset(repo_id)
except Exception:
status = f"{repo_id}: failed\n {traceback.format_exc()}"
logging.info(status)
with open(logfile, "a") as file:
file.write(status + "\n")
if __name__ == "__main__":
batch_fix()
src/lerobot/datasets/v21/batch_convert_dataset_v20_to_v21.py
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#!/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.
"""
This script is for internal use to convert all datasets under the 'lerobot' hub user account to v2.1.
"""
import traceback
from pathlib import Path
from huggingface_hub import HfApi
from lerobot import available_datasets
from lerobot.datasets.v21.convert_dataset_v20_to_v21 import V21, convert_dataset
LOCAL_DIR = Path("data/")
def batch_convert():
status = {}
LOCAL_DIR.mkdir(parents=True, exist_ok=True)
logfile = LOCAL_DIR / "conversion_log_v21.txt"
hub_api = HfApi()
for num, repo_id in enumerate(available_datasets):
print(f"\nConverting {repo_id} ({num}/{len(available_datasets)})")
print("---------------------------------------------------------")
try:
if hub_api.revision_exists(repo_id, V21, repo_type="dataset"):
status = f"{repo_id}: success (already in {V21})."
else:
convert_dataset(repo_id)
status = f"{repo_id}: success."
except Exception:
status = f"{repo_id}: failed\n {traceback.format_exc()}"
with open(logfile, "a") as file:
file.write(status + "\n")
if __name__ == "__main__":
batch_convert()
src/lerobot/datasets/v21/convert_dataset_v20_to_v21.py
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# 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.
"""
This script will help you convert any LeRobot dataset already pushed to the hub from codebase version 2.0 to
2.1. It will:
- Generate per-episodes stats and writes them in `episodes_stats.jsonl`
- Check consistency between these new stats and the old ones.
- Remove the deprecated `stats.json`.
- Update codebase_version in `info.json`.
- Push this new version to the hub on the 'main' branch and tags it with "v2.1".
Usage:
```bash
python -m lerobot.datasets.v21.convert_dataset_v20_to_v21 \
--repo-id=aliberts/koch_tutorial
```
"""
import argparse
import logging
from huggingface_hub import HfApi
from lerobot.datasets.lerobot_dataset import CODEBASE_VERSION, LeRobotDataset
from lerobot.datasets.utils import EPISODES_STATS_PATH, STATS_PATH, load_stats, write_info
from lerobot.datasets.v21.convert_stats import check_aggregate_stats, convert_stats
V20 = "v2.0"
V21 = "v2.1"
class SuppressWarnings:
def __enter__(self):
self.previous_level = logging.getLogger().getEffectiveLevel()
logging.getLogger().setLevel(logging.ERROR)
def __exit__(self, exc_type, exc_val, exc_tb):
logging.getLogger().setLevel(self.previous_level)
def convert_dataset(
repo_id: str,
branch: str | None = None,
num_workers: int = 4,
):
with SuppressWarnings():
dataset = LeRobotDataset(repo_id, revision=V20, force_cache_sync=True)
if (dataset.root / EPISODES_STATS_PATH).is_file():
(dataset.root / EPISODES_STATS_PATH).unlink()
convert_stats(dataset, num_workers=num_workers)
ref_stats = load_stats(dataset.root)
check_aggregate_stats(dataset, ref_stats)
dataset.meta.info["codebase_version"] = CODEBASE_VERSION
write_info(dataset.meta.info, dataset.root)
dataset.push_to_hub(branch=branch, tag_version=False, allow_patterns="meta/")
# delete old stats.json file
if (dataset.root / STATS_PATH).is_file:
(dataset.root / STATS_PATH).unlink()
hub_api = HfApi()
if hub_api.file_exists(
repo_id=dataset.repo_id, filename=STATS_PATH, revision=branch, repo_type="dataset"
):
hub_api.delete_file(
path_in_repo=STATS_PATH, repo_id=dataset.repo_id, revision=branch, repo_type="dataset"
)
hub_api.create_tag(repo_id, tag=CODEBASE_VERSION, revision=branch, repo_type="dataset")
if __name__ == "__main__":
parser = argparse.ArgumentParser()
parser.add_argument(
"--repo-id",
type=str,
required=True,
help="Repository identifier on Hugging Face: a community or a user name `/` the name of the dataset "
"(e.g. `lerobot/pusht`, `cadene/aloha_sim_insertion_human`).",
)
parser.add_argument(
"--branch",
type=str,
default=None,
help="Repo branch to push your dataset. Defaults to the main branch.",
)
parser.add_argument(
"--num-workers",
type=int,
default=4,
help="Number of workers for parallelizing stats compute. Defaults to 4.",
)
args = parser.parse_args()
convert_dataset(**vars(args))
src/lerobot/datasets/v21/convert_stats.py
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# 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 concurrent.futures import ThreadPoolExecutor, as_completed
import numpy as np
from tqdm import tqdm
from lerobot.datasets.compute_stats import aggregate_stats, get_feature_stats, sample_indices
from lerobot.datasets.lerobot_dataset import LeRobotDataset
from lerobot.datasets.utils import write_episode_stats
def sample_episode_video_frames(dataset: LeRobotDataset, episode_index: int, ft_key: str) -> np.ndarray:
ep_len = dataset.meta.episodes[episode_index]["length"]
sampled_indices = sample_indices(ep_len)
query_timestamps = dataset._get_query_timestamps(0.0, {ft_key: sampled_indices})
video_frames = dataset._query_videos(query_timestamps, episode_index)
return video_frames[ft_key].numpy()
def convert_episode_stats(dataset: LeRobotDataset, ep_idx: int):
ep_start_idx = dataset.episode_data_index["from"][ep_idx]
ep_end_idx = dataset.episode_data_index["to"][ep_idx]
ep_data = dataset.hf_dataset.select(range(ep_start_idx, ep_end_idx))
ep_stats = {}
for key, ft in dataset.features.items():
if ft["dtype"] == "video":
# We sample only for videos
ep_ft_data = sample_episode_video_frames(dataset, ep_idx, key)
else:
ep_ft_data = np.array(ep_data[key])
axes_to_reduce = (0, 2, 3) if ft["dtype"] in ["image", "video"] else 0
keepdims = True if ft["dtype"] in ["image", "video"] else ep_ft_data.ndim == 1
ep_stats[key] = get_feature_stats(ep_ft_data, axis=axes_to_reduce, keepdims=keepdims)
if ft["dtype"] in ["image", "video"]: # remove batch dim
ep_stats[key] = {
k: v if k == "count" else np.squeeze(v, axis=0) for k, v in ep_stats[key].items()
}
dataset.meta.episodes_stats[ep_idx] = ep_stats
def convert_stats(dataset: LeRobotDataset, num_workers: int = 0):
assert dataset.episodes is None
print("Computing episodes stats")
total_episodes = dataset.meta.total_episodes
if num_workers > 0:
with ThreadPoolExecutor(max_workers=num_workers) as executor:
futures = {
executor.submit(convert_episode_stats, dataset, ep_idx): ep_idx
for ep_idx in range(total_episodes)
}
for future in tqdm(as_completed(futures), total=total_episodes):
future.result()
else:
for ep_idx in tqdm(range(total_episodes)):
convert_episode_stats(dataset, ep_idx)
for ep_idx in tqdm(range(total_episodes)):
write_episode_stats(ep_idx, dataset.meta.episodes_stats[ep_idx], dataset.root)
def check_aggregate_stats(
dataset: LeRobotDataset,
reference_stats: dict[str, dict[str, np.ndarray]],
video_rtol_atol: tuple[float] = (1e-2, 1e-2),
default_rtol_atol: tuple[float] = (5e-6, 6e-5),
):
"""Verifies that the aggregated stats from episodes_stats are close to reference stats."""
agg_stats = aggregate_stats(list(dataset.meta.episodes_stats.values()))
for key, ft in dataset.features.items():
# These values might need some fine-tuning
if ft["dtype"] == "video":
# to account for image sub-sampling
rtol, atol = video_rtol_atol
else:
rtol, atol = default_rtol_atol
for stat, val in agg_stats[key].items():
if key in reference_stats and stat in reference_stats[key]:
err_msg = f"feature='{key}' stats='{stat}'"
np.testing.assert_allclose(
val, reference_stats[key][stat], rtol=rtol, atol=atol, err_msg=err_msg
)

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