lerobot/docs/source/vlabench.mdx

# VLABench

[VLABench](https://github.com/OpenMOSS/VLABench) is a large-scale benchmark for **language-conditioned robotic manipulation with long-horizon reasoning**. The upstream suite covers 100 task categories across 2,000+ objects and evaluates six dimensions of robot intelligence: mesh & texture understanding, spatial reasoning, world-knowledge transfer, semantic instruction comprehension, physical-law understanding, and long-horizon planning. Built on MuJoCo / dm_control with a Franka Panda 7-DOF arm. LeRobot exposes **43 of these tasks** through `--env.task` (21 primitives + 22 composites, see [Available tasks](#available-tasks) below).

- Paper: [VLABench: A Large-Scale Benchmark for Language-Conditioned Robotics Manipulation with Long-Horizon Reasoning](https://arxiv.org/abs/2412.18194)
- GitHub: [OpenMOSS/VLABench](https://github.com/OpenMOSS/VLABench)
- Project website: [vlabench.github.io](https://vlabench.github.io)
- Pretrained policy: [`lerobot/smolvla_vlabench`](https://huggingface.co/lerobot/smolvla_vlabench)

<img
  src="https://huggingface.co/datasets/huggingface/documentation-images/resolve/main/lerobot/vlabench.png"
  alt="VLABench benchmark overview"
  width="85%"
/>

## Available tasks

VLABench ships two task suites covering **43 task categories** in LeRobot's `--env.task` surface:

| Suite     | CLI name    | Tasks | Description                                                      |
| --------- | ----------- | ----- | ---------------------------------------------------------------- |
| Primitive | `primitive` | 21    | Single / few-skill combinations (select, insert, physics QA)     |
| Composite | `composite` | 22    | Multi-step reasoning and long-horizon planning (cook, rearrange) |

**Primitive tasks:** `select_fruit`, `select_toy`, `select_chemistry_tube`, `add_condiment`, `select_book`, `select_painting`, `select_drink`, `insert_flower`, `select_billiards`, `select_ingredient`, `select_mahjong`, `select_poker`, and physical-reasoning tasks (`density_qa`, `friction_qa`, `magnetism_qa`, `reflection_qa`, `simple_cuestick_usage`, `simple_seesaw_usage`, `sound_speed_qa`, `thermal_expansion_qa`, `weight_qa`).

**Composite tasks:** `cluster_billiards`, `cluster_book`, `cluster_drink`, `cluster_toy`, `cook_dishes`, `cool_drink`, `find_unseen_object`, `get_coffee`, `hammer_nail`, `heat_food`, `make_juice`, `play_mahjong`, `play_math_game`, `play_poker`, `play_snooker`, `rearrange_book`, `rearrange_chemistry_tube`, `set_dining_table`, `set_study_table`, `store_food`, `take_chemistry_experiment`, `use_seesaw_complex`.

`--env.task` accepts three forms:

- a single task name (`select_fruit`)
- a comma-separated list (`select_fruit,heat_food`)
- a suite shortcut (`primitive`, `composite`, or `primitive,composite`)

## Installation

VLABench is **not on PyPI** — its only distribution is the [OpenMOSS/VLABench](https://github.com/OpenMOSS/VLABench) GitHub repo — so LeRobot does not expose a `vlabench` extra. Install it manually as an editable clone, alongside the MuJoCo / dm_control pins VLABench needs, then fetch the mesh assets:

```bash
# After following the standard LeRobot installation instructions.

git clone https://github.com/OpenMOSS/VLABench.git ~/VLABench
git clone https://github.com/motion-planning/rrt-algorithms.git ~/rrt-algorithms
pip install -e ~/VLABench -e ~/rrt-algorithms
pip install "mujoco==3.2.2" "dm-control==1.0.22" \
            open3d colorlog scikit-learn openai gdown

python ~/VLABench/scripts/download_assets.py
```

<Tip>
VLABench requires Linux (`sys_platform == 'linux'`) and Python 3.10+. Set the MuJoCo rendering backend before running:

```bash
export MUJOCO_GL=egl  # for headless servers (HPC, cloud)
```

</Tip>

## Evaluation

All eval snippets below mirror the command CI runs (see `.github/workflows/benchmark_tests.yml`). The `--rename_map` argument maps VLABench's `image` / `second_image` / `wrist_image` camera keys onto the three-camera (`camera1` / `camera2` / `camera3`) input layout the released `smolvla_vlabench` policy was trained on.

### Single-task evaluation (recommended for quick iteration)

```bash
lerobot-eval \
  --policy.path=lerobot/smolvla_vlabench \
  --env.type=vlabench \
  --env.task=select_fruit \
  --eval.batch_size=1 \
  --eval.n_episodes=10 \
  --eval.use_async_envs=false \
  --policy.device=cuda \
  '--rename_map={"observation.images.image": "observation.images.camera1", "observation.images.second_image": "observation.images.camera2", "observation.images.wrist_image": "observation.images.camera3"}'
```

### Multi-task evaluation

Pass a comma-separated list of tasks:

```bash
lerobot-eval \
  --policy.path=lerobot/smolvla_vlabench \
  --env.type=vlabench \
  --env.task=select_fruit,select_toy,add_condiment,heat_food \
  --eval.batch_size=1 \
  --eval.n_episodes=10 \
  --eval.use_async_envs=false \
  --policy.device=cuda \
  '--rename_map={"observation.images.image": "observation.images.camera1", "observation.images.second_image": "observation.images.camera2", "observation.images.wrist_image": "observation.images.camera3"}'
```

### Suite-wide evaluation

Run an entire suite (all 21 primitives or all 22 composites):

```bash
lerobot-eval \
  --policy.path=lerobot/smolvla_vlabench \
  --env.type=vlabench \
  --env.task=primitive \
  --eval.batch_size=1 \
  --eval.n_episodes=10 \
  --eval.use_async_envs=false \
  --policy.device=cuda \
  --env.max_parallel_tasks=1 \
  '--rename_map={"observation.images.image": "observation.images.camera1", "observation.images.second_image": "observation.images.camera2", "observation.images.wrist_image": "observation.images.camera3"}'
```

Or both suites:

```bash
lerobot-eval \
  --policy.path=lerobot/smolvla_vlabench \
  --env.type=vlabench \
  --env.task=primitive,composite \
  --eval.batch_size=1 \
  --eval.n_episodes=10 \
  --eval.use_async_envs=false \
  --policy.device=cuda \
  --env.max_parallel_tasks=1 \
  '--rename_map={"observation.images.image": "observation.images.camera1", "observation.images.second_image": "observation.images.camera2", "observation.images.wrist_image": "observation.images.camera3"}'
```

### Recommended evaluation episodes

**10 episodes per task** for reproducible benchmarking (210 total for the full primitive suite, 220 for composite). Matches the protocol in the VLABench paper.

## Policy inputs and outputs

**Observations:**

- `observation.state` — 7-dim end-effector state (position xyz + Euler xyz + gripper)
- `observation.images.image` — front camera, 480×480 HWC uint8
- `observation.images.second_image` — second camera, 480×480 HWC uint8
- `observation.images.wrist_image` — wrist camera, 480×480 HWC uint8

**Actions:**

- Continuous control in `Box(-1, 1, shape=(7,))` — 3D position + 3D Euler orientation + 1D gripper.

## Training

### Datasets

Pre-collected VLABench datasets in LeRobot format on the Hub:

- [`VLABench/vlabench_primitive_ft_lerobot_video`](https://huggingface.co/datasets/VLABench/vlabench_primitive_ft_lerobot_video) — 5,000 episodes, 128 tasks, 480×480 images.
- [`VLABench/vlabench_composite_ft_lerobot_video`](https://huggingface.co/datasets/VLABench/vlabench_composite_ft_lerobot_video) — 5,977 episodes, 167 tasks, 224×224 images.

### Example training command

Fine-tune a SmolVLA base on the primitive suite:

```bash
lerobot-train \
  --policy.type=smolvla \
  --policy.repo_id=${HF_USER}/smolvla_vlabench_primitive \
  --policy.load_vlm_weights=true \
  --policy.push_to_hub=true \
  --dataset.repo_id=VLABench/vlabench_primitive_ft_lerobot_video \
  --env.type=vlabench \
  --env.task=select_fruit \
  --output_dir=./outputs/smolvla_vlabench_primitive \
  --steps=100000 \
  --batch_size=4 \
  --env_eval_freq=5000 \
  --eval.batch_size=1 \
  --eval.n_episodes=1 \
  --save_freq=10000
```

## Reproducing published results

The released checkpoint [`lerobot/smolvla_vlabench`](https://huggingface.co/lerobot/smolvla_vlabench) was trained on the primitive-suite dataset above and is evaluated with the [Single-task](#single-task-evaluation-recommended-for-quick-iteration) / [Suite-wide](#suite-wide-evaluation) commands. CI runs a 10-primitive-task smoke eval (one episode each) on every PR touching the benchmark.